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Please check the errata for any errors or issues reported since publication.
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This specification defines the syntax and semantics of XSLT 3.0, a language designed primarily for transforming XML documents into other XML documents.
XSLT 3.0 is a revised version of the XSLT 2.0 Recommendation [XSLT 2.0] published on 23 January 2007.
The primary purpose of the changes in this version of the language is to enable transformations to be performed in streaming mode, where neither the source document nor the result document is ever held in memory in its entirety. Another important aim is to improve the modularity of large stylesheets, allowing stylesheets to be developed from independently-developed components with a high level of software engineering robustness.
XSLT 3.0 is designed to be used in conjunction with XPath 3.0, which is defined in [XPath 3.0]. XSLT shares the same data model as XPath 3.0, which is defined in [XDM 3.0], and it uses the library of functions and operators defined in [Functions and Operators 3.0]. XPath 3.0 and the underlying function library introduce a number of enhancements, for example the availability of higher-order functions.
As an implementer option, XSLT 3.0 can also be used with XPath 3.1. All XSLT 3.0 processors
provide maps, an addition to the data model which is specified (identically) in both
XSLT 3.0
and XPath 3.1. Other features from XPath 3.1, such as arrays, and new functions such
as random-number-generator
FO31 and sort
FO31, are available in XSLT 3.0
stylesheets only if the implementer chooses to support XPath 3.1.
Some of the functions that were previously defined in the XSLT 2.0 specification, such as the
format-date
FO30 and format-number
FO30
functions, are now defined in the standard function library to make them available
to
other host languages.
XSLT 3.0 also includes optional facilities to serialize the results of a transformation, by means of an interface to the serialization component described in [XSLT and XQuery Serialization]. Again, the new serialization capabilities of [XSLT and XQuery Serialization 3.1] are available at the implementer’s option.
This document contains hyperlinks to specific sections or definitions within other documents in this family of specifications. These links are indicated visually by a superscript identifying the target specification: for example XP30 for XPath 3.0, DM30 for the XDM data model version 3.0, FO30 for Functions and Operators version 3.0.
This section describes the status of this document at the time of its publication. Other documents may supersede this document. A list of current W3C publications and the latest revision of this technical report can be found in the W3C technical reports index at https://www.w3.org/TR/.
This document is governed by the 1 March 2017 W3C Process Document.
This is a Recommendation of the W3C. It was developed by the W3C XSLT Working Group.
This Recommendation specifies XSLT version 3.0. Changes since XSLT 2.0 are listed in J Changes since XSLT 2.0. The only incompatibilities with XSLT 2.0 relate to the way in which certain error conditions are handled: the details are given in N Incompatibilities with XSLT 2.0.
No substantive changes have been made to this specification since its publication as a Proposed Recommendation. A few corrections and clarifications have been made to non-normative text: these are listed in M Changes since the Proposed Recommendation of 18 April 2017.
This document has been reviewed by W3C Members, by software developers, and by other W3C groups and interested parties, and is endorsed by the Director as a W3C Recommendation. It is a stable document and may be used as reference material or cited from another document. W3C's role in making the Recommendation is to draw attention to the specification and to promote its widespread deployment. This enhances the functionality and interoperability of the Web.
A test suite for XSLT 3.0, containing over 11,000 test cases, is available at https://dvcs.w3.org/hg/xslt30-test/. The metadata for each test case describes any dependencies on optional or implementation-defined features of the specification, and provides expected results for each test. Documentation on how to run tests is available within the test suite. New tests may be added from time to time, and contributions are welcome.
An implementation report is available detailing test results for various implementations. This link points to the latest version of the report; older versions are available within the repository. New submissions of test results are welcome. Submitted test results and a stylesheet for generating the reports can be found within the repository.
This specification has been developed in conjunction with [XPath 3.0] and other documents that underpin both XSLT and XQuery. XSLT 3.0 requires support for XPath 3.0 augmented by a selection of features from XPath 3.1 which are described in 21 Maps and 22 Processing JSON Data. XSLT 3.0 in addition allows a processor to support the whole of XPath 3.1, in which case it must do so as described in 27.7 XPath 3.1 Feature. In the event that future versions of XPath are defined beyond XPath 3.1, this specification allows XSLT 3.0 processors to provide support for such versions, but leaves it implementation-defined how this is done. References in this document to XPath and related specifications are by default to the 3.0 versions, but such references should be treated as version-agnostic unless the relevant prose indicates otherwise.
XSLT 3.0 specifies extensions to the XDM 3.0 data model, to the XPath 3.0 language syntax, and to the XPath 3.0 function library to underpin the introduction of maps, which were found necessary to support some XSLT streaming use cases, to enable XSLT to process JSON data, and to make many other processing tasks easier. These extensions have been incorporated into XDM 3.1 and XPath 3.1. Although XDM 3.1 and XPath 3.1 have reached Recommendation status, XSLT 3.0 has not been made dependent on XPath 3.1, other than those features needed to meet the XSLT 3.0 requirements.
Please report errors in this document using W3C’s public Bugzilla system (instructions can be found at https://www.w3.org/XML/2005/04/qt-bugzilla). If access to that system is not feasible, you may send your comments to the W3C XSLT/XPath/XQuery public comments mailing list, public-qt-comments@w3.org. It will be very helpful if you include the string “[XSLT30]” in the subject line of your report, whether made in Bugzilla or in email. Please use multiple Bugzilla entries (or, if necessary, multiple email messages) if you have more than one comment to make. Archives of the comments and responses are available at https://lists.w3.org/Archives/Public/public-qt-comments/.
The same mechanism may be used for reporting errors in the test suite.
This document was produced by a group operating under the 5 February 2004 W3C Patent Policy. W3C maintains a public list of any patent disclosures made in connection with the deliverables of the group; that page also includes instructions for disclosing a patent. An individual who has actual knowledge of a patent which the individual believes contains Essential Claim(s) must disclose the information in accordance with section 6 of the W3C Patent Policy.
This specification defines the syntax and semantics of the XSLT 3.0 language.
A transformation in the XSLT language is expressed in the form of a stylesheet. A stylesheet is made up of one or more well-formed XML [XML 1.0] documents conforming to the Namespaces in XML Recommendation [Namespaces in XML].
A stylesheet generally includes elements that are defined by XSLT as well as elements
that are not defined by XSLT. XSLT-defined elements are distinguished by use of the
namespace http://www.w3.org/1999/XSL/Transform
(see 3.1 XSLT Namespace), which is referred to in this specification as the
XSLT namespace. Thus this specification
is a definition of the syntax and semantics of the XSLT namespace.
The term stylesheet reflects the fact that one of the important roles of XSLT is to add styling information to an XML source document, by transforming it into a document consisting of XSL formatting objects (see [XSL-FO]), or into another presentation-oriented format such as HTML, XHTML, or SVG. However, XSLT is used for a wide range of transformation tasks, not exclusively for formatting and presentation applications.
A transformation expressed in XSLT describes rules for transforming input data into output data. The inputs and outputs will all be instances of the XDM data model, described in [XDM 3.0]. In the simplest and most common case, the input is an XML document referred to as the source tree, and the output is an XML document referred to as the result tree. It is also possible to process multiple source documents, to generate multiple result documents, and to handle formats other than XML. The transformation is achieved by a set of template rules. A template rule associates a pattern, which typically matches nodes in the source document, with a sequence constructor. In many cases, evaluating the sequence constructor will cause new nodes to be constructed, which can be used to produce part of a result tree. The structure of the result trees can be completely different from the structure of the source trees. In constructing a result tree, nodes from the source trees can be filtered and reordered, and arbitrary structure can be added. This mechanism allows a stylesheet to be applicable to a wide class of documents that have similar source tree structures.
Stylesheets have a modular structure; they may contain several packages developed independently of each other, and each package may consist of several stylesheet modules.
[Definition: A stylesheet consists of one or more packages: specifically, one top-level package and zero or more library packages.]
[Definition: For a given transformation, one package functions as the top-level package. The
complete stylesheet is assembled by finding
the packages referenced directly or indirectly from the top-level package using
xsl:use-package
declarations: see 3.5.2 Dependencies between Packages.]
[Definition: Every package within a stylesheet, other than the top-level package, is referred to as a library package.]
[Definition: Within a package, one stylesheet module functions as the
principal stylesheet module. The complete package is assembled by
finding the stylesheet modules referenced directly or indirectly from the
principal stylesheet module using xsl:include
and
xsl:import
elements: see 3.11.2 Stylesheet Inclusion and 3.11.3 Stylesheet Import.]
A major focus for enhancements in XSLT 3.0 is the requirement to enable streaming of source documents. This is needed when source documents become too large to hold in main memory, and also for applications where it is important to start delivering results before the entire source document is available.
While implementations of XSLT that use streaming have always been theoretically possible, the nature of the language has made it very difficult to achieve this in practice. The approach adopted in this specification is twofold: it identifies a set of restrictions which, if followed by stylesheet authors, will enable implementations to adopt a streaming mode of operation without placing excessive demands on the optimization capabilities of the processor; and it provides new constructs to indicate that streaming is required, or to express transformations in a way that makes it easier for the processor to adopt a streaming execution plan.
Capabilities provided in this category include:
A new xsl:source-document
instruction, which reads and processes a
source document, optionally in streaming mode;
The ability to declare that a mode is a streaming mode, in which case all the template rules using that mode must be streamable;
A new xsl:iterate
instruction, which iterates over the items
in a sequence, allowing parameters for the processing of one item to be set
during the processing of the previous item;
A new xsl:merge
instruction, allowing multiple input streams
to be merged into a single output stream;
A new xsl:fork
instruction, allowing multiple computations to
be performed in parallel during a single pass through an input document;
Accumulators, which allow a value to be computed progressively during streamed processing of a document, and accessed as a function of a node in the document, without compromise to the functional nature of the XSLT language.
A second focus for enhancements in XSLT 3.0 is the introduction of a new mechanism for stylesheet modularity, called the package. Unlike the stylesheet modules of XSLT 1.0 and 2.0 (which remain available), a package defines an interface that regulates which functions, variables, templates and other components are visible outside the package, and which can be overridden. There are two main goals for this facility: it is designed to deliver software engineering benefits by improving the reusability and maintainability of code, and it is intended to streamline stylesheet deployment by allowing packages to be compiled independently of each other, and compiled instances of packages to be shared between multiple applications.
Other significant features in XSLT 3.0 include:
An xsl:evaluate
instruction allowing evaluation of XPath
expressions that are dynamically constructed as strings, or that are read from
a source document;
Enhancements to the syntax of patterns, in particular enabling the matching of atomic values as well as nodes;
An xsl:try
instruction to allow recovery from dynamic
errors;
The element xsl:global-context-item
, used to declare the
stylesheet’s expectations of the global context item (notably, its
type);
A new instruction xsl:assert
to assist developers in producing
correct and robust code.
XSLT 3.0 also delivers enhancements made to the XPath language and to the standard function library, including the following:
Variables can now be bound in XPath using the let
expression.
Functions are now first class values, and can be passed as arguments to other (higher-order) functions, making XSLT a fully-fledged functional programming language.
A number of new functions are available, for example trigonometric functions,
and the functions parse-xml
FO30 and
serialize
FO30 to convert between lexical and tree
representations of XML.
XSLT 3.0 also includes support for maps (a data structure consisting of key/value pairs, sometimes referred to in other programming languages as dictionaries, hashes, or associative arrays). This feature extends the data model, provides new syntax in XPath, and adds a number of new functions and operators. Initially developed as XSLT-specific extensions, maps have now been integrated into XPath 3.1 (see [XPath 3.1]). XSLT 3.0 does not require implementations to support XPath 3.1 in its entirety, but it does requires support for these specific features.
A full list of changes is at J Changes since XSLT 2.0.
For a full glossary of terms, see C Glossary.
[Definition: The software responsible for transforming source trees into result trees using an XSLT stylesheet is referred to as the processor. This is sometimes expanded to XSLT processor to avoid any confusion with other processors, for example an XML processor.]
[Definition: A specific product that performs the functions of an XSLT processor is referred to as an implementation.]
[Definition: The term tree is used (as in [XDM 3.0]) to refer to the aggregate consisting of a parentless node together with all its descendant nodes, plus all their attributes and namespaces.]
Note:
The use of the term tree in this document does not imply the use of a data structure in memory that holds the entire contents of the document at one time. It implies rather a logical view of the XML input and output in which elements have a hierarchic relationship to each other. When a source document is being processed in a streaming manner, access to the nodes in this tree is constrained, but it is still viewed and described as a tree.
The output of a transformation consists of the following:
[Definition: A principal result: this can be any sequence of items (as defined in [XDM 3.0]).] The principal result is the value returned by the function or template in the stylesheet that is nominated as the entry point, as described in 2.3 Initiating a Transformation.
[Definition: Zero or more
secondary results: each secondary result can be any sequence
of items (as defined in [XDM 3.0]).] A
secondary result is the value returned by evaluating the body of an
xsl:result-document
instruction.
Zero or more messages. Messages are generated by the
xsl:message
and xsl:assert
instructions, and are described in 23.1 Messages and 23.2 Assertions.
Static or dynamic errors: see 2.14 Error Handling.
The principal result and the secondary results may be post-processed as described in 2.3.6 Post-processing the Raw Result.
[Definition: The term result tree is used to refer to any tree constructed by instructions in the stylesheet. A result tree is either a final result tree or a temporary tree.]
[Definition: A final result tree is a result tree that forms part of the output of a transformation: specifically, a tree built by post-processing the items in the principal result or in a secondary result. Once created, the contents of a final result tree are not accessible within the stylesheet itself.] Any final result tree may be serialized as described in 26 Serialization.
[Definition: The term source tree
means any tree provided as input to the transformation. This includes the document
containing the global context item if any, documents containing
nodes present in the initial match selection,
documents containing nodes supplied as the values of stylesheet parameters, documents
obtained from the results of functions such as document
,
doc
FO30, and collection
FO30, documents read using the xsl:source-document
instruction, and documents returned by extension functions or
extension instructions. In the context of a particular XSLT instruction, the term
source tree means any tree provided as input to that instruction;
this may be a source tree of the transformation as a whole, or it may be a
temporary tree produced during the
course of the transformation.]
[Definition: The term temporary tree means any tree that is neither a source tree nor a final result tree.] Temporary trees are used to hold intermediate results during the execution of the transformation.
The use of the term “tree” in phrases such as source tree, result tree, and temporary tree is not confined to documents that the processor materializes in memory in their entirety. The processor may, and in some cases must, use streaming techniques to limit the amount of memory used to hold source and result documents. When streaming is used, the nodes of the tree may never all be in memory at the same time, but at an abstract level the information is still modeled as a tree of nodes, and the document is therefore still described as a tree. Unless otherwise stated, the term “tree” refers to a tree rooted at a parentless node: that is, the term does not include subtrees of larger trees. Every node therefore belongs to exactly one tree.
In this specification the phrases must, must not, should, should not, may, required, and recommended, when used in normative text and rendered in capitals, are to be interpreted as described in [RFC2119].
Where the phrase must, must not, or required relates to the behavior of the XSLT processor, then an implementation is not conformant unless it behaves as specified, subject to the more detailed rules in 27 Conformance.
Where the phrase must, must not, or required relates to a stylesheet then the processor must enforce this constraint on stylesheets by reporting an error if the constraint is not satisfied.
Where the phrase should, should not, or recommended relates to a stylesheet then a processor may produce warning messages if the constraint is not satisfied, but must not treat this as an error.
[Definition: In this specification, the term implementation-defined refers to a feature where the implementation is allowed some flexibility, and where the choices made by the implementation must be described in documentation that accompanies any conformance claim.]
[Definition: The term implementation-dependent refers to a feature where the behavior may vary from one implementation to another, and where the vendor is not expected to provide a full specification of the behavior.] (This might apply, for example, to limits on the size of source documents that can be transformed.)
In all cases where this specification leaves the behavior implementation-defined or implementation-dependent, the implementation has the option of providing mechanisms that allow the user to influence the behavior.
A paragraph labeled as a Note or described as an example is non-normative.
Many terms used in this document are defined in the XPath specification [XPath 3.0] or the XDM specification [XDM 3.0]. Particular attention is drawn to the following:
[Definition: The term atomization is defined in Section 2.4.2 Atomization XP30. It is a process that takes as input a sequence of items, and returns a sequence of atomic values, in which the nodes are replaced by their typed values as defined in [XDM 3.0]. If the XPath 3.1 Feature is implemented, then arrays (see 27.7.1 Arrays) are atomized by atomizing their members, recursively.] For some items (for example, elements with element-only content, function items, and maps), atomization generates a dynamic error.
[Definition: The term typed
value is defined in Section
5.15 typed-value Accessor
DM30.
Every node, other than an element whose type
annotation identifies it as having element-only content, has a
typed value. For example, the
typed value of an attribute of
type xs:IDREFS
is a sequence of zero or more
xs:IDREF
values.]
[Definition: The term string value is defined in Section 5.13 string-value Accessor DM30. Every node has a string value. For example, the string value of an element is the concatenation of the string values of all its descendant text nodes.]
[Definition: The term
XPath 1.0 compatibility mode is defined in Section
2.1.1 Static Context
XP30. This is a setting in the static
context of an XPath expression; it has two values, true
and
false
. When the value is set to true, the semantics of
function calls and certain other operations are adjusted to give a greater
degree of backwards compatibility between XPath
3.0 and XPath 1.0.]
[Definition: An XSLT element is an element in the XSLT namespace whose syntax and semantics are defined in this specification.] For a non-normative list of XSLT elements, see D Element Syntax Summary.
In this document the specification of each XSLT element is preceded by a summary of its syntax in the form of a model for elements of that element type. A full list of all these specifications can be found in D Element Syntax Summary. The meaning of the syntax summary notation is as follows:
An attribute that is required is shown with its name in bold. An attribute that may be omitted is shown with a question mark following its name.
An attribute that is deprecated is shown in a grayed font within square brackets.
The string that occurs in the place of an attribute value specifies the allowed
values of the attribute. If this is surrounded by curly brackets
({...}
), then the attribute value is treated as an attribute value template, and
the string occurring within curly brackets specifies the allowed values of the
result of evaluating the attribute value template. Alternative allowed values
are separated by |
. A quoted string indicates a value equal to
that specific string. An unquoted, italicized name specifies a particular type
of value.
The types used, and their meanings, are as follows:
boolean
One of the strings "yes"
,
"true"
, or "1"
to indicate the value
true
, or one of the strings "no"
,
"false"
, or "0"
to indicate the value
false
. Note: the values are synonyms; where this
specification uses a phrase such as “If required='yes'
is
specified ...” this is to be interpreted as meaning “If the attribute
named required
is present, and has the value
yes
, true
, or 1
(after
stripping leading and trailing whitespace) ...”.
string
Any string
expression
An XPath expression
pattern
A pattern as described in 5.5 Patterns.
item-type
An ItemTypeXP30 as defined in the XPath 3.0 specification (or in XPath 3.1 if the processor implements the XPath 3.1 Feature)
sequence-type
A SequenceTypeXP30 as defined in the XPath 3.0 specification (or in XPath 3.1 if the processor implements the XPath 3.1 Feature)
uri; uris
A URI, for example a namespace URI or a collation URI; a whitespace-separated list of URIs
qname
A lexical QName as defined in 5.1.1 Qualified Names
eqname; eqnames
An EQName as defined in 5.1.1 Qualified Names; a whitespace-separated list of EQNames
token; tokens
A string containing no significant whitespace; a whitespace-separated list of such strings
nmtoken; nmtokens
A string conforming to the XML schema rules for the type
xs:NMTOKEN
; a whitespace-separated list of such
strings.
char
A string comprising a single Unicode character
integer
An integer, that is a string in the lexical space of the schema type
xs:integer
decimal
A decimal value, that is a string in the lexical space of the schema
type xs:decimal
ncname
An unprefixed name: a string in the value space of the schema type
xs:NCName
prefix
An xs:NCName
representing a namespace prefix, which must
be in scope for the element on which it appears
id
An xs:NCName
used as a unique identifier for an element
in the containing XML document
Except where the set of allowed values of an attribute is specified using the italicized name string or char, leading and trailing whitespace in the attribute value is ignored. In the case of an attribute value template, this applies to the effective value obtained when the attribute value template is expanded.
XPath comments (delimited by (: ... :)
)
are permitted anywhere that inter-token whitespace is permitted in attributes whose
type is given as expression, pattern, item-type,
or sequence-type, and are not permitted in attributes of other types
(other than within expressions enclosed by curly braces within an attribute value template).
Unless the element is required to be empty, the model element contains a comment specifying the allowed content. The allowed content is specified in a similar way to an element type declaration in XML; sequence constructor means that any mixture of text nodes, literal result elements, extension instructions, and XSLT elements from the instruction category is allowed; other-declarations means that any mixture of XSLT elements from the declaration category is allowed, together with user-defined data elements.
The element is prefaced by comments indicating if it belongs to the
instruction
category or declaration
category or
both. The category of an element only affects whether it is allowed in the
content of elements that allow a sequence constructor or other-declarations.
This example illustrates the notation used to describe XSLT elements.
<!-- Category: instruction -->
<xsl:example-element
select = expression
debug? = boolean
validation? = { "strict" | "lax" } >
<!-- Content: ((xsl:variable | xsl:param)*, xsl:sequence) -->
</xsl:example-element>
This example defines a (non-existent) element xsl:example-element
.
The element is classified as an instruction. It takes the following
attributes:
A mandatory select
attribute, whose value is an XPath expression
An optional debug
attribute, whose
value must be yes
, true
, or
1
to indicate true
, or no
,
false
, or 0
to indicate false
.
An optional validation
attribute, whose value must be
strict
or lax
; the curly brackets indicate that
the value can be defined as an attribute value template, allowing a value such as
validation="{$val}"
, where the variable
val
is evaluated to yield "strict"
or
"lax"
at run-time.
The content of an xsl:example-element
instruction is defined to be a
sequence of zero or more xsl:variable
and
xsl:param
elements, followed by an
xsl:sequence
element.
[ERR XTSE0010] It is a static error if an XSLT-defined element is used in a context where it is not permitted, if a required attribute is omitted, or if the content of the element does not correspond to the content that is allowed for the element.
The rules in the element syntax summary (both for the element structure and for its attributes) apply to the stylesheet content after preprocessing as described in 3.13 Stylesheet Preprocessing.
Attributes are validated as follows. These rules apply to the value of the attribute after removing leading and trailing whitespace.
[ERR XTSE0020] It is a static error if an attribute (other than an attribute written using curly brackets in a position where an attribute value template is permitted) contains a value that is not one of the permitted values for that attribute.
[ERR XTDE0030] It is a dynamic error if the effective value of an attribute written using curly brackets, in a position where an attribute value template is permitted, is a value that is not one of the permitted values for that attribute. If the processor is able to detect the error statically (for example, when any XPath expressions within the curly brackets can be evaluated statically), then the processor may optionally signal this as a static error.
Special rules apply if the construct appears in part of the stylesheet that is processed with forwards compatible behavior: see 3.10 Forwards Compatible Processing.
[Definition: Some constructs defined in this specification are described as being deprecated. The use of this term implies that stylesheet authors should not use the construct, and that the construct may be removed in a later version of this specification.]
Note:
This specification includes a non-normative XML Schema for XSLT stylesheet modules (see H Schemas for XSLT 3.0 Stylesheets). The syntax summaries described in this section are normative.
XSLT defines a set of standard functions which are additional to those defined in [Functions and Operators 3.0]. A list of these functions appears in G.2 List of XSLT-defined functions. The signatures of these functions are described using the same notation as used in [Functions and Operators 3.0]. The names of many of these functions are in the standard function namespace.
This document does not specify any application programming interfaces or other interfaces for initiating a transformation. This section, however, describes the information that is supplied when a transformation is initiated. Except where otherwise indicated, the information is required.
The execution of a stylesheet necessarily involves two activities: static analysis
and dynamic evaluation. Static analysis consists of those tasks that can be performed
by inspection of the stylesheet alone, including the
binding of static variables,
the evaluation of [xsl:]use-when
expressions (see 3.13.1 Conditional Element Inclusion), and shadow attributes
(see 3.13.2 Shadow Attributes) and detection of static errors. Dynamic evaluation consists of
tasks which in general cannot be carried out until a source document is
available.
Dynamic evaluation is further divided into two activities: priming the stylesheet, and invoking a selected component.
Priming the stylesheet provides the dynamic context for evaluation, and supplies all the information needed to establish the values of global variables.
Invoking a component (such as a template or function) causes evaluation of that template or function to produce a result, which is an arbitrary XDM value.
[Definition: The result of invoking the selected component, after any required conversion to the declared result type of the component, is referred to as the raw result.]
The raw result of the invocation
is the immediate result of evaluating the sequence constructor
contained in the target template or function, modified by applying the function conversion rules
to convert the immediate result to the type declared in the as
attribute of the xsl:template
or xsl:function
declaration, if present.
This raw result may optionally be post-processed to construct a result tree, to serialize the result, or both, as described in 2.3.6 Post-processing the Raw Result.
Implementations may allow static analysis and dynamic evaluation to be initiated independently, so that the cost of static analysis can be amortized over multiple transformations using the same stylesheet. Implementations may also allow priming of a stylesheet and invocation of components to be initiated independently, in which case a single act of priming the stylesheet may be followed by a series of independent component invocations. Although this specification does not require such a separation, this section distinguishes information that is needed before static analysis can proceed, information that is needed to prime the stylesheet, and information that is needed when invoking components.
The language is designed to allow the static analysis of each package to be performed independently of other packages, with only basic knowledge of the properties of components made available by used packages. Beyond this, the specification leaves it to implementations to decide how to organize this process. When packages are not used explicitly, the entire stylesheet is treated as a single package.
The following information is needed prior to static analysis of a package:
The location of the package manifest,
or in the absence of a package manifest, the stylesheet module that is to act as
the principal stylesheet
module
of the package. The complete package is
assembled by recursively expanding the xsl:import
and
xsl:include
declarations in the principal stylesheet
module, as described in 3.11.2 Stylesheet Inclusion and 3.11.3 Stylesheet Import.
Information about the packages referenced from this
package using xsl:use-package
declarations. The information
needed will include the names and signatures of public components exported
by the referenced package.
A set (possibly empty) of values for static parameters (see 9.5 Global Variables and Parameters). These values are available for use within
static expressions (notably
in [xsl:]use-when
expressions and shadow attributes) as well as
non-static expressions in the stylesheet. As a minimum, values must be
supplied for any static parameters declared with the attribute
required="yes"
.
Conceptually, the output of the static analysis of a package is an object which might be referred to (without constraining the implementation) as a compiled package. Prior to dynamic evaluation, all the compiled packages needed for execution must be checked for consistency, and component references must be resolved. This process may be referred to, again without constraining the implementation, as linking.
The information needed when priming a stylesheet is as follows:
A set (possibly empty) of values for non-static
stylesheet parameters (see
9.5 Global Variables and Parameters). These values are available for use
within expressions in the stylesheet. As a minimum, values
must be supplied for any parameters declared with the
attribute required="yes"
.
A supplied value is converted if necessary to the declared type of the stylesheet parameter using the function conversion rules.
Note:
Non-static stylesheet parameters are implicitly
public
, which ensures that all the parameters in the
stylesheet for which values can be supplied externally have distinct
names. Static parameters, by contrast,
are local to a package.
[Definition: An item that acts as the global
context item for the transformation. This item acts
as the context item when evaluating
the
select
expression or sequence constructor of a
global variable declaration
within the top-level package, as described in 5.3.3.1 Maintaining Position: the Focus. The global context item may also be available in a named template
when the stylesheet is invoked as described in 2.3.4 Call-Template Invocation].
Note:
In previous releases of this specification, a single node was typically
supplied to represent the source document for the transformation. This
node was used as the target node for the implicit call on
xsl:apply-templates
used to start the transformation
process (now called the initial match selection), and
the root node of the containing tree was used as the context item for
evaluation of global variables (now called the global context item). This relationship between the
initial match selection and the global context item is likely to be found for compatibility
reasons in a transformation API designed to work with earlier versions of
this specification, but it is no longer a necessary relationship; the two
values can in principle be completely independent of each other.
Stylesheet authors wanting to write code that can be invoked using legacy APIs should not rely on the caller being able to supply different values for the initial match selection and the global context item.
The value given to the global context item (and the values given to stylesheet parameters) cannot be nodes in a streamed document. This rule ensures that all global variables can freely navigate within the relevant tree, with no constraints imposed by the streamability rules.
The global context item is potentially
used when initializing global variables and parameters. If the
initialization of any global
variables or parameter depends on the context item, a dynamic error can
occur if the context item is absent. It is implementation-defined whether this error occurs during
priming of the stylesheet or subsequently when the variable is referenced;
and it is implementation-defined whether the error
occurs at all if the variable or parameter is never referenced. The error
can be suppressed by use of xsl:try
and
xsl:catch
within the sequence constructor used to initialize the variable or parameter. It
cannot be suppressed by use of xsl:try
around a
reference to the global variable.
In a library package, the context item, context position, and context size used for evaluation of global variables will be absent, and the evaluation of any expression that references these values will result in a dynamic error. This will also be the case in the top-level package if no global context item is supplied.
Note:
If a context item is available within a global variable declaration, then the context position and context size will always be 1 (one).
Note:
For maximum reusability of code, it is best to avoid use of the context item when initializing global variables and parameters. Instead, all external information should be supplied using named stylesheet parameters. Especially when these use namespaces to avoid conflicts, there is then no risk of confusion between the information supplied externally to different packages.
When a stylesheet parameter is defined in a library package, it is
possible for a using package to supply a value for the parameter by
overriding the parameter declaration within an
xsl:override
element. If the using package is the
top-level package then the overriding declaration
can refer to the global context item.
A mechanism for obtaining a document node and a media type, given an
absolute URI. The total set of available documents (modeled as a mapping
from URIs to document nodes) forms part of the context for evaluating XPath
expressions, specifically the doc
FO30 function. The XSLT
document
function additionally requires the media
type of the resource representation, for use in interpreting any fragment
identifier present within a URI Reference.
Note:
The set of documents that are available to the stylesheet is implementation-dependent, as is the processing that is carried out to construct a tree representing the resource retrieved using a given URI. Some possible ways of constructing a document (specifically, rules for constructing a document from an Infoset or from a PSVI) are described in [XDM 3.0].
Once a stylesheet is primed, the values of global variables
remain stable through all component invocations. In addition, priming a stylesheet
creates an execution scopeFO30
during which the dynamic context and all calls
on deterministicFO30
functions remain stable; for example two calls on the
current-dateTime
FO30 function within an execution scope are
defined to return the same result.
Parameters passed to the transformation by the client application when a stylesheet is primed are matched against stylesheet parameters (see 9.5 Global Variables and Parameters), not against the template parameters of any template executed during the course of the transformation.
[ERR XTDE0050] It is a dynamic error if a stylesheet declares a visible stylesheet parameter that is explicitly or implicitly mandatory, and no value for this parameter is supplied when the stylesheet is primed. A stylesheet parameter is visible if it is not masked by another global variable or parameter with the same name and higher import precedence. If the parameter is a static parameter then the value must be supplied prior to the static analysis phase.
[Definition: A stylesheet may be evaluated by supplying a
value to be processed, together with an initial mode. The
value (which can be any sequence of items) is referred to as the initial
match selection. The processing then corresponds to the effect of the
xsl:apply-templates
instruction.]
The initial match selection will often be a single document node, traditionally called the source document of the transformation; but in general, it can be any sequence. If the initial match selection is an empty sequence, the result of the transformation will be empty, since no template rules are evaluated.
Processing proceeds by finding the template rules that match the items in the initial match selection, and evaluating these template rules with a focus based on the initial match selection. The template rules are evaluated in final output state.
The following information is needed when dynamic evaluation is to start with a template rule:
The initial match selection. An API that chooses to maintain compatibility with previous versions of this specification should allow a method of invocation in which a singleton node is provided, which is then used in two ways: the node itself acts as the initial match selection, and the root node of the containing tree acts as the global context item.
Optionally, an initial mode.
[Definition: The initial mode is the mode used to select template rules for processing items in the initial match selection when apply-templates invocation is used to initiate a transformation.]
In searching for the template rule that best matches the items in the initial match selection, the processor considers only those rules that apply to the initial mode.
If no initial mode is supplied explicitly, then the initial mode is that named in the
default-mode
attribute of the (explicit or implicit) xsl:package
element of the top-level package or in
the absence of such an attribute, the unnamed mode.
[ERR XTDE0044] It is a dynamic error if the invocation of the stylesheet specifies an initial mode when no initial match selection is supplied (either explicitly, or defaulted to the global context item).
A (named or unnamed) mode M is eligible as an initial mode if one of the following conditions applies, where P is the top-level package of the stylesheet:
M is explicitly declared in an xsl:mode
declaration
within P, and has public
or final
visibility (either by virtue
of its visibility
attribute, or by virtue of an xsl:expose
declaration).
M is the unnamed mode.
M is named in the default-mode
attribute of the (explicit or implicit)
xsl:package
element of P.
M is declared in a package used by P, and is given public
or final
visibility in P by means of an xsl:accept
declaration.
The effective value of the declared-modes
attribute of the explicit or implicit
xsl:package
element of P is no
, and M appears as
a mode-name in the mode
attribute of a template rule declared within P.
[ERR XTDE0045] It is a dynamic error if the invocation of the stylesheet specifies an initial mode and the specified mode is not eligible as an initial mode (as defined above).
Parameters, which will be passed to the template rules
used to process items in the input sequence. The parameters consist of two
sets of (QName, value) pairs, one set for tunnel parameters and one for non-tunnel parameters, in which
the QName identifies the name of a parameter and the value provides the
value of the parameter. Either or both sets of parameters may be empty. The
effect is the same as when a template is invoked using
xsl:apply-templates
with an
xsl:with-param
child specifying
tunnel="yes"
or tunnel="no"
as appropriate. If
a parameter is supplied that is not declared or used, the value is simply
ignored. These parameters are not used to set stylesheet parameters.
A supplied value is converted if necessary to the declared type of the template parameter using the function conversion rules.
Details of how the result of the initial template is to be returned. For details, see 2.3.6 Post-processing the Raw Result
The raw result of the invocation is the
result of processing the supplied input sequence as if by a call on
xsl:apply-templates
in the specified mode: specifically, each
item in the input sequence is processed by selecting and evaluating the best
matching template rule, and converting the result (if necessary) to the type
declared in the as
attribute of that template using the function conversion rules; and the results of processing each item
are then concatenated into a single sequence, respecting the order of items in the
input sequence.
Note:
If the initial mode is declared-streamable, then a streaming processor should allow some or all of the items in the initial match selection to be nodes supplied in streamable form, and any nodes that are supplied in this form must then be processed using streaming.
Since the global context item cannot be a streamed node, in cases where the transformation is to proceed by applying streamable templates to a streamed input document, the global context item must either be absent, or must be something that differs from the initial match selection.
Note:
The design of the API for invoking a transformation should provide some means for users to designate the unnamed mode as the initial mode in cases where it is not the default mode.
It is a dynamic error
[see ERR XTDE0700] if the template rule selected for processing any item in the initial match selection defines a template parameter that specifies required="yes"
and no value is supplied for that
parameter.
Note:
A stylesheet can process further source
documents in addition to those supplied when the transformation is invoked.
These additional documents can be loaded using the functions
document
(see 20.1 fn:document) or
doc
FO30 or collection
FO30 (see [Functions and Operators 3.0]), or using the
xsl:source-document
instruction; alternatively, they can
be supplied as stylesheet
parameters (see 9.5 Global Variables and Parameters), or returned as
the result of an extension
function (see 24.1 Extension Functions).
[Definition: A stylesheet may be evaluated by selecting a
named template to be evaluated; this is referred to as the initial named
template.] The effect is analogous to the effect of
executing an xsl:call-template
instruction. The following
information is needed in this case:
Optionally, the name of the initial
named template which is to be executed as the entry point to
the transformation. If no template name is
supplied, the default template name is
xsl:initial-template
. The selected template
must exist within the stylesheet.
Optionally, a context item for evaluation of this named
template, defaulting to the global context item if it
exists. This is constrained by any
xsl:context-item
element appearing within the
selected xsl:template
element. The initial named
template is evaluated with a singleton focus based on
this context item if it exists, or with an absent
focus otherwise.
Parameters, which will be passed to the selected template
rule. The parameters consist of two sets of (QName, value) pairs, one set
for tunnel parameters and one
for non-tunnel parameters, in which the QName identifies the name of a
parameter and the value provides the value of the parameter. Either or both
sets of parameters may be empty. The effect is the same as when a template
is invoked using xsl:call-template
with an
xsl:with-param
child specifying
tunnel="yes"
or tunnel="no"
as appropriate. If
a parameter is supplied that is not declared or used, the value is simply
ignored. These parameters are not used to set stylesheet parameters.
A supplied value is converted if necessary to the declared type of the template parameter using the function conversion rules.
Details of how the result of the initial named template is to be returned. For details, see 2.3.6 Post-processing the Raw Result
The raw result of the invocation is the
result of evaluating the initial named template, after
conversion of the result to the type declared in the as
attribute of
that template using the function conversion rules, if such
conversion is necessary.
The initial named template is evaluated in final output state.
[ERR XTDE0040] It is a dynamic error if the invocation of
the stylesheet specifies a template
name that does not match the expanded
QName of a named template defined in the stylesheet, whose
visibility is public
or final
.
It is a dynamic error
[see ERR XTDE0700] if the initial named template, or any of the template rules invoked to
process items in the initial match selection, defines a
template parameter that
specifies required="yes"
and no value is supplied for that parameter.
[Definition: A stylesheet may be evaluated by calling a named stylesheet function, referred to as the initial function.] The following additional information is needed in this case:
The name and arity of a stylesheet function which is to be executed as the entry point to the transformation.
Note:
In the design of a concrete API, the arity may be inferred from the length of the parameter list.
A list of values to act as parameters to the initial function. The number of values in the list must be the same as the arity of the function.
A supplied value is converted if necessary to the declared type of the function parameter using the function conversion rules.
Details of how the result of the initial function is to be returned. For details, see 2.3.6 Post-processing the Raw Result
The raw result of the invocation is the
result of evaluating the initial function, after conversion of
the result to the type declared in the as
attribute of that function
using the function conversion rules, if such conversion is
necessary.
Note:
The initial function (like all stylesheet functions) is evaluated with an absent focus.
If the initial function is declared-streamable, a streaming processor should allow the value of the first argument to be supplied in streamable form, and if it is supplied in this form, then it must be processed using streaming.
[ERR XTDE0041] It is a dynamic error if the invocation of the stylesheet specifies a function name and
arity that does not match the expanded
QName and arity of a named stylesheet function defined in the stylesheet, whose visibility is
public
or final
.
When a transformation is invoked by calling an initial function, the entire transformation executes in temporary output state, which means that calls on
xsl:result-document
are not permitted.
There are three ways the result of a transformation
may be delivered. (This applies both to the principal result, described here, and
also to secondary results, generated using xsl:result-document
.)
The raw result (a sequence of values) may be returned directly to the calling application.
A result tree may be constructed from the raw result.
By default, a result tree is constructed if the build-tree
attribute of the unnamed output definition
has the effective value yes
. An API for invoking transformations may
allow this setting to be overridden by the calling application. If result tree construction
is requested, it is performed as described in 2.3.6.1 Result Tree Construction.
Alternatively, the raw result may be serialized as described in 2.3.6.2 Serializing the Result. The decision whether or not to serialize the result is determined by the rules of transformation API provided by the processor, and is not influenced by anything in the stylesheet.
Note:
This specification does not constrain the design of application programming interfaces or the choice of defaults. In previous versions of this specification, result tree construction was a mandatory process, while serialization was optional. When invoking stylesheet functions directly, however, result tree construction and serialization may be inappropriate as defaults. These considerations may affect the design of APIs.
In previous versions of XSLT, results were delivered either
in serialized form (as a character or byte stream), or as a tree. In the latter case
processors
typically would use either their own tree representation, or a standardized tree
representation such as the W3C Document Object Model (DOM) (see [DOM Level 2]),
adapted to the data structures offered by the programming language in which the API
is defined.
To deliver a raw result, processors need to define a representation not only of XDM
nodes but
also of sequences, atomic values, maps and even functions. As with the return of a
simple tree,
this may involve a trade-off between strict fidelity to the XDM data model and usability
in the particular
programming language environment. It is not a requirement that an API should return results
in a way that exposes every property of the XDM data model; for example there may
be APIs that do not expose
the precise type annotation of a returned node or atomic value, or that fail to expose
the base URI
or document URI of a node, or that provide no way of determining whether two nodes
in the result
sequence are the same node in the sense of the XPath is
operator.
The way in which maps and functions (and where XPath 3.1 is supported, arrays)
are returned requires careful design choices. It is recommended that an API should be capable
of returning any XDM value without error, and that there should be minimal loss of
information if
the raw results output by one transformation are subsequently used as input to another
transformation.
If a result tree is to be constructed from the raw result, then this is done
by applying the rules for the process of sequence normalizationSER30 as defined in
[XSLT and XQuery Serialization]. This process takes as input the serialization parameters defined in the
unnamed output definition of the top-level package; though the only parameter
that is actually used by this process is item-separator
. In particular, sequence normalization is carried
out regardless of any method
attribute in the unnamed output definition.
The sequence normalization process either returns a document node, or raises a serialization error. The content of the document node is not necessarily well-formed (the document node may have any number of element or text nodes among its children).
Note:
More specifically, the process raises a serialization error if any item in the raw result is an attribute node, a namespace node, or a function (including a map, but not an array: arrays are flattened).
The tree that is constructed is referred to as a final result tree.
If the raw result is an empty sequence, the final result tree will consist of a document node with no children.
The base URI of the document node is set to the base output URI.
Note:
The item-separator
property has no effect if the raw result of the transformation is a sequence
of length zero or one, which in practice will often be the case, especially in a traditional
scenario such as
transformation of an XML document to HTML.
If there is no item-separator
, then a single space is inserted between adjacent atomic values;
for example if the raw result is the sequence 1 to 5
, then sequence normalization produces a tree
comprising a document node with a single child, the child being a text node with the
string value
1 2 3 4 5
.
If there is an item-separator
, then it is used not only between adjacent atomic values,
but between any pair of items in the raw result. For example if the raw result is
a sequence of two
element nodes A
and B
, and the item-separator
is a comma,
then the result of sequence normalization will be a document node with three children:
a copy of A
,
a text node whose string value is a single comma, and a copy of B
.
See 2.7 Parsing and Serialization.
The raw result may optionally be serialized as described in 26 Serialization. The serialization is controlled by the serialization parameters defined in the unnamed output definition of the top-level package.
Note:
The first phase of serialization, called sequence normalizationSER30,
takes place for some output methods but not others. For example, if the json
output method
(defined in [XSLT and XQuery Serialization 3.1]) is selected, then the process of constructing
a tree is bypassed.
The effect of serialization is to generate a sequence of octets, representing the serialized result in some character encoding. The processor’s API may define mechanisms enabling this sequence of octets to be written to persistent storage at some location. The default location is the location identified by the base output URI.
In previous versions of this specification it was stated that
when the raw result of the initial template or function is an empty sequence,
a result tree should be produced if and only if the transformation generates no secondary
results
(that is, if it does not invoke xsl:result-document
). This provision is most likely
to have a noticeable effect if the transformation produces serialized results, and
these results
are written to persistent storage: the effect is then that a transformation producing
an empty
principal result will overwrite any existing content at the base output URI location
if and only
if the transformation produces no other output. Processor APIs offering backwards
compatibility
with earlier versions of XSLT must respect this behavior, but there is no requirement
for new
processor APIs to do so.
[Definition: The base output URI is a URI to be used as the base URI when
resolving a relative URI reference allocated
to a final result tree. If the
transformation generates more than one final result tree, then typically each
one will be allocated a URI relative to this base URI.] The way in
which a base output URI is established is implementation-defined. Each invocation of the stylesheet may supply
a different base output URI. It is acceptable for the base output URI to be
absent, provided no constructs (such as
xsl:result-document
) are evaluated that depend on the value of
the base output URI.
Note:
It will often be convenient for the base output URI to be the same as the location to which the principal result document is serialized, but this relationship is not a necessary one.
The main executable components of a stylesheet are templates and functions. The body of a template or function is a sequence constructor, which is a sequence of elements and text nodes that can be evaluated to produce a result.
A sequence constructor is a sequence of sibling nodes in the stylesheet, each of which is either an XSLT instruction, a literal result element, a text node, or an extension instruction.
[Definition: An instruction is either an XSLT instruction or an extension instruction.]
[Definition: An XSLT
instruction is an XSLT element
whose syntax summary in this specification contains the annotation <!--
category: instruction -->
.]
Extension instructions are described in 24.2 Extension Instructions.
The main categories of XSLT instruction are as follows:
instructions that create new nodes: xsl:document
,
xsl:element
, xsl:attribute
,
xsl:processing-instruction
, xsl:comment
,
xsl:value-of
, xsl:text
,
xsl:namespace
;
instructions that copy nodes: xsl:copy
,
xsl:copy-of
;
an instruction that returns an arbitrary sequence by evaluating an XPath
expression: xsl:sequence
;
instructions that cause conditional or repeated evaluation of nested
instructions: xsl:if
, xsl:choose
, xsl:try
,
xsl:for-each
, xsl:for-each-group
, xsl:fork
, xsl:iterate
and its subordinate instructions xsl:next-iteration
and
xsl:break
;
instructions that generate output conditionally if elements are or are not
empty: xsl:on-empty
, xsl:on-non-empty
,
xsl:where-populated
;
instructions that invoke templates: xsl:apply-templates
,
xsl:apply-imports
, xsl:call-template
,
xsl:next-match
;
Instructions that declare variables: xsl:variable
;
Instructions to assist debugging: xsl:message
,
xsl:assert
;
other specialized instructions: xsl:number
,
xsl:analyze-string
, xsl:fork
,
xsl:result-document
, xsl:source-document
, xsl:perform-sort
,
xsl:merge
.
The classic method of executing an XSLT transformation is to apply template rules to the root node of an input document (see 2.3.3 Apply-Templates Invocation). The operation of applying templates to a node searches the stylesheet for the best matching template rule for that node. This template rule is then evaluated. A common coding pattern, especially when XSLT is used to convert XML documents into display formats such as HTML, is to have one template rule for each kind of element in the source document, and for that template rule to generate some appropriate markup elements, and to apply templates recursively to its own children. The effect is to perform a recursive traversal of the source tree, in which each node is processed using the best-fit template rule for that node. The final result of the transformation is then the tree produced by this recursive process. This result can then be optionally serialized (see 2.3.6 Post-processing the Raw Result).
This example uses rule-based processing to convert a simple XML input document into an HTML output document.
The input document takes the form:
<PERSONAE PLAY="OTHELLO"> <TITLE>Dramatis Personae</TITLE> <PERSONA>DUKE OF VENICE</PERSONA> <PERSONA>BRABANTIO, a senator.</PERSONA> <PERSONA>Other Senators.</PERSONA> <PERSONA>GRATIANO, brother to Brabantio.</PERSONA> <PERSONA>LODOVICO, kinsman to Brabantio.</PERSONA> <PERSONA>OTHELLO, a noble Moor in the service of the Venetian state.</PERSONA> <PERSONA>CASSIO, his lieutenant.</PERSONA> <PERSONA>IAGO, his ancient.</PERSONA> <PERSONA>RODERIGO, a Venetian gentleman.</PERSONA> <PERSONA>MONTANO, Othello's predecessor in the government of Cyprus.</PERSONA> <PERSONA>Clown, servant to Othello. </PERSONA> <PERSONA>DESDEMONA, daughter to Brabantio and wife to Othello.</PERSONA> <PERSONA>EMILIA, wife to Iago.</PERSONA> <PERSONA>BIANCA, mistress to Cassio.</PERSONA> <PERSONA>Sailor, Messenger, Herald, Officers, Gentlemen, Musicians, and Attendants.</PERSONA> </PERSONAE>
The stylesheet to render this as HTML can be written as a set of template rules:
<xsl:stylesheet xmlns:xsl="http://www.w3.org/1999/XSL/Transform" version="3.0" expand-text="yes"> <xsl:strip-space elements="PERSONAE"/> <xsl:template match="PERSONAE"> <html> <head> <title>The Cast of {@PLAY}</title> </head> <body> <xsl:apply-templates/> </body> </html> </xsl:template> <xsl:template match="TITLE"> <h1>{.}</h1> </xsl:template> <xsl:template match="PERSONA[count(tokenize(., ',') = 2]"> <p><b>{substring-before(., ',')}</b>: {substring-after(., ',')}</p> </xsl:template> <xsl:template match="PERSONA"> <p><b>{.}</b></p> </xsl:template> </xsl:stylesheet>
There are four template rules here:
The first rule matches the outermost element, named PERSONAE
(it could equally
have used match="/"
to match the document node). The effect of this rule is to create
the skeleton of the output HTML page. Technically, the body of the template is a sequence
constructor
comprising a single literal result element (the html
element); this
in turn contains a sequence constructor comprising two literal result elements (the
head
and body
elements). The head
element is populated with a literal title
element whose content is computed as a mixture of fixed and variable text using a
text value template.
The body
element is populated by evaluating an xsl:apply-templates
instruction.
The effect of the xsl:apply-templates
instruction is to process the children of
the PERSONAE
element in the source tree: that is, the TITLE
and
PERSONA
elements. (It would also process any whitespace text node children, but these
have been stripped by virtue of the xsl:strip-space
declaration.) Each of these
child elements is processed by the best matching template rule for that element, which
will be one
of the other three rules in the stylesheet.
The template rule for the TITLE
element outputs an h1
element
to the HTML result document, and populates this with the value of ".", the context
item. That is,
it copies the text content of the TITLE
element to the output h1
element.
The last two rules match PERSONA
element. The first rule matches PERSONA
elements whose text content contains exactly one comma; the second rule matches all
PERSONA
elements,
but it has lower priority than the first rule, so in practice it only applies to PERSONA
elements that contain no comma or multiple commas.
For both rules the body of the rule is a sequence constructor containing a single
literal result element,
the p
element. These literal result elements contain
further sequence constructors comprising literal result elements and text nodes.
In each of these examples the text nodes are in the form of a text value template:
in general this is a combination of fixed text together with XPath expressions enclosed
in curly braces, which
are evaluated to form the content of the containing literal result element.
[Definition: A stylesheet contains a set of template rules (see 6 Template Rules). A template rule has three parts: a pattern that is matched against selected items (often but not necessarily nodes), a (possibly empty) set of template parameters, and a sequence constructor that is evaluated to produce a sequence of items.] In many cases these items are newly constructed nodes, which are then written to a result tree.
The results of some expressions and instructions in a stylesheet may depend on information provided contextually. This context information is divided into two categories: the static context, which is known during static analysis of the stylesheet, and the dynamic context, which is not known until the stylesheet is evaluated. Although information in the static context is known at analysis time, it is sometimes used during stylesheet evaluation.
Some context information can be set by means of declarations within the stylesheet itself. For example, the namespace bindings used for any XPath expression are determined by the namespace declarations present in containing elements in the stylesheet. Other information may be supplied externally or implicitly: an example is the current date and time.
The context information used in processing an XSLT stylesheet includes as a subset
all the context information required when evaluating XPath expressions. The XPath 3.0 specification defines a static and dynamic
context that the host language (in this case, XSLT) may initialize, which affects
the
results of XPath expressions used in that context. XSLT augments the context with
additional information: this additional information is used firstly by XSLT
constructs outside the scope of XPath (for example, the xsl:sort
element), and secondly, by functions that are defined in the XSLT specification (such
as key
and current-group
) that are
available for use in XPath expressions appearing within a stylesheet.
The static context for an expression or other construct in a stylesheet is determined by the place in which it appears lexically. The details vary for different components of the static context, but in general, elements within a stylesheet module affect the static context for their descendant elements within the same stylesheet module.
The dynamic context is maintained as a stack. When an instruction or expression is evaluated, it may add dynamic context information to the stack; when evaluation is complete, the dynamic context reverts to its previous state. An expression that accesses information from the dynamic context always uses the value at the top of the stack.
The most commonly used component of the dynamic context is the context item. This is an implicit variable whose
value is the item currently being processed (it may be a node, an atomic value,
or a function item). The value of the context
item can be referenced within an XPath expression using the expression .
(dot).
Full details of the static and dynamic context are provided in 5.3 The Static and Dynamic Context.
An XSLT stylesheet
describes a process that constructs a set of results from a set of inputs. The inputs
are the data provided at stylesheet invocation, as described in 2.3 Initiating a Transformation. The results include the principal result
(an arbitrary sequence), which is the result of the initial component invocation,
together with any secondary results
produced using xsl:result-document
instructions.
The stylesheet does not describe how a source tree is constructed. Some possible ways of constructing source trees are described in [XDM 3.0]. Frequently an implementation will operate in conjunction with an XML parser (or more strictly, in the terminology of [XML 1.0], an XML processor), to build a source tree from an input XML document. An implementation may also provide an application programming interface allowing the tree to be constructed directly, or allowing it to be supplied in the form of a DOM Document object (see [DOM Level 2]). This is outside the scope of this specification. Users should be aware, however, that since the input to the transformation is a tree conforming to the XDM data model as described in [XDM 3.0], constructs that might exist in the original XML document, or in the DOM, but which are not within the scope of the data model, cannot be processed by the stylesheet and cannot be guaranteed to remain unchanged in the transformation output. Such constructs include CDATA section boundaries, the use of entity references, and the DOCTYPE declaration and internal DTD subset.
[Definition: A frequent requirement is to output a final result tree as an XML document (or in other formats such as HTML). This process is referred to as serialization.]
Like parsing, serialization is not part of the transformation process, and it is not
required that an XSLT processor must be able
to perform serialization. However, for pragmatic reasons, this specification
describes declarations (the xsl:output
element and the
xsl:character-map
declarations, see 26 Serialization), and attributes on the xsl:result-document
instruction, that
allow a stylesheet to specify the desired
properties of a serialized output file. When serialization is not being performed,
either because the implementation does not support the serialization option, or
because the user is executing the transformation in a way that does not invoke
serialization, then the content of the xsl:output
and
xsl:character-map
declarations has no effect. Under these
circumstances the processor may report any errors in an
xsl:output
or xsl:character-map
declaration, or
in the serialization attributes of xsl:result-document
, but is not
required to do so.
In previous versions of the XSLT language, it has been possible to structure a
stylesheet as a collection of modules, using the xsl:include
and
xsl:import
declarations to express the dependency of one module on
others.
In XSLT 3.0 an additional layer of modularization of stylesheet code is enabled through the introduction of packages. A package is a collection of stylesheet modules with a controlled interface to the packages that use it: for example, it defines which functions and templates defined in the package are visible to callers, which are purely internal, and which are not only public but capable of being overridden by other functions and templates supplied by the using package.
Packages are introduced with several motivations, which broadly divide into two categories:
Software engineering benefits: greater re-use of code, greater robustness through ease of testing, controlled evolution of code in response to new requirements, ability to deliver code that users cannot see or modify.
Efficiency benefits: the ability to avoid compiling libraries repeatedly when they are used in multiple stylesheets, and to avoid holding multiple copies of the same library in memory simultaneously.
Packages are designed to allow separate compilation: that is, a package can be compiled independently of the packages that use it. This specification does not define a process model for compilation, or expand on what it means to compile different packages independently. Nor does it mandate that implementations offer any feature along these lines. It merely defines language features that are designed to make separate compilation of packages possible.
To achieve this, packages (unlike modules):
Must not contain unresolved references to functions, templates, or variables declared in other packages;
Have strict rules governing the ability to override declarations in a library package with declarations in a package that uses the library;
Constrain the visibility of component names and of context declarations such as the declarations of keys and decimal formats;
Can declare a mode (a collection of template rules) as final, which disallows the addition of new overriding template rules in a using package;
Require explicit disambiguation where naming conflicts arise, for example when a package uses two other packages that both export like-named components;
Allow multiple specializations of library components to coexist in the same application.
A package is defined in XSLT
by means of an XML document whose
outermost element is an xsl:package
element. This is referred to as
the package manifest. The xsl:package
element
has optional child elements xsl:use-package
and
xsl:expose
describing properties of the package. The package
manifest may refer to an external top-level stylesheet module using an
xsl:include
or xsl:import
declaration, or it may
contain the body of a stylesheet module inline (the two approaches can also be
mixed).
Although this specification defines packages as constructs written using a defined XSLT syntax, implementations may provide mechanisms that allow packages to be written using other languages (for example, XQuery).
When no packages are explicitly defined, the entire
stylesheet is treated as a single package; the effect is as if the
xsl:stylesheet
or xsl:transform
element of the
principal stylesheet
module were replaced by an xsl:package
element with no
other information in the package manifest.
XSLT defines a number of features that allow the language to be extended by implementers, or, if implementers choose to provide the capability, by users. These features have been designed, so far as possible, so that they can be used without sacrificing interoperability. Extensions other than those explicitly defined in this specification are not permitted.
These features are all based on XML namespaces; namespaces are used to ensure that the extensions provided by one implementer do not clash with those of a different implementer.
The most common way of extending the language is by providing additional functions, which can be invoked from XPath expressions. These are known as extension functions, and are described in 24.1 Extension Functions.
It is also permissible to extend the language by providing new instructions. These are referred to as extension instructions, and are described
in 24.2 Extension Instructions. A stylesheet that uses extension
instructions in a particular namespace must declare that it is doing so by using the
[xsl:]extension-element-prefixes
attribute.
Extension instructions and extension functions defined according to these rules may be provided by the implementer of the XSLT processor, and the implementer may also provide facilities to allow users to create further extension instructions and extension functions.
This specification defines how extension instructions and extension functions are invoked, but the facilities for creating new extension instructions and extension functions are implementation-defined. For further details, see 24 Extensibility and Fallback.
The XSLT language can also be extended by the use of extension attributes (see 3.2 Extension Attributes), and by means of user-defined data elements (see 3.7.3 User-defined Data Elements).
An XSLT stylesheet can make use of information from a schema. An XSLT transformation can take place in the absence of a schema (and, indeed, in the absence of a DTD), but where the source document has undergone schema validity assessment, the XSLT processor has access to the type information associated with individual nodes, not merely to the untyped text.
Information from a schema can be used both statically (when the stylesheet is compiled), and dynamically (during evaluation of the stylesheet to transform a source document).
There are places within a stylesheet, and within XPath expressions and patterns in a stylesheet, where it is possible to refer to named type definitions in a schema, or to element and attribute declarations. For example, it is possible to declare the types expected for the parameters of a function. This is done using a SequenceType.
[Definition: A SequenceType constrains the type and number of items in a sequence. The term is used both to denote the concept, and to refer to the syntactic form in which sequence types are expressed in the XPath grammar: specifically SequenceTypeXP30 in [XPath 3.0], or SequenceTypeXP31 in [XPath 3.1], depending on whether or not the XPath 3.1 Feature is implemented.]
[Definition: Type definitions and element and attribute declarations are referred to collectively as schema components.]
[Definition: The schema components that may be referenced by name in a package are referred to as the in-scope schema components.]
The set of in-scope schema components may vary between one package and another, but as explained in 3.15 Importing Schema Components, the schema components used in different packages must be consistent with each other.
The conformance rules for XSLT 3.0, defined in
27 Conformance, distinguish between a basic XSLT processor and a schema-aware XSLT processor. As the
names suggest, a basic XSLT processor does not support the features of XSLT that
require access to schema information, either statically or dynamically. A stylesheet that works with a basic XSLT processor
will produce the same results with a schema-aware XSLT processor provided that the
source documents are untyped (that is, they are not validated against a schema).
However, if source documents are validated against a schema then the results may be
different from the case where they are not validated. Some constructs that work on
untyped data may fail with typed data (for example, an attribute of type
xs:date
cannot be used as an argument of the
substring
FO30 function) and other constructs may produce
different results depending on the datatype (for example, given the element
<product price="10.00" discount="2.00"/>
, the expression
@price gt @discount
will return true if the attributes have type
xs:decimal
, but will return false if they are untyped).
There is a standard set of type definitions that are always available as in-scope schema components in every stylesheet. These are defined in 3.14 Built-in Types.
The remainder of this section describes facilities that are available only with a schema-aware XSLT processor.
Additional schema components (type
definitions, element declarations, and attribute declarations) may be added to the
in-scope schema components
by means of the xsl:import-schema
declaration in a stylesheet.
The xsl:import-schema
declaration may reference an external schema
document by means of a URI, or it may contain an inline xs:schema
element.
It is only necessary to import a schema explicitly if one or more of its schema components are referenced explicitly by name in the stylesheet; it is not necessary to import a schema merely because the stylesheet is used to process a source document that has been assessed against that schema. It is possible to make use of the information resulting from schema assessment (for example, the fact that a particular attribute holds a date) even if no schema has been imported by the stylesheet.
Importing a schema does not of itself say anything about the type of the source document that the stylesheet is expected to process. The imported type definitions can be used for temporary nodes or for nodes on a result tree just as much as for nodes in source documents. It is possible to make assertions about the type of an input document by means of tests within the stylesheet. For example:
<xsl:mode typed="lax"/> <xsl:global-context-item use="required" as="document-node(schema-element(my:invoice))"/>
This example will cause the transformation to fail with an error message, unless
the global context item is valid against the top-level element
declaration my:invoice
, and has been annotated as such.
The setting typed="lax"
further ensures that in any
match pattern for a template rule in this mode, an element name that corresponds
to the name of an element declaration in the schema is taken as referring to
elements validated against that declaration: for example,
match="employee"
will only match a validated employee
element. Selecting this option enables the XSLT processor to do more compile-time
type-checking against the schema, for example it allows the processor to produce
warning or error messages when path expressions contain misspelt element names, or
confuse an element with an attribute.
It is also true that importing a schema does not of itself say
anything about the structure of the result tree. It is possible to request validation
of a result tree against the schema by using the xsl:result-document
instruction, for example:
<xsl:template match="/"> <xsl:result-document validation="strict"> <xhtml:html> <xsl:apply-templates/> </xhtml:html> </xsl:result-document> </xsl:template>
This example will cause the transformation to fail with an error message unless
the document element of the result document is valid against the top-level element
declaration xhtml:html
.
It is possible that a source document may contain nodes whose type annotation is not one of the types
imported by the stylesheet. This creates a potential problem because in the case of
an expression such as data(.) instance of xs:integer
the system needs to
know whether the type named in the type annotation of the context node is derived
by
restriction from the type xs:integer
. This information is not explicitly
available in an XDM tree, as defined in [XDM 3.0]. The
implementation may choose one of several strategies for dealing with this
situation:
The processor may signal a dynamic error if a source document is found to contain a type annotation that is not known to the processor.
The processor may maintain additional metadata, beyond that described in
[XDM 3.0], that allows the source document to be
processed as if all the necessary schema information had been imported using
xsl:import-schema
. Such metadata might be held in the data
structure representing the source document itself, or it might be held in a
system catalog or repository.
The processor may be configured to use a fixed set of schemas, which are automatically used to validate all source documents before they can be supplied as input to a transformation. In this case it is impossible for a source document to have a type annotation that the processor is not aware of.
The processor may be configured to treat the source document as if no schema
processing had been performed, that is, effectively to strip all type
annotations from elements and attributes on input, marking them instead as
having type xs:untyped
and xs:untypedAtomic
respectively.
Where a stylesheet author chooses to make assertions about the types of nodes or of variables and parameters, it is possible for an XSLT processor to perform static analysis of the stylesheet (that is, analysis in the absence of any source document). Such analysis may reveal errors that would otherwise not be discovered until the transformation is actually executed. An XSLT processor is not required to perform such static type-checking. Under some circumstances (see 2.14 Error Handling) type errors that are detected early may be reported as static errors. In addition an implementation may report any condition found during static analysis as a warning, provided that this does not prevent the stylesheet being evaluated as described by this specification.
A stylesheet can also control the type annotations of nodes that it constructs in a result tree. This can be done in a number of ways.
It is possible to request explicit validation of a complete document, that is,
a result
tree rooted at a document node. Validation
is either strict or lax, as described in [XML Schema Part 1]. If
validation of a result tree fails
(strictly speaking, if the outcome of the validity assessment is
invalid
), then the transformation fails, but in all other
cases, the element and attribute nodes of the tree will be annotated with the
names of the types to which these nodes conform. These type annotations will be discarded if the
result tree is serialized as an XML document, but they remain available when
the result tree is passed to an application (perhaps another stylesheet) for further processing.
It is also possible to validate individual element and attribute nodes as they
are constructed. This is done using the type
and
validation
attributes of the xsl:element
,
xsl:attribute
, xsl:copy
, and
xsl:copy-of
instructions, or the xsl:type
and
xsl:validation
attributes of a literal result element.
When elements, attributes, or document nodes are copied, either explicitly
using the xsl:copy
or xsl:copy-of
instructions, or implicitly when nodes in a sequence are attached to a new
parent node, the options validation="strip"
and
validation="preserve"
are available, to control whether
existing type annotations are to be
retained or not.
When nodes in a temporary tree are validated, type information is available for use by operations carried out on the temporary tree, in the same way as for a source document that has undergone schema assessment.
For details of how validation of element and attribute nodes works, see 25.4 Validation.
[Definition: The term streaming refers to a manner of processing in which XML documents (such as source and result documents) are not represented by a complete tree of nodes occupying memory proportional to document size, but instead are processed “on the fly” as a sequence of events, similar in concept to the stream of events notified by an XML parser to represent markup in lexical XML.]
[Definition: A streamed document is a source tree that is processed using streaming, that is, without constructing a complete tree of nodes in memory.]
[Definition: A streamed node is a node in a streamed document.]
Many processors implementing earlier versions of this specification have adopted an architecture that allows streaming of the result tree directly to a serializer, without first materializing the complete result tree in memory. Streaming of the source tree, however, has proved to be more difficult without subsetting the language. This has created a situation where documents exceeding the capacity of virtual memory could not be transformed. XSLT 3.0 therefore introduces facilities allowing stylesheets to be written in a way that makes streaming of source documents possible, without excessive reliance on processor-specific optimization techniques.
Streaming achieves two important objectives: it allows large documents to be transformed without requiring correspondingly large amounts of memory; and it allows the processor to start producing output before it has finished receiving its input, thus reducing latency.
This specification does not attempt to legislate precisely which implementation techniques fall under the definition of streaming, and which do not. A number of techniques are available that reduce memory requirements, while still requiring a degree of buffering, or allocation of memory to partial results. A stylesheet that requests streaming of a source document is indicating that the processor should avoid assuming that the entire source document will fit in memory; in return, the stylesheet must be written in a way that makes streaming possible. This specification does not attempt to describe the algorithms that the processor should actually use, or to impose quantitative constraints on the resources that these algorithms should consume.
Nothing in this specification, nor in its predecessors [XSLT 1.0] and [XSLT 2.0], prevents a processor using streaming whenever it sees an opportunity to do so. However, experience has shown that in order to achieve streaming, it is often necessary to write stylesheet code in such a way as to make this possible. Therefore, XSLT 3.0 provides explicit constructs allowing the stylesheet author to request streaming, and defines explicit static constraints on the structure of the code which are designed to make streaming possible.
A processor that claims conformance with the streaming option offers a guarantee that when streaming is requested for a source document, and when the stylesheet conforms to the rules that make the processing guaranteed-streamable, then an algorithm will be adopted in which memory consumption is either completely independent of document size, or increases only very slowly as document size increases, allowing documents to be processed that are orders-of-magnitude larger than the physical memory available. A processor that does not claim conformance with the streaming option must still process a stylesheet and deliver the correct results, but is not required to use streaming algorithms, and may therefore fail with out-of-memory errors when presented with large source documents.
Apart from the fact that there are constructs to request streaming, and rules that must be followed to guarantee that streaming is possible, the language has been designed so there are as few differences as possible between streaming and non-streaming evaluation. The semantics of the language continue to be expressed in terms of the XDM data model, which is substantively unchanged; but readers must take care to observe that when terms like “node” and “axis” are used, the concepts are completely abstract and may have no direct representation in the run-time execution environment.
Streamed processing of a document can be initiated in one of three ways:
The initial mode can be declared as a
streamable mode. In this case
the initial match selection will generally be a document node (or
sequence of document nodes), supplied by the calling application in
a form that allows streaming (that is, in some form other than a tree in
memory; for example, as a reference to a push or pull XML parser primed to
deliver a stream of events). The type of
these nodes can be constrained by using the attribute
on-no-match="fail"
on the initial mode,
and using this mode only for processing the top-level nodes.
Streamed processing of any document can be initiated using the
xsl:source-document
instruction. This has an attribute
href
whose value is the URI of a document to be processed,
and an attribute streamable
that
indicates whether it is to be processed using
streaming; the actual processing to be applied is defined by the
instructions written as children of the xsl:source-document
instruction.
Streamed merging of a set of input documents can be initiated using the
xsl:merge
instruction.
The rules for streamability, which are defined in detail in 19 Streamability, impose two main constraints:
The only nodes reachable from the node that is currently being processed are its attributes and namespaces, its ancestors and their attributes and namespaces, and its descendants and their attributes and namespaces. The siblings of the node, and the siblings of its ancestors, are not reachable in the tree, and any attempt to use their values is a static error.
When processing a given node in the tree, each descendant node can only be visited once. Essentially this allows two styles of processing: either visit each of the children once, and then process that child with the same restrictions applied; or process all the descendants in a single pass, in which case it is not possible while processing a descendant to make any further downward selection.
The second restriction, that only one visit to the children is
allowed, means that XSLT code that was not designed with streaming in mind will often
need to be rewritten to make it streamable. In many cases it is possible to do this
using a technique sometimes called windowing or burst-mode
streaming (note this is not quite the same meaning as
windowing in XQuery 3.0). Many XML documents consist of a large
number of elements, each of manageable size, representing transactions or business
objects where each such element can be processed independently: in such cases, an
effective design pattern is to write a streaming transformation that takes a snapshot
of each element in turn, processing the snapshot using the full power of the XSLT
language. Each snapshot is a tree built in memory and is therefore fully navigable.
For details see the snapshot
and copy-of
functions.
The new facility of accumulators allows applications complete control over how much information is retained (and by implication, how much memory is required) in the course of a pass over a streamed document. An accumulator computes a value for every node in a streamed document: or more accurately, two values, one for the first visit to a node (before visiting its descendants), and a second value for the second visit to the node (after visiting the descendants). The computation is structured in such a way that the value for a given node can depend only on the value for the previous node in document order together with the data available when positioned at the current node (for example, the attribute values). Based on the well-established fold operation of functional programming languages, accumulators provide the convenience and economy of mutable variables while remaining within the constraints of a purely declarative processing model.
When streaming is initiated, for example using the
xsl:source-document
instruction, it is necessary to declare which
accumulators are applicable to the streamed document.
Streaming applications often fall into one of the following categories:
Aggregation applications, where a single aggregation operation (perhaps
count
FO30, sum
FO30,
exists
FO30, or distinct-values
FO30) is
applied to a set of elements selected from the streamed source document by
means of a path expression.
Record-at-a-time applications, where the source document consists of a long
sequence of elements with similar structure (“records”), and each “record” is
processed using the same logic, independently of any other “records”. This kind
of processing is facilitated using the snapshot
and
copy-of
function mentioned earlier.
Grouping applications, where the output follows the structure of the input, except that an extra layer of hierarchy is added. For example, the input might be a flat series of banking transactions in date/time order, and the output might contain the same transactions grouped by date.
Accumulator applications, which are the same as record-at-a-time applications,
except that the processing of one “record” might depend on data encountered
earlier in the document. A classic example is processing a sequence of banking
transactions in which the input transaction contains a debit or credit amount,
and the output adds a running total (the account balance). The
xsl:iterate
instruction has been introduced to facilitate
this style of processing.
Isomorphic transformations, in which there is an ordered (often largely
one-to-one) relationship between the nodes of the source tree and the nodes of
the result tree: for example, transformations that involve only the renaming or
selective deletion of nodes, or scalar manipulations of the values held in the
leaf nodes. Such transformations are most conveniently expressed using
recursive application of template rules. This is possible with a streamed input
document only if all the template rules adhere to the constraints required for
streamability. To enforce these rules, while still allowing unrestricted
processing of other documents within the same transformation, all streaming
evaluation must be carried out using a specific mode, which is declared to be a streaming mode by means of an
xsl:mode
declaration in the stylesheet.
There are important classes of application in which streaming is possible only if multiple streams can be processed in parallel. This specification therefore provides facilities:
allowing multiple sorted input sequences to be merged into one sorted output
sequence (the xsl:merge
instruction)
allowing multiple output sequences to be generated during a single pass of an
input sequence (the xsl:fork
instruction).
These facilities have been designed in such a way that they can readily be implemented using streaming, that is, without materializing the input or output sequences in memory.
Streaming can be combined with schema-aware processing: that is, the streamed input to a transformation can be subjected to on-the-fly validation, a process which typically accepts an input stream from the XML parser and delivers an output stream (of type-annotated nodes) to the transformation processor. The XSD specification is designed so that validation is, with one or two exceptions, a streamable process. The exceptions include:
There may be a need to allocate memory to hold keys, in order to enforce uniqueness
and
referential integrity constraints (xs:unique
, xs:key
, xs:keyref
).
In XSD 1.1, assertions can be defined by means of XPath expressions. These are not constrained to be streamable; in the general case, any subtree of the document that is validated using an assertion may need to be buffered in memory while the assertion is processed.
Applications that need to run in finite memory may therefore need to avoid these XSD features, or to use them with care.
XSD is designed so that the intended type of an element (the “governing type”) can be determined as soon as the start tag of the element is encountered: the process of validation checks whether the content of the element actually conforms to this type, and by the time the end tag is encountered, the process will have established either that the element is valid against the governing type, or that it is invalid.
By default, dynamic errors occurring during streamed processing are fatal: they typically cause the transformation to fail immediately. XSLT 3.0 introduces the ability to catch dynamic errors and recover from them. Schema invalidity, however, is treated as a dynamic error of the instruction that processes the entire input stream, so after a validation failure, no further processing of that input stream is possible.
In consequence, a streamed validator that is running in tandem with a streamed transformation
can present the transformer with element nodes that carry a provisional type annotation
representing
the type that the element will have if it turns out to be valid. As soon as a node
is encountered that
violates this assumption, the validator should stop the flow of data to the transformer,
so that the
transformer never sees invalid data. This allows the stylesheet code to be compiled
with the assumption
of type-safety: at run-time, all nodes seen by the transformation will conform to
their XSLT-declared types
(for example, a type declared implicitly using match="schema-element(invoice)"
on an
xsl:template
element).
A streamed transformation that only accesses part of the input document (for example, a header at the start of a document) is not required to continue reading once the data it needs has been read. This means that XML well-formedness or validity errors occurring in the unread part of the input stream may go undetected.
The facilities in this specification designed to enable large data sets to be processed in a streaming manner are oriented almost entirely to XML data. This does not mean that there is never a requirement to stream non-XML data, or that the Working Group has ignored this requirement; rather, the Working Group has concluded that for the most part, streaming of non-XML data can be achieved by implementations without the need for specific language features in XSLT.
To make streamed processing of unparsed text files easier, the function unparsed-text-lines
FO30
has been introduced. This is not only more convenient for stylesheet authors than
reading the entire input
using the unparsed-text
FO30 function and then tokenizing the result, it is also easier for implementations
to optimize, allowing each line of text to be discarded from memory after it has been
processed.
For all functions that access external data, including document
, doc
FO30,
collection
FO30, unparsed-text
FO30, unparsed-text-lines
FO30,
and (in XPath 3.1) json-doc
FO31, the requirements on determinism can now
be relaxed using implementation-defined configuration options. This is significant
because it means that when a transformation reads the same external resource more
than once, it becomes
legitimate for the contents of the resource to be different on different invocations,
and this eliminates
the need for the processor to cache the contents of the resource in memory.
In the XDM data model, every value is a sequence, and (as with most functional programming languages), processing of sequences of items is pervasive throughout the XSLT and XPath languages and their function library. Good performance of a functional programming language often depends on sequence-based operations being pipelined, and being evaluated in a lazy fashion (that is, many operations process items in a sequence one at a time, in order; and many operations can deliver a result without processing the entire sequence). The semantics of XSLT and XPath permit pipelined and lazy evaluation (for example, the error handling semantics are carefully written to ensure this), but they do not require it: the details are left to implementations. Pipelined processing of a sequence is not the same thing as streamed processing of a tree, and where the XSLT specification talks of operations being “guaranteed streamable”, this is always referring to processing of trees, not of sequences.
The facilities for streaming of XML trees include operations such as copy-of
and snapshot
which are able to take a sequence of streamed nodes as input,
and produce a sequence of in-memory (unstreamed) nodes as output. It is also possible
to generate
a sequence of strings or other atomic values through the process of atomization.
The actual memory usage of a streamed
XSLT application may depend significantly on whether the processing of the resulting
sequence of in-memory
nodes or atomic values is pipelined or not. The specification, however, has nothing
to say on this matter:
it is considered an area where implementers can exercise their discretion and ingenuity.
Streaming of JSON input receives little attention in this specification. One can envisage
an implementation
of the json-to-xml
function in which the XML delivered by the function consists of
streamed nodes; but the Working Group has not researched the feasibility of such an
implementation in any detail.
[Definition: An error that can be detected by examining a stylesheet before execution starts (that is, before the source document and values of stylesheet parameters are available) is referred to as a static error.]
Generally, errors in the structure of the stylesheet, or in the syntax of XPath expressions contained in the stylesheet, are classified as static errors. Where this specification states that an element in the stylesheet must or must not appear in a certain position, or that it must or must not have a particular attribute, or that an attribute must or must not have a value satisfying specified conditions, then any contravention of this rule is a static error unless otherwise specified.
A processor must provide a mode of operation that takes a (possibly erroneous) stylesheet package as input and enables the user to determine whether or not that package contains any static errors.
Note:
The manner in which static errors are reported, and the behavior when there are multiple static errors, are left as design choices for the implementer. It is recommended that the error codes defined in this specification should be made available in any diagnostics.
A processor may also provide a mode of operation in which static errors in parts of the stylesheet that are not evaluated can go unreported.
Note:
For example, when operating in this mode, a processor might report static errors in a template rule only if the input document contains nodes that match that template rule. Such a mode of operation can provide performance benefits when large and well-tested stylesheets are used to process source documents that might only use a small part of the XML vocabulary that the stylesheet is designed to handle.
[Definition: An error that is not capable of detection until a source document is being transformed is referred to as a dynamic error.]
When a dynamic error occurs, and is not caught
using xsl:catch
, the processor
must signal the error, and the transformation fails.
Because different implementations may optimize execution of the stylesheet in different ways, the detection of dynamic errors is to some degree implementation-dependent. In cases where an implementation is able to produce a principal result or secondary result without evaluating a particular construct, the implementation is never required to evaluate that construct solely in order to determine whether doing so causes a dynamic error. For example, if a variable is declared but never referenced, an implementation may choose whether or not to evaluate the variable declaration, which means that if evaluating the variable declaration causes a dynamic error, some implementations will signal this error and others will not.
There are some cases where this specification requires that a construct must
not be evaluated: for example, the content of an xsl:if
instruction must not be evaluated if the test condition is false.
This means that an implementation must not signal any dynamic
errors that would arise if the construct were evaluated.
An implementation may signal a dynamic error before any source document is available, but only if it can determine that the error would be signaled for every possible source document and every possible set of parameter values. For example, some circularity errors fall into this category: see 9.11 Circular Definitions.
There are also some dynamic
errors where the specification gives a processor license to signal the
error during the analysis phase even if the construct might never be executed; an
example is the use of an invalid QName as a literal argument to a function such as
key
, or the use of an invalid regular expression in the
regex
attribute of the xsl:analyze-string
instruction.
A dynamic error is also signaled during the static analysis phase if the error occurs during evaluation of a static expression.
The XPath specification states (see Section 2.3.1 Kinds of Errors XP30) that if any expression (at any level) can be evaluated during the analysis phase (because all its explicit operands are known and it has no dependencies on the dynamic context), then any error in performing this evaluation may be reported as a static error. For XPath expressions used in an XSLT stylesheet, however, any such errors must not be reported as static errors in the stylesheet unless they would occur in every possible evaluation of that stylesheet; instead, they must be signaled as dynamic errors, and signaled only if the XPath expression is actually evaluated.
An XPath processor may report statically that the expression 1 div 0
fails with a “divide by zero” error. But suppose this XPath expression occurs in
an XSLT construct such as:
<xsl:choose> <xsl:when test="system-property('xsl:version') = '1.0'"> <xsl:value-of select="1 div 0"/> </xsl:when> <xsl:otherwise> <xsl:value-of select="xs:double('INF')"/> </xsl:otherwise> </xsl:choose>
Then the XSLT processor must not report an error, because the relevant XPath construct appears in a context where it will never be executed by an XSLT 2.0 or 3.0 processor. (An XSLT 1.0 processor will execute this code successfully, returning positive infinity, because it uses double arithmetic rather than decimal arithmetic.)
[Definition: Certain errors are classified as type errors. A type error occurs when the value supplied as input to an operation is of the wrong type for that operation, for example when an integer is supplied to an operation that expects a node.] If a type error occurs in an instruction that is actually evaluated, then it must be signaled in the same way as a dynamic error. Alternatively, an implementation may signal a type error during the analysis phase in the same way as a static error, even if it occurs in part of the stylesheet that is never evaluated, provided it can establish that execution of a particular construct would never succeed.
It is implementation-defined whether type errors are signaled statically.
The following construct contains a type error, because
42
is not allowed as the value of the select
expression of the xsl:number
instruction (it must be a node). An
implementation may optionally signal this as a static error,
even though the offending instruction will never be evaluated, and the type error
would therefore never be signaled as a dynamic error.
<xsl:if test="false()"> <xsl:number select="42"/> </xsl:if>
On the other hand, in the following example it is not possible to determine
statically whether the operand of xsl:number
will have a suitable dynamic type. An
implementation may produce a warning in such cases, but it
must not treat it as an error.
<xsl:template match="para"> <xsl:param name="p" as="item()"/> <xsl:number select="$p"/> </xsl:template>
If more than one error arises, an implementation is not required to signal any errors other than the first one that it detects. It is implementation-dependent which of the several errors is signaled. This applies both to static errors and to dynamic errors. An implementation is allowed to signal more than one error, but if any errors have been signaled, it must not finish as if the transformation were successful.
When a transformation signals one or more dynamic errors, the final state of any persistent resources updated by the transformation is implementation-dependent. Implementations are not required to restore such resources to their initial state. In particular, where a transformation produces multiple result documents, it is possible that one or more serialized result documents may be written successfully before the transformation terminates, but the application cannot rely on this behavior.
Everything said above about error handling applies equally to errors in evaluating XSLT instructions, and errors in evaluating XPath expressions. Static errors and dynamic errors may occur in both cases.
[Definition: If a transformation has successfully produced a principal result or secondary result, it is still possible that errors may occur in serializing that result . For example, it may be impossible to serialize the result using the encoding selected by the user. Such an error is referred to as a serialization error.] If the processor performs serialization, then it must do so as specified in 26 Serialization, and in particular it must signal any serialization errors that occur.
Errors are identified by a QName. For errors defined in this specification, the
namespace of the QName is always http://www.w3.org/2005/xqt-errors
(and
is therefore not given explicitly), while the local part is an 8-character code in
the form PPSSNNNN. Here PP is always XT
(meaning
XSLT), and SS is one of SE
(static error), DE
(dynamic error), or TE
(type error). Note that the allocation of an error to one of these categories is
purely for convenience and carries no normative implications about the way the error
is handled. Many errors, for example, can be reported either dynamically or
statically. These error codes are used to label error conditions in this
specification, and are summarized in E Summary of Error Conditions.
Errors defined in related specifications ([XPath 3.0], [Functions and Operators 3.0] [XSLT and XQuery Serialization]) use QNames with a similar structure, in the same namespace. When errors occur in processing XPath expressions, an XSLT processor should use the original error code reported by the XPath processor, unless a more specific XSLT error code is available.
Implementations must use the codes
defined in these specifications when signaling dynamic errors, to ensure that
xsl:catch
behaves in an interoperable way across
implementations. Stylesheet authors should note, however, that there are many
examples of errors where more than one rule in this specification is violated, and
where the processor therefore has discretion in deciding which error code to
associate with the condition: there is therefore no guarantee that different
processors will always use the same error code for the same erroneous
input.
Additional errors defined by an implementation (or by an application) may use QNames in an implementation-defined (or user-defined) namespace without risk of collision.
This section describes the overall structure of a stylesheet as a collection of XML documents.
[Definition: The XSLT namespace
has the URI http://www.w3.org/1999/XSL/Transform
. It is used to
identify elements, attributes, and other names that have a special meaning defined
in this specification.]
Note:
The 1999
in the URI indicates the year in which the URI was allocated
by the W3C. It does not indicate the version of XSLT being used, which is
specified by attributes (see 3.7 Stylesheet Element and 3.8 Simplified Stylesheet Modules).
XSLT processors must use the XML namespaces mechanism [Namespaces in XML] to recognize elements and attributes from this namespace. Elements from the XSLT namespace are recognized only in the stylesheet and not in the source document. The complete list of XSLT-defined elements is specified in D Element Syntax Summary. Implementations must not extend the XSLT namespace with additional elements or attributes. Instead, any extension must be in a separate namespace. Any namespace that is used for additional instruction elements must be identified by means of the extension instruction mechanism specified in 24.2 Extension Instructions.
This specification uses a prefix of xsl:
for referring to elements in
the XSLT namespace. However, XSLT stylesheets are free to use any prefix, provided
that there is a namespace declaration that binds the prefix to the URI of the XSLT
namespace.
Note:
Throughout this specification, an element or attribute that is in no namespace, or an expanded QName whose namespace part is an empty sequence, is referred to as having a null namespace URI.
Note:
By convention, the names of XSLT
elements, attributes and functions are all lower-case;
they use hyphens to separate words, and they use abbreviations only if these already
appear
in the syntax of a related language such as XML or HTML. Names of types defined in
XML Schema are regarded as single words and are capitalized exactly as in XML
Schema. This sometimes leads to composite function names such as
current-dateTime
FO30.
[Definition: An element from the XSLT namespace may have any attribute not from the XSLT namespace, provided that the expanded QName (see [XPath 3.0]) of the attribute has a non-null namespace URI. These attributes are referred to as extension attributes.] The presence of an extension attribute must not cause the principal result or any secondary result of the transformation to be different from the results that a conformant XSLT 3.0 processor might produce. They must not cause the processor to fail to signal an error that a conformant processor is required to signal. This means that an extension attribute must not change the effect of any instruction except to the extent that the effect is implementation-defined or implementation-dependent.
Furthermore, if serialization is performed using one of the serialization methods described in [XSLT and XQuery Serialization], the presence of an extension attribute must not cause the serializer to behave in a way that is inconsistent with the mandatory provisions of that specification.
Note:
Extension attributes may be used to modify the behavior of extension functions and extension instructions. They may be used to select processing options in cases where the specification leaves the behavior implementation-defined or implementation-dependent. They may also be used for optimization hints, for diagnostics, or for documentation.
Extension attributes may also be
used to influence the behavior of the serialization methods xml
,
xhtml
, html
, or text
, to the extent that
the behavior of the serialization method is implementation-defined or implementation-dependent. For example, an extension attribute might
be used to define the amount of indentation to be used when
indent="yes"
is specified. If a serialization method other than
one of these four is requested (using a prefixed QName in the method parameter)
then extension attributes may influence its behavior in arbitrary ways. Extension
attributes must not be used to cause the standard serialization methods to
behave in a non-conformant way, for example by failing to report serialization
errors that a serializer is required to report. An implementation that wishes to
provide such options must create a new serialization method for the purpose.
An implementation that does not recognize the name of an extension attribute, or that does not recognize its value, must perform the transformation as if the extension attribute were not present. As always, it is permissible to produce warning messages.
The namespace used for an extension attribute will be copied to the result tree in the normal way if it is in scope
for a literal result element.
This can be prevented using the [xsl:]exclude-result-prefixes
attribute.
The following code might be used to indicate to a particular implementation that
the xsl:message
instruction is to ask the user for confirmation
before continuing with the transformation:
<xsl:message abc:pause="yes" xmlns:abc="http://vendor.example.com/xslt/extensions"> Phase 1 complete </xsl:message>
Implementations that do not recognize the namespace
http://vendor.example.com/xslt/extensions
will simply ignore the
extra attribute, and evaluate the xsl:message
instruction in the
normal way.
[ERR XTSE0090] It is a static error for an element from the XSLT namespace to have an attribute whose namespace is either null (that is, an attribute with an unprefixed name) or the XSLT namespace, other than attributes defined for the element in this document.
The media type application/xslt+xml
has been registered for XSLT stylesheet
modules.
The definition of the media type is at [XSLT Media Type].
This media type should be used for an XML document containing a standard stylesheet module at its top level, and it may also be used for a simplified stylesheet module. It should not be used for an XML document containing an embedded stylesheet module.
[Definition: There are a number of
standard attributes that may appear on any XSLT element: specifically
default-collation
, default-mode
,
default-validation
,
exclude-result-prefixes
, expand-text
, extension-element-prefixes
,
use-when
, version
, and
xpath-default-namespace
.]
These attributes may also appear on a literal result element, but in this case, to distinguish them from
user-defined attributes, the names of the attributes are in the XSLT namespace. They are thus typically written
as xsl:default-collation
, xsl:default-mode
, xsl:default-validation
,
xsl:exclude-result-prefixes
, xsl:expand-text
,
xsl:extension-element-prefixes
, xsl:use-when
,
xsl:version
, or xsl:xpath-default-namespace
.
It is recommended that all these attributes should also be permitted on extension instructions, but this is at the discretion of the implementer of each extension instruction. They may also be permitted on user-defined data elements, though they will only have any useful effect in the case of data elements that are designed to behave like XSLT declarations or instructions.
In the following descriptions, these attributes are referred to generically as
[xsl:]version
, and so on.
These attributes all affect the element they appear on, together with any elements and attributes that have that element as an ancestor. The two forms with and without the XSLT namespace have the same effect; the XSLT namespace is used for the attribute if and only if its parent element is not in the XSLT namespace.
In the case of [xsl:]default-collation
, [xsl:]expand-text
,
[xsl:]version
, and [xsl:]xpath-default-namespace
, the value
can be overridden by a different value for the same attribute appearing on a
descendant element. The effective value of the attribute for a particular stylesheet
element is determined by the innermost ancestor-or-self element on which the
attribute appears.
In an embedded stylesheet module, standard attributes appearing on ancestors of the outermost element of the stylesheet module have no effect.
In the case of [xsl:]exclude-result-prefixes
and
[xsl:]extension-element-prefixes
the values are cumulative. For these
attributes, the value is given as a whitespace-separated list of namespace prefixes,
and the effective value for an element is the combined set of namespace URIs
designated by the prefixes that appear in this attribute for that element and any
of
its ancestor elements. Again, the two forms with and without the XSLT namespace are
equivalent.
The effect of the [xsl:]use-when
attribute is described in 3.13.1 Conditional Element Inclusion.
Because these attributes may appear on any XSLT
element, they are not listed in the syntax summary of each individual
element. Instead they are listed and described in the entry for the
xsl:stylesheet
, xsl:transform
, and xsl:package
elements only. This
reflects the fact that these attributes are often used on the outermost element of the stylesheet, in which case they apply to
the entire stylesheet module
or package manifest.
Note that the effect of these attributes does not extend to stylesheet modules referenced by
xsl:include
or xsl:import
declarations, nor to packages referenced using
xsl:use-package
.
For the detailed effect of each attribute, see the following sections:
[xsl:]default-collation
[xsl:]default-mode
[xsl:]default-validation
see 25.4 Validation
[xsl:]exclude-result-prefixes
[xsl:]expand-text
[xsl:]extension-element-prefixes
[xsl:]use-when
[xsl:]version
see 3.9 Backwards Compatible Processing and 3.10 Forwards Compatible Processing
[xsl:]xpath-default-namespace
see 5.1.2 Unprefixed Lexical QNames in Expressions and Patterns
[Definition: An explicit package is
represented by an xsl:package
element, which will generally be
the outermost element of an XML document. When the
xsl:package
element is not used explicitly, the entire
stylesheet comprises a single implicit package.] (This
specification does not preclude the xsl:package
being embedded in
another XML document, but it will never have any other XSLT element as an
ancestor).
<xsl:package
id? = id
name? = uri
package-version? = string
version = decimal
input-type-annotations? = "preserve" | "strip" | "unspecified"
declared-modes? = boolean
default-mode? = eqname | "#unnamed"
default-validation? = "preserve" | "strip"
default-collation? = uris
extension-element-prefixes? = prefixes
exclude-result-prefixes? = prefixes
expand-text? = boolean
use-when? = expression
xpath-default-namespace? = uri >
<!-- Content: ((xsl:expose | declarations)*) -->
</xsl:package>
[Definition: The content of the
xsl:package
element is referred to as the package
manifest].
The version
attribute indicates the
version of the XSLT language specification to which the package manifest conforms.
The value should normally be
3.0
. If the value is numerically less than 3.0
, the
content of the xsl:package
element is processed using the rules
for backwards compatible
behavior (see 3.9 Backwards Compatible Processing). If the value is
numerically greater than 3.0
, it is processed using the rules for
forwards compatible behavior (see 3.10 Forwards Compatible Processing).
A package typically has a name, given in its name
attribute, which must be an absolute URI. Unnamed packages are
allowed, but they can only be used as the “top level” of an application; they cannot
be the target of an xsl:use-package
declaration in another
package.
A package may have a version identifier, given in
its package-version
attribute. This is used to distinguish different
versions of a package. The value of the version
attribute, after trimming leading and trailing whitespace, must
conform to the syntax given in 3.5.1 Versions of a Package. If no version
number is specified for a package, version 1
is assumed.
The attributes default-collation
, default-mode
, default-validation
,
exclude-result-prefixes
, expand-text
,
extension-element-prefixes
, use-when
,
version
, and xpath-default-namespace
are standard
attributes that can appear on any XSLT element, and potentially affect all descendant
elements. Their meaning is described in 3.4 Standard Attributes.
The package manifest contains the following elements, arbitrarily ordered:
Zero or more xsl:expose
declarations that define the interface
offered by this package to the outside world. An xsl:expose
declaration may appear only as a child of xsl:package
.
Zero or more additional declarations.
These are the same as the declarations permitted as children of xsl:stylesheet
or xsl:transform
.
Some declarations of particular relevance to packages include:
The xsl:use-package
declaration, which declares the names and
versions of the packages on which this package is dependant.
The optional xsl:global-context-item
element; if present this
element defines constraints on the existence and type of the global context item.
Zero or more xsl:include
and xsl:import
declarations, which define additional stylesheet modules to be incorporated into this
package.
Zero or more ordinary declarations, that is,
elements that are permitted as children of xsl:stylesheet
or
xsl:transform
. One possible coding style is to include in
the package manifest just a single xsl:import
or
xsl:include
declaration as a reference to the effective
top-level stylesheet module; this approach is particularly suitable when
writing code that is required to run under earlier releases of XSLT as well as
under XSLT 3.0. Another approach is to include the substance of the top-level
stylesheet module inline within the package manifest.
The following example shows a package that offers a number of functions for manipulating complex numbers. A complex number is represented as a map with two entries, the keys being 0 for the real part, and 1 for the imaginary part.
<xsl:package name="http://example.org/complex-arithmetic.xsl" package-version="1.0" version="3.0" xmlns:xsl="http://www.w3.org/1999/XSL/Transform" xmlns:xs="http://www.w3.org/2001/XMLSchema" xmlns:f="http://example.org/complex-arithmetic.xsl"> <xsl:function name="f:complex-number" as="map(xs:integer, xs:double)" visibility="public"> <xsl:param name="real" as="xs:double"/> <xsl:param name="imaginary" as="xs:double"/> <xsl:sequence select="map{ 0:$real, 1:$imaginary }"/> </xsl:function> <xsl:function name="f:real" as="xs:double" visibility="public"> <xsl:param name="complex" as="map(xs:integer, xs:double)"/> <xsl:sequence select="$complex(0)"/> </xsl:function> <xsl:function name="f:imag" as="xs:double" visibility="public"> <xsl:param name="complex" as="map(xs:integer, xs:double)"/> <xsl:sequence select="$complex(1)"/> </xsl:function> <xsl:function name="f:add" as="map(xs:integer, xs:double)" visibility="public"> <xsl:param name="x" as="map(xs:integer, xs:double)"/> <xsl:param name="y" as="map(xs:integer, xs:double)"/> <xsl:sequence select=" f:complex-number( f:real($x) + f:real($y), f:imag($x) + f:imag($y))"/> </xsl:function> <xsl:function name="f:multiply" as="map(xs:integer, xs:double)" visibility="public"> <xsl:param name="x" as="map(xs:integer, xs:double)"/> <xsl:param name="y" as="map(xs:integer, xs:double)"/> <xsl:sequence select=" f:complex-number( f:real($x)*f:real($y) - f:imag($x)*f:imag($y), f:real($x)*f:imag($y) + f:imag($x)*f:real($y))"/> </xsl:function> <!-- etc. --> </xsl:package>
A more complex package might include private or abstract functions as well as
public functions; it might expose components other than functions (for example,
templates or global variables), and it might contain
xsl:use-package
elements to allow it to call on the services
of other packages.
Note:
In this example, the way in which complex numbers are represented is exposed to
users of the package. It would be possible to hide the representation by
declaring the types on public functions simply as item()
; but this
would be at the cost of type safety.
A package that does not itself expose any components may be written
using a simplified syntax: the xsl:package
element is omitted, and
the xsl:stylesheet
or xsl:transform
element is now
the outermost element of the stylesheet module. For compatibility reasons, all the
named templates and modes declared in the package are made public. More formally,
the
principal stylesheet module of the top-level
package may be expressed as an xsl:stylesheet
or
xsl:transform
element, which is equivalent to the package represented
by the output of the following transformation, preserving the base URI of the
source:
<xsl:transform version="3.0" xmlns:xsl="http://www.w3.org/1999/XSL/Transform" xmlns:t="http://www.w3.org/1999/XSL/TransformAlias"> <xsl:namespace-alias stylesheet-prefix="t" result-prefix="xsl"/> <xsl:template match="xsl:stylesheet|xsl:transform"> <t:package declared-modes="no"> <xsl:copy-of select="@*"/> <t:expose component="mode" names="*" visibility="public"/> <t:expose component="template" names="*" visibility="public"/> <xsl:copy-of select="node()"/> </t:package> </xsl:template> </xsl:transform>
The effect of the input-type-annotations
attribute is defined in 4.4.1 Stripping Type Annotations from a Source Tree.
A more extensive example of a package, illustrating how components in a package can be overridden in a client package, is given in 3.5.7 Worked Example of a Library Package.
If a package has a version number, the version number must conform to the grammar:
PackageVersion ::= NumericPart ( "-" NamePart )? NumericPart ::= IntegerLiteral ( "." IntegerLiteral )* NamePart ::= NCName
Here IntegerLiteralXP30 and NCName
are as defined in
the XPath 3.0 grammar productions of the same name (including rules on
limits). Leading and trailing whitespace is ignored; no other
whitespace is allowed.
Examples of valid version numbers are 2.0.5
or
3.10-alpha
.
[Definition: The integer literals and the optional
NamePart
within the version number are referred to as the
portions of the version number.]
Note:
This means that 1-alpha-2
is a valid version number, with two
portions: 1
and
alpha-2
. The second hyphen is part of the NCName
,
it does not act as a portion separator.
Versions are ordered. When comparing two versions:
Trailing zero portions (that is, any zero-valued integer that is not followed by another integer) are discarded.
Comparison proceeds by comparing portions pairwise from the left.
If both versions have the same number of portions and all portions
compare equal (under the rules of the
XPath eq
operator using the Unicode codepoint
collation), then the versions compare equal.
If the number of portions in the two
versions V1 and V2 is N1 and N2,
with N1<N2, and if all portions in positions 1 to N compare equal, then
V1 is less than V2 if the portion of V2 in position N1 is an integer, and is
greater than V2 if this portion is an
NCName
. For example, 1.2
is less than
1.2.5
, while 2.0
is greater than
2.0-rc1
.
Portions are compared as follows:
If both portions are integers, they are compared using the rules of XPath value comparisons.
If both portions are NCNames, they are compared using the rules of XPath value comparisons, using the Unicode Codepoint Collation.
If one portion is an integer and the other is an
NCName
, the NCName
comes first.
For example, the following shows a possible ordered sequence of version numbers:
0-rc1 < 0-rc2 < 0 < 1 = 1.0 < 1.0.2 < 1.0.3-rc1 < 1.0.3 < 1.0.3.2 < 1.0.10
Note:
The version number format defined here is designed to be general enough to accommodate a variety of conventions in common use, and to allow useful semantics for matching of versions and ranges of versions, without being over-prescriptive. It is influenced by [SemVer], but is not as prescriptive, and it imposes no assumptions about backwards compatibility of packages between successive versions.
Implementations may impose limits on the values used in a version number (or a version range: see below). Such limits are implementation-defined. As a minimum, a processor must accept version numbers including:
A numeric part containing four integers;
Each integer being in the range 0 to 999999;
An NCName
of up to 100 characters
Dependencies between packages may specify a version range (see 3.5.2 Dependencies between Packages). A version range represents a set of accepted versions. The syntax of a version range is shown below. Whitespace is permitted only where indicated, using the terminal symbol S.
PackageVersionRange ::= AnyVersion | VersionRanges AnyVersion ::= "*" VersionRanges ::= VersionRange (S? "," S? VersionRange)* VersionRange ::= PackageVersion | VersionPrefix | VersionFrom | VersionTo | VersionFromTo VersionPrefix ::= PackageVersion ".*" VersionFrom ::= PackageVersion "+" VersionTo ::= "to" S (PackageVersion | VersionPrefix) VersionFromTo ::= PackageVersion S "to" S (PackageVersion | VersionPrefix)
The meanings of the various forms of version range are defined below:
The range AnyVersion
matches any version.
The range VersionRanges
matches a version if any constituent
VersionRange
matches that version.
For example, 9.5.0.8, 9.6.1.2
matches those specific versions only, while 9.5.0.8, 9.6+
matches either version 9.5.0.8 or any version from 9.6 onwards.
A range that is a PackageVersion
matches that version only.
The range VersionPrefix
matches any version whose leading
portions are the same as the portions in the PackageVersion
part of the
VersionPrefix
.
For example, 1.3.*
matches 1.3
,
1.3.5
, 1.3.10.2
, and
1.3-beta
(but not 1
or
1.4
).
Note:
The .*
indicates that additional portions may follow; it does not indicate a substring match
on the final portion. So
1.3.*
does not match 1.35
, and
3.3-beta.*
does not match 3.3-beta12
. Also,
3.3-beta.*
does not match 3.3-beta.5
: this
is because the last dot is not a portion separator, but is part of the
final NCName
. In fact, using .*
after a version
number that includes an NCName
portion is pointless, because
an NCName
portion can never be followed by further
portions.
The range VersionFrom
matches any version that is greater than
or equal to the version supplied.
For example 1.3+
matches
1.3
, 1.3.2
, 1.4
,
and 2.1
(but not 1.3-beta
or 1.2
).
And 1.3-beta+
matches 1.3-beta
,
1.3-gamma
, 1.3.0
, 1.4
,
and 8.0
, but not 1.3-alpha
or
1.2
.
The range VersionTo
matches any version that is less than or
equal to some version that matches the VersionPrefix
.
For example, to 4.0
matches 1.5
,
2.3
, 3.8
, 4.0
,
and 4.0-beta
(but not 4.0.1
), while to
3.3.*
matches 1.5
or 2.0.6
or
3.3.4621
, but not 3.4.0
or
3.4.0-beta
.
The range VersionFromTo
matches any version that is greater
than or equal to the starting PackageVersion
, and less than or
equal to some version that matches the VersionPrefix
.
For example, 1 to 5
matches 1.1
,
2.1
, 3.1
, or 5.0
(but
not 5.1
), while 1 to 5.*
matches all of these,
plus versions such as 5.7.2
(but not 6.0
or
6.0-beta
). Similarly,
1.0-beta to 1.0
matches 1.0-beta
,
1.0-beta.2
, 1.0-gamma
, and 1.0
,
but not 1.0-alpha
or 1.0.1
.
When components in one package reference components in another, the dependency of the first
package on the second must be represented by an xsl:use-package
element. This may appear in the principal stylesheet module
of the first package (which may be a package manifest), or
it may appear in a stylesheet module that is referenced from
the principal stylesheet module via one or more
xsl:include
declarations; however it must not be referenced
via xsl:import
declarations (this is to avoid complications
caused by multiple xsl:use-package
declarations with
different import precedence).
[Definition: If a package Q contains an
xsl:use-package
element that references package
P, then package Q is said to use package
P. In this relationship package Q is referred to as
the using package, package P as the used
package.]
The phrase directly uses is synonymous with uses as defined above, while directly or indirectly uses refers to the transitive closure of this relationship.
<!-- Category: declaration -->
<xsl:use-package
name = uri
package-version? = string >
<!-- Content: (xsl:accept | xsl:override)* -->
</xsl:use-package>
A package may be used by more than one other package, but the relationship must not be cyclic. It is possible, but by no means inevitable, that using the same package in more than one place within a stylesheet will cause static errors due to the presence of conflicting components according to the above rules. Where a package is successfully used by more than one other package, its components may be overridden in different ways by different using packages.
The name
and package-version
attributes together
identify the used package. The value of the
package-version
attribute, if present, must conform to the
rules for a PackageVersionRange
given in 3.5.1 Versions of a Package; if omitted the value *
is assumed,
which matches any version. The used package must have a name that is an exact
match for the name in the name
attribute (using codepoint
comparison), and its explicit or implicit package-version
must
match the version range given in the package-version
attribute.
This specification does not define how the implementation locates a package given its name and version. If several matching versions of a package are available, it does not define which of them is chosen. Nor does it define whether this process locates source code or some other representation of the package contents. Such mechanisms are implementation-defined. Use of the package name as a dereferenceable URI is not recommended, because the intent of the packaging feature is to allow a package to be distributed as reusable code and therefore to exist in many different locations.
[ERR XTSE3000] It is a static error if no package matching the package
name and version specified in an xsl:use-package
declaration can be located.
[ERR XTSE3005] It is a static error if a package is dependent on
itself, where package A is defined as being dependent on package
B if A contains an xsl:use-package
declaration that references B, or if A contains an
xsl:use-package
declaration that references a package
C that is itself dependent on B.
[ERR XTSE3008] It is a static error if an xsl:use-package
declaration appears in a stylesheet module that is not in the
same stylesheet level as the principal stylesheet module
of the package.
Note:
Depending on the implementation architecture, there may be a need to locate used packages both during static analysis (for example, to get information about the names and type signatures of the components exposed by the used package), and also at evaluation time (to link to the implementation of these components so they can be invoked). A failure to locate a package may cause an error at either stage.
The xsl:accept
and xsl:override
elements are
used to modify the visibility or behavior of components acquired from the used
package; they are described in 3.5.3.2 Accepting Components below.
Note:
It is not intrinsically an error to have two
xsl:use-package
declarations that identify the same package
(or different versions of the same package). This has the same effect as
having two declarations that identify packages with different names but
identical content. In most cases it will result in an error ([see ERR XTSE3050])
due to the presence of multiple components with the same name; but
no error would occur, for example, if the used package is empty, or if the
two xsl:use-package
declarations use xsl:accept
to accept non-overlapping subsets of the components in the used package.
This section discusses the use of named components in packages.
The components which can be declared in one package and referenced in another are: functions, named templates, attribute sets, modes, and global variables and parameters.
In addition, keys and accumulators are classified as named components because they can contain references to components in another package, even though they cannot themselves be referenced from outside the package.
Named and unnamed modes come within the scope of this section, but there are differences noted in 3.5.4 Overriding Template Rules from a Used Package.
Not all declarations result in components:
Named declarations that can neither be referenced from outside their
containing package, nor can contain references to components in other
packages (examples are xsl:output
,
xsl:character-map
, and
xsl:decimal-format
) are not considered to be components
and are therefore outside the scope of this section.
Some declarations, such as xsl:decimal-format
and
xsl:strip-space
, declare aspects of the processing
context which are not considered to be components as defined here.
Template rules
(xsl:template
with a match
attribute) are
also not considered to be components for the purposes of this section, which
is concerned only with components that are bound by name. However, when an
xsl:template
has both a match
attribute and
a name
attribute, then it establishes both a template rule and
a named template, and in its role
as a named template it comes within the scope of this discussion.
A named declaration, for example a named template, a function, or a global variable, may be overridden within the same package by another like-named declaration having higher import precedence. When a declaration is overridden in this way it cannot be referenced by name either from within its containing package or from outside that package.
In the case of xsl:attribute-set
and xsl:key
declarations, several declarations combine to
form a single component.
The section is largely concerned with details of the rules that affect references from one component to another by name, whether the components are in the same package or in different packages. The rules are designed to meet a number of requirements:
A component defined in one package can be overridden by a component in another package, provided the signatures are type-compatible.
The author of a package can declare whether the components in the package are public or private (that is, whether or not they can be used from outside the package) and whether they are final, overridable, or abstract (that is whether they can or must be overridden by the using package).
Within an application, two packages can make use of a common library and override its components in different ways.
Visibility of components can be defined either as part of the declaration of the component, or in the package manifest.
An application that wishes to make use of a library package can be selective about which components from the library it acquires, perhaps to avoid name clashes between components acquired from different libraries.
[Definition: The term component is used to refer to any of the following: a stylesheet function, a named template, a mode, an accumulator, an attribute set, a key, global variable, or a mode.]
[Definition: The symbolic identifier of a component is a composite name used to identify the component uniquely within a package. The symbolic identifier comprises the kind of component (stylesheet function, named template, accumulator, attribute set, global variable, key, or mode), the expanded QName of the component (namespace URI plus local name), and in the case of stylesheet functions, the arity.]
Note:
In the case of the unnamed mode, the expanded QName of the component may be considered to be some system-allocated name different from any user-defined mode name.
[Definition: Two components are said to be homonymous if they have the same symbolic identifier.]
Every component has a declaration in some stylesheet module and therefore within some package. In the case of attribute sets and keys, there may be several declarations. The declaration is an element in an XDM tree representing the stylesheet module. Declarations therefore have identity, based on XDM node identity.
[Definition: The declaring
package of a component is the
package that contains the declaration (or,
in the case of xsl:attribute-set
and
xsl:key
, multiple declarations) of the
component.]
When a component declared in one package is made available in another, the using package will contain a separate component that can be regarded as a modified copy of the original. The new component shares the same symbolic identifier as the original, and it has the same declaration, but it has other properties such as its visibility that may differ from the original.
[Definition: A
component declaration results in multiple components, one in the package in
which the declaration appears, and potentially one in each package that uses
the declaring package, directly or indirectly, subject to the visibility of the
component. Each of these multiple components has the same declaring package, but each has a different containing
package. For the original component, the declaring package and the
containing package are the same; for a copy of a component made as a result of
an xsl:use-package
declaration, the declaring package will be
the original package, and the containing package will be the package in which
the xsl:use-package
declaration appears.]
Note:
Within this specification, we generally use the notation CP for a component named C whose declaring package and containing package are both P; and the notation CPQ for a component whose containing package is P and whose declaring package is Q (that is, a component in P that is derived from a component CQ in the used package Q).
The properties of a component are as follows:
The original declaration of the component.
The package to which the component belongs (called its containing package, not to be confused with the declaring package).
The symbolic identifier of the component.
The visibility of the component,
which determines the way in which the component is seen by other components
within the same package and within using packages. This is one of
public
, private
, abstract
,
final
, or hidden
. The visibility of components
is discussed further in 3.5.3.1 Visibility of Components.
A set of bindings for the symbolic references in the component. The way in which these bindings are established is discussed further in 3.5.3.5 Binding References to Components.
Note:
When a function F defined in a package P is acquired by two using packages Q and R, we may think of P, Q, and R as all providing access to the “same” function. The detailed semantics, however, demand an understanding that there is one function declaration, but three components. The three components representing the function F within packages P, Q, and R have some properties in common (the same symbolic identifier, the same declaration), but other properties (the visibility and the bindings of symbolic references) that may vary from one of these components to another.
[Definition: The declaration of a component includes
constructs that can be interpreted as references to other components by means of their symbolic identifiers. These
constructs are generically referred to as symbolic references.
Examples of constructs that give rise to symbolic references are the
name
attribute of xsl:call-template
; the
[xsl:]use-attribute-sets
attribute of
xsl:copy
, xsl:element
, and literal result elements; the
explicit or implicit
mode
attribute of xsl:apply-templates
; XPath
variable references referring to global variables; XPath static function calls (including partial function
applications) referring to stylesheet functions; and
named function references (example: my:f#1
) referring to
stylesheet functions.
]
Symbolic references exist as properties of the declaration of a component.
The symbolic identifier being
referred to can be determined straightforwardly from the syntactic form and
context of the reference: for example, the instruction <xsl:value-of
select="f:price($o)" xmlns:f="http://f.com/"/>
contains a symbolic
reference to a function with expanded name {http://f.com/}price
and
with arity=1. However, because there may be several (homonymous) function
components with this symbolic identifier, translating this symbolic reference into
a reference to a specific component (a process called “binding”) is less
straightforward, and is described in the text that follows.
The process of assembling a stylesheet from its constituent packages is primarily a process of binding these symbolic references to actual components. Within any component whose declaration is D, there is a set of bindings; each binding is an association between a symbolic reference in D and a component whose symbolic identifier matches the outward reference. Outward references for which a component C contains a binding are said to be bound in C; those for which C contains no binding are said to be unbound.
For example, suppose that in some package Q, function A
calls B, which in turn calls C, and that B is
private
. Now suppose that in some package P which uses
Q, C is overridden. The effect of the binding process is
that P will contain three components corresponding to A,
B, and C, which we might call AP,
BP, and CP. The declarations of AP and BP are in package
Q, but the declaration of CP is in P. The
internal visibility of BP will be hidden
(meaning that it
cannot be referenced from within P), and BP will contain a
binding for the component CP that corresponds to the outward reference
from B to C. The effect is that when A calls
B and B calls C, it is the overriding version
of C that is executed.
In another package R that uses Q without overriding C, there will be three different components AR, BR, and CR. This time the declaration of all three components is in the original package Q. Component BR will contain a binding to CR, so in this package, the original version of C is executed. The fact that one package P overrides C thus has no effect on R, which does not override it.
The binding process outlined above is described in more detail in 3.5.3.5 Binding References to Components.
Template rules are not components in their own right; unlike named templates, they are never referenced by name. Component references within a template rule (for example, references to functions, global variables, or named templates) are treated as occurring within the component that represents the containing mode. This includes component references within the match patterns of template rules. If a template rule lists several modes, it is treated as if there were multiple template rules one in each mode.
An xsl:apply-templates
instruction
with no mode
attribute is treated as a reference to the default mode
defined for that instruction (see 3.7.2 The default-mode Attribute), which in turn defaults to the unnamed mode. An implicit
reference to the unnamed made is treated in the same way as any other symbolic reference. Note that there is an unnamed mode in every
package, and the unnamed mode always has private visibility.
Where an xsl:template
element has both
a name
and a match
attribute, it is treated as if there
were two separate xsl:template
elements, one with a
name
attribute and one with a match
attribute.
Keys
and accumulators behave rather differently from other
components. Their visibility is always private, which means they can only be used
within their declaring package. In addition, the component binding is generally
made dynamically rather than statically, by
virtue of a string passed as an argument to the function
key
, accumulator-before
, or
accumulator-after
. (In the case of accumulators, there
can also be static references: see the use-accumulators
attribute
of xsl:source-document
,
xsl:merge-source
, and xsl:mode
.)
However, outward references from key
definitions and accumulators to other components (such as global
variables and functions) behave in the same way as component references contained
in any other private component, in that they may be re-bound to an overriding
declaration of the target component.
[Definition: The visibility of a
component is one of:
private
, public
, abstract
,
final
, or hidden
.]
The meanings of these visibility values is as follows:
The component can be referenced from other components in this package or in any using package; it can be overridden by a different component in any using package.
The component can be referenced from other components in this package; it cannot be referenced or overridden within a using package.
The component can be referenced from other components in this package or in any using package; in a using package it can either remain abstract or be overridden by a different component.
The component can be referenced from other components in this package or in any using package; it cannot be overridden by a different component in any using package.
The component cannot be referenced from other components in this package; it cannot be referenced or overridden within a using package.
Note:
The visibility of a component in a package P primarily affects
how the component can be used in other packages, specifically, packages that
use P. There is one exception: if the visibility is
hidden
, it also affects how the component can be used within
P.
When a component is declared within a particular
package, its visibility, which affects
how it can be used in other (using) packages, depends on two factors: the value
of the visibility
declaration on the declaration itself (if
present), and the rules given in the xsl:expose
declarations
of the package manifest.
The xsl:function
, xsl:template
,
xsl:attribute-set
, xsl:variable
,
and
xsl:mode
declarations each have an optional
visibility
attribute. The value is one of private
,
public
, abstract
, or final
(never
hidden
). In the case of
an xsl:param
element there is no explicit
visibility
attribute; rather the declaration has the
implicit attribute visibility="public"
.
Any xsl:expose
declarations that
appear as children of xsl:package
define the visibility of
components whose declaration has no explicit visibility
attribute,
and can also be used to reduce the visibility of components where this
attribute is present.
<xsl:expose
component = "template" | "function" | "attribute-set" | "variable" | "mode" | "*"
names = tokens
visibility = "public" | "private" | "final" | "abstract" />
The xsl:expose
element allows the visibility of selected components within a package to be defined.
The components in question are identified using their symbolic identifiers. The
component
attribute defines the kind of component that is
selected.
The value *
means “all component kinds”;
in this case the value of the names
attribute must be a WildcardXP30.
An xsl:expose
declaration has no effect on the
unnamed mode, which is always private to a package.
The names
attribute selects a subset of these components by name
(and in the case of functions, arity); its value is a whitespace-separated
sequence of tokens each of which is either a NameTestXP30 or a NamedFunctionRefXP30. (Examples are
*
, p:*
, *:local
,
p:local
, and p:local#2
.)
The value may be a NamedFunctionRef
only in the case of stylesheet
functions, and distinguishes functions with the same name and different
arity.
The visibility of a named template, function, variable, attribute set, or mode declared within a package is the first of the following that applies, subject to consistency constraints which are defined below:
The visibility of a variable declared using
an xsl:param
element is
always public
. No xsl:expose
element
ever matches an xsl:param
component.
Note:
Attempting to match an xsl:param
with
an explicit EQName
will therefore always give an error, while
using a wildcard has no effect.
If the package manifest contains an xsl:expose
element
that matches this component by virtue of an explicit EQName
or NamedFunctionRef
(that is, not by virtue of a wildcard
match), then the value of the visibility
attribute of the
last such xsl:expose
element in document order (call
this the explicit exposed visibility).
If the declaration of the component has a visibility
attribute, then the value of this attribute (call this the declared
visibility).
If the package manifest contains an xsl:expose
element
that matches this component by virtue of a wildcard match that specifies
either the namespace part of the component name or the local part of the
name (for example, prefix:*
or *:local
or
Q{uri}*
), then the value of the visibility
attribute of the last such xsl:expose
element in
document order.
If the package manifest contains an xsl:expose
element
that matches this component by virtue of a wildcard match that matches
all names (that is, *
), then the value of the
visibility
attribute of the last such
xsl:expose
element in document order.
Otherwise, private
.
Note:
In the above rules, no distinction is made between declarations that specify
a specific component kind, and those that specify component="*"
. If both match,
the value of the component
attribute plays no role in deciding which
declaration wins.
If both a declared visibility and an explicit
exposed visibility exist for the same component, then as mentioned above, they
must be consistent. This is determined by reference to the following table,
where the entry N/P means “not permitted”. (In cases where the combination is
permitted, the actual visibility is always the same as the visibility
determined by xsl:expose
.)
Explicit exposed visibility | Declared visibility | |||
---|---|---|---|---|
public | private | final | abstract | |
public | public | N/P | N/P | N/P |
private | private | private | private | N/P |
final | final | N/P | final | N/P |
abstract | N/P | N/P | N/P | abstract |
[ERR XTSE3010] It is a static error if the
explicit exposed visibility of a component is inconsistent with its
declared visibility, as defined in the above table. (This error occurs
only when the component declaration has an explicit
visibility
attribute, and the component is also listed
explicitly by name in an xsl:expose
declaration.)
[ERR XTSE3020] It is a static error if a token
in the names
attribute of xsl:expose
, other
than a wildcard, matches no component in the containing package.
[ERR XTSE3022] It is a static error if the
component
attribute of xsl:expose
specifies *
(meaning all component kinds) and the names
attribute is not a wildcard.
Note:
There is no ambiguity, and no error, if several tokens within the same
xsl:expose
element match the same component.
If the visibility of a component as established by the above rules
is abstract
, then the component must have a declared visibility of abstract
.
Note:
In other words, the xsl:expose
declaration cannot be used to make a component
abstract unless it was declared as abstract to start with.
[ERR XTSE3025] It is a static error if the
effect of an xsl:expose
declaration would be to make a component
abstract
, unless the component is already abstract
in the absence of the xsl:expose
declaration.
For a component accepted into a package P
from another package Q, the visibility of the component in P (which primarily
affects how it can be used in a package R that uses P)
depends on the visibility declared in the relevant xsl:accept
or xsl:override
element in P (see 3.5.3.2 Accepting Components); this in turn has a default that depends on
the visibility of the corresponding component in Q. In this case the
visibility is unaffected by any xsl:expose
declaration in
P.
When a package P uses a package Q, by virtue of an
xsl:use-package
element in the package manifest of P, then
P will contain a component
corresponding to every component in Q. The visibility of the component within
P depends on the visibility of the component in Q, optionally modified
by two elements that may appear as children of the
xsl:use-package
element, namely xsl:accept
and xsl:override
.
For every component CQ in package Q that is not matched
by any xsl:override
or xsl:accept
element in
the package manifest of P, there will be a corresponding component
CP in package P that has the same symbolic identifier and declaration as CQ.
If CQ is an xsl:param
component, then the visibility of CP is
public
.
In other cases, the visibility of CP depends on the visibility of CQ, as defined by the following table:
Visibility in used package CQ | Visibility in using package CP |
---|---|
public | private |
final | private |
private | hidden |
hidden | hidden |
abstract | hidden |
Note:
The effect of these rules is as follows:
Components that are public or final in the used package Q become private in the using package P. This means that they can be referenced within P but are not (by default) visible within a package R that uses P.
Components that are private or hidden in the used package Q become hidden in the using package P. This means that they cannot be referenced within P; but if they contain references to components that are overridden in P, the hidden component’s references are bound to the overriding components in P.
Components that are abstract in the used package Q become hidden in the using package P. The hidden component in this case raises a dynamic error if it is invoked. Such an invocation cannot originate within P, because the component is not visible within P; but it can occur if a public component in Q is invoked, which in turn invokes the abstract component.
<xsl:accept
component = "template" | "function" | "attribute-set" | "variable" | "mode" | "*"
names = tokens
visibility = "public" | "private" | "final" | "abstract" | "hidden" />
The xsl:accept
element has very similar syntax and semantics
to xsl:expose
. Whereas xsl:expose
allows a
package to restrict the visibility of its own components to other (using)
packages, xsl:accept
allows a package to restrict the
visibility of components exposed by a package that it uses. This may be
necessary if, for example, it uses two different packages whose component names
conflict. It may also simply be good practice if the package author knows that
only a small subset of the functionality of a used package is required.
The rules for determining whether an xsl:accept
element
matches a particular component, and for which element to use if there are
several matches, are the same as the rules for the xsl:expose
element.
No xsl:accept
element
ever matches a variable declared using xsl:param
.
Note:
Attempting to match an xsl:param
with
an explicit EQName
will therefore always give an error, while
using a wildcard has no effect.
[ERR XTSE3030] It is a static error if a token
in the names
attribute of xsl:accept
, other
than a wildcard, matches no component in the used package.
[ERR XTSE3032] It is a static error if the
component
attribute of xsl:accept
specifies *
(meaning all component kinds) and the names
attribute is not a wildcard.
In the absence of a matching xsl:override
element (see
3.5.3.3 Overriding Components from a Used Package), the visibility of a component that matches an
xsl:accept
element depends both on the
visibility
attribute of the best-matching
xsl:accept
element and on the visibility of the corresponding component in the used package,
according to the following table. In this table the entry “N/P” means “not
permitted”.
Visibility in xsl:accept element
|
Visibility in used package | |||
---|---|---|---|---|
public | private | final | abstract | |
public | public | N/P | N/P | N/P |
private | private | N/P | private | N/P |
final | final | N/P | final | N/P |
abstract | N/P | N/P | N/P | abstract |
hidden | hidden | N/P | hidden | hidden |
[ERR XTSE3040] It is a static error if the
visibility assigned to a component by an xsl:accept
element is incompatible with the visibility of the corresponding
component in the used package, as defined by the above table, unless the
token that matches the component name is a wildcard, in which case the
xsl:accept
element is treated as not matching that
component.
[ERR XTSE3050] It is a static error if the
xsl:use-package
elements in a package manifest cause two or more
homonymous components to be
accepted with a visibility other than hidden
.
Conflicts between the components accepted from used packages and those declared within the package itself are handled as follows:
If the conflict is between two components both declared within the package itself, then it is resolved by the rules relating to import precedence defined for each kind of component.
If the conflict is between two components both accepted from used packages, or between a component declared within the package and an accepted component, then a static error occurs.
If a component is explicitly accepted from a used package (by name, rather
than by a matching wildcard), and if the same component is the subject
of an xsl:override
declaration, then a static error
occurs (see below). There is no conflict, however, if a component declared
within xsl:override
also matches a wildcard in an xsl:accept
element.
[ERR XTSE3051] It is a static error if
a token in the names
attribute of xsl:accept
,
other than a wildcard, matches the symbolic name of a component declared
within an xsl:override
child of the same
xsl:use-package
element.
Where the used package Q contains a component whose
visibility is abstract
, the using package P has three options:
P can accept the component with visibility="abstract"
.
In this case P can contain references to the component, but invocation via
these references will fail unless a non-abstract overriding component has
been supplied in some package R that (directly or indirectly) uses P.
P can accept the component with visibility="hidden"
.
In this case P cannot contain references to the component, and invocation via
references in Q will always fail with a dynamic error. This is the default
if P does not explicitly accept or override the component.
P can provide a concrete implementation of the component
within an xsl:override
element.
Any invocation of the absent component (typically from within its declaring package) causes a dynamic error, as if the component were overridden by a component that unconditionally raises a dynamic error.
[ERR XTDE3052] It is a dynamic error if an invocation of an abstract component is evaluated.
Note:
This can occur when a public component in the used package invokes
an abstract component in the used package, and the using package provides
no concrete implementation for the component in an xsl:override
element.
Note:
To override a component accepted from a used package, the overriding
declaration must appear as a child of the xsl:override
element.
Note:
There is no rule that prevents a function (say) being declared in the using
package with the same name as a private
function in the used
package. This does not create a conflict, since all references in the used
package are bound to one function and all those in the using package are
bound to another.
[Definition: A component in a using package may
override a component in a used package, provided that the
visibility of the component in the
used package is either abstract
or public
. The
overriding declaration is written as a child of the
xsl:override
element, which in turn appears as a child
of xsl:use-package
.]
<xsl:override>
<!-- Content: (xsl:template | xsl:function | xsl:variable | xsl:param | xsl:attribute-set)* -->
</xsl:override>
Note:
This mechanism is distinct from the mechanism for overriding declarations within the same package by relying on import precedence. It imposes stricter rules: the overriding component is required to be type-compatible with the component that it overrides.
If the used package Q contains a component
CQ and the xsl:use-package
element contains an
xsl:override
element which contains a declaration
D whose symbolic
identifier matches the symbolic identifier of CQ, then
the using package P will contain a component CP whose
declaration is D, whose symbolic identifier is that of D, and whose visibility is equal to the value of the visibility
attribute of D, or private
if this is absent,
except in the case
of xsl:param
, which is implicitly
public
.
The using package P will also contain a component CPQ
whose body is the same as the body of CQ and whose visibility is hidden
. This
component is used as the target of a binding for the symbolic reference
xsl:original
described below.
Other than its appearance as a child of xsl:override
, the
overriding declaration is a normal xsl:function
,
xsl:template
, ,
xsl:variable
, xsl:param
, or
xsl:attribute-set
element. In the case of
xsl:variable
and xsl:param
, the variable
that is declared is a global
variable.
The rules in the remainder of this section apply to
components having a name
attribute (named
components). The only element with no name
attribute that
can appear as a child of xsl:override
is an
xsl:template
declaration having a match
attribute (that is, a template rule). The rules for
overriding of template rules appear in 3.5.4 Overriding Template Rules from a Used Package. If
an xsl:template
element has both a name
attribute
and a match
attribute, then it defines both a named component and
a template rule, and both sections apply.
[ERR XTSE3055] It is a static error if a
component declaration appearing as a child of
xsl:override
is homonymous with any other declaration in the using package,
regardless of import
precedence, including any other overriding declaration in
the package manifest of the using package.
Note:
When an attribute set is overridden, the
overriding attribute set must be defined using a single
xsl:attribute-set
element. Attribute sets defined in
different packages are never merged by virtue of having the same name,
though they may be merged explicitly by using the
use-attribute-sets
attribute.
[ERR XTSE3058] It is a static error if a
component declaration appearing as a child of
xsl:override
does not match (is not homonymous with) some component in the
used package.
[ERR XTSE3060] It is a static error if the
component referenced by an xsl:override
declaration has
visibility other than
public
or abstract
A package is executable if and only if it contains no component whose visibility is abstract
. A package that is not
executable is not a stylesheet, and
therefore cannot be nominated as the stylesheet to be used when initiating a
transformation.
Note:
In other words, if a component is declared as abstract, then some package that uses the declaring package of that component directly or indirectly must override that component with one that is not abstract. It is not necessary for the override to happen in the immediately using package.
[ERR XTSE3070] It is a static error if the signature of an overriding component is not compatible with the signature of the component that it is overriding.
[Definition: The signatures of two components are compatible if they present the same interface to the user of the component. The additional rules depend on the kind of component.]
Compatibility is only relevant when comparing two components that have the same symbolic identifier. The compatibility rules for each kind of component are as follows:
Two attribute sets with the same name are compatible if and only if they satisfy the following rule:
If the overridden attribute set specifies
streamable="yes"
then the overriding attribute set
also specifies streamable="yes"
.
Two functions with the same name and arity are compatible if and only if they satisfy all the following rules:
The declared types of the arguments
(defaulting to item()*
) are pairwise identical.
The declared return types
(defaulting to item()*
) are identical.
The effective value of the
new-each-time
attribute on the overriding function is the same as its value on the overridden function.
If the overridden function specifies
streamable="yes"
then the overriding function also
specifies streamable="yes"
, and in addition, it has
the same posture and sweep
as the function that it overrides.
Two named templates with the same name are compatible if and only if they satisfy all the following rules:
Their return types are identical.
For every non-tunnel parameter on the overridden template, there is a
non-tunnel parameter on the overriding template that has the same name, an
identical required
type, and the same effective value for the required
attributes.
For every tunnel parameter P on the overridden template, if there is a parameter Q on the overriding template that has the same name as P then Q is also a tunnel parameter, and P and Q have identical required types.
Any parameter on the overriding template for which there is no
corresponding parameter on the overridden template specifies
required="no"
.
The two templates have equivalent
xsl:context-item
children, where equivalence
means that the use
attributes are the same and the
required types are identical; an absent
xsl:context-item
is equivalent to one that
specifies use="optional"
and
as="item()"
.
Two variables (including parameters) with the same name are compatible if and only if they satisfy all the following rules:
Their declared types are identical.
Note:
A variable may override a parameter or vice-versa, and the initial value may differ.
Because static variables and parameters are
constrained to have visibility private
,
they cannot be overridden in another package. The compatibility rules
therefore do not arise. The reason that such variables cannot be
overridden is that they are typically used during stylesheet
compilation (for example, in [xsl:]use-when
expressions
and shadow attributes) and it is a design goal that packages should be
capable of independent compilation.
[Definition: Types S and T are considered identical for the purpose of
these rules if and only if subtype(S, T)
and subtype(T,
S)
both hold, where the subtype relation is defined in Section
2.5.6.1 The judgement subtype(A, B)
XP30.]
Note:
One consequence of this rule is that two plain union types are considered identical if they have the same set of member types, even if the union types have different names or the ordering of the member types is different.
Consider a function that accepts an argument
whose declared type is a union type with member types xs:double
and xs:decimal
, in that order (we might write this as union(xs:double, xs:decimal)
).
Using the same notation, this can be overridden by a function that declares the argument
type as union(xs:decimal, xs:double)
. This does not affect type checking:
a function call that passes the type checking rules with one signature will also pass
the
type checking rules with the other. It does however affect the way that the function
conversion rules work: a call that passes the xs:untypedAtomic
value
"93.7"
(or an untyped node with this as its string value) will be converted to
an xs:decimal
in one case and an xs:double
in the other.
While this rule may appear formal, it is not as straightforward as might be supposed, because the subtype relation in XPath has a dependency on the “Type derivation OK (Simple)” relation in XML Schema, which itself appeals to a judgement as to whether the two type definitions being compared “are the same type definition”. Both XSD 1.0 and XSD 1.1 add the note “The wording of [this rule] appeals to a notion of component identity which is only incompletely defined by this version of this specification.” However, they go on to say that component identity is well defined if the components are named simple type definitions, which will always apply in this case. For named atomic types, the final result of these rules is that two atomic types are identical if and only if they have the same name.
Modes are not overridable, so the xsl:mode
declaration cannot
appear as a child of xsl:override
.
Within the declaration of an overriding named component
(that is, a component whose declaration is a child of
xsl:override
, and has a name
attribute), where
the overridden component has public visibility, it is
possible to use the name xsl:original
as a symbolic reference to
the overridden component. More specifically:
Within a named template appearing as a child of
xsl:override
, the name xsl:original
may appear as the value of the name
attribute of
xsl:call-template
: for example,
<xsl:call-template name="xsl:original"/>
.
Within a stylesheet function appearing as a child of
xsl:override
, the static context for contained XPath
expressions (other than static
expressions) is augmented as follows: the statically
known function signatures includes a mapping from the name
xsl:original
to the signature of the overridden
function (which is the same as the signature of the overriding function).
This means that the name xsl:original
can be used in static
function calls, including calls that use partial function application
(where one of the arguments is given as "?"), and also in named function
references. For example: xsl:original($x)
,
xsl:original($x, ?)
, xsl:original#2
.
Note:
The result of calling function-name(xsl:original#2)
is
the name of the overridden function, not
xsl:original
.
Neither xsl:original
, nor the overridden function, is added
to the named functions component of the dynamic context for
XPath expressions within the overriding function. This means that any
attempt to bind the function name xsl:original
dynamically
(for example using function-lookup
FO30, or
function-available
, or
xsl:evaluate
) will fail, and any attempt to bind
the name of the overriding/overridden function dynamically will return
the overriding function.
Within a global variable or parameter appearing as a
child of xsl:override
, the static context for contained
XPath expressions (other than static
expressions) is augmented as follows: the in-scope
variables includes a mapping from the name
xsl:original
to the declared type of the overridden
variable or parameter (which is the same as the type of the overriding
global variable or parameter).
Within an attribute set appearing as a child of
xsl:override
, any
[xsl:]use-attribute-sets
attribute (whether on the
xsl:attribute-set
element itself, or on any
descendant element) may include the name xsl:original
as a
reference to the overridden attribute set.
Within the overriding component CP, the symbolic reference
xsl:original
is bound to the hidden component CPQ
described earlier, whose body is that of the component CQ in the
used package.
[ERR XTSE3075] It is a static error to use the
component reference xsl:original
when the overridden
component has visibility="abstract"
.
Modes are not overridable, so the name
xsl:original
cannot be used to refer to a mode (for example in the mode
attribute of
xsl:apply-templates
).
Note:
In the case of variables, templates, and attribute sets, the invocation of the overridden component can occur only within the lexical scope of the overriding component. With functions, however, there is greater flexibility. The overriding component can obtain a reference to the overridden component in the form of a function item, and can export this value by passing it to other functions or returning it in its result. A dynamic invocation of this function item (and hence, of the overridden function) can thus occur anywhere.
[Definition: The process of identifying the component to which a symbolic reference applies (possibly chosen from several homonymous alternatives) is called reference binding.]
The process of reference binding in the presence of overriding declarations is best illustrated by an example. The formal rules follow later in the section.
Consider a package Q defined as follows:
<xsl:package name="Q" version="3.0" xmlns:xsl="http://www.w3.org/1999/XSL/Transform"> <xsl:variable name="A" visibility="final" select="$B + 1"/> <xsl:variable name="B" visibility="private" select="$C * 2"/> <xsl:variable name="C" visibility="public" select="22"/> </xsl:package>
(The process is illustrated here using variables as the components, but the logic would be the same if the example used functions, named templates, or attribute sets.)
There are three components in this package, and their properties are illustrated in the following table. (The ID column is an arbitrary component identifier used only for the purposes of this exposition.)
ID | Symbolic Name | Declaring Package | Containing Package | Visibility | Body | Bindings |
---|---|---|---|---|---|---|
AQ | variable A | Q | Q | final | $B + 1 |
$B → BQ |
BQ | variable B | Q | Q | private | $C * 2 |
$C → CQ |
CQ | variable C | Q | Q | public | 22 |
none |
Now consider a package P that uses Q, and that overrides one of the variables declared in Q:
<xsl:package name="P" version="3.0" xmlns:xsl="http://www.w3.org/1999/XSL/Transform"> <xsl:use-package name="Q"> <xsl:override> <xsl:variable name="C" visibility="private" select="$xsl:original + 3"/> </xsl:override> </xsl:use-package> <xsl:template name="T" visibility="public"> <xsl:value-of select="$A"/> </xsl:template> </xsl:package>
Package P has five components, whose properties are shown in the following table:
ID | Symbolic Name | Declaring Package | Containing Package | Visibility | Body | Bindings |
---|---|---|---|---|---|---|
APQ | variable A | Q | P | final | $B + 1 |
$B → BPQ |
BPQ | variable B | Q | P | hidden | $C * 2 |
$C → CP |
CPQ | variable C | Q | P | hidden | 22 |
none |
CP | variable C | P | P | private | $xsl:original + 3 |
$xsl:original → CPQ |
TP | template T | P | P | public | value-of select="$A |
$A → APQ |
The effect of these bindings is that when template T is called,
the result is 51
. This is why:
The result of T is the value of APQ.
The value of APQ is the value of BPQ plus 1.
The value of BPQ is the value of CP times 2.
The value of CP is the value of CPQ plus 3.
The value of CPQ is 22.
So the final result is ((22 + 3) * 2) + 1
In this example, the components of P are established in three different ways:
Components APQ, BPQ, and CPQ are modified copies of the corresponding component AQ, BQ, and CQ in the used package Q. The properties of these components are modified as follows:
The symbolic identifier, declaring package, and body are unchanged.
The containing package is changed to P.
The visibility is changed according to the
rules in 3.5.3.2 Accepting Components: in particular,
visibility="private"
changes to
visibility="hidden"
.
The references to other components are rebound as described in this section.
Component CP is the overriding component. Its properties
are exactly as if it were declared as a top-level component in
P (outside the xsl:use-package
element), except that (a) it must adhere to the constraints on
overriding components (see 3.5.3.3 Overriding Components from a Used Package), (b) it is allowed to use
the variable reference $xsl:original
, and (c) the fact
that it overrides CQ affects the way that references from
other components are rebound.
Component TP is a new component declared locally in P.
The general rules for reference binding can now be stated:
If the containing package of a component CP is P, then all symbolic references in CP are bound to components whose containing package is P.
When a package P uses a package Q, then for every component CQ in Q, there is a corresponding component CP in P, as described in 3.5.3.2 Accepting Components.
Given a component CP whose containing package and declaring package are the same package P, then (as a consequence of rules
elsewhere in this specification) for every symbolic reference
D within CP, other than a reference using the name
xsl:original
, there will always be exactly one non-hidden
component DP whose containing package is P and
whose symbolic identifier matches D
(otherwise a static error will have been reported). The reference is then
bound to DP.
In the case of a component reference using the name
xsl:original
, this will in general appear within a
component CP that overrides a component CQ whose
corresponding component in P is CPQ, and the
xsl:original
reference is bound to CPQ.
Given a component CP whose containing package
P is a different package from its declaring package
R (that is, CP is present in P by
virtue of an xsl:use-package
declaration referencing
package Q, which may or may not be the same as R),
then the component bindings in CP are derived from the
component bindings in the corresponding component CQ as
follows: if the component binding within CQ is to a component
DQ, then:
If DQ is overridden within P by a component DP, then the reference is bound to DP;
Otherwise, the reference is bound to the component DPQ in P whose corresponding component in Q is DQ.
When reference resolution is performed on a package that is intended to be used
as a stylesheet (that is, for the
top-level package), there must
be no symbolic references referring to components whose visibility is
abstract
(that is, an implementation must be provided for every
abstract component).
[ERR XTSE3080] It is a static error if a
top-level package (as
distinct from a library
package) contains
components whose visibility is abstract
.
Note:
This means that abstract components must either be overridden in a using
package by a component that supplies a real implementation, or they
must be accepted with visibility="hidden"
(see 3.5.3.2 Accepting Components), which has the effect that any invocation
of the component raises a dynamic error.
Note:
Unresolved references are allowed at the module level but not at the package level. A stylesheet module can contain references to components that are satisfied only when the module is imported into another module that declares the missing component.
Note:
The process of resolving references (or linking) is critical to an implementation that uses separate compilation. One of the aims of these rules is to ensure that when compiling a package, it is always possible to determine the signature of called functions, templates, and other components. A further aim is to establish unambiguously in what circumstances components can be overridden, so that compilers know when it is possible to perform optimizations such as inlining of function and variable references.
Suppose a public template T calls a private function F. When the package containing these two components is referenced by a using package, the template remains public, while the function becomes hidden. Because the function becomes hidden, it can no longer conflict with any other function of the same name, or be overridden by any other function; at this stage the compiler knows exactly which function T will be calling, and can perform optimizations based on this knowledge.
The mechanism for resolving component references described in this section is consistent with the mechanism used for binding function and variable references described in the XPath specification. XPath requires these variable and function names to be present in the static context for an XPath expression. XSLT ensures that all the non-hidden functions, global variables, and global parameters in a package are present in the static context for every XPath expression that appears in that package, along with required information such as the type of a variable and the signature of a function.
Named component references within inline functions follow the standard rules, but the rules need to be interpreted with care. Suppose that in package P we find the declarations:
<xsl:variable name="v" as="xs:integer" visibility="public" select="3"/> <xsl:function name="f:factory" as="function(*)" visibility="final"> <xsl:sequence select="function() {$v}"/> </xsl:function>
and that in a using package Q we find:
<xsl:use-package name="P"> <xsl:override> <xsl:variable name="v" as="xs:integer" select="4"/> </xsl:override> </xsl:use-package> <xsl:template name="xsl:initial-template"> <v value="{f:factory()()}"/> </xsl:template>
The correct output here is <v value="4"/>
.
The explanation for this is as follows. Package Q contains a function f:factoryQP
whose declaring package is P and whose containing package is Q. The symbolic reference
$v
within the body of this function is resolved in the normal way; since the containing
package
is Q, it is resolved to the global variable vQ: that is, the overriding declaration
of $v
that appears within the xsl:override
element within package Q,
whose value is 4.
In terms of internal implementation, one way of looking at this is that the anonymous
function returned
by f:factory
contains within its closure bindings for the global variables and functions that
the anonymous function references; these bindings are inherited from the component
bindings of the
component that lexically contains these symbolic references, which in this case is
f:factory
,
and more specifically the version of the f:factory
component in package Q.
There are several functions in which a dynamically-evaluated QName is used to
identify a component: these include key
,
accumulator-before
,
accumulator-after
,
function-lookup
FO30, and
function-available
. Dynamic references can also occur
in the XPath expression supplied to the xsl:evaluate
instruction.
In all these cases, the set of components that are available to be referenced
are those that are declared in the package where this function call appears,
including components declared within an xsl:override
declaration in that package, but excluding components declared with
visibility="abstract"
. If the relevant component has been
overridden in a different package, the overriding declarations are not
considered.
If one of these functions (for example key
or
accumulator-before
) is invoked via a dynamic function
invocation, then the relevant package is the one in which the function item is
created (using a construct such as key#2
, key('my-key',
?)
, or function-lookup($KEYFN, 2)
). Function items
referring to context-dependent functions bind the context at the point where
the function item is created, not the context at the point where the function
item is invoked.
Note:
This means that if a package wishes to make a key available for use by a
calling package, it can do so by creating a public global variable whose
value is a partial application of the key
function:
<xsl:variable name="get-order" select="key('orders-key', ?, ?)"/>
which the calling code can invoke as $get-order('123-456', /)
.
The rules in the previous section apply to named components including functions, named templates, global variables, and named attribute sets. The rules for modes, and the template rules appearing within a mode, are slightly different.
The unnamed mode is local to a package: in effect, each package has its own
private unnamed mode, and the unnamed mode of one package does not interact with
the unnamed mode of any other package. An
xsl:apply-templates
instruction with no mode
attribute is treated as a symbolic reference to the default
mode defined for that instruction (see 3.7.2 The default-mode Attribute), which in
turn defaults to the unnamed mode. Because the unnamed mode
always has private visibility, it cannot be overridden in another
package.
A named mode may be declared in an xsl:mode
declaration as being
either public
, private
, or final
. The
values of the visibility
attribute are interpreted as follows:
Value | Meaning |
---|---|
public | A using package may use
xsl:apply-templates to invoke templates in this mode;
it may also declare additional template rules in this mode, which are
selected in preference to template rules in the used package. These may
appear only as children of the xsl:override element
within the xsl:use-package element.
|
private | A using package may neither reference the mode nor provide additional templates in this mode; the name of the mode is not even visible in the using package, so no such attempt is possible. The using package can use the same name for its own modes without risk of conflict. |
final | A using package may use
xsl:apply-templates to invoke templates in this mode,
but it must not provide additional template rules in this mode.
|
As with other named components, an xsl:use-package
declaration
may contain an xsl:accept
element to control the visibility of a
mode acquired from the used package. The allowed values of its
visibility
attribute are public
,
private
, and final
.
The xsl:mode
declaration itself must not be overridden. A using
package must not contain an xsl:mode
declaration whose name
matches that of a public
or final
xsl:mode
component accepted from a used package.
The xsl:expose
and xsl:accept
elements may be
used to reduce the visibility of a mode in a using package; the same rules apply
in general, though some of the rules are not applicable because, for example,
modes cannot be abstract
.
It is not possible for a package to combine the template rules from two other
packages into a single mode. When xsl:apply-templates
is used
without specifying a mode, the chosen template rules will always come from the
same package; when it is used with a named mode, then they will come from the
package where the mode is defined, or any package that uses that package and adds
template rules to the mode. If two template rules defined in different packages
match the same node, then the rule in the using package wins over any rule in the
used package; this decision is made before taking other factors such as import
precedence and priority into account.
A static error occurs if two modes with the same name are visible within a package, either because they are both declared within the package, or because one is declared within the package and the other is acquired from a used package, or because both are accepted from different used packages.
The rules for matching template rules by import precedence and priority operate as
normal, with the addition that template rules declared within an
xsl:use-package
element have higher precedence than any
template rule declared in the used package. More specifically, given an xsl:apply-templates
instruction
in package P, naming a mode M that is declared in a used
package Q and is overridden in P, the search order for
template rules is:
Rules declared within P (specifically,
xsl:template
rules declared as children of an
xsl:override
element within the
xsl:use-package
element that references package
Q). If there are multiple rules declared within P
that match a selected node, they are resolved on the basis of their explicit
or implicit priority, and if the priorities are equal, the last one in declaration order wins.
Rules declared within Q, taking import precedence, priority, and declaration order into account in the usual way (see 6.4 Conflict Resolution for Template Rules).
Built-in template rules (see 6.7 Built-in Template Rules) selected
according to the on-no-match
attribute of the
xsl:mode
declaration (in Q), or its
default.
If the mode is overridden again in a package R that uses P, then this search order is extended by adding R at the start of the search list, and so on recursively.
Note:
If existing XSLT code has been written to use template rules in the unnamed
mode, a convenient way to incorporate this code into a library package is to add a stub module
that defines a new named public
or final
mode, in
which there is a single template rule whose content is the single instruction
<xsl:apply-templates select="."/>
. This in effect redirects
xsl:apply-templates
instructions using the named mode to
the rules defined in the unnamed mode.
In previous versions of XSLT, modes were implicitly declared by simply using a
mode name in the mode
attribute of xsl:template
or xsl:apply-templates
. XSLT 3.0 introduces the ability to
declare a mode explicitly using an xsl:mode
declaration (see
6.6.1 Declaring Modes).
By default, within a package that is defined using an explicit
xsl:package
element, all modes must be explicitly declared.
In an implicit package, however (that is, one rooted at an
xsl:stylesheet
or xsl:transform
element),
modes can be implicitly declared as in previous XSLT versions.
The declared-modes
attribute of xsl:package
determines whether or not modes that
are referenced within the package must be explicitly declared.
If the value is yes
(the default),
then it is an error to use a mode name
unless the package either contains
an explicit xsl:mode
declaration for that mode, or accepts the mode
from a used package. If the value is no
, then this is not an error.
This attribute affects all modules making up the package, it is not confined to
declarations appearing as children of the xsl:package
element.
[ERR XTSE3085] It is a static error,
when the effective value of the declared-modes
attribute of
an xsl:package
element is yes
, if the
package contains an explicit reference to an undeclared mode, or if
it implicitly uses the unnamed mode and the unnamed mode is undeclared.
For the purposes of the above rule:
A mode is declared if either of the following conditions is true:
The package contains an xsl:mode
declaration for that mode.
The mode is a public or final mode accepted from a used package.
The offending reference may be either an explicit mode name, or the token #unnamed
treated as a reference to the unnamed mode, or a defaulted mode attribute, and it
may occur in any of the following:
The mode
attribute of an xsl:template
declaration
The mode
attribute of an xsl:apply-templates
instruction
An [xsl:]default-mode
attribute.
A package implicitly uses the unnamed mode if either of the following conditions is true:
There is an xsl:apply-templates
element with no mode
attribute, and with no ancestor-or-self having
an [xsl:]default-mode
attribute.
There is an xsl:template
element with a match
attribute and no mode
attribute, and with no ancestor-or-self having
an [xsl:]default-mode
attribute.
The xsl:import
and
xsl:include
declarations are local to a package.
Declarations of keys, accumulators,
decimal formats, namespace aliases (see
11.1.4 Namespace Aliasing), output definitions, and character
maps within a package have local scope within that package —
they are all effectively private. The elements that declare these constructs do
not have a visibility
attribute. The unnamed decimal format and the
unnamed output format are also local to a package.
If xsl:strip-space
or xsl:preserve-space
declarations appear within a library
package, they only affect calls to the doc
FO30 or
document
functions appearing within that package. Such a declaration within the top-level package additionally affects stripping of whitespace in
the document that contains the global context item.
An xsl:decimal-format
declaration within a package applies only
to calls on format-number
FO30 appearing within that
package.
An xsl:namespace-alias
declaration within a package applies only
to literal result elements within the same package.
An xsl:import-schema
declaration within a package adds the names
of the imported schema components to the static context for that package only;
these names are effectively private, in the sense that they do not become
available for use in any other packages. However, the names of schema components
must be consistent across the stylesheet as a whole: it is not possible for two
different packages within a stylesheet to use a type-name such as part-number
to
refer to different schema-defined simple or complex types.
Type names used in the interface of public components in a package (for example, in the arguments of a function) must be respected by callers of those components, in the sense that the caller must supply values of the correct type. Often this will mean that the using component, if it contains calls on such interfaces, must itself import the necessary schema components. However, the requirement for an explicit schema import applies only where the package contains explicit use of the names of schema components required to call such interfaces.
Note:
For example, suppose a library
package contains a function which requires an argument of type
mfg:part-number
. The caller of this function must supply an
argument of the correct type, but does not need to import the schema unless it
explicitly uses the schema type name mfg:part-number
. If it
obtains an instance of this type from outside the package, for example as the
result of another function call, then it can supply this instance to the
acquired function even though it has not imported a schema that defines this
type.
At execution time, the schema available for validating instance documents contains (at least) the union of the schema components imported into all constituent packages of the stylesheet.
The xsl:global-context-item
element is used to declare whether a
global context item is required, and if so, what its
required type is.
The element is a declaration that
can appear at most once in any stylesheet module; and if more than one
xsl:global-context-item
declaration appears within a package, then the declarations must be consistent. Specifically, all
the attributes must have semantically-equivalent values.
Note:
This means that omitting an attribute is equivalent to specifying its default value explicitly; and purely lexical variations, such as the presence of whitespace in an attribute value, are not considered significant.
[ERR XTSE3087] It is a static error if more than
one xsl:global-context-item
declaration appears within a
stylesheet module, or if several modules within a
single package contain inconsistent
xsl:global-context-item
declarations
If there is no xsl:global-context-item
declaration for a package,
this is equivalent to specifying the empty element
<xsl:global-context-item/>
, which imposes no constraints.
<!-- Category: declaration -->
<xsl:global-context-item
as? = item-type
use? = "required" | "optional" | "absent" />
The use
attribute takes the value required
,
optional
, or absent
. The
default is optional
.
If the value required
is specified, then there must be a
global context item.
If the value optional
is specified, or if the attribute is
omitted, or if the xsl:global-context-item
element is
omitted, then there may or may not be a global context item.
If the value absent
is specified, then the global focus
(context item, position, and size) will be absent
Note:
This specification does not define whether supplying a global context item in this situation results in an error or warning, or whether the supplied context item is simply ignored.
If the as
attribute is present then its value must be an ItemTypeXP30. If the attribute is
omitted this is equivalent to specifying as="item()"
.
The as
attribute defines the required type of the global context
item. The default value is as="item()"
. If a global context item is
supplied then it must conform to the required type, after conversion (if
necessary) using the function conversion rules.
[ERR XTSE3089] It is a static error if the as
attribute is
present when use="absent"
is specified.
The global context item is available only within the top-level package. If a valid xsl:global-context-item
declaration appears within a library package, then it is
ignored, unless it specifies use="required"
, in which case an error
is signaled: [see ERR XTTE0590].
Note:
In earlier releases of this specification, the global context item and
the initial match selection were essentially the same thing, often referred
to as the principal source document. In XSLT 3.0, they have been separated:
the global context item is a single item accessible to the initializers of global
variables
as the value of the expression .
(dot), while the initial match selection
is a sequence of nodes or other items supplied to an initial implicit xsl:apply-templates
invocation.
APIs that were originally designed for use with earlier versions of XSLT are likely to bundle the two concepts together.
With a streamable processor, the initial match selection can consist of streamed nodes, but the global context item is always grounded, because it is available to all global variables and there is no control over the sequence of processing.
A type error is signaled if there
is a package with an xsl:global-context-item
declaration specifying a required type that does not match the supplied global context item. The error code is the same as for
xsl:param
: [see ERR XTTE0590].
Note:
If the ItemType
is one that can only be satisfied by a
schema-validated input document, for example
as="schema-element(invoice)"
, the processor may interpret this as a request to apply schema
validation to the input. Similarly, if the KindTest
indicates that
an element node is required, the processor may interpret this as a request to
supply the document element rather than the document node of a supplied input
document.
The example in this section illustrates the use of overrides to customize or
extend a (fictional) library package named
http://example.com/csv-parser
, which provides a parsing function
for data formatted as lines containing comma-separated values. For simplicity of
exposition, the example shows a simple, naive implementation; a realistic CSV
parser would be more complicated and make the example harder to follow.
The basic functionality of the package is provided by the function
csv:parse
, which expects a string parameter named
input
. By default, the function parses the input into lines,
and breaks lines on commas, returning as result an element named
csv
containing one row
element per line, each
row
containing a sequence of field
elements.
A simple stylesheet which uses this library and applies it to a string might
look like the following. The initial template applies csv:parse
to
a suitable string and returns a copy of the result:
<?xml version="1.0" encoding="UTF-8"?> <xsl:stylesheet xmlns:xsl="http://www.w3.org/1999/XSL/Transform" xmlns:xs="http://www.w3.org/2001/XMLSchema" xmlns:csv="http://example.com/csv" exclude-result-prefixes="xs csv" version="3.0"> <xsl:output indent="yes"/> <xsl:use-package name="http://example.com/csv-parser" package-version="*"/> <!-- example input "file" --> <xsl:variable name="input" as="xs:string"> name,id,postal code "Abel Braaksma",34291,1210 KA "Anders Berglund",473892,9843 ZD </xsl:variable> <!-- entry point --> <xsl:template name="xsl:initial-template"> <xsl:copy-of select="csv:parse($input)"/> </xsl:template> </xsl:stylesheet>
The result returned by this stylesheet would be:
<csv> <row> <field quoted="no">name</field> <field quoted="no">id</field> <field quoted="no">postal code</field> </row> <row> <field quoted="yes">Abel Braaksma</field> <field quoted="no">34291</field> <field quoted="no">1210 KA</field> </row> <row> <field quoted="yes">Anders Berglund</field> <field quoted="no">473892</field> <field quoted="no">9843 ZD</field> </row> </csv>
Variations on this default behavior are achieved by overriding selected declarations in the package, as described below.
The package module itself is version 1.0.0 of a package called
http://example.com/csv-parser
; it has the following
structure:
<?xml version="1.0" encoding="UTF-8"?> <xsl:package name="http://example.com/csv-parser" package-version="1.0.0" xmlns:xsl="http://www.w3.org/1999/XSL/Transform" xmlns:xs="http://www.w3.org/2001/XMLSchema" xmlns:csv="http://example.com/csv" exclude-result-prefixes="xs csv" declared-modes="yes" version="3.0"> <!--* Mode declarations ... *--> <!--* Variable declarations ... *--> <!--* Attribute-set declaration ... *--> <!--* Function declarations ... *--> <!--* Templates ... *--> </xsl:package>
The contents of the package (represented here by comments) are described more fully below.
csv:parse
Function and its User-customization HooksThe csv:parse
function is final and cannot be overridden. As can be
seen from the code below, it (1) parses its input
parameter into
lines, (2) calls function csv:preprocess-line
on each line, then
(3) applies the templates of mode csv:parse-line
to the
pre-processed value. The result is then (4) processed again by mode
csv:post-process
.
<xsl:function name="csv:parse" visibility="final"> <xsl:param name="input" as="xs:string"/> <xsl:variable name="result" as="element()"> <csv> <xsl:apply-templates select="(tokenize($input, $csv:line-separator) ! csv:preprocess-line(.))" mode="csv:parse-line"/> </csv> </xsl:variable> <xsl:apply-templates select="$result" mode="csv:post-process"/> </xsl:function>
The default code for this processing is given below. Each part of the processing except the first (the tokenization into lines) can be overridden by the user of the package.
The first user-customization hook is given by the global variable
csv:line-separator
, which specifies the line separator used to
break the input string into lines. It can be overridden by the user if need be.
The default declaration attempts to handle the line-separator sequences used by
most common operating systems in text files:
<xsl:variable name="csv:line-separator" as="xs:string" select="'\r\n?|\n\r?'" visibility="public"/>
The function csv:preprocess-line
calls
normalize-space()
on its argument:
<xsl:function name="csv:preprocess-line" as="xs:string?" visibility="public"> <xsl:param name="line" as="xs:string"/> <xsl:sequence select="normalize-space($line)"/> </xsl:function>
Because the function is declared public
, it can be overridden by a
user. (This might be necessary, for example, if whitespace within quoted
strings needs to be preserved.)
csv:parse-line
By default, the mode csv:parse-line
parses the current item (this
will be one line of the input data) into fields, using mode
csv:parse-field
on the individual fields and (by default)
wrapping the result in a row
element.
The mode is declared with visibility="public"
to allow it to be
called from elsewhere and overridden:
<xsl:mode name="csv:parse-line" visibility="public"/>
<xsl:template match="." mode="csv:parse-line"> <row> <xsl:apply-templates select="tokenize(., $csv:field-separator)" mode="csv:parse-field"/> </row> </xsl:template>
This relies on the variable csv:field-separator
, which is a comma
by default but which can be overridden by the user to parse tab-separated data
or data with other delimiters.
<xsl:variable name="csv:field-separator" as="xs:string" select="','" visibility="public"/>
The default implementation of csv:parse-line
does not handle
occurrences of the field separator occurring within quoted strings. The user
can add templates to the mode to provide that functionality.
csv:parse-field
Mode csv:parse-field
processes the current item as a field; by
default it strips quotation marks from the value, calls the function
csv:preprocess-field()
on it, and wraps the result in a
field
element, which carries the attributes declared in the
attribute set csv:field-attributes
.
<xsl:template match="." mode="csv:parse-field" expand-text="yes"> <xsl:variable name="string-body-pattern" as="xs:string" select="'([^' || $csv:validated-quote || ']*)'"/> <xsl:variable name="quoted-value" as="xs:string" select="$csv:validated-quote || $string-body-pattern || $csv:validated-quote"/> <xsl:variable name="unquoted-value" as="xs:string" select="'(.+)'"/> <field xsl:use-attribute-sets="csv:field-attributes">{ csv:preprocess-field( replace(., $quoted-value || '|' || $unquoted-value, '$1$2')) }</field> </xsl:template>
The attribute set csv:field-attributes
includes, by default, a
quoted
attribute which has the values yes
or
no
to show whether the input value was quoted or not.
<xsl:attribute-set name="csv:field-attributes" visibility="public"> <xsl:attribute name="quoted" select="if (starts-with(., $csv:validated-quote)) then 'yes' else 'no'"/> </xsl:attribute-set>
The mode csv:parse-field
is declared with
visibility="public"
to allow it to be called from elsewhere and
overridden; it specifies on-no-match="shallow-copy"
so that any
string not matching a template will simply be copied:
<xsl:mode name="csv:parse-field" on-no-match="shallow-copy" visibility="public"/>
csv:quote
VariableThe variable csv:quote
can be used to specify the character used
in a particular input stream to quote values.
<xsl:variable name="csv:quote" as="xs:string" select="'"'" visibility="public"/>
The template given above assumes that the variable is one character long. To
ensure that any overriding value of the variable is properly checked, references to
the value use a
second variable csv:validated-quote
, which
is declared private
to ensure that the checking cannot be
disabled.
<xsl:variable name="csv:validated-quote" visibility="private" as="xs:string" select=" if (string-length($csv:quote) ne 1) then error(xs:QName('csv:ERR001'), 'Incorrect length for $csv:quote, should be 1') else $csv:quote"/>
When the value of csv:quote
is not
exactly one character long, the reference to
csv:validated-quote
will cause an error (csv:ERR001)
to be raised.
csv:preprocess-field
FunctionThe function csv:preprocess-field
is called on each field after
any quotation marks are stripped and before it is written out as the value of a
field
element:
<xsl:function name="csv:preprocess-field" as="xs:string"> <xsl:param name="field" as="xs:string"/> <xsl:sequence select="$field"/> </xsl:function>
As can be seen, the function does nothing but return its input; its only purpose is to provide the opportunity for the user to supply a suitable function to be invoked at this point in the processing of each field.
csv:post-process
The mode csv:post-process
is intended solely as a hook for user
code. By default, it does nothing.
The package defines no templates for this mode; the mode definition makes it return a copy of its input:
<xsl:mode name="csv:post-process" on-no-match="shallow-copy" visibility="public"/>
As can be seen from the code shown above, the package provides several opportunities for users to override the default behavior:
The global variables csv:line-separator
,
csv:field-separator
, and csv:quote
can be
overridden to specify the character strings used to separate lines and
fields and to quote individual field values.
The function csv:preprocess-line
can be overridden to do
more (or less) than stripping white space; the function
csv:preprocess-field
can be overridden to process
individual field values.
Templates can be added to the modes csv:parse-line
,
csv:parse-field
, and csv:post-process
to
change their behavior.
The attribute set csv:field-attributes
can be overridden to
specify a different set of attributes (or none) for field
elements.
The following using stylesheet illustrates the use of the
xsl:override
element to take advantage of several of these
opportunities:
<xsl:stylesheet xmlns:xsl="http://www.w3.org/1999/XSL/Transform" xmlns:xs="http://www.w3.org/2001/XMLSchema" xmlns:csv="http://example.com/csv" exclude-result-prefixes="xs csv" version="3.0"> <xsl:output indent="yes"/> <xsl:use-package name="http://example.com/csv-parser" package-version="*"> <xsl:override> <!-- Change the root element from 'csv' to 'root' --> <xsl:template match="csv" mode="csv:post-process"> <root> <xsl:apply-templates mode="csv:post-process"/> </root> </xsl:template> <!-- add an extra attribute that uses the context item --> <xsl:attribute-set name="csv:field-attributes" use-attribute-sets="xsl:original"> <xsl:attribute name="type" select="if (. castable as xs:decimal) then 'numeric' else 'string'"/> </xsl:attribute-set> <!-- use semicolon not comma between fields --> <xsl:variable name="csv:field-separator" as="xs:string" select="';'" visibility="public"/> <!-- prevent empty rows from appearing with empty lines --> <xsl:function name="csv:preprocess-line" as="xs:string?" visibility="public"> <xsl:param name="line" as="xs:string"/> <xsl:variable name="norm-line" select="normalize-space(xsl:original($line))"/> <xsl:sequence select="if (string-length($norm-line) > 0) then $norm-line else ()"/> </xsl:function> </xsl:override> </xsl:use-package> <!-- example input "file" --> <xsl:variable name="input" as="xs:string"> name;id;postal code "Braaksma Abel";34291;1210 KA "Berglund Anders";473892;9843 ZD </xsl:variable> <!-- entry point --> <xsl:template name="xsl:initial-template"> <xsl:copy-of select="csv:parse($input)"/> </xsl:template> </xsl:stylesheet>
Note:
As it does elsewhere, the visibility of components declared within
xsl:override
defaults to private
; to keep
the component public, it is necessary to specify visibility
explicitly.
The types and optionality of all function parameters must match those of the function being overridden; for function overriding to be feasible, packages must document the function signature thoroughly.
The names, types, and optionality of all named-template parameters must match those of the template being overridden; for overriding to be feasible, packages must document the template signature thoroughly.
The values for the attributes in the attribute set
csv:field-attributes
are calculated once for each
element for which the attribute set is supplied; the
select
attributes which determine the values can thus
refer to the context item. Here, the value specification for the
type
attribute checks to see whether the string value
of the context item is numeric by inquiring whether it can be cast to
decimal, and sets the value for the type
attribute
accordingly.
The result returned by this stylesheet would be:
<root> <row> <field quoted="no" type="string">name</field> <field quoted="no" type="string">id</field> <field quoted="no" type="string">postal code</field> </row> <row> <field quoted="yes" type="string">Braaksma Abel</field> <field quoted="no" type="numeric">34291</field> <field quoted="no" type="string">1210 KA</field> </row> <row> <field quoted="yes" type="string">Berglund Anders</field> <field quoted="no" type="numeric">473892</field> <field quoted="no" type="string">9843 ZD</field> </row> </root>
[Definition: A package consists of one or more stylesheet modules, each one forming all or part of an XML document.]
Note:
A stylesheet module is represented by an XDM element node (see [XDM 3.0]). In the case of a standard stylesheet module, this
will be an xsl:stylesheet
or xsl:transform
element. In the case of a simplified stylesheet module, it can be any element (not
in the XSLT namespace) that has an
xsl:version
attribute.
Although stylesheet modules will commonly be maintained in the form of documents conforming to XML 1.0 or XML 1.1, this specification does not mandate such a representation. As with source trees, the way in which stylesheet modules are constructed, from textual XML or otherwise, is outside the scope of this specification.
The principal stylesheet module of a package may take one of three forms:
A package manifest, as described in 3.5 Packages, which is a
subtree rooted at an xsl:package
element
An implicit package, which is a subtree rooted at an
xsl:stylesheet
or xsl:transform
element.
This is transformed automatically to a package as described in 3.5 Packages.
A simplified stylesheet, which is a subtree rooted at a literal result element,
as described in 3.8 Simplified Stylesheet Modules. This is first converted
to an implicit package by wrapping it in an xsl:stylesheet
element using the transformation described in 3.8 Simplified Stylesheet Modules, and then to an explicit package (rooted at an
xsl:package
element) using the transformation described in
3.5 Packages.
A stylesheet module other than the principal stylesheet module of a package may take either of two forms:
[Definition: A
standard stylesheet module, which is a subtree rooted at an
xsl:stylesheet
or xsl:transform
element.]
[Definition: A simplified stylesheet, which is a subtree rooted at a literal result element, as described in 3.8 Simplified Stylesheet Modules. This is first converted to a standard stylesheet module by wrapping it in an xsl:stylesheet element using the transformation described in 3.8 Simplified Stylesheet Modules.]
Whichever of the above forms a module takes, the outermost
element (xsl:package
, xsl:stylesheet
, or a literal result element) may either be the outermost
element of an XML document, or it may be a child of some
(non-XSLT) element in a host document.
[Definition: A stylesheet module whose outermost element is the child of a non-XSLT element in a host document is referred to as an embedded stylesheet module. See 3.12 Embedded Stylesheet Modules.]
<xsl:stylesheet
id? = id
version = decimal
default-mode? = eqname | "#unnamed"
default-validation? = "preserve" | "strip"
input-type-annotations? = "preserve" | "strip" | "unspecified"
default-collation? = uris
extension-element-prefixes? = prefixes
exclude-result-prefixes? = prefixes
expand-text? = boolean
use-when? = expression
xpath-default-namespace? = uri >
<!-- Content: (declarations) -->
</xsl:stylesheet>
<xsl:transform
id? = id
version = decimal
default-mode? = eqname | "#unnamed"
default-validation? = "preserve" | "strip"
input-type-annotations? = "preserve" | "strip" | "unspecified"
default-collation? = uris
extension-element-prefixes? = prefixes
exclude-result-prefixes? = prefixes
expand-text? = boolean
use-when? = expression
xpath-default-namespace? = uri >
<!-- Content: (declarations) -->
</xsl:transform>
A stylesheet module is represented by an xsl:stylesheet
element in
an XML document. xsl:transform
is allowed as a synonym for
xsl:stylesheet
; everything this specification says about the
xsl:stylesheet
element applies equally to
xsl:transform
.
The version
attribute indicates the version
of XSLT that the stylesheet module requires. The attribute is
required.
[ERR XTSE0110] The value of the version
attribute must be a number:
specifically, it must be a valid instance of the type
xs:decimal
as defined in [XML Schema Part 2].
The version
attribute is intended to indicate the
version of the XSLT specification against which the stylesheet is written. In a
stylesheet written to use XSLT 3.0, the value should normally be
set to 3.0
. If the value is numerically less than 3.0
, the
stylesheet is processed using the rules for backwards compatible behavior
(see 3.9 Backwards Compatible Processing). If the value is numerically greater than
3.0
, the stylesheet is processed using the rules for forwards compatible behavior (see 3.10 Forwards Compatible Processing).
The effect of the input-type-annotations
attribute is described in
4.4.1 Stripping Type Annotations from a Source Tree.
The [xsl:]default-validation
attribute defines the default value of the
validation
attribute of all relevant instructions appearing within
its scope. For details of the effect of this attribute, see 25.4 Validation.
[ERR XTSE0120] An xsl:stylesheet
, xsl:transform
,
or xsl:package
element must not have any
text node children. (This rule applies after stripping of whitespace text nodes as described in 4.3 Stripping Whitespace from the Stylesheet.)
[Definition: An element occurring as a child of an
xsl:package
,
xsl:stylesheet
,
xsl:transform
, or xsl:override
element is called a top-level element.]
[Definition: Top-level elements fall into two categories: declarations, and user-defined data elements. Top-level elements whose names are in the XSLT namespace are declarations. Top-level elements in any other namespace are user-defined data elements (see 3.7.3 User-defined Data Elements)].
The declaration elements permitted in the
xsl:stylesheet
element are:
xsl:accumulator
xsl:attribute-set
xsl:character-map
xsl:decimal-format
xsl:function
xsl:global-context-item
xsl:import
xsl:import-schema
xsl:include
xsl:key
xsl:mode
xsl:namespace-alias
xsl:output
xsl:param
xsl:preserve-space
xsl:strip-space
xsl:template
xsl:use-package
xsl:variable
Note that the xsl:variable
and xsl:param
elements
can act either as declarations or as instructions. A global variable or parameter is
defined using a declaration; a local variable or parameter using an instruction.
The child elements of the xsl:stylesheet
element may appear in any order. In most cases, the ordering of these elements does
not affect the results of the transformation; however:
As described in 6.4 Conflict Resolution for Template Rules, when two template rules with the same priority match the same nodes, there are situations where the order of the template rules will affect which is chosen.
Forwards references to static variables are not allowed in static expressions.
default-collation
AttributeThe default-collation
attribute is a standard attribute that may appear on
any element in the XSLT namespace, or (as xsl:default-collation
) on a
literal result element.
The attribute, when it appears on an element
E, is used to specify the default collation used by all XPath
expressions appearing in attributes or text value templates that have E as an
ancestor, unless overridden by another default-collation
attribute on an inner element. It also determines the collation used by certain
XSLT constructs (such as xsl:key
and
xsl:for-each-group
) within its scope.
The value of the attribute is a whitespace-separated list of collation URIs. If any of these URIs is a relative URI reference, then it is resolved relative to the base URI of the attribute’s parent element. If the implementation recognizes one or more of the resulting absolute collation URIs, then it uses the first one that it recognizes as the default collation.
[ERR XTSE0125] It is a static error if the value
of an [xsl:]default-collation
attribute, after resolving
against the base URI, contains no URI that the implementation recognizes as
a collation URI.
Note:
The reason the attribute allows a list of collation URIs is that collation URIs
will often be meaningful only to one particular XSLT implementation.
Stylesheets designed to run with several different implementations can
therefore specify several different collation URIs, one for use with each. To
avoid the above error condition, it is possible to include as the last
collation URI in the list either the Unicode Codepoint Collation or a collation in the UCA family (see 13.4 The Unicode Collation Algorithm) with the parameter
fallback=yes
.
The [xsl:]default-collation
attribute does not affect the collation
used by xsl:sort
or by xsl:merge
.
In the absence of an
[xsl:]default-collation
attribute, the default collation
may be set by the calling application in an implementation-defined way. The recommended default, unless the user
chooses otherwise, is to use the Unicode codepoint collation.
default-mode
AttributeThe [xsl:]default-mode
attribute defines the default value for the
mode attribute of all
xsl:template
and xsl:apply-templates
elements
within its scope.
More specifically, when an element E matches
the pattern (xsl:template[@match] | xsl:apply-templates)[not(@mode) or
normalize-space(@mode) eq "#default"]
(using the Unicode codepoint
collation), then the effective value of the mode
attribute is taken
from the value of the [xsl:]default-mode
attribute of the innermost
ancestor-or-self element of E that has such an attribute. If there is
no such element, then the default is the unnamed
mode. This is equivalent to specifying #unnamed
.
In addition, when the attribute appears on the xsl:package
,
xsl:stylesheet
, or xsl:transform
element of the
principal stylesheet module of the top-level package,
it provides a default value for the initial mode used on stylesheet
invocation.
The value of the [xsl:]default-mode
attribute must
either be an EQName, or the token #unnamed
which refers to
the unnamed mode.
Note:
This attribute is provided to support an approach to stylesheet modularity in which all the template rules for one mode are collected together into a single stylesheet module. Using this attribute reduces the risk of forgetting to specify the mode in one or more places where it is needed, and it also makes it easier to reuse an existing stylesheet module that does not use modes in an application where modes are needed to avoid conflicts with existing template rules.
It is not necessary for the referenced mode to be
explicitly declared in an xsl:mode
declaration, unless this is
mandated by the declared-modes
attribute (which defaults to
yes
on an xsl:package
element).
[Definition: In addition to
declarations, the
xsl:stylesheet
element may contain among its children any
element not from the XSLT namespace,
provided that the expanded QName of
the element has a non-null namespace URI. Such elements are referred to as
user-defined data elements.]
[ERR XTSE0130] It is a static error if an
xsl:stylesheet
, xsl:transform
,
or xsl:package
element has a child element whose name
has a null namespace URI.
An implementation may attach an implementation-defined meaning to user-defined data elements that
appear in particular namespaces. The set of namespaces that are recognized for
such data elements is implementation-defined. The presence of a user-defined data element
must not change the behavior of XSLT elements and functions defined in this
document; for example, it is not permitted for a user-defined data element to
specify that xsl:apply-templates
should use different rules to
resolve conflicts. The constraints on what user-defined data elements can and
cannot do are exactly the same as the constraints on extension attributes, described in
3.2 Extension Attributes. Thus, an implementation is always free
to ignore user-defined data elements, and must ignore such data
elements without giving an error if it does not recognize the namespace URI.
User-defined data elements can provide, for example,
information used by extension instructions or extension functions (see 24 Extensibility and Fallback),
information about what to do with any final result tree,
information about how to construct source trees,
optimization hints for the processor,
metadata about the stylesheet,
structured documentation for the stylesheet.
A simplified syntax is allowed for a stylesheet
module that defines only a single template rule for the document node.
The stylesheet module may consist of just a literal result element (see 11.1 Literal Result Elements)
together with its contents. The literal result element must have an
xsl:version
attribute (and it must therefore also declare the XSLT
namespace). Such a stylesheet module is equivalent to a standard stylesheet module
whose xsl:stylesheet
element contains a template rule containing the literal result
element, minus its xsl:version
attribute; the template rule has a match
pattern of /
.
For example:
<html xsl:version="3.0" xmlns:xsl="http://www.w3.org/1999/XSL/Transform" xmlns="http://www.w3.org/1999/xhtml"> <head> <title>Expense Report Summary</title> </head> <body> <p>Total Amount: <xsl:value-of select="expense-report/total"/></p> </body> </html>
has the same meaning as
<xsl:stylesheet version="3.0" xmlns:xsl="http://www.w3.org/1999/XSL/Transform" xmlns="http://www.w3.org/1999/xhtml"> <xsl:template match="/"> <html> <head> <title>Expense Report Summary</title> </head> <body> <p>Total Amount: <xsl:value-of select="expense-report/total"/></p> </body> </html> </xsl:template> </xsl:stylesheet>
Note that it is not possible, using a simplified stylesheet, to request that the
serialized output contains a DOCTYPE
declaration. This can only be
done by using a standard stylesheet module, and using the
xsl:output
element.
More formally, a simplified stylesheet module is equivalent to the standard
stylesheet module that would be generated by applying the following transformation
to
the simplified stylesheet module, invoking the transformation by calling the named template
expand
, with the containing literal result element as the context node:
<xsl:stylesheet version="3.0" xmlns:xsl="http://www.w3.org/1999/XSL/Transform"> <xsl:template name="expand"> <xsl:element name="xsl:stylesheet"> <xsl:attribute name="version" select="@xsl:version"/> <xsl:element name="xsl:template"> <xsl:attribute name="match" select="'/'"/> <xsl:copy-of select="."/> </xsl:element> </xsl:element> </xsl:template> </xsl:stylesheet>
[ERR XTSE0150] A literal result element
that is used as the outermost element of a simplified stylesheet module
must have an xsl:version
attribute. This indicates the version of XSLT that the stylesheet requires. For this
version of XSLT, the value will normally be
3.0
; the value must be a valid instance of the type
xs:decimal
as defined in [XML Schema Part 2].
The allowed content of a literal result element when used as a simplified stylesheet
is the same as when it occurs within a sequence constructor. Thus, a literal result element used as the
document element of a simplified stylesheet cannot contain declarations. Simplified stylesheets therefore
cannot use template rules, global variables, stylesheet parameters, stylesheet functions, keys, attribute-sets, or
output definitions. In turn this
means that the only useful way to initiate the transformation is to supply a document
node as the initial match selection, to be matched by the implicit
match="/"
template rule using the unnamed mode.
[Definition: The effective
version of an element in a stylesheet module or package manifest is the decimal value of the [xsl:]version
attribute
(see 3.4 Standard Attributes) on that element or on the innermost
ancestor element that has such an attribute, excluding the version
attribute on an xsl:output
element.]
[Definition: An element is processed with backwards compatible behavior if its
effective version is less than
3.0
.]
Specifically:
If the effective version is equal to 1.0, then the element is processed with XSLT 1.0 behavior as described in 3.9.1 XSLT 1.0 Compatibility Mode.
If the effective version is equal to 2.0, then the element is processed with XSLT 2.0 behavior as described in 3.9.2 XSLT 2.0 Compatibility Mode.
If the effective version is any other value less than 3.0, the recommended action is to report a static error; however, processors may recognize such values and process the element in an implementation-defined way.
Note:
XSLT 1.0 allowed the version
attribute to take any decimal
value, and invoked forwards compatible processing for any value other than
1.0. XSLT 2.0 allowed the attribute to take any decimal value, and invoked
backwards compatible (i.e. 1.0-compatible) processing for any value less
than 2.0. Some stylesheets may therefore be encountered that use values
other than 1.0 or 2.0. In particular, the value 1.1 is sometimes
encountered, as it was used at one stage in a draft language proposal.
These rules do not apply to the xsl:output
element, whose
version
attribute has an entirely different purpose: it is used to
define the version of the output method to be used for serialization.
It is implementation-defined whether a particular XSLT 3.0 implementation supports backwards compatible behavior for any XSLT version earlier than XSLT 3.0.
[ERR XTDE0160] It is a dynamic error if an element has an effective version of V (with V < 3.0) when the implementation does not support backwards compatible behavior for XSLT version V.
Note:
By making use of backwards compatible behavior, it is possible to write the stylesheet in a way that ensures that its results when processed with an XSLT 3.0 processor are identical to the effects of processing the same stylesheet using a processor for an earlier version of XSLT. To assist with transition, some parts of a stylesheet may be processed with backwards compatible behavior enabled, and other parts with this behavior disabled.
All data values manipulated by an XSLT 3.0 processor are defined by the XDM data model, whether or not the relevant expressions use backwards compatible behavior. Because the same data model is used in both cases, expressions are fully composable. The result of evaluating instructions or expressions with backwards compatible behavior is fully defined in the XSLT 3.0 and XPath 3.0 specifications, it is not defined by reference to earlier versions of the XSLT and XPath specifications.
To write a stylesheet that makes use of features that
are new in version N, while also working with a processor that only
supports XSLT version M (M < N),
it is necessary to understand both the rules for backwards compatible behavior in
XSLT version N, and the rules for
forwards compatible behavior in XSLT version
M. If the xsl:stylesheet
element
specifies version="2.0"
or version="3.0"
, then an XSLT 1.0
processor will ignore XSLT 2.0 and XSLT 3.0
declarations that were not defined in XSLT
1.0, for example xsl:function
and
xsl:import-schema
. If any new XSLT
3.0 instructions are used (for example xsl:evaluate
or xsl:source-document
), or if new XPath
3.0 features are used (for example, new functions, or let expressions), then the stylesheet must provide
fallback behavior that relies only on facilities available in the earliest XSLT version supported. The fallback
behavior can be invoked by using the xsl:fallback
instruction, or
by testing the results of the function-available
or
element-available
functions, or by testing the value of
the xsl:version
property returned by the
system-property
function.
[Definition: An element in the stylesheet is processed with XSLT 1.0 behavior if its effective version is equal to 1.0.]
In this mode, if any attribute contains an XPath expression, then the expression is evaluated with XPath 1.0 compatibility mode set to
true
. For details of this mode, see Section
2.1.1 Static Context
XP30. Expressions contained in
text value templates are
always evaluated with XPath 1.0
compatibility mode set to false
, since this construct
was not available in XSLT 1.0.
Furthermore, in such an expression any function call for which no implementation is available (unless it uses the standard function namespace) is bound to a fallback error function whose effect when evaluated is to raise a dynamic error [see ERR XTDE1425] . The effect is that with backwards compatible behavior enabled, calls on extension functions that are not available in a particular implementation do not cause an error unless the function call is actually evaluated. For further details, see 24.1 Extension Functions.
Note:
This might appear to contradict the specification of XPath 3.0, which states that a static error [XPST0017] is raised when an expression contains a call to a function that is not present (with matching name and arity) in the static context. This apparent contradiction is resolved by specifying that the XSLT processor constructs a static context for the expression in which every possible function name and arity (other than names in the standard function namespace) is present; when no other implementation of the function is available, the function call is bound to a fallback error function whose run-time effect is to raise a dynamic error.
Certain XSLT constructs also produce different results when XSLT 1.0 compatibility mode is enabled. This is described separately for each such construct.
Processing an instruction with XSLT 1.0 behavior is not compatible with streaming. More specifically, and notwithstanding anything stated in 19 Streamability, an instruction that is processed with XSLT 1.0 behavior is roaming and free-ranging, which has the effect that any construct containing such an instruction is not guaranteed-streamable.
[Definition: An element is processed with XSLT 2.0 behavior if its effective version is equal to 2.0.]
In this specification, no differences are defined for XSLT 2.0 behavior. An XSLT 3.0 processor will therefore produce the same results whether the effective version of an element is set to 2.0 or 3.0.
Note:
An XSLT 2.0 processor, by contrast, will in some cases produce different
results in the two cases. For example, if the stylesheet contains an
xsl:iterate
instruction with an
xsl:fallback
child, an XSLT 3.0 processor will process the
xsl:iterate
instruction regardless whether the effective
version is 2.0 or 3.0, while an XSLT 2.0 processor will report a static error
if the effective version is 2.0, and will take the fallback action if the
effective version is 3.0.
The intent of forwards compatible behavior is to make it possible to write a stylesheet that takes advantage of features introduced in some version of XSLT subsequent to XSLT 3.0, while retaining the ability to execute the stylesheet with an XSLT 3.0 processor using appropriate fallback behavior.
It is always possible to write conditional code to run under different XSLT versions
by using the use-when
feature described in 3.13.1 Conditional Element Inclusion. The rules for forwards compatible behavior
supplement this mechanism in two ways:
certain constructs in the stylesheet that mean nothing to an XSLT 3.0 processor are ignored, rather than being treated as errors.
explicit fallback behavior can be defined for instructions defined in a future
XSLT release, using the xsl:fallback
instruction.
The detailed rules follow.
[Definition: An
element is processed with forwards compatible behavior if its
effective version is greater than
3.0
.]
These rules do not apply to the version
attribute of the
xsl:output
element, which has an entirely different purpose: it
is used to define the version of the output method to be used for serialization.
When an element is processed with forwards compatible behavior:
If the element is in the XSLT namespace and appears as a child of the
xsl:stylesheet
element, and XSLT 3.0 does not allow the element to appear as a child of the
xsl:stylesheet
element, then the element and its content
must be ignored.
If the element has an attribute that XSLT 3.0 does not allow the element to have, then the attribute must be ignored.
If the element is in the XSLT namespace and appears as a child of an element whose content model requires a sequence constructor, and XSLT 3.0 does not allow such elements to appear as part of a sequence constructor, then:
If the element has one or more xsl:fallback
children,
then no error is reported either statically or dynamically, and the
result of evaluating the instruction is the concatenation of the
sequences formed by evaluating the sequence constructors within its
xsl:fallback
children, in document order. Siblings of
the xsl:fallback
elements are ignored, even if they are
valid XSLT 3.0 instructions.
If the element has no xsl:fallback
children, then a
static error is reported in the same way as if forwards compatible
behavior were not enabled.
For example, an XSLT 3.0 processor will process the following stylesheet without error, although the stylesheet includes elements from the XSLT namespace that are not defined in this specification:
<xsl:stylesheet version="17.0" xmlns:xsl="http://www.w3.org/1999/XSL/Transform"> <xsl:template match="/"> <xsl:exciting-new-17.0-feature> <xsl:fly-to-the-moon/> <xsl:fallback> <html> <head> <title>XSLT 17.0 required</title> </head> <body> <p>Sorry, this stylesheet requires XSLT 17.0.</p> </body> </html> </xsl:fallback> </xsl:exciting-new-17.0-feature> </xsl:template> </xsl:stylesheet>
Note:
If a stylesheet depends crucially on a declaration introduced by a version of XSLT after 3.0, then the stylesheet can use an
xsl:message
element with terminate="yes"
(see
23.1 Messages) to ensure that implementations that conform to an
earlier version of XSLT will not silently ignore the declaration.
For example,
<xsl:stylesheet version="18.0" xmlns:xsl="http://www.w3.org/1999/XSL/Transform"> <xsl:important-new-17.0-declaration/> <xsl:template match="/"> <xsl:choose> <xsl:when test="number(system-property('xsl:version')) lt 17.0"> <xsl:message terminate="yes"> <xsl:text>Sorry, this stylesheet requires XSLT 17.0.</xsl:text> </xsl:message> </xsl:when> <xsl:otherwise> ... </xsl:otherwise> </xsl:choose> </xsl:template> ... </xsl:stylesheet>
Note:
The XSLT 1.0 and XSLT 2.0 specifications did not anticipate the
introduction of the xsl:package
element. An XSLT 1.0 or 2.0
processor encountering this element will report a static error, regardless of the
version
setting.
This problem can be circumvented by using the simplified package
syntax (whereby an
xsl:stylesheet
element is implicitly treated as
xsl:package
), or by writing the stylesheet code in
a separate module from the package manifest, and using the separate module as the
version of the stylesheet that is presented to a 2.0 processor.
XSLT provides two mechanisms to construct a package from multiple stylesheet modules:
an inclusion mechanism that allows stylesheet modules to be combined without changing the semantics of the modules being combined, and
an import mechanism that allows stylesheet modules to override each other.
The include and import mechanisms use two declarations,
xsl:include
and xsl:import
, which are defined
in the sections that follow.
These declarations use an href
attribute, whose value is a URI reference, to identify the stylesheet module to be included or
imported. If the value of this attribute is a relative URI reference, it is resolved as described in 5.8 URI References.
After resolving against the base URI, the way in which the URI reference is used to locate a representation of a stylesheet module, and the way in which the stylesheet module is constructed from that representation, are implementation-defined. In particular, it is implementation-defined which URI schemes are supported, whether fragment identifiers are supported, and what media types are supported. Conventionally, the URI is a reference to a resource containing the stylesheet module as a source XML document, or it may include a fragment identifier that selects an embedded stylesheet module within a source XML document; but the implementation is free to use other mechanisms to locate the stylesheet module identified by the URI reference.
The referenced stylesheet module must be either a standard stylesheet module or a simplified stylesheet. It must not be a package manifest. If it is a simplified stylesheet module then it is transformed into the equivalent standard stylesheet module by applying the transformation described in 3.8 Simplified Stylesheet Modules.
Implementations may choose to accept URI references containing a fragment identifier defined by reference to the XPointer specification (see [XPointer Framework]). Note that if the implementation does not support the use of fragment identifiers in the URI reference, then it will not be possible to include an embedded stylesheet module.
[ERR XTSE0165] It is a static error if the processor is not able to retrieve the resource identified by the URI reference, or if the resource that is retrieved does not contain a stylesheet module.
Note:
It is appropriate to use this error code when the resource cannot be retrieved, or when the retrieved resource is not well formed XML. If the resource contains XML that can be parsed but that violates the rules for stylesheet modules, then a more specific error code may be more appropriate.
<!-- Category: declaration -->
<xsl:include
href = uri />
A stylesheet module may include another stylesheet module using an
xsl:include
declaration.
The xsl:include
declaration has a required
href
attribute whose value is a URI reference identifying the
stylesheet module to be included. This attribute is used as described in 3.11.1 Locating Stylesheet Modules.
[ERR XTSE0170] An xsl:include
element must be a
top-level element.
[Definition: A stylesheet
level is a collection of stylesheet modules connected using xsl:include
declarations: specifically, two stylesheet modules A and
B are part of the same stylesheet level if one of them includes
the other by means of an xsl:include
declaration, or if there
is a third stylesheet module C that is in the same stylesheet level
as both A and B.]
Note:
A stylesheet level thus groups the declarations in a package by import precedence: two declarations within a package are in the same stylesheet level if and only if they have the same import precedence.
[Definition: The declarations within a stylesheet level have a total ordering
known as declaration order. The order of declarations within a
stylesheet level is the same as the document order that would result if each
stylesheet module were inserted textually in place of the
xsl:include
element that references it.] In other
respects, however, the effect of xsl:include
is not equivalent to
the effect that would be obtained by textual inclusion.
[ERR XTSE0180] It is a static error if a stylesheet module directly or indirectly includes itself.
Note:
It is not intrinsically an error for a stylesheet to include the same module more than once. However, doing so can cause errors because of duplicate definitions. Such multiple inclusions are less obvious when they are indirect. For example, if stylesheet B includes stylesheet A, stylesheet C includes stylesheet A, and stylesheet D includes both stylesheet B and stylesheet C, then A will be included indirectly by D twice. If all of B, C and D are used as independent stylesheets, then the error can be avoided by separating everything in B other than the inclusion of A into a separate stylesheet B′ and changing B to contain just inclusions of B′ and A, similarly for C, and then changing D to include A, B′, C′.
<!-- Category: declaration -->
<xsl:import
href = uri />
A stylesheet module may import another stylesheet module using an xsl:import
declaration. Importing a stylesheet module
is the same as including it (see 3.11.2 Stylesheet Inclusion) except that template rules and other declarations in the importing module take
precedence over template rules and declarations in the imported module; this is
described in more detail below.
The xsl:import
declaration has a required
href
attribute whose value is a URI reference identifying the
stylesheet module to be included. This attribute is used as described in 3.11.1 Locating Stylesheet Modules.
[ERR XTSE0190] An xsl:import
element must be a top-level element.
xsl:import
For example,
<xsl:stylesheet version="3.0" xmlns:xsl="http://www.w3.org/1999/XSL/Transform"> <xsl:import href="article.xsl"/> <xsl:import href="bigfont.xsl"/> <xsl:attribute-set name="note-style"> <xsl:attribute name="font-style">italic</xsl:attribute> </xsl:attribute-set> </xsl:stylesheet>
[Definition: The stylesheet levels making up a stylesheet are treated as forming an
import tree. In the import tree, each stylesheet level has one
child for each xsl:import
declaration that it
contains.] The ordering of the children is the declaration order of the
xsl:import
declarations within their stylesheet level.
[Definition: A declaration D in the stylesheet is defined to have lower import precedence than another declaration E if the stylesheet level containing D would be visited before the stylesheet level containing E in a post-order traversal of the import tree (that is, a traversal of the import tree in which a stylesheet level is visited after its children). Two declarations within the same stylesheet level have the same import precedence.]
For example, suppose
stylesheet module A imports stylesheet modules B and C in that order;
stylesheet module B imports stylesheet module D;
stylesheet module C imports stylesheet module E.
Then the import tree has the following structure:
The order of import precedence (lowest first) is D, B, E, C, A.
In general, a declaration with higher import precedence takes precedence over a declaration with lower import precedence. This is defined in detail for each kind of declaration.
[ERR XTSE0210] It is a static error if a stylesheet module directly or indirectly imports itself.
Note:
The case where a stylesheet module with a particular URI is imported several times is not treated specially. The effect is exactly the same as if several stylesheet modules with different URIs but identical content were imported. This might or might not cause an error, depending on the content of the stylesheet module.
An embedded stylesheet module is a stylesheet module whose containing element is not the outermost element of the containing XML document. Both standard stylesheet modules and simplified stylesheet modules may be embedded in this way.
Two situations where embedded stylesheets may be useful are:
The stylesheet may be embedded in the source document to be transformed.
The stylesheet may be embedded in an XML document that describes a sequence of processing of which the XSLT transformation forms just one part.
The xsl:stylesheet
element may have an
id
attribute to facilitate reference to the stylesheet module within
the containing document.
Note:
In order for such an attribute value to be used as a fragment identifier in a URI,
the XDM attribute node must generally have the is-id
property: see
Section
5.5 is-id Accessor
DM30. This property will typically be set if
the attribute is defined in a DTD as being of type ID
, or if it is
defined in a schema as being of type xs:ID
. It is also necessary that
the media type of the containing document should support the use of ID values as
fragment identifiers.
Such support is widespread in existing products, and is
endorsed in respect of the media type application/xml
by [RFC7303].
An alternative, if the implementation supports it, is to use an
xml:id
attribute. XSLT allows this attribute (like other
namespaced attributes) to appear on any XSLT
element.
The following example shows how the xml-stylesheet
processing
instruction (see [XML Stylesheet]) can be used to allow a source
document to contain its own stylesheet. The URI reference uses a fragment identifier
to locate the
xsl:stylesheet
element:
<?xml-stylesheet type="application/xslt+xml" href="#style1"?> <!DOCTYPE doc SYSTEM "doc.dtd"> <doc> <head> <xsl:stylesheet id="style1" version="3.0" xmlns:xsl="http://www.w3.org/1999/XSL/Transform" xmlns:fo="http://www.w3.org/1999/XSL/Format"> <xsl:import href="doc.xsl"/> <xsl:template match="id('foo')"> <fo:block font-weight="bold"><xsl:apply-templates/></fo:block> </xsl:template> <xsl:template match="xsl:stylesheet"> <!-- ignore --> </xsl:template> </xsl:stylesheet> </head> <body> <para id="foo"> ... </para> </body> </doc>
Note:
A stylesheet module that is embedded in the document to which it is to be applied
typically needs to contain a template
rule that specifies that xsl:stylesheet
elements are
to be ignored.
Note:
The above example uses the pseudo-attribute
type="application/xslt+xml"
in the xml-stylesheet
processing instruction to denote an XSLT stylesheet. This is the officially
registered media type for XSLT: see 3.3 XSLT Media Type. However,
browsers developed before this media type was registered are more likely to accept
the unofficial designation type="text/xsl"
.
Note:
Support for the xml-stylesheet
processing instruction is not required
for conformance with this Recommendation. Implementations are not constrained in
the mechanisms they use to identify a stylesheet when a transformation is
initiated: see 2.3 Initiating a Transformation.
This specification provides two features that cause the
raw stylesheet to be preprocessed as the first stage of static processing: elements
may be conditionally included or excluded by means of an [xsl:]use-when
attribute as described in 3.13.1 Conditional Element Inclusion, and attributes may
be conditionally computed as described in 3.13.2 Shadow Attributes.
Note that many of the rules affecting the validity of stylesheet documents apply to a stylesheet after this preprocessing phase has been carried out.
Any element in the XSLT namespace may have a use-when
attribute whose
value is an XPath expression that can be evaluated statically.
A literal result element, or
any other element within a stylesheet
module that is not in the XSLT namespace, may similarly carry an
xsl:use-when
attribute.
If the attribute is
present and the effective boolean
valueXP30 of the expression is false, then the element, together with
all the nodes having that element as an ancestor, is effectively excluded from the
stylesheet module. When a node is
effectively excluded from a stylesheet module the stylesheet module has the same
effect as if the node were not there. Among other things this means that no static
or dynamic errors will be reported in respect of the element and its contents,
other than errors in the use-when
attribute itself.
Note:
This does not apply to XML parsing or validation errors, which will be reported
in the usual way. It also does not apply to attributes that are necessarily
processed before [xsl:]use-when
, examples being
xml:space
and [xsl:]xpath-default-namespace
.
If the xsl:package
,
xsl:stylesheet
or xsl:transform
element
itself is effectively excluded, the effect is to exclude all the children of the
xsl:stylesheet
or xsl:transform
element, but
not the xsl:stylesheet
or xsl:transform
element
or its attributes.
Note:
This allows all the declarations that depend on the same condition to be
included in one stylesheet module, and for their inclusion or exclusion to be
controlled by a single use-when
attribute at the level of the
module.
Conditional element exclusion happens after stripping of whitespace text nodes from the stylesheet, as described in 4.3 Stripping Whitespace from the Stylesheet.
The XPath expression used as the value of the
xsl:use-when
attribute follows the rules for static expressions, including the rules for handling errors.
The use of [xsl:]use-when
is illustrated in the following
examples.
This example demonstrates the use of the use-when
attribute to
achieve portability of a stylesheet across schema-aware and non-schema-aware
processors.
<xsl:import-schema schema-location="http://example.com/schema" use-when="system-property('xsl:is-schema-aware')='yes'"/> <xsl:template match="/" use-when="system-property('xsl:is-schema-aware')='yes'" priority="2"> <xsl:result-document validation="strict"> <xsl:apply-templates/> </xsl:result-document> </xsl:template> <xsl:template match="/"> <xsl:apply-templates/> </xsl:template>
The effect of these declarations is that a non-schema-aware processor ignores
the xsl:import-schema
declaration and the first template rule,
and therefore generates no errors in respect of the schema-related constructs
in these declarations.
This example includes different stylesheet modules depending on which XSLT processor is in use.
<xsl:include href="module-A.xsl" use-when="system-property('xsl:vendor')='vendor-A'"/> <xsl:include href="module-B.xsl" use-when="system-property('xsl:vendor')='vendor-B'"/>
When a no-namespace attribute name N is permitted to appear on an element in the XSLT namespace (provided that N does not start with an underscore), then a value V can be supplied for N in one of two ways:
The conventional way is for an attribute node with name N and value V to appear in the XDM representation of the element node in the stylesheet tree.
As an alternative, a shadow attribute may be supplied allowing the value V to be statically computed during the preprocessing phase. The shadow attribute has a name that is the same as the name N prefixed with an underscore, and the value of the shadow attribute is a value template in which all expressions enclosed between curly braces must be static expressions. The value V is the result of evaluating the value template. If a shadow attribute is present, then any attribute node with name N (sharing the same parent element) is ignored.
For example, an xsl:include
element might be written:
<xsl:include _href="common{$VERSION}.xsl"/>
allowing the stylesheet to include a specific version of a library module based on the value of a static parameter.
Similarly, a mode might be declared like this:
<xsl:param name="streamable" as="xs:boolean" required="yes" static="yes"/> <xsl:mode _streamable="{$streamable}" on-no-match="shallow-skip"/>
this allowing the streamability of the mode to be controlled using a static parameter
(Note: this example relies on the fact that the
streamable
attribute accepts a boolean value, which means that
the values true
and false
are accepted as synonyms of
yes
and no
).
This mechanism applies to all attributes in the stylesheet where the attribute
name is in no namespace and the name of the parent element is in the XSLT namespace. This includes attributes that have static
significance such as the use-when
attribute, the version
attribute, and the static
attribute on xsl:variable
.
The mechanism does not apply to shadow attributes (that is, it is not possible to
invoke two stages of preprocessing by using two leading underscores). It does not
apply to attributes of literal result elements, nor to attributes in a namespace
such as the XML or XSLT namespace, nor to namespace declarations.
Note:
If a shadow attribute and its corresponding target attribute are both present in the stylesheet, the non-shadow attribute is ignored. This may be useful to make stylesheet code compatible across XSLT versions; an XSLT 2.0 processor operating in forwards compatible mode will ignore shadow attributes, and will require the target attribute to be valid.
Note:
The statement that the non-shadow attribute is ignored extends to error detection: it is not an error if the non-shadow attribute has an invalid value. However, this is not reflected in the schema for XSLT stylesheets, so validation using this schema may report errors in such cases.
Note:
An attribute whose name begins with an underscore is treated specially only when it appears on an element in the XSLT namespace. On a literal result element, it is treated in the same way as any other attribute (that is, its effective value is copied to the result tree). On an extension instruction or user-defined data element, as with other attributes on these elements, its meaning is entirely implementation-defined.
Although it is not usually considered good practice, it sometimes happens that variants or versions of an XML vocabulary exist in which the same local names are used, but in different namespaces. There is then a requirement to write code that will process source documents in a variety of different namespaces.
It is possible to define a static stylesheet parameter containing the target namespace, for example:
<xsl:param name="NS" as="xs:string" static="yes" select="'http://example.com/ns/one'"/>
And this can then be used to set the default namespace for XPath expressions:
_xpath-default-namespace="{$NS}"
However, it is not possible to put this shadow attribute on the
xsl:stylesheet
or xsl:package
element of
the principal stylesheet module, because at that point the variable
$NS
is not in scope. A workaround is to create a stub
stylesheet module which contains nothing but the static parameter declaration
and an xsl:include
of the stylesheet module containing the
real logic. The static stylesheet parameter will then be in scope on the
xsl:stylesheet
element of the included stylesheet module,
and the shadow attribute _xpath-default-namespace="{$NS}"
can
therefore appear on this xsl:stylesheet
element.
The following stylesheet produces a report giving information about selected employees. The predicate defining which employees are to be included in the report is supplied (as a string containing an XPath expression) in a static stylesheet parameter:
<xsl:param name="filter" static="yes" as="xs:string" select="'true()'"/> <xsl:function name="local:filter" as="xs:boolean"> <xsl:param name="e" as="element(employee)"/> <xsl:sequence _select="$e/({$filter})"/> </xsl:function> <xsl:template match="/"> <report> <xsl:apply-templates mode="report" select="//employee[local:filter(.)]"/> </report> </xsl:template>
If the supplied value of the filter parameter is, say location =
"UK"
, then the report will cover employees based in the UK.
Note:
The stylesheet function local:filter
is used here in preference
to direct use of the supplied predicate within the select
attribute of the xsl:apply-templates
instruction because it
reduces exposure to code injection attacks. It does not necessarily
eliminate all such risks, however. For example, it would be possible for a
caller to supply an expression that never terminates, thus creating a
denial-of-service risk.
Every XSLT 3.0 processor includes the following named type definitions in the in-scope schema components:
All built-in types defined in [XML Schema Part 2], including xs:anyType
and
xs:anySimpleType
.
The following types defined in [XPath 3.0]:
xs:yearMonthDuration
, xs:dayTimeDuration
,
xs:anyAtomicType
, xs:untyped
, and
xs:untypedAtomic
.
XSLT 3.0 processors may optionally include types
defined in XSD 1.1 (see [XML Schema 1.1 Part 1]). XSD 1.1 adopts the types
xs:yearMonthDuration
, xs:dayTimeDuration
, and
xs:anyAtomicType
previously defined in XPath 2.0, and adds one new
type: xs:dateTimeStamp
. XSD 1.1 also allows implementers to define
additional primitive types, and XSLT 3.0 permits such types to be supported by an
XSLT processor.
A schema-aware XSLT processor additionally supports:
User-defined types, and element and attribute declarations, that are imported
using an xsl:import-schema
declaration as described in
3.15 Importing Schema Components. These may include both simple and complex
types.
Note:
The names that are imported from the XML Schema namespace do not include all the
names of top-level types defined in either the Schema for Schema Documents or the
Schema for Schema Documents (Datatypes). The Schema for Schema Documents, as well
as defining built-in types such as xs:integer
and
xs:double
, also defines types that are intended for use only
within that schema, such as xs:derivationControl
. A stylesheet that is designed to process XML Schema
documents as its input or output may import the Schema for Schema Documents.
An implementation may define mechanisms that allow additional schema components to be added to the in-scope schema components for the stylesheet. For example, the mechanisms used to define extension functions (see 24.1 Extension Functions) may also be used to import the types used in the interface to such functions.
These schema components are the only
ones that may be referenced in XPath expressions within the stylesheet, or in the
[xsl:]type
and as
attributes of those elements that
permit these attributes.
Note:
The facilities described in this section are not available with a basic XSLT processor. They require a schema-aware XSLT processor, as described in 27 Conformance.
<!-- Category: declaration -->
<xsl:import-schema
namespace? = uri
schema-location? = uri >
<!-- Content: xs:schema? -->
</xsl:import-schema>
The xsl:import-schema
declaration is used to identify schema components (that is, top-level type
definitions and top-level element and attribute declarations) that need to be
available statically, that is, before any source document is available. Names of such
components used statically within the stylesheet must refer to an in-scope schema component, which means they must either be built-in
types as defined in 3.14 Built-in Types, or they must be imported using
an xsl:import-schema
declaration.
The xsl:import-schema
declaration identifies a namespace containing
the names of the components to be imported (or indicates that components whose names
are in no namespace are to be imported). The effect is that the names of top-level
element and attribute declarations and type definitions from this namespace (or
non-namespace) become available for use within XPath expressions in the package, and within
other stylesheet constructs such as the type
and as
attributes of various XSLT elements.
The same schema components are available in all stylesheet modules within the declaring package; importing components in one stylesheet module makes them available throughout the package.
The schema components imported into different packages within a stylesheet must be consistent. Specifically, it is not permitted to use the same name in the same XSD symbol space to refer to different schema components within different packages; and the union of the schema components imported into the packages of a stylesheet must constitute a valid schema (as well as the set of schema components imported into each package forming a valid schema in its own right).
The namespace
and schema-location
attributes are both
optional.
If the xsl:import-schema
element contains an xs:schema
element, then the schema-location
attribute must be
absent, and one of the following must be true:
the namespace
attribute of the xsl:import-schema
element and the targetNamespace
attribute of the
xs:schema
element are both absent (indicating a no-namespace
schema), or
the namespace
attribute of the xsl:import-schema
element and the targetNamespace
attribute of the
xs:schema
element are both present and both have the same
value, or
the namespace
attribute of the xsl:import-schema
element is absent and the targetNamespace
attribute of the
xs:schema
element is present, in which case the target
namespace is as given on the xs:schema
element.
[ERR XTSE0215] It is a static error if an
xsl:import-schema
element that contains an
xs:schema
element has a schema-location
attribute,
or if it has a namespace
attribute that conflicts with the target
namespace of the contained schema.
If two xsl:import-schema
declarations specify the same namespace, or
if both specify no namespace, then only the one with highest import precedence is used. If this leaves
more than one, then all the declarations at the highest import precedence are used
(which may cause conflicts, as described below).
After discarding any xsl:import-schema
declarations under the above
rule, the effect of the remaining xsl:import-schema
declarations is
defined in terms of a hypothetical document called the synthetic schema document,
which is constructed as follows. The synthetic schema document defines an arbitrary
target namespace that is different from any namespace actually used by the
application, and it contains xs:import
elements corresponding
one-for-one with the xsl:import-schema
declarations in the stylesheet, with the following correspondence:
The namespace
attribute of the xs:import
element is
copied from the namespace
attribute of the
xsl:import-schema
declaration if it is explicitly present,
or is implied by the targetNamespace
attribute of a contained
xs:schema
element, and is absent if it is absent.
The schemaLocation
attribute of the xs:import
element
is copied from the schema-location
attribute of the
xsl:import-schema
declaration if present, and is absent if
it is absent. If there is a contained xs:schema
element, the
effective value of the schemaLocation
attribute is a URI
referencing a document containing a copy of the xs:schema
element.
The base URI of the xs:import
element is the same as the base URI
of the xsl:import-schema
declaration.
The schema components included in the in-scope schema components (that is, the components whose names are available for use within the stylesheet) are the top-level element and attribute declarations and type definitions that are available for reference within the synthetic schema document. See [XML Schema Part 1] (section 4.2.3, References to schema components across namespaces).
[ERR XTSE0220] It is a static error if the synthetic schema document does not satisfy the constraints described in [XML Schema Part 1] (section 5.1, Errors in Schema Construction and Structure). This includes, without loss of generality, conflicts such as multiple definitions of the same name.
Note:
The synthetic schema document does not need to be constructed by a real
implementation. It is purely a mechanism for defining the semantics of
xsl:import-schema
in terms of rules that already exist within
the XML Schema specification. In particular, it implicitly defines the rules that
determine whether the set of xsl:import-schema
declarations are
mutually consistent.
These rules do not cause names to be imported transitively. The fact that a name is available for reference within a schema document A does not of itself make the name available for reference in a stylesheet that imports the target namespace of schema document A. (See [XML Schema Part 1] section 3.15.3, Constraints on XML Representations of Schemas.) The stylesheet must import all the namespaces containing names that it actually references.
The namespace
attribute indicates that a schema for the given
namespace is required by the stylesheet.
This information may be enough on its own to enable an implementation to locate
the required schema components. The namespace
attribute may be
omitted to indicate that a schema for names in no namespace is being imported. The
zero-length string is not a valid namespace URI, and is therefore not a valid
value for the namespace
attribute.
The schema-location
attribute is a URI Reference that gives a hint indicating where a schema document
or other resource containing the required definitions may be found. It is likely
that a schema-aware XSLT
processor will be able to process a schema document found at this
location.
The XML Schema specification gives implementations flexibility in how to handle multiple imports for the same namespace. Multiple imports do not cause errors if the definitions do not conflict.
A consequence of these rules is that it is not intrinsically an error if no schema
document can be located for a namespace identified in an
xsl:import-schema
declaration. This will cause an error only
if it results in the stylesheet containing references to names that have not been
imported.
An inline schema document (using an xs:schema
element as a child of
the xsl:import-schema
element) has the same status as an external
schema document, in the sense that it acts as a hint for a source of schema
components in the relevant namespace. To ensure that the inline schema document is
always used, it is advisable to use a target namespace that is unique to this
schema document.
The use of a namespace in an xsl:import-schema
declaration does not
by itself associate any namespace prefix with the namespace. If names from the
namespace are used within the stylesheet module then a namespace declaration must
be
included in the stylesheet module, in the usual way.
The following example shows an inline schema document. This declares a simple type
local:yes-no
, which the stylesheet then uses in the declaration of
a variable.
The example assumes the namespace declaration
xmlns:local="http://example.com/ns/yes-no"
<xsl:import-schema> <xs:schema targetNamespace="http://example.com/ns/yes-no" xmlns:xs="http://www.w3.org/2001/XMLSchema" xmlns:local="http://example.com/ns/yes-no"> <xs:simpleType name="yes-no"> <xs:restriction base="xs:string"> <xs:enumeration value="yes"/> <xs:enumeration value="no"/> </xs:restriction> </xs:simpleType> </xs:schema> </xsl:import-schema> <xsl:variable name="condition" select="local:yes-no('yes')" as="local:yes-no"/>
There are two built-in functions
(analyze-string
FO30 and json-to-xml
) whose
result is an XML structure for which a schema is defined. The namespace for these
schema definitions is (in both cases) http://www.w3.org/2005/xpath-functions
. Schema
components for these namespaces are available for reference within the stylesheet
if
and only if an xsl:import-schema
declaration is present referencing
this namespace. If such a declaration is present, then the schema that is
imported is the schema defined in the specification of these functions: the schemaLocation
attribute has no effect.
The data model used by XSLT is the XPath 3.0 and XQuery 3.0 data model (XDM), as defined in [XDM 3.0]. XSLT operates on source, result and stylesheet documents using the same data model.
This section elaborates on some particular features of XDM as it is used by XSLT:
The rules in 4.3 Stripping Whitespace from the Stylesheet and 4.4.2 Stripping Whitespace from a Source Tree make use of the concept of a whitespace text node.
[Definition: A whitespace text node is a text node whose content consists entirely of whitespace characters (that is, #x09, #x0A, #x0D, or #x20).]
Note:
Features of a source XML document that are not represented in the XDM tree will have no effect on the operation of an XSLT stylesheet. Examples of such features are entity references, CDATA sections, character references, whitespace within element tags, and the choice of single or double quotes around attribute values.
The XDM data model defined in [XDM 3.0] is capable of representing either an XML 1.0 document (conforming to [XML 1.0] and [Namespaces in XML]) or an XML 1.1 document (conforming to [XML 1.1] and [Namespaces in XML 1.1]), and it makes no distinction between the two. In principle, therefore, XSLT 3.0 can be used with either of these XML versions.
Construction of the XDM tree is outside the scope of this specification, so XSLT 3.0 places no formal requirements on an XSLT processor to accept input from either XML 1.0 documents or XML 1.1 documents or both. This specification does define a serialization capability (see 26 Serialization), though from a conformance point of view it is an optional feature. Although facilities are described for serializing the XDM tree as either XML 1.0 or XML 1.1 (and controlling the choice), there is again no formal requirement on an XSLT processor to support either or both of these XML versions as serialization targets.
Because the XDM tree is the same whether the original document was XML 1.0 or XML 1.1, the semantics of XSLT processing do not depend on the version of XML used by the original document. There is no reason in principle why all the input and output documents used in a single transformation must conform to the same version of XML.
Some of the syntactic constructs in XSLT 3.0 and XPath 3.0, for example the productions CharXML and NCNameNames, are defined by reference to the XML and XML Namespaces specifications. There are slight variations between the XML 1.0 and XML 1.1 versions of these productions (and, indeed, between different editions of XML 1.0). Implementations may support any version; it is recommended that an XSLT 3.0 processor that implements the 1.1 versions should also provide a mode that supports the 1.0 versions. It is thus implementation-defined which versions and editions of XML and XML Namespaces are supported by the implementation.
Note:
The specification referenced as [Namespaces in XML] was actually published without a version number.
The current version of [XML Schema 1.1 Part 2] references the XML 1.1 specifications, but the previous version ([XML Schema Part 2]) (that is, XSD 1.0) remains in widespread use, and only
references XML 1.0. With processors lacking support for XSD 1.1,
therefore, datatypes such as xs:NCName
and xs:ID
may be
constrained by the XML 1.0 rules, and not allow the full range of values permitted
by
XML 1.1. It is recommended that implementers wishing to support
XML 1.1 should consult [XML Schema 1.0 and XML 1.1] for guidance.
XSLT 3.0 requires a processor to support XDM 3.0 as defined in [XDM 3.0], augmented with support for maps as described in 21 Maps.
A processor may also provide a user option to support XDM 3.1 as defined in [XDM 3.1], in which case it must do so as defined in 27.7 XPath 3.1 Feature.
Note:
The essential differences between XDM 3.0 (with the extensions defined in this
specification) and XDM 3.1 are that XDM 3.1 adds support for arrays, and for the
xs:numeric
union type.
A processor may also provide a user option to support versions of XDM later than 3.1, in which case the way it does so is implementation-defined.
The tree representing the stylesheet is preprocessed as follows:
All comments and processing instructions are removed.
Any text nodes that are now adjacent to each other are merged.
Any whitespace text node that satisfies both the following conditions is removed from the tree:
The parent of the text node is not an xsl:text
element
The text node does not have an ancestor element that has an
xml:space
attribute with a value of
preserve
, unless there is a closer ancestor element having
an xml:space
attribute with a value of
default
.
Any whitespace text node whose
parent is one of the following elements is removed from the tree, regardless of
any xml:space
attributes:
xsl:accumulator
xsl:analyze-string
xsl:apply-imports
xsl:apply-templates
xsl:attribute-set
xsl:call-template
xsl:character-map
xsl:choose
xsl:evaluate
xsl:fork
xsl:merge
xsl:merge-source
xsl:mode
xsl:next-iteration
xsl:next-match
xsl:override
xsl:package
xsl:stylesheet
xsl:transform
xsl:use-package
Any whitespace text node whose
immediate following-sibling node is an xsl:param
or
xsl:sort
or xsl:context-item
or
xsl:on-completion
element is removed from the
tree, regardless of any xml:space
attributes.
Any whitespace text
node whose immediate preceding-sibling node is an
xsl:catch
element is removed from the
tree, regardless of any xml:space
attributes.
[ERR XTSE0260] Within an XSLT element that is
required to be empty, any content other than comments or
processing instructions, including any whitespace text node preserved using the
xml:space="preserve"
attribute, is a static error.
Note:
Using xml:space="preserve"
in parts of the stylesheet that contain
sequence constructors will
cause whitespace text nodes in that part of the
stylesheet to be copied to the result of the sequence constructor.
When the result of the sequence constructor is used to form the content of an
element, this can cause errors if such text nodes are followed by attribute nodes
generated using xsl:attribute
.
Note:
If an xml:space
attribute is specified on a literal result element, it will be
copied to the result tree in the same way as any other attribute.
Source documents supplied as input to a transformation may be subject to preprocessing. Two kinds of preprocessing are defined: stripping of type annotations (see 4.4.1 Stripping Type Annotations from a Source Tree), and stripping of whitespace text nodes (see 4.4.2 Stripping Whitespace from a Source Tree).
Stripping of type annotations happens before stripping of whitespace text nodes.
The source documents to which this applies are as follows:
The document containing the global context item if it is a node;
Any documents containing a node present in the initial match selection;
Any document containing a node that is returned by the functions document
, doc
FO30,
or collection
FO30;
Any document read using xsl:source-document
.
Note:
This list excludes documents passed as the values of
stylesheet parameters or parameters
of the initial named template or initial function,
trees created by functions such as parse-xml
FO30, parse-xml-fragment
,
analyze-string
FO30, or json-to-xml
,
nor values returned from extension
functions.
If a node other than a document node is supplied (for example as the global context
item),
then the preprocessing is applied to the entire document containing that node. If
several nodes within the same
document are supplied (for example as nodes in the initial match selection, or as
nodes returned by the
collection
FO30 function), then the preprocessing is only applied to that document once.
If a whitespace text node is supplied (for example as the global context item) and
the rules cause this node
to be stripped from its containing tree, then the behavior is as if this node had
not been supplied
(which may cause an error, for example if a global context item is required.)
The rules determining whether or not stripping of annotations and/or whitespace
happens are defined at the level of a package. Declarations within a library package
only affect the handling of documents loaded using a call on the document
, doc
FO30,
or collection
FO30 functions or an evaluation of an xsl:source-document
instruction
appearing lexically within the same package. Declarations within the top-level package also affect the processing
of the global context item and the initial match selection.
The semantics of the document
, doc
FO30,
and collection
FO30 functions are formally defined in terms of mappings from URIs to document nodes
maintained within the dynamic context (see 5.3.3 Initializing the Dynamic Context). The effect of the
declarations that control stripping of type annotations
and whitespace is therefore to modify this mapping (so it now maps the URI to a stripped
document). The modification
applies to the dynamic context for calls to these function appearing within a particular
package; each package therefore
has a different set of mappings. This means that when two calls to the doc
FO30 function appear in
different packages, specifying the same absolute URI, then in general different documents
are returned. An implementation
may return the same document for two such calls if it is able to determine that the effect
of the annotation
and whitespace stripping rules in both packages is the same.
The effect of dynamic calls to the document
, doc
FO30,
and collection
FO30 functions is defined in the same way as for other functions with dependencies on
the dynamic context. As described in 5.3.4 Additional Dynamic Context Components used by XSLT, named function references
(such as doc#1
) and calls on function-lookup
FO30 (for example, function-lookup("doc", 1)
)
are defined to retain the XPath static and dynamic context at the point of invocation
as part of the closure of the
resulting function item, and to use this preserved context when a dynamic function
call is subsequently made using the function item.
[Definition: The term type
annotation is used in this specification to refer to the value returned
by the dm:type-name
accessor of a node: see Section
5.14 type-name Accessor
DM30.]
There is sometimes a requirement to write stylesheets that produce the same results
whether or not the source documents have been validated against a schema. To achieve
this, an option is provided to remove any type
annotations on element and attribute nodes in a source tree, replacing them with an annotation of
xs:untyped
in the case of element nodes, and
xs:untypedAtomic
in the case of attribute nodes.
Such stripping of type annotations can be
requested by specifying input-type-annotations="strip"
on the xsl:package
element. This
attribute has three permitted values: strip
, preserve
, and
unspecified
. The default value is unspecified
.
The input-type-annotations
attribute may also
be specified on the xsl:stylesheet
element; if it is specified at
this level then it must be consistent for all stylesheet modules within the same
package.
[ERR XTSE0265] It is a static error if there is a
stylesheet module in a
package that specifies
input-type-annotations="strip"
and another stylesheet module that specifies
input-type-annotations="preserve"
, or if a stylesheet module specifies the value
strip
or preserve
and the same value is not
specified on the xsl:package
element of the containing
package.
When type annotations are stripped, the following changes are made to the source tree:
The type annotation of every element node is changed to xs:untyped
The type annotation of every attribute node is changed to
xs:untypedAtomic
The typed value of every element and attribute node is set to be the same as
its string value, as an instance of xs:untypedAtomic
.
The is-nilled
property of every element node is set to
false
.
The values of the is-id
and is-idrefs
properties are not
changed.
Note:
Stripping type annotations does not
necessarily return the document to the state it would be in had validation not
taken place. In particular, any defaulted elements and attributes that were added
to the tree by the validation process will still be present, and elements and
attributes validated as IDs will still be accessible using the
id
FO30 function.
A source tree supplied as input to the transformation process may contain whitespace text nodes that are of no interest, and that do not need to be retained by the transformation. Conceptually, an XSLT processor makes a copy of the source tree from which unwanted whitespace text nodes have been removed. This process is referred to as whitespace stripping.
The stripping process takes as input a set of element names whose child whitespace text nodes are to be preserved.
The way in which this set of element names is established using the
xsl:strip-space
and xsl:preserve-space
declarations is described later in this section.
The stripping process that applies for a particular
package is determined by the xsl:strip-space
and xsl:preserve-space
declarations within that package.
A whitespace text node is preserved if either of the following apply:
The element name of the parent of the text node is in the set of whitespace-preserving element names.
An ancestor element of the text node has an xml:space
attribute
with a value of preserve
, and no closer ancestor element has
xml:space
with a value of default
.
Otherwise, the whitespace text node is stripped.
The xml:space
attributes are not removed from the tree.
<!-- Category: declaration -->
<xsl:strip-space
elements = tokens />
<!-- Category: declaration -->
<xsl:preserve-space
elements = tokens />
The set of whitespace-preserving element names is specified by
xsl:strip-space
and xsl:preserve-space
declarations. Whether an element name is
included in the set of whitespace-preserving names is determined by the best match
among all the xsl:strip-space
or xsl:preserve-space
declarations: it is included if and only if there is no match or the best match is
an
xsl:preserve-space
element. The xsl:strip-space
and xsl:preserve-space
elements each have an elements
attribute whose value is a whitespace-separated list of NameTestsXP30; an element name matches an
xsl:strip-space
or xsl:preserve-space
element if
it matches one of the NameTestsXP30.
An element matches a NameTestXP30 if
and only if the NameTestXP30 would be
true for the element as an XPath node test.
[ERR XTSE0270] It is a static error if within any package the same NameTestXP30 appears in both an
xsl:strip-space
and an xsl:preserve-space
declaration if both have the same import
precedence. Two NameTests are considered the same if they match
the same set of names (which can be determined by comparing them after
expanding namespace prefixes to URIs).
Otherwise, when more than one
xsl:strip-space
and xsl:preserve-space
element
within the relevant package matches, the best matching element is determined by
the best matching NameTestXP30.
The rules are similar to those for
template rules:
First, any match with lower import precedence than another match is ignored.
Next, any match that has a lower default priority than the default priority of another match is ignored.
If several matches have the same default priority (which can only happen
if one of the NameTests takes the form *:local
and the other takes
the form prefix:*
), then the declaration that appears last in
declaration order is used.
If an element in a source document has a type
annotation that is a simple type or a complex type with simple content,
then any whitespace text nodes among its children are preserved, regardless of any
xsl:strip-space
declarations. The reason for this is that
stripping a whitespace text node from an element with simple content could make the
element invalid: for example, it could cause the minLength
facet to be
violated.
Stripping of type annotations happens
before stripping of whitespace text nodes, so this situation will not occur if
input-type-annotations="strip"
is specified.
Note:
In [XDM 3.0], processes are described for constructing an
XDM tree from an Infoset or from a PSVI. Those processes deal with whitespace
according to their own rules, and the provisions in this section apply to the
resulting tree. In practice this means that elements that are defined in a DTD or
a Schema to contain element-only content will have whitespace text nodes stripped,
regardless of the xsl:strip-space
and
xsl:preserve-space
declarations in the stylesheet.
However, source trees are not necessarily constructed using those processes; indeed, they are not necessarily constructed by parsing XML documents. Nothing in the XSLT specification constrains how the source tree is constructed, or what happens to whitespace text nodes during its construction. The provisions in this section relate only to whitespace text nodes that are present in the tree supplied as input to the XSLT processor. The XSLT processor cannot preserve whitespace text nodes unless they were actually present in the supplied tree.
The mapping from the Infoset to the XDM data model, described in [XDM 3.0], does not retain attribute types. This means, for
example, that an attribute described in the DTD as having attribute type
NMTOKENS
will be annotated in the XDM tree as
xs:untypedAtomic
rather than xs:NMTOKENS
, and its typed
value will consist of a single xs:untypedAtomic
value rather than a
sequence of xs:NMTOKEN
values.
Attributes with a DTD-derived type of ID, IDREF, or IDREFS will be marked in the XDM
tree as having the is-id
or is-idrefs
properties. It is
these properties, rather than any type
annotation, that are examined by the functions id
FO30
and idref
FO30 described in [Functions and Operators 3.0].
The data model for nodes in a document that is being streamed is no different from the standard XDM data model, in that it contains the same objects (nodes) with the same properties and relationships. The facilities for streaming do not change the data model; instead they impose rules that limit the ability of stylesheets to navigate the data model.
A useful way to visualize streaming is to suppose that at any point in time, there is a current position in the streamed input document which may be the start or end of the document, the start or end tag of an element, or a text, comment, or processing instruction node. From this position, the stylesheet has access to the following information:
Properties intrinsic to the node, such as its name, its base URI, its type
annotation, and its is-id
and is-idref
properties.
The ancestors of the node (but navigation downwards from the ancestors is not permitted).
The attributes of the node, and the attributes of its ancestors. For each such attribute, all the properties of the node including its string value and typed value are available, but there are limitations that restrict navigation from the attribute node to other nodes in the document.
The in-scope namespace bindings of the node.
In the case of attributes, text nodes, comments, and processing instructions, the string value and typed value of the node.
In the case of element nodes, whether or not the element has children. This
information is obtained by calling the has-children
FO30
function. This implies that the processor performs look-ahead (limited to a
single token) to determine whether the start tag is immediately followed by a
matching end tag.
In the case of document nodes, details of unparsed entities in the document.
This information is obtained by calling the
unparsed-entity-uri
and
unparsed-entity-public-id
functions. A processor might
enable this by reading the DTD as soon as the document is opened. Since
comments and processing instructions that precede the DOCTYPE declaration are
available as children of the document node, this also implies that a streaming
processor needs sufficient memory to hold these comments and processing
instructions until the start tag of the first element is encountered.
Information about unparsed entities remains available for the duration of
processing, in the same way as attributes of ancestor elements.
The children and other descendants of a node are not accessible except as a by-product of changing the current position in the document. The same applies to properties of an element or document node that require examination of the node’s descendants, that is, the string value and typed value. This is enforced by means of a rule that only one expression requiring downward navigation from a node is permitted.
Information about the type of a node is in general
considered a property intrinsic to the node, and is available without advancing the
input stream. There is an exception for an expression of the form (/) instance
of document-node(element(invoice))
. This is not guaranteed streamable,
because it requires reading ahead to check that the document node has only one
element child. However, a processor that knows that the parser delivering the
document stream is only capable of delivering well-formed documents may use this
knowledge (along with the limited look-ahead needed to get the name of the outermost
element) to make this expression streamable.
A streaming processor is not required to read any more of the source document than is needed to generate correct stylesheet output. It is not required to read the full source document merely in order to satisfy the requirement imposed by the XML Recommendation that an XML Processor must report violations of well-formedness in the input.
More detailed rules are defined in 19 Streamability.
Two new data structures have been added to the data model: maps and arrays. Both are defined in XPath 3.1, but maps are also available in XSLT processors that only support XPath 3.0 (see 21 Maps).
Streaming facilities in this specification are, for the most part, relevant only to streamed processing of XML trees, and not to other structures such as sequences, maps and arrays, which will typically be held in memory unless the processor is capable of avoiding this.
Maps, however, play in important role in enabling streamed applications
to be written. For example, a map can be used as the data structure maintained
by an accumulator (see 18.2 Accumulators) to remember information
that has been retrieved from a streamed document, given that it is not possible to
revisit the same nodes later. There is also a special streamability rule for
map constructor expressions (see 21.6 Maps and Streaming) that allows
such an expression to make multiple downward selections in the streamed input
document: for example one can write map{'authors':data(author), 'editors':data(editor)}
,
which gathers the values of these these two elements, or sets of elements, from the
input
stream, regardless what order they appear in — even if they are interleaved.
The rules for creating maps and arrays are designed to ensure that the entries in a map, and the members of an array, cannot contain nodes from a streamed document. This is achieved by the way in which the streamability properties of the relevant expressions and functions are defined.
By contrast, sequences can and often do contain nodes from streamed documents, and a major purpose of the rules for streamability is to make this possible.
The XDM data model (see [XDM 3.0]) leaves it to the host language to define limits. This section describes the limits that apply to XSLT.
Limits on some primitive datatypes are defined in [XML Schema Part 2]. Other limits, listed below, are implementation-defined. Note that this does not necessarily mean that each limit must be a simple constant: it may vary depending on environmental factors such as available resources.
The following limits are implementation-defined:
For the xs:decimal
type, the maximum number of decimal digits (the
totalDigits
facet). This must be at least 18 digits. (Note,
however, that support for the full value range of xs:unsignedLong
requires 20 digits.)
For the types xs:date
, xs:time
,
xs:dateTime
, xs:gYear
, and
xs:gYearMonth
: the range of values of the year component, which
must be at least +0001 to +9999; and the maximum number of fractional second
digits, which must be at least 3.
For the xs:duration
type: the maximum absolute values of the
years, months, days, hours, minutes, and seconds components.
For the xs:yearMonthDuration
type: the maximum absolute value,
expressed as an integer number of months.
For the xs:dayTimeDuration
type: the maximum absolute value,
expressed as a decimal number of seconds.
For the types xs:string
, xs:hexBinary
,
xs:base64Binary
, xs:QName
, xs:anyURI
,
xs:NOTATION
, and types derived from them: the maximum length of
the value.
For sequences, the maximum number of items in a sequence.
For backwards compatibility reasons, XSLT 3.0
continues to support the disable-output-escaping
feature introduced in
XSLT 1.0. This is an optional feature and implementations are not
required to support it. A new facility, that of named character maps (see 26.1 Character Maps) was introduced in XSLT 2.0. It provides
similar capabilities to disable-output-escaping
, but without distorting
the data model.
If an implementation supports the
disable-output-escaping
attribute of xsl:text
and
xsl:value-of
, (see 26.2 Disabling Output Escaping),
then the data model for trees constructed by the processor is augmented with a boolean value representing the value of
this property. This boolean value, however, can be set only within a final result tree that is being passed to the
serializer.
Conceptually, each character in a text node on such a result tree has a boolean
property indicating whether the serializer is to disable the normal rules for
escaping of special characters (for example, outputting of &
as
&
) in respect of this character.
Note:
In practice, the nodes in a final result
tree will often be streamed directly from the XSLT processor to the
serializer. In such an implementation, disable-output-escaping
can be
viewed not so much a property stored with nodes in the tree, but rather as
additional information passed across the interface between the XSLT processor and
the serializer.
Many constructs appearing in a stylesheet, for example named templates, modes, and attribute sets, are named using a qualified name: this consists of a local name and an optional namespace URI.
In most cases where such names are written in a stylesheet, the syntax for expressing the name is given by the production EQNameXP30 in the XPath specification. In practice, this means that three forms are permitted:
A simple NCName
appearing on its own (without any prefix). This
represents the local name of the object. The interpretation of unprefixed
names is described below.
A lexical QName written in the
form NCName ":" NCName
where the first part is a namespace
prefix and the second part is the local name. The namespace part of the
object’s name is then derived from the prefix by examining the
in-scope namespace bindings of the element node in the stylesheet where the
name appears.
A URIQualifiedNameXP30 in the form "Q{" URI? "}" NCName
where the two parts of the name, that is the namespace part and the local
part, both appear explicitly. If the URI part is omitted (for example
Q{}local
), the resulting expanded QName is a QName whose
namespace part is absent.
Note:
There are a few places where the third form, a URIQualifiedName, is not
permitted. These include the name
attribute of
xsl:element
and xsl:attribute
(which have
a separate namespace
attribute for the purpose), and constructs
defined by other specifications. For example, names appearing within an
embedded xs:schema
element must follow the XSD rules.
[Definition: An expanded
QName is a value in the value space of the xs:QName
datatype as defined in the XDM data model (see [XDM 3.0]): that is, a triple containing namespace prefix (optional), namespace URI
(optional), and local name. Two expanded QNames are equal if the namespace URIs
are the same (or both absent) and the local names are the same. The prefix
plays no part in the comparison, but is used only if the expanded QName needs
to be converted back to a string.]
[Definition: An EQName is a string representing an expanded QName where the string, after removing leading and trailing whitespace, is in the form defined by the EQNameXP30 production in the XPath specification.]
[Definition: A lexical QName
is a string representing an expanded
QName where the string, after removing leading and trailing
whitespace, is within the lexical space of the xs:QName
datatype
as defined in XML Schema (see [XML Schema Part 2]): that is, a local
name optionally preceded by a namespace prefix and a colon.]
Note that every lexical QName is an EQName, but the converse is not true.
The following rules are used when interpreting a lexical QName:
[Definition: A string in the form of a lexical QName may occur as the value of an attribute node in a stylesheet module, or within an XPath expression contained in an attribute or text node within a stylesheet module, or as the result of evaluating an XPath expression contained in such a node. The element containing this attribute or text node is referred to as the defining element of the lexical QName.]
If the lexical QName has a prefix, then the prefix is expanded into a URI reference using the namespace declarations in effect on its defining element. The expanded QName consisting of the local part of the name and the possibly null URI reference is used as the name of the object. The default namespace of the defining element (see Section 6.2 Element Nodes DM30) is not used for unprefixed names.
[ERR XTSE0280] In the case of a prefixed lexical QName used as the value (or as part of the value) of an attribute in the stylesheet, or appearing within an XPath expression in the stylesheet, it is a static error if the defining element has no namespace node whose name matches the prefix of the lexical QName.
[ERR XTDE0290] Where the result of evaluating an XPath expression (or an attribute value template) is required to be a lexical QName, or if it is permitted to be a lexical QName and the actual value takes the form of a lexical QName, then unless otherwise specified it is a dynamic error if the value has a prefix and the defining element has no namespace node whose name matches that prefix. This error may be signaled as a static error if the value of the expression can be determined statically.
If the lexical QName has no prefix, then:
In the case of an unprefixed QName used as a NameTest
within an XPath expression (see
5.2 Expressions), and in certain other contexts, the
namespace to be used in expanding the QName may be specified by means
of the [xsl:]xpath-default-namespace
attribute, as
specified in 5.1.2 Unprefixed Lexical QNames in Expressions and Patterns.
If the name is in one of the following categories, then the default namespace of the defining element is used:
Where a QName is used to define the name of an element being
constructed. This applies both to cases where the name is known
statically (that is, the name of a literal result element) and
to cases where it is computed dynamically (the value of the
name
attribute of the
xsl:element
instruction).
The default namespace is used when expanding the first argument
of the function element-available
.
The default namespace applies to any unqualified element names
appearing in the cdata-section-elements
or
suppress-indentation
attributes of
xsl:output
or
xsl:result-document
In all other cases, a lexical
QName with no prefix represents an expanded QName in no namespace
(that is, an xs:QName
value in which both the prefix and
the namespace URI are absent).
The attribute [xsl:]xpath-default-namespace
(see 3.4 Standard Attributes) may be used on an element in the stylesheet to define the namespace that will be
used for an unprefixed element name or type name within an XPath expression, and
in certain other contexts listed below.
The value of the attribute is the namespace URI to be used.
For any element in the stylesheet, this
attribute has an effective value, which is the value of the
[xsl:]xpath-default-namespace
on that element or on the innermost
containing element that specifies such an attribute, or the zero-length string if
no containing element specifies such an attribute.
For any element in the stylesheet, the effective value of this attribute determines the value of the default namespace for element and type names in the static context of any XPath expression contained in an attribute or text node of that element (including XPath expressions in attribute value templates and text value templates). The effect of this is specified in [XPath 3.0]; in summary, it determines the namespace used for any unprefixed type name in the SequenceType production, and for any element name appearing in a path expression or in the SequenceType production.
The effective value of this attribute similarly applies to any of the following constructs appearing within its scope:
any unprefixed element name or type name used in a pattern
any unprefixed element name used in the elements
attribute of
the xsl:strip-space
or xsl:preserve-space
instructions
any unprefixed element name or type name used in the as
attribute of an XSLT element
any unprefixed type name used in the type
attribute of an
XSLT element
any unprefixed type name used in the xsl:type
attribute of a
literal result
element.
The [xsl:]xpath-default-namespace
attribute must
be in the XSLT namespace if and only if
its parent element is not in the XSLT namespace.
If the effective value of the attribute is a zero-length string, which will be the case if it is explicitly set to a zero-length string or if it is not specified at all, then an unprefixed element name or type name refers to a name that is in no namespace. The default namespace of the parent element (see Section 6.2 Element Nodes DM30) is not used.
The attribute does not affect other names, for example function names, variable
names, or template names, or strings that are interpreted as lexical QNames during stylesheet evaluation,
such as the effective value of the
name
attribute of xsl:element
or the string
supplied as the first argument to the key
function.
[Definition: The XSLT namespace, together with certain other namespaces recognized by an XSLT processor, are classified as reserved namespaces and must be used only as specified in this and related specifications.] The reserved namespaces are those listed below.
The XSLT namespace, described in 3.1 XSLT Namespace, is reserved.
[Definition: The standard function
namespace
http://www.w3.org/2005/xpath-functions
is used for functions
in the function library defined in [Functions and Operators 3.0] and
for standard functions defined in this specification.]
The namespace
http://www.w3.org/2005/xpath-functions/math
is used for
mathematical functions in the function library defined in [Functions and Operators 3.0].
The namespace
http://www.w3.org/2005/xpath-functions/map
is used for
functions defined in this specification relating to the manipulation of
maps.
The namespace
http://www.w3.org/2005/xpath-functions/array
is reserved for
use as described in [Functions and Operators 3.1]. The namespace is
reserved whether or not the processor actually supports XPath 3.1.
[Definition: The XML
namespace, defined in [Namespaces in XML] as
http://www.w3.org/XML/1998/namespace
, is used for
attributes such as xml:lang
, xml:space
, and
xml:id
.]
[Definition: The schema
namespace
http://www.w3.org/2001/XMLSchema
is used as defined in
[XML Schema Part 1]]. In a stylesheet this namespace may be used to
refer to built-in schema datatypes and to the constructor functions
associated with those datatypes.
[Definition: The schema instance namespace
http://www.w3.org/2001/XMLSchema-instance
is used as defined
in [XML Schema Part 1]]. Attributes in this namespace,
if they appear in a stylesheet, are
treated by the XSLT processor in the same way as any other attributes.
[Definition: The standard error namespace
http://www.w3.org/2005/xqt-errors
is used for error codes
defined in this specification and related specifications. It is also used
for the names of certain predefined variables accessible within the scope
of an xsl:catch
element.]
The namespace http://www.w3.org/2000/xmlns/
is reserved for use
as described in [Namespaces in XML]. No element or attribute node can
have a name in this namespace, and although the prefix xmlns
is
implicitly bound to this namespace, no namespace node will ever define this
binding.
Note:
With the exception of the XML namespace, any of the above namespaces that are used in a stylesheet must be explicitly declared with a namespace declaration. Although conventional prefixes are used for these namespaces in this specification, any prefix may be used in a user stylesheet.
Reserved namespaces may be used without restriction to refer to the names of elements and attributes in source documents and result documents. As far as the XSLT processor is concerned, reserved namespaces other than the XSLT namespace may be used without restriction in the names of literal result elements and user-defined data elements, and in the names of attributes of literal result elements or of XSLT elements: but other processors may impose restrictions or attach special meaning to them. Reserved namespaces must not be used, however, in the names of stylesheet-defined objects such as variables and stylesheet functions, nor in the names of extension functions or extension instructions.
It is not an error to use a reserved namespace in the name of an
extension attribute:
attributes such as xml:space
and xsi:type
fall into this category. XSLT processors must not reject such attributes,
and must not attach any meaning to them other than any meaning
defined by the relevant specification.
[ERR XTSE0080] It is a static error to use a
reserved namespace in the
name of a named template, a
mode, an attribute set, a key, a
decimal-format, a variable or parameter, a stylesheet
function, a named output
definition, an accumulator, or a character map; except that the name
xsl:initial-template
is permitted as a template
name.
Note:
The name xsl:original
is used within xsl:override
to refer to a component that is being overridden. Although
the name xsl:original
is used to refer to the component, the
component has its own name, and no component ever has the name
xsl:original
.
XSLT uses the expression language defined by XPath 3.0 [XPath 3.0]. Expressions are used in XSLT for a variety of purposes including:
selecting nodes for processing;
specifying conditions for different ways of processing a node;
generating text to be inserted in a result tree.
[Definition: Within this specification, the term XPath expression, or simply expression, means a string that matches the production ExprXP30 defined in [XPath 3.0], with the extensions defined in 21 Maps.]
If the processor implements the XPath 3.1 Feature, then the definition of the production
Expr
from XPath 3.1 is used.
If the processor is configured to use a version of XPath later than XPath 3.1, then the syntax of an XPath expression is implementation-defined.
An XPath expression may occur as the value of certain attributes on XSLT-defined elements, and also within curly brackets in attribute value templates and text value templates.
Except where forwards compatible behavior is enabled (see 3.10 Forwards Compatible Processing), it is a static error if the value of such an attribute, or the text between curly brackets in an attribute value template or text value template, does not match the XPath production ExprXP30, or if it fails to satisfy other static constraints defined in the XPath specification, for example that all variable references must refer to variables that are in scope. Error codes are defined in [XPath 3.0].
The transformation fails with a dynamic error if any XPath expression is evaluated and raises a dynamic error. Error codes are defined in [XPath 3.0].
The transformation fails with a type error if an XPath expression raises a type error, or if the result of evaluating the XPath expression is evaluated and raises a type error, or if the XPath processor signals a type error during static analysis of an expression. Error codes are defined in [XPath 3.0].
[Definition: The context within a stylesheet where an XPath expression appears may specify the required
type of the expression. The required type indicates the type of the
value that the expression is expected to return.] If no required type is
specified, the expression may return any value: in effect, the required type is then
item()*
.
[Definition: When used in this specification without further qualification, the term function conversion rules means the function conversion rules defined in [XPath 3.0], applied with XPath 1.0 compatibility mode set to false.]
Note:
These are the rules defined in [XPath 3.0] for converting the
supplied argument of a function call to the required type of that argument, as
defined in the function signature. The same rules are used in XSLT for converting
the value of a variable to the declared type of the variable, or the result of
evaluating a function or template body to the declared type of the function or
template. They are also used when parameters are supplied to a template using
xsl:with-param
. In all such cases, the rules that apply are
the XPath 3.0 rules without XPath 1.0 compatibility mode. The rules with XPath 1.0
compatibility mode set to true are used only for XPath function calls, and for the
operands of certain XPath operators.
This specification also invokes the XPath 3.0
function conversion rules to
convert the result of evaluating an XSLT sequence constructor to a required type (for example, the sequence
constructor enclosed in an xsl:variable
,
xsl:template
, or xsl:function
element).
Any dynamic error or type error that occurs when applying the function conversion rules to convert a value to a required type results in the transformation failing, in the same way as if the error had occurred while evaluating an expression.
Note:
Note the distinction between the two kinds of error that may occur. Attempting to
convert an integer to a date is a type error, because such a conversion is never
possible. Type errors can be reported statically if they can be detected
statically, whether or not the construct in question is ever evaluated. Attempting
to convert the string 2003-02-29
to a date is a dynamic error rather
than a type error, because the problem is with this particular value, not with its
type. Dynamic errors are reported only if the instructions or expressions that
cause them are actually evaluated.
The XPath specification states that the host language must specify whether the XPath processor normalizes all line breaks on input, before parsing, and if it does so, whether it uses the rules of [XML 1.0] or [XML 1.1]. In the case of XSLT, all handling of line breaks is the responsibility of the XML parser (which may support either XML 1.0 or XML 1.1); the XSLT and XPath processors perform no further changes.
Note:
Most XPath expressions in a stylesheet appear within
XML attributes. They are therefore subject to XML line-ending normalization (for
example, a CRLF sequence is normalized to LF) and also to XML attribute-value
normalization, which replaces tabs and newlines by spaces. XPath expressions
appearing in text value templates, however (see 5.6.2 Text Value Templates) are subject to line-ending normalization but not
attribute-value normalization. In both cases, normalization of whitespace can be
prevented by using character references such as 	
.
XPath defines the concept of an expression contextXP30 which contains all the information that can affect the result of evaluating an expression. The expression context has two parts, the static contextXP30, and the dynamic contextXP30. The components that make up the expression context are defined in the XPath specification (see Section 2.1 Expression Context XP30). This section describes the way in which these components are initialized when an XPath expression is contained within an XSLT stylesheet.
As well as providing values for the static and dynamic context components defined
in
the XPath specification, XSLT defines additional context components of its own. These
context components are used by XSLT instructions (for example,
xsl:next-match
and xsl:apply-imports
), and also
by the functions in the extended function library described in this
specification.
The following four sections describe:
5.3.1 Initializing the Static Context
5.3.2 Additional Static Context Components used by XSLT
5.3.3 Initializing the Dynamic Context
5.3.4 Additional Dynamic Context Components used by XSLT
The static contextXP30 of an XPath expression appearing in an XSLT stylesheet is initialized as follows. In these rules, the term containing element means the element within the stylesheet that is the parent of the attribute or text node whose value contains the XPath expression in question, and the term enclosing element means the containing element or any of its ancestors.
XPath 1.0 compatibility mode is set to true if and only if the containing element is processed with XSLT 1.0 behavior (see 3.9 Backwards Compatible Processing).
The statically known namespacesXP30 are the namespace declarations that are in scope for the containing element.
The default element/type
namespaceXP30 is the namespace defined by the
[xsl:]xpath-default-namespace
attribute on the innermost
enclosing element that has such an attribute, as described in 5.1.2 Unprefixed Lexical QNames in Expressions and Patterns. The value of this attribute is a namespace
URI. If there is no [xsl:]xpath-default-namespace
attribute on
an enclosing element, the default namespace for element names and type names
is the null namespace.
The default function
namespaceXP30 is the standard function namespace, defined in [Functions and Operators 3.0]. This means that it is not necessary to
declare this namespace in the stylesheet, nor is it necessary to use the prefix
fn
(or any other prefix) in calls to functions
in this namespace.
The in-scope schema definitionsXP30 for the XPath expression are the same as the in-scope schema components for the stylesheet, and are as specified in 3.14 Built-in Types.
The in-scope variablesXP30 are defined by the variable binding elements that are in scope for the containing element (see 9 Variables and Parameters).
The context item
static typeXP30 may be determined by an XSLT processor that
performs static type inferencing, using rules that are outside the scope of
this specification; if no static type inferencing is done, then the context
item static type for every XPath expression is item()
. Note that some limited static type inferencing is
required in the case of a processor that performs streamability analysis:
see 19.1 Determining the Static Type of a Construct.
The statically known function signaturesXP30 are:
The functions defined in [Functions and Operators 3.0] in
namespaces http://www.w3.org/2005/xpath-functions
and
http://www.w3.org/2005/xpath-functions/math
;
The functions defined in this specification in namespaces
http://www.w3.org/2005/xpath-functions
and
http://www.w3.org/2005/xpath-functions/map
;
Constructor functions for all the simple types in the in-scope schema definitionsXP30, including both built-in types and user-defined types;
The stylesheet functions defined in the containing package;
Stylesheet functions defined in used packages, subject to visibility: see 3.5.2 Dependencies between Packages;
any extension functions bound using implementation-defined mechanisms (see 24 Extensibility and Fallback).
Note:
The term extension function includes both vendor-supplied and user-written extension functions.
Note:
It follows from the above that a conformant XSLT processor must implement the entire library of functions defined in [Functions and Operators 3.0] as well as those defined in this specification.
The statically known collationsXP30 are implementation-defined, except that they must always include (a) the Unicode codepoint collation, defined in Section 5.3 Comparison of strings FO30, and (b) the family of UCA collations described in 13.4 The Unicode Collation Algorithm.
The default
collationXP30 is defined by the value of the
[xsl:]default-collation
attribute on the innermost enclosing
element that has such an attribute. For details, see 3.7.1 The default-collation Attribute.
[Definition: In this
specification the term default collation means the collation
that is used by XPath operators such as eq
and
lt
appearing in XPath expressions within the
stylesheet.]
This collation is also used by default when comparing strings in the
evaluation of the xsl:key
and
xsl:for-each-group
elements. This may
also (but need not necessarily) be the same as the default collation used
for xsl:sort
elements within the stylesheet. Collations
used by xsl:sort
are described in 13.1.3 Sorting Using Collations.
Static base URI: In a conventional interpreted environment, the static base URI of an expression in the stylesheet is the base URI of the containing element in the stylesheet. The concept of the base URI of a node is defined in Section 5.2 base-uri Accessor DM30.
When stylesheets are executed in an environment where no source code is present
(for example, because the code of the stylesheet has been compiled and is distributed
as executable object code), it is recommended (subject to operational
constraints such as security) that the static base URI used during stylesheet evaluation
should be the location from which the stylesheet was loaded for execution
(its “deployed location”). This means, for example, that when the doc
FO30
or document
functions are called with a relative URI, the required document
is by default located relative to the deployed location of the stylesheet.
Whether or not the stylesheet is executed directly from source code,
it is possible that no static base URI is available, for example because the code
was supplied
as an anonymous input stream, or because security policies are set to prevent executable
code discovering
the location from which it was loaded. If the static base URI is not known, the static-base-uri
FO30
function returns an empty sequence, and other operations that depend on the static
base URI may fail with
a dynamic error.
The set of statically known documentsXP30 is implementation-defined.
The set of statically known collectionsXP30 is implementation-defined.
The statically known default collection typeXP30 is implementation-defined.
The set of statically
known decimal formatsXP30 is the set of decimal formats defined by
xsl:decimal-format
declarations in the stylesheet.
Note:
XSLT 3.0 provides support for the exponent-separator
property which is added to the static context in XPath 3.1; when XSLT 3.0
is used with XPath 3.0, this property is ignored.
Some of the components of the XPath static context are used also by XSLT elements. For example, the
xsl:sort
element makes use of the collations defined in the
static context, and attributes such as type
and as
may
reference types defined in the in-scope schema components.
Many top-level declarations in a stylesheet, and attributes on the
xsl:stylesheet
element, affect the behavior of instructions
within the stylesheet. Each of these constructs is described in its appropriate
place in this specification.
A number of these constructs are of particular significance because they are used by functions defined in XSLT, which are added to the library of functions available for use in XPath expressions within the stylesheet. These are:
The set of named keys, used by the key
function
The values of system properties, used by the
system-property
function
The set of available instructions, used by the
element-available
function
A dynamic function call clears the first of these
components: this means that a dynamic call to the key
function will always raise a dynamic error (the key name is unknown). The values
of system properties and the set of available instructions, by contrast, reflect
the capabilities and configuration of the processor rather than values specific to
the stylesheet code itself; the result of a dynamic call to
system-property
or element-available
will reflect the information available to the processor at evaluation time.
Note:
If these functions are called within a static expression, the results will reflect the capabilities and configuration of the processor used to perform static analysis, while if they are called elsewhere, the results should reflect the capabilities and configuration of the processor used to perform dynamic evaluation, which might give a different result. These calls should not be pre-evaluated at compile time unless it is known that this will give the same result.
For convenience, the dynamic context is described in two parts: the focus, which represents the place in the source document that is currently being processed, and a collection of additional context variables.
A number of functions specified in [Functions and Operators 3.0] are defined
to be deterministicFO30,
meaning that if they are called twice during the same execution scopeFO30, with the same arguments, then
they return the same results (see Section
1.6 Terminology
FO30). In
XSLT, the execution of a stylesheet defines the execution scope. This means, for
example, that if the function current-dateTime
FO30 is called
repeatedly during a transformation, it produces the same result each time. By
implication, the components of the dynamic context on which these functions depend
are also stable for the duration of the transformation. Specifically, the
following components defined in Section
2.1.2 Dynamic Context
XP30 must be
stable: function implementations, current dateTime,
implicit timezone, available documents,
available collections, and default collection. The
values of global variables and stylesheet parameters are also stable for the
duration of a transformation. The focus is not stable; the additional
dynamic context components defined in 5.3.4 Additional Dynamic Context Components used by XSLT
are also not stable.
As specified in [Functions and Operators 3.0], implementations may provide
user options that relax the requirement for the doc
FO30 and
collection
FO30 functions (and therefore, by implication, the
document
function) to return stable results. By default,
however, the functions must be stable. The manner in which such user options are
provided, if at all, is implementation-defined.
XPath expressions contained in [xsl:]use-when
attributes are not
considered to be evaluated “during the transformation” as defined above. For
details see 3.13.1 Conditional Element Inclusion.
[Definition: A component of the context that has no value is said to be absent.] This is a distinguishable state, and is not the same as having the empty sequence as its value.
[Definition: When a sequence constructor is evaluated, the processor keeps track of which items are being processed by means of a set of implicit variables referred to collectively as the focus.] More specifically, the focus consists of the following three values:
[Definition: The context
item is the item currently being processed. An item (see
[XDM 3.0]) is either an atomic value (such
as an integer, date, or string), a node, or
a function item. It changes whenever instructions such as
xsl:apply-templates
and
xsl:for-each
are used to process a sequence of
items; each item in such a sequence becomes the context item while
that item is being processed.] The context item is returned
by the XPath expression
.
(dot).
[Definition: The
context position is the position of the context item
within the sequence of items currently being processed. It changes
whenever the context item changes. When an instruction such as
xsl:apply-templates
or
xsl:for-each
is used to process a sequence of
items, the first item in the sequence is processed with a context
position of 1, the second item with a context position of 2, and so
on.] The context position is returned by the XPath expression
position()
.
[Definition: The context
size is the number of items in the sequence of items
currently being processed. It changes whenever instructions such as
xsl:apply-templates
and
xsl:for-each
are used to process a sequence of
items; during the processing of each one of those items, the context
size is set to the count of the number of items in the sequence (or
equivalently, the position of the last item in the
sequence).] The context size is returned by the XPath
expression
last()
.
[Definition: If the context item is a node (as distinct from
an atomic value such as an integer), then it is also referred to as the
context node. The context node is not an independent
variable, it changes whenever the context item changes. When the context
item is an atomic value or a function
item, there is no context node.] The context node is
returned by the XPath expression
self::node()
, and it is used as the starting node for all relative
path expressions.
Where the containing element of an XPath expression is an instruction or a literal result element, the initial context item, context position, and context size for the XPath expression are the same as the context item, context position, and context size for the evaluation of the containing instruction or literal result element.
The context item for evaluating global variables in the top-level package is set to the global context item supplied when the transformation is invoked (see 2.3 Initiating a Transformation). In library packages, the context item for evaluating global variables is absent.
For an XPath expression contained in a value template, the initial context item, context position, and context size for the XPath expression are the same as the context item, context position, and context size for the evaluation of the containing sequence constructor.
In other cases (for example, where the containing element is
xsl:sort
, xsl:with-param
, or
xsl:key
), the rules are given in the specification of the
containing element.
The current
function can be used within any XPath expression to select the item that was
supplied as the context item to the XPath expression by the XSLT processor.
Unlike .
(dot) this is unaffected by changes to the context item
that occur within the XPath expression. The current
function is described in 20.4.1 fn:current.
On completion of an instruction that changes the focus (such as xsl:apply-templates
or
xsl:for-each
), the focus reverts to its previous value.
When a stylesheet function is called, the focus within the body of the function is initially absent.
When the focus is absent, evaluation of any expression that references the context item, context position, or context size results in a dynamic error [ERR XPDY0002] XP30
The description above gives an outline of the way the focus works. Detailed rules for the effect of each instruction are given separately with the description of that instruction. In the absence of specific rules, an instruction uses the same focus as its parent instruction.
[Definition: A singleton focus based on an item J has the context item (and therefore the context node, if J is a node) set to J, and the context position and context size both set to 1 (one).]
The previous section explained how the focus for an XPath expression appearing in an XSLT stylesheet is initialized. This section explains how the other components of the dynamic contextXP30 of an XPath expression are initialized.
The dynamic variablesXP30 are the current values of the in-scope variable binding elements.
The named functionsXP30
(representing the functions accessible using function-available
or function-lookup
FO30)
include all the functions available in the static context, and may also include an
additional
implementation-defined set of functions that are available dynamically but not statically.
Note:
This set therefore includes some functions that are not available for
dynamic calling using xsl:evaluate
, for example stylesheet functions
whose visibility is private, and XSLT-defined functions such as current
and key
.
Note:
The rule that all functions present in the static context must always be present in
the dynamic context is a consistency constraint. The effect of violating a consistency
constraint is
implementation-defined: it does not necessarily lead to an error.
For example, if the version of a used package that is available
at evaluation time does not include all public user-defined functions that were available
in the version that was
used at analysis time, then a processor may recover by signaling an error only if the function
is actually called. Conversely, if the evaluation-time version of the package includes
additional public functions, these may
be included in the dynamic context even though they were absent from the static context.
Dynamic calling of functions using function-lookup
FO30
may therefore be an effective strategy for coping with variations between versions
of a library package on which a stylesheet
depends.
The available
documentsXP30 are defined as part of the XPath 3.0 dynamic context to support the
doc
FO30 function, but this component is also
referenced by the similar XSLT document
function:
see 20.1 fn:document. This variable defines a mapping
between URIs passed to the doc
FO30 or
document
function and the document nodes that are
returned.
The mapping from URIs to document nodes is
affected by xsl:strip-space
declarations and by the
input-type-annotations
attribute, and may therefore vary
from one package to another.
Note:
Defining this as part of the evaluation context is a formal way of specifying that the way in which URIs get turned into document nodes is outside the control of the language specification, and depends entirely on the run-time environment in which the transformation takes place.
The XSLT-defined document
function allows the use of
URI references containing fragment identifiers. The interpretation of a
fragment identifier depends on the media type of the resource
representation. Therefore, the information supplied in available documentsXP30 for
XSLT processing must provide not only a mapping from URIs to document
nodes as required by XPath, but also a mapping from URIs to media
types.
All other aspects of the dynamic context (for example, the current date and time, the implicit timezone, the default language, calendar, and place, the available documents, text resources, and collections, and the default collection — details vary slightly between XPath 3.0 and XPath 3.1) are implementation-defined, and do not change in the course of a single transformation, except to the extent that they may be different from one package to another.
In addition to the values that make up the focus, an XSLT processor maintains a number of other dynamic context components that reflect aspects of the evaluation context. These components are fully described in the sections of the specification that maintain and use them. They are:
The current template rule,
which is the template rule most
recently invoked by an xsl:apply-templates
,
xsl:apply-imports
, or xsl:next-match
instruction: see 6.8 Overriding Template Rules;
The current mode, which is the
mode set by the most recent call of
xsl:apply-templates
(for a full definition see 6.6 Modes);
The current group and current grouping key, which
provide information about the collection of items currently being processed
by an xsl:for-each-group
instruction: see 14.2.1 fn:current-group and 14.2.2 fn:current-grouping-key;
Note:
In XSLT 3.0 the initial value of these two properties is “absent”, which means that any reference to their values causes a dynamic error. Previously, the initial value was an empty sequence.
The current merge group and current merge key, which provide information about the
collection of items currently being processed by an
xsl:merge
instruction.
The current captured
substrings: this is a sequence of strings, which is maintained
when a string is matched against a regular expression using the
xsl:analyze-string
instruction, and which is accessible
using the regex-group
function: see 17.2 fn:regex-group.
The output state: this is a flag
whose two possible values are final
output state and temporary output state. The initial setting when the stylesheet is invoked by executing a
template is final output
state, and it is switched to temporary output state by
instructions such as xsl:variable
. For more details, see
25.2 Restrictions on the use of xsl:result-document.
The current output URI: this
is the URI associated with the result tree to which instructions are
currently writing. The current output URI is initially the same as the
base output URI. During the evaluation of an
xsl:result-document
instruction, the current output URI
is set to the absolute URI identified by the href
attribute of
that instruction.
The following non-normative table summarizes the initial state of each of the components in the evaluation context, and the instructions which cause the state of the component to change.
[Definition: The initial setting of a component of the dynamic context is used
when evaluating global variables
and stylesheet parameters,
when evaluating the use
and match
attributes of
xsl:key
, and when evaluating the initial-value
of
xsl:accumulator
and the select
expressions or
contained sequence constructors of
xsl:accumulator-rule
].
[Definition: The term non-contextual function
call is used to refer to function calls that do not pass the dynamic
context to the called function. This includes all calls on stylesheet functions and all
dynamic function
invocationsXP30, (that is calls to function items as permitted by
XPath 3.0). It excludes calls to some
functions in the namespace
http://www.w3.org/2005/xpath-functions
, in
particular those that explicitly depend on the context, such as the
current-group
and regex-group
functions. It is implementation-defined whether, and under what circumstances,
calls to extension functions are
non-contextual.]
Named function references (such as position#0
) and
calls on function-lookup
FO30 (for example,
function-lookup("position", 0)
) are defined to retain the XPath
static and dynamic context at the point of invocation as part of the closure of
the resulting function item, and to use this preserved context when a dynamic
function call is subsequently made using the function item. This rule does not
extend to the XSLT extensions to the dynamic context defined in this section. If a
dynamic function call is made that depends on the XSLT part of the dynamic context
(for example, regex-group#1(2)
), then the relevant components of the
context are cleared as described in the table above.
The definition of the format-number
FO30 function
is now in [Functions and Operators 3.0]. What remains here is the definition of
the xsl:decimal-format
declaration, which provides the context for
this function when used in an XSLT stylesheet.
<!-- Category: declaration -->
<xsl:decimal-format
name? = eqname
decimal-separator? = char
grouping-separator? = char
infinity? = string
minus-sign? = char
exponent-separator? = char
NaN? = string
percent? = char
per-mille? = char
zero-digit? = char
digit? = char
pattern-separator? = char />
The xsl:decimal-format
element sets the
statically known decimal formats component of the static context
for XPath expressions, which controls the interpretation of a picture string used by the
format-number
FO30 function.
[Definition: The picture string
is the string supplied as the second argument of the
format-number
FO30 function.]
Note:
The format-number
FO30 function, previously defined in this
specification, is now defined in [Functions and Operators 3.0].
A package may
contain multiple xsl:decimal-format
declarations and may include or
import stylesheet modules that also
contain xsl:decimal-format
declarations. The name of an
xsl:decimal-format
declaration is the value of its
name
attribute, if any.
[Definition: All the
xsl:decimal-format
declarations in a package that share the same name are grouped into a named
decimal format; those that have no name are grouped into a single
unnamed decimal format.]
The attributes of the xsl:decimal-format
declaration define the value of the corresponding property in the relevant decimal
format in the statically known
decimal formatsXP30 component of the static context for all XPath
expressions in the package. The attribute names used in the XSLT 3.0 syntax are the
same as the property names used in the definition of the static context.
The exponent-separator
attribute is provided
for use with XPath 3.1. It has no effect when used with XPath 3.0.
The scope of an xsl:decimal-format
name is the
package in which it is declared; the name is available for use only in calls to
format-number
FO30 that appear within the same package.
If a package does not contain a declaration of
the unnamed decimal format, a declaration equivalent to an
xsl:decimal-format
element with no attributes is implied.
The attributes of the xsl:decimal-format
declaration establish
values for a number of variables used as input to the algorithm followed by the
format-number
FO30 function. An outline of the purpose of each
attribute is given below; however, the definitive explanations are given as part of the specification of
format-number
FO30.
For any named decimal format, the
effective value of each attribute is taken from an
xsl:decimal-format
declaration that has that name, and that
specifies an explicit value for the required attribute. If there is no such
declaration, the default value of the attribute is used. If there is more than one
such declaration, the one with highest import
precedence is used.
For any unnamed decimal format, the
effective value of each attribute is taken from an
xsl:decimal-format
declaration that is unnamed, and that
specifies an explicit value for the required attribute. If there is no such
declaration, the default value of the attribute is used. If there is more than one
such declaration, the one with highest import
precedence is used.
[ERR XTSE1290] It is a static error if a named or
unnamed decimal format contains two
conflicting values for the same attribute in different
xsl:decimal-format
declarations having the same import precedence, unless there is
another definition of the same attribute with higher import precedence.
The following attributes control the interpretation of characters in the picture string supplied to the
format-number
FO30 function, and also specify characters that
may appear in the result of formatting the number. In each case the value
must be a single character [see ERR XTSE0020].
decimal-separator
specifies the character used to separate the
integer part from the fractional part of the formatted number; the default
value is the period character (.
)
grouping-separator
specifies the character typically used as a
thousands separator; the default value is the comma character
(,
)
percent
specifies the character used to indicate that the number
is represented as a per-hundred fraction; the default value is the percent
character (%
)
per-mille
specifies the character used to indicate that the number
is represented as a per-thousand fraction; the default value is the Unicode
per-mille character (#x2030)
zero-digit
specifies the character used to represent the digit
zero; the default value is the Western digit zero (0
). This
character must be a digit (category Nd
in the
Unicode property database), and it must have the numeric
value zero. This attribute implicitly defines the Unicode character that is
used to represent each of the values 0 to 9 in the final result string: Unicode
is organized so that each set of decimal digits forms a contiguous block of
characters in numerical sequence.
[ERR XTSE1295] It is a static error if the character
specified in the zero-digit
attribute is not a digit or is a digit
that does not have the numeric value zero.
The following attributes control the interpretation of characters in the picture string supplied to the
format-number
FO30 function. In each case the value
must be a single character [see ERR XTSE0020].
digit
specifies the character used in the picture string as a place-holder for an
optional digit; the default value is the number sign character
(#
)
pattern-separator
specifies the character used to separate
positive and negative sub-pictures in a picture string; the default value is the semi-colon character
(;
)
The following attributes specify characters or strings that may appear in the result of formatting the number:
infinity
specifies the string used to represent the
xs:double
value INF
; the default value is the
string Infinity
NaN
specifies the string used to represent the
xs:double
value NaN
(not-a-number); the default
value is the string NaN
minus-sign
specifies the character used to signal a negative
number; the default value is the hyphen-minus character (-
, #x2D).
The value must be a single character.
[ERR XTSE1300] It is a static error if, for any named or unnamed decimal format, the variables representing characters used in a picture string do not each have distinct values. These variables are decimal-separator-sign, grouping-sign, percent-sign, per-mille-sign, digit-zero-sign, digit-sign, and pattern-separator-sign.
Every (named or unnamed) decimal format defined in a package is added to the statically known decimal formatsXP30 in the
static contextXP30 of every
expression in the package, excluding expressions
appearing in [xsl:]use-when
attributes.
In XSLT 3.0, patterns can match any kind of item: atomic values and function items as well as nodes.
A template rule identifies the items to which it applies by means of a pattern. As well as being used in template rules, patterns are used for numbering (see 12 Numbering), for grouping (see 14 Grouping), and for declaring keys (see 20.2 Keys).
[Definition: A pattern specifies a set of conditions on an item. An item that satisfies the conditions matches the pattern; an item that does not satisfy the conditions does not match the pattern.]
There are two kinds of pattern: predicate patterns, and selection patterns:
[Definition: A predicate pattern is written as
.
(dot) followed by zero or more predicates in square
brackets, and it matches any item for which each of the predicates evaluates
to true
.]
The detailed semantics are given in 5.5.3 The Meaning of a Pattern. This construct can be used to match items of any
kind (nodes, atomic values, and function items). For example, the pattern
.[starts-with(., '$')]
matches any string that starts with the
character "$", or a node whose atomized value starts with "$". This example
shows a predicate pattern with a single predicate, but the grammar allows any
number of predicates (zero or more).
[Definition: A selection pattern uses a subset of the syntax for path expressions, and is defined to match a node if the corresponding path expression would select the node. Selection patterns may also be formed by combining other patterns using union, intersection, and difference operators.]
The syntax for selection patterns
(UnionExprP
in the grammar:
see 5.5.2 Syntax of Patterns) is a subset of the syntax for
expressions. Selection patterns are
used only for matching nodes; an item other than a node will never match a
selection pattern.
As explained in detail below, a node matches a selection pattern if the node can be selected by
deriving an equivalent expression, and evaluating this expression with respect
to some possible context.
Note:
The specification uses the phrases an item matches a pattern and a pattern matches an item interchangeably. They are equivalent: an item matches a pattern if and only if the pattern matches the item.
Here are some examples of patterns:
.
matches any item.
*
matches any element.
para
matches any para
element.
chapter|appendix
matches any chapter
element
and any appendix
element.
olist/entry
matches any entry
element with an
olist
parent.
appendix//para
matches any para
element with an
appendix
ancestor element.
schema-element(us:address)
matches any element that is
annotated as an instance of the type defined by the schema element
declaration us:address
, and whose name is either
us:address
or the name of another element in its
substitution group.
attribute(*, xs:date)
matches any attribute annotated as
being of type xs:date
.
/
matches a document node.
document-node()
matches a document node.
document-node(schema-element(my:invoice))
matches the
document node of a document whose document element is named
my:invoice
and matches the type defined by the global
element declaration my:invoice
.
text()
matches any text node.
namespace-node()
matches any namespace
node.
node()
matches any node other than an attribute node,
namespace node, or document node.
id("W33")
matches the element with unique ID
W33
.
para[1]
matches any para
element that is the
first para
child element of its parent. It also matches a
parentless para
element.
//para
matches any para
element in a tree that is rooted at a document node.
bullet[position() mod 2 = 0]
matches any bullet
element that is an even-numbered bullet
child of its
parent.
div[@class="appendix"]//p
matches any p
element
with a div
ancestor element that has a class
attribute with value appendix
.
@class
matches any class
attribute
(not any element that has a class
attribute).
@*
matches any attribute node.
$xyz
matches any node that is present in
the value of the variable $xyz
.
$xyz//*
matches any element that is a
descendant of a node that is present in the value of the variable
$xyz
.
doc('product.xml')//*
matches any element
within the document whose document URI is 'product.xml'.
.[. instance of node()]
matches any node.
(Note the distinction from the pattern node()
.)
.[. instance of xs:date]
matches any
atomic value of type xs:date
(or a type derived by
restriction from xs:date
).
.[. gt current-date()]
matches any date in
the future. It can match an atomic value of type xs:date
or
xs:untypedAtomic
, or a node whose atomized value is an
xs:date
or xs:untypedAtomic
value.
.[starts-with(., 'e')]
matches any node or
atomic value that after conversion to a string using the function
conversion rules starts with the letter 'e'.
.[. instance of function(*)]
matches any
function item.
.[$f(.)]
matches any item provided that
the call on the function bound to the variable $f
returns a
result whose effective boolean value is true.
[ERR XTSE0340] Where an attribute is defined to contain a pattern, it is a static error if the pattern does not match the production Pattern30.
The grammar for patterns uses the notation defined in Section A.1.1 Notation XP30.
The lexical rules for patterns are the same as the lexical rules
for XPath expressions, as defined in Section
A.2 Lexical structure
XP30. Comments are permitted between tokens, using the
syntax (: ... :)
. All other provisions of the XPath grammar apply
where relevant, for example the rules for whitespace handling and
extra-grammatical constraints.
[1] | Pattern30 |
::= | PredicatePattern | UnionExprP |
|
[2] | PredicatePattern |
::= | "." PredicateListXP30 |
|
[3] | UnionExprP |
::= | IntersectExceptExprP (("union" | "|") IntersectExceptExprP)* |
|
[4] | IntersectExceptExprP |
::= | PathExprP (("intersect" | "except") PathExprP)* |
|
[5] | PathExprP |
::= | RootedPath |
|
[6] | RootedPath |
::= | (VarRefXP30 | FunctionCallP) PredicateListXP30 (("/" | "//") RelativePathExprP)? |
|
[7] | FunctionCallP |
::= | OuterFunctionName ArgumentListP |
|
[8] | OuterFunctionName |
::= | "doc" | "id" | "element-with-id" | "key" | "root" | URIQualifiedNameXP30 |
|
[9] | ArgumentListP |
::= | "(" (ArgumentP ("," ArgumentP)*)? ")" |
|
[10] | ArgumentP |
::= | VarRefXP30 | LiteralXP30 |
|
[11] | RelativePathExprP |
::= | StepExprP (("/" | "//") StepExprP)* |
|
[12] | StepExprP |
::= | PostfixExprP | AxisStepP |
|
[13] | PostfixExprP |
::= | ParenthesizedExprP PredicateListXP30 |
|
[14] | ParenthesizedExprP |
::= | "(" UnionExprP ")" |
|
[15] | AxisStepP |
::= | ForwardStepP PredicateListXP30 |
|
[16] | ForwardStepP |
::= | (ForwardAxisP NodeTestXP30) | AbbrevForwardStepXP30 |
|
[17] | ForwardAxisP |
::= | ("child" "::") |
The names of these constructs are chosen to align with the XPath 3.0 grammar.
Constructs whose names are suffixed with P
are restricted forms of
the corresponding XPath 3.0 construct without the suffix. Constructs labeled with
the suffix “XP30” are defined in [XPath 3.0].
Where the XSLT 3.0 processor implements the XPath 3.1 Feature, the definitions that apply to constructs labeled with the suffix “XP30” are those in [XPath 3.1]
In a FunctionCallP, the
EQName
used for the function name must have local part
doc
, id
, element-with-id
,
key
, or
root
, and must use the standard function namespace either explicitly or implicitly.
In the case of a call to the
root
FO30 function, the argument list must be empty: that is,
only the zero-arity form of the function is allowed.
Note:
As with XPath expressions, the pattern / union /*
can be parsed in
two different ways, and the chosen interpretation is to treat
union
as an element name rather than as an operator. The other
interpretation can be achieved by writing (/) union (/*)
The meaning of a pattern is defined formally as follows, where “if” is to be read as “if and only if”.
If the pattern is a PredicatePattern PP, then it matches an item J if the XPath expression taking the same form as PP returns a non-empty sequence when evaluated with a singleton focus based on J.
Note:
The pattern .
, which is a PredicatePattern
with an
empty PredicateListXP30,
matches every item.
A predicate with the numeric value 1 (one) always matches, and a predicate with
any other numeric value never matches. Numeric predicates in a
PredicatePattern
are therefore not useful, but are defined this
way in the interests of consistency with XPath.
Otherwise (the pattern is a selection
pattern), the pattern is converted to an expression, called the equivalent expression. The
equivalent expression to a Pattern is the XPath
expression that takes the same lexical form as the Pattern
as
written, with the following adjustment:
If any PathExprP
in the
Pattern
is a RelativePathExprP
, then the
first StepExprP
PS of this RelativePathExprP
is adjusted
to allow it to match a parentless element, attribute, or namespace node. The
adjustment depends on the axis used in this step, whether it appears
explicitly or implicitly (according to the rules of Section
3.3.5 Abbreviated Syntax
XP30), and is made as follows:
If the NodeTest
in PS is
document-node()
(optionally with arguments), and if no
explicit axis is specified, then the axis in step PS is
taken as self
rather than child
.
If PS uses the child axis (explicitly or implicitly), and
if the NodeTest
in PS is not
document-node()
(optionally with arguments), then the
axis in step PS is replaced by child-or-top
,
which is defined as follows. If the context node is a parentless
element, comment, processing-instruction, or text node then the
child-or-top
axis selects the context node; otherwise
it selects the children of the context node. It is a forwards axis
whose principal node kind is element.
If PS uses the attribute axis (explicitly or implicitly),
then the axis in step PS is replaced by
attribute-or-top
, which is defined as follows. If the
context node is an attribute node with no parent, then the
attribute-or-top
axis selects the context node;
otherwise it selects the attributes of the context node. It is a
forwards axis whose principal node kind is attribute.
If PS uses the namespace axis (explicitly or implicitly), then the axis in step
PS is replaced by namespace-or-top
, which
is defined as follows. If the context node is a namespace node with no
parent, then the namespace-or-top
axis selects the
context node; otherwise it selects the namespace nodes of the context
node. It is a forwards axis whose principal node kind is
namespace.
The axes child-or-top
, attribute-or-top
, and
namespace-or-top
are introduced only for definitional
purposes. They cannot be used explicitly in a user-written pattern or
expression.
Note:
The purpose of this adjustment is to ensure that a pattern such as
person
matches any element named person
,
even if it has no parent; and similarly, that the pattern
@width
matches any attribute named width
,
even a parentless attribute. The rule also ensures that a pattern using a
NodeTest
of the form document-node(...)
matches a document node. The pattern node()
will match any
element, text node, comment, or processing instruction, whether or not it
has a parent. For backwards compatibility reasons, the pattern
node()
, when used without an explicit axis, does not
match document nodes, attribute nodes, or namespace nodes. The rules are
also phrased to ensure that positional patterns of the form
para[1]
continue to count nodes relative to their parent,
if they have one. To match any node at all,
XSLT 3.0 allows the pattern .[. instance of node()]
to be
used.
The meaning of the pattern is then defined in terms of the semantics of the
equivalent expression, denoted below as EE
.
Specifically, an item N matches a pattern P if the following applies, where
EE
is the equivalent expression to P:
N is a node, and the result of evaluating the expression
root(.)//(EE)
with a singleton focus based on N is a sequence that
includes the node N
If a pattern appears in an attribute of an element that is processed with XSLT 1.0 behavior (see 3.9 Backwards Compatible Processing), then the semantics of the pattern are defined on the basis that the equivalent XPath expression is evaluated with XPath 1.0 compatibility mode set to true.
The selection pattern
p
matches any p
element, because a p
element will always be present in the result of evaluating the expression
root(.)//(child-or-top::p)
. Similarly, /
matches a
document node, and only a document node, because the result of the expression
root(.)//(/)
returns the root node of the tree containing the
context node if and only if it is a document node.
The selection pattern
node()
matches all nodes selected by the expression
root(.)//(child-or-top::node())
, that is, all element, text,
comment, and processing instruction nodes, whether or not they have a parent.
It does not match attribute or namespace nodes because the expression does not
select nodes using the attribute or namespace axes. It does not match document
nodes because for backwards compatibility reasons the child-or-top
axis does not match a document node.
The selection pattern
$V
matches all nodes selected by the expression
root(.)//($V)
, that is, all nodes in the value of $V (which
will typically be a global variable, though when the pattern is used in
contexts such as the xsl:number
or
xsl:for-each-group
instructions, it can also be a local
variable).
The selection pattern
doc('product.xml')//product
matches all nodes selected by the
expression root(.)//(doc('product.xml')//product)
, that is, all
product
elements in the document whose URI is
product.xml
.
The selection pattern
root(.)/self::E
matches an E
element that is the root
of a tree (that is, an E
element with no parent node).
Although the semantics of selection patterns are
specified formally in terms of expression evaluation, it is possible to understand
pattern matching using a different model. A selection pattern such as
book/chapter/section
can be examined from right to left. A node
will only match this pattern if it is a section
element; and then,
only if its parent is a chapter
; and then, only if the parent of that
chapter
is a book
. When the pattern uses the
//
operator, one can still read it from right to left, but this
time testing the ancestors of a node rather than its parent. For example
appendix//section
matches every section
element that
has an ancestor appendix
element.
The formal definition, however, is useful for understanding the meaning of a
pattern such as para[1]
. This matches any node selected by the
expression root(.)//(child-or-top::para[1])
: that is, any
para
element that is the first para
child of its
parent, or a para
element that has no parent.
Note:
An implementation, of course, may use any algorithm it wishes for evaluating patterns, so long as the result corresponds with the formal definition above. An implementation that followed the formal definition by evaluating the equivalent expression and then testing the membership of a specific node in the result would probably be very inefficient.
A dynamic error or type error that occurs during the evaluation of a pattern against a particular item has the effect that the item being tested is treated as not matching the pattern. The error does not cause the transformation to fail, and cannot be caught by a try/catch expression surrounding the instruction that causes the pattern to be evaluated.
Note:
The reason for this provision is that it is difficult for the stylesheet author to predict which predicates in a pattern will actually be evaluated. In the case of match patterns in template rules, it is not even possible to predict which patterns will be evaluated against a particular node.
There is a risk that ignoring errors in this way may make programming mistakes harder to debug. Implementations may mitigate this by providing warnings or other diagnostics when evaluation of a pattern triggers an error condition.
Static errors in patterns, including dynamic and type errors that are signaled statically as permitted by the specification, are reported in the normal way and cause the transformation to fail.
The requirement to detect and report a circularity as a dynamic error overrides this rule.
The string value of an attribute or text node in the stylesheet may in particular circumstances contain embedded expressions enclosed between curly brackets. Attributes and text nodes that use (or are permitted to use) this mechanism are referred to respectively as attribute value templates and text value templates.
[Definition: Collectively, attribute value templates and text value templates are referred to as value templates.]
A value template is a string consisting of an alternating sequence of fixed parts and variable parts:
A variable part consists of an optional XPath expression enclosed in curly brackets ({}
):
more specifically, a string conforming
to the XPath production Expr?
.
Note:
An expression within a variable part may contain an unescaped curly bracket within a StringLiteralXP30 or within a comment.
Currently no XPath expression starts with an opening curly
bracket, so the use of {{
creates no ambiguity. If an enclosed
expression ends with a closing curly bracket, no whitespace is required between
this and the closing delimiter.
The fact that the expression is optional means that the string contained between the curly brackets may be zero-length, may comprise whitespace only, or may contain XPath comments. The effective value in this case is a zero-length string, which is equivalent to omitting the variable part entirely, together with its curly-bracket delimiters.
A fixed part
may contain any characters, except that a left curly bracket must
be written as {{
and a right curly bracket must be
written as }}
.
[ERR XTSE0350] It is a static error if an unescaped left curly bracket appears in a fixed part of a value template without a matching right curly bracket.
It is a static error if the string contained between matching curly brackets in a value template does not match the XPath production Expr?XP30, or if it contains other XPath static errors. The error is signaled using the appropriate XPath error code.
[ERR XTSE0370] It is a static error if an unescaped right curly bracket occurs in a fixed part of a value template.
[Definition: The result of evaluating a value template is referred to as its effective value.] The effective value is the string obtained by concatenating the expansions of the fixed and variable parts:
The expansion of a fixed part is obtained by replacing any double curly
brackets ({{
or }}
) by the corresponding single curly
bracket.
The expansion of a variable part is as follows:
If an expression is present, the result of evaluating the enclosed XPath expression and converting the resulting value to a string. This conversion is done using the rules given in 5.7.2 Constructing Simple Content.
If the expression is omitted, a zero-length string.
Note:
This process can generate dynamic errors, for example if the sequence contains an element with a complex content type (which cannot be atomized).
In the case of an attribute value template, the effective value becomes the string value of the new attribute node. In the case of a text value template, the effective value becomes the string value of the new text node.
[Definition: In an
attribute that is designated as an attribute value template, such
as an attribute of a literal result
element, an expression can
be used by surrounding the expression with curly brackets ({}
),
following the general rules for value
templates].
Curly brackets are not treated specially in an attribute value in an XSLT stylesheet unless the attribute is specifically designated as one that permits an attribute value template; in an element syntax summary, the value of such attributes is surrounded by curly brackets.
Note:
Not all attributes are designated as attribute value templates. Attributes
whose value is an expression or pattern, attributes of declaration elements and attributes that
refer to named XSLT objects are generally not designated as attribute value
templates (an exception is the format
attribute of
xsl:result-document
). Namespace declarations are not XDM
attribute nodes and are therefore never treated as attribute value
templates.
If the element containing the attribute is processed with XSLT 1.0 behavior, then the rules for converting the value of the expression to a string (given in 5.6 Value Templates) are modified as follows. After atomizing the result of the expression, all items other than the first item in the resulting sequence are discarded, and the effective value is obtained by converting the first item in the sequence to a string. If the atomized sequence is empty, the result is a zero-length string.
Note:
The above rule applies to attribute value templates but not to text value templates, since the latter were not available in XSLT 1.0.
The following example creates an img
result element from a
photograph
element in the source; the value of the
src
and width
attributes are computed using XPath
expressions enclosed in attribute value templates:
<xsl:variable name="image-dir" select="'/images'"/> <xsl:template match="photograph"> <img src="{$image-dir}/{href}" width="{size/@width}"/> </xsl:template>
With this source
<photograph> <href>headquarters.jpg</href> <size width="300"/> </photograph>
the result would be
<img src="/images/headquarters.jpg" width="300"/>
The following example shows how the values in a sequence are output as a space-separated list. The following literal result element:
<temperature readings="{10.32, 5.50, 8.31}"/>
produces the output node:
<temperature readings="10.32 5.5 8.31"/>
Curly brackets are not recognized recursively inside expressions.
The standard attribute
[xsl:]expand-text
may appear on any element in the stylesheet, and
determines whether descendant text nodes of that element are treated as text value
templates. A text node in the stylesheet is treated as a text value template if
(a) it is part of a sequence
constructor
or a child of an xsl:text
instruction, (b) there is an ancestor element with an
[xsl:]expand-text
attribute, and (c) on the innermost ancestor
element that has such an attribute, the value of the attribute is
yes
. The attribute is boolean and
must therefore take one of the values yes
(synonyms true
or 1
) or no
(synonyms
false
or 0
).
This section describes how text nodes are processed when the effective value is
yes
. Such text nodes are referred to as text value templates.
[Definition: In a text node
that is designated as a text value template, expressions can be used by surrounding each
expression with curly brackets ({}
).]
The rules for text value templates are given in 5.6 Value Templates.
A text node
whose value is a text value template results in the construction of a text node in
the result of the containing sequence
constructor or xsl:text
instruction. The string value
of that text node is obtained by computing the effective value of the value
template.
Note:
The result of evaluating a text value template is a (possibly zero-length) text
node. This text node becomes part of the result of the containing sequence
constructor or xsl:text
instruction, and is thereafter handled
exactly as if the value had appeared explicitly as a text node in the
stylesheet.
The way in which the effective value is computed does not depend on any
separator
attribute on a containing
xsl:value-of
or xsl:attribute
instruction.
The separator
attribute only affects how the text node is combined
with adjacent items in the result of the containing sequence constructor.
Fixed parts consisting entirely of whitespace are significant and are handled in the same way as any other fixed part. This is different from the default treatment of “boundary space” in XQuery.
<xsl:variable name="id" select="'A123'"/> <xsl:variable name="step" select="5"/> <xsl:message expand-text="yes">Processing id={$id}, step={$step}</xsl:message>
This will typically output the message text Processing id=A123,
step=5
.
<xsl:function name="f:sum" expand-text="yes" as="xs:integer"> <xsl:param name="x" as="xs:integer"/> <xsl:param name="y" as="xs:integer"/> {$x + $y} </xsl:function>
Note that although this is a very readable way of expressing the computation
performed by the function, the semantics are somewhat complex, and this could
mean that execution is inefficient. The function computes the value of $x
+ $y
as an integer, and then constructs a text node containing the
string representation of this integer (preceded and followed by whitespace).
Because the declared result type of the function is xs:integer
,
this text node is then atomized, giving an xs:untypedAtomic
value,
and the xs:untypedAtomic
value is then cast to an
xs:integer
.
Note:
The main motivations for adding text value templates to the XSLT language are
firstly, to make it easier to construct parameterized text in contexts such as
xsl:value-of
and xsl:message
, and
secondly, to allow use of complex multi-line XPath expressions where
maintaining correct indentation is important for readability. The fact that XML
processors are required to normalize whitespace in attribute values means that
writing such expressions within a select
attribute is not
ideal.
The facility is only present if enabled using the
[xsl:]expand-text
attribute. This is partly for backwards
compatibility, and partly to avoid creating difficulties when constructing
content that is rich in curly brackets, for example JavaScript code or CSS
style sheets.
[Definition: A sequence constructor is a sequence of zero or more sibling nodes in the stylesheet that can be evaluated to return a sequence of nodes, atomic values, and function items. The way that the resulting sequence is used depends on the containing instruction.]
Many XSLT elements, and also literal result elements, are defined to take a sequence constructor as their content.
Four kinds of nodes may be encountered in a sequence constructor:
A Text node appearing in the stylesheet (if it has not been removed in the process of whitespace stripping: see 4.3 Stripping Whitespace from the Stylesheet) is processed as follows:
if the effective value of the standard attribute
[xsl:]expand-text
is no
, or in the absence
of this attribute, the text node in the stylesheet is copied to create a
new parentless text node in the result of the sequence constructor.
Otherwise (the effective value of [xsl:]expand-text
is
yes
), the text node in the stylesheet is processed as
described in 5.6.2 Text Value Templates.
A literal result element is evaluated to create a new parentless element node, having the same expanded QName as the literal result element: see 11.1 Literal Result Elements.
An XSLT instruction produces a sequence
of zero, one, or more items as its result. For most XSLT instructions, these
items are nodes, but some instructions (such
as
xsl:sequence
and xsl:copy-of
) can also
produce atomic values or function items.
Several instructions, such as xsl:element
, return a newly
constructed parentless node (which may have its own attributes, namespaces,
children, and other descendants). Other instructions, such as
xsl:if
, pass on the items produced by their own nested
sequence constructors. The xsl:sequence
instruction may return
atomic values, function items, or existing
nodes.
An extension instruction (see 24.2 Extension Instructions) also produces a sequence of items as its result.
[Definition: The result of evaluating a sequence constructor is the sequence of items formed by concatenating the results of evaluating each of the nodes in the sequence constructor, retaining order. This is referred to as the immediate result of the sequence constructor.]
However:
For the effect of the xsl:fallback
instruction, see 24.2.3 Fallback.
For the effect of the xsl:on-empty
and
xsl:on-non-empty
instructions, see 8.4 Conditional Content Construction.
The way that immediate result of a sequence constructor is used depends on the containing element in the stylesheet, and is specified in the rules for that element. It is typically one of the following:
The immediate result may be bound to a variable or
delivered as the result of a stylesheet function.
In this case the as
attribute of the containing xsl:variable
or xsl:function
element may be used to declare its required type,
and the immediate result is then converted to the required type
by applying the function conversion rules.
Note:
In the absence of an as
attribute, the result of a
function is the immediate result of the sequence constructor;
but the value of a variable (for backwards compatibility reasons) is a document node
whose content is formed by applying the rules in 5.7.1 Constructing Complex Content
to the immediate result.
The function conversion rules do not merge adjacent text nodes
or insert separators between adjacent items. This means it is often inappropriate
to use xsl:value-of
in the body of xsl:variable
or
xsl:function
, especially when the intent is to return an atomic result.
The xsl:sequence
instruction is designed for this purpose, and
is usually a better choice.
The result of a function, or the value of a variable, may contain nodes
(such as elements, attributes, and text nodes) that are not attached to any parent
node
in a result tree. The semantics of XPath expressions when applied to parentless nodes
are well-defined; however, such expressions should be used with care. For example,
the expression /
causes a type error if the root of the tree containing
the context node is not a document node.
Parentless attribute nodes require particular care because they have no namespace nodes associated with them. A parentless attribute node is not permitted to contain namespace-sensitive content (for example, a QName or an XPath expression) because there is no information enabling the prefix to be resolved to a namespace URI. Parentless attributes can be useful in an application (for example, they provide an alternative to the use of attribute sets: see 10.2 Named Attribute Sets) but they need to be handled with care.
The sequence may be returned as the result of the containing element. This
happens, for example, when
the element containing the
sequence constructor is
xsl:break
,
xsl:catch
,
xsl:fallback
, xsl:for-each
,
xsl:for-each-group
, xsl:fork
, xsl:if
, xsl:iterate
,
xsl:matching-substring
,
xsl:non-matching-substring
, xsl:on-completion
,
xsl:otherwise
, xsl:perform-sort
,
xsl:sequence
, xsl:try
, or xsl:when
.
The sequence may be used to construct the content of a new element or document
node. This happens when the sequence constructor appears as the content of a
literal result element,
or of one of the instructions xsl:copy
,
xsl:element
, xsl:document
,
xsl:result-document
, xsl:assert
, or xsl:message
.
It also happens when the sequence constructor is contained in one of the
elements xsl:variable
, xsl:param
, or
xsl:with-param
, when this instruction has no
as
attribute. For details, see 5.7.1 Constructing Complex Content.
The sequence may be used to construct the string
value of an attribute node, text node, namespace node, comment
node, or processing instruction node. This happens when the sequence
constructor is contained in one of the elements xsl:attribute
,
xsl:value-of
, xsl:namespace
,
xsl:comment
, or
xsl:processing-instruction
. For details, see 5.7.2 Constructing Simple Content.
Many instructions, for example xsl:copy
, xsl:element
,
xsl:document
, xsl:result-document
, and
literal result elements,
create a new parent node, and evaluate a sequence constructor
forming the content of the instruction to create the attributes,
namespaces, and children of the new parent node. The immediate result
of the sequence constructor is processed to create the content of the new parent
node as described in this section.
When constructing the content of an element, the inherit-namespaces
attribute of the xsl:element
or xsl:copy
instruction, or the xsl:inherit-namespaces
property of the literal
result element, determines whether namespace nodes are to be inherited. The effect
of this attribute is described in the rules that follow.
The immediate result of the sequence constructor is processed as follows (applying the rules in the order they are listed):
The containing instruction may generate attribute nodes and/or namespace
nodes, as specified in the rules for the individual instruction. For
example, these nodes may be produced by expanding an
[xsl:]use-attribute-sets
attribute, or by expanding the
attributes of a literal result
element. Any such nodes are prepended to the
immediate result of the sequence constructor.
Any array item in the sequence (see 27.7.1 Arrays)
is replaced by its members, recursively. This is equivalent to applying
the array:flatten
FO31 function defined in
[Functions and Operators 3.1].
Note:
This situation only arises if the XPath 3.1 Feature is implemented. Note that if the array contains nodes, this operation leaves the nodes in the sequence: they are not atomized.
Any atomic value in the sequence is cast to a string.
Note:
Casting from xs:QName
or xs:NOTATION
to
xs:string
always succeeds, because these values retain a
prefix for this purpose. However, there is no guarantee that the prefix
used will always be meaningful in the context where the resulting string
is used.
Any consecutive sequence of strings in the sequence is converted to a single text node, whose string value contains the content of each of the strings in turn, with a single space (#x20) used as a separator between successive strings.
Any document node within the sequence is replaced by a sequence containing each of its children, in document order.
Zero-length text nodes within the sequence are removed.
Adjacent text nodes within the sequence are merged into a single text node.
Invalid items in the sequence are detected as follows.
[ERR XTDE0410] It is a dynamic error if the sequence used to construct the content of an element node contains a namespace node or attribute node that is preceded in the sequence by a node that is neither a namespace node nor an attribute node.
[ERR XTDE0420] It is a dynamic error if the sequence used to construct the content of a document node contains a namespace node or attribute node.
[ERR XTDE0430] It is a dynamic error if the sequence contains two or more namespace nodes having the same name but different string values (that is, namespace nodes that map the same prefix to different namespace URIs).
[ERR XTDE0440] It is a dynamic error if the sequence contains a namespace node with no name and the element node being constructed has a null namespace URI (that is, it is an error to define a default namespace when the element is in no namespace).
[ERR XTDE0450] It is a dynamic error if the result sequence contains a function item.
If the sequence contains two or more namespace nodes with the same name (or no name) and the same string value (that is, two namespace nodes mapping the same prefix to the same namespace URI), then all but one of the duplicate nodes are discarded.
Note:
Since the order of namespace nodes is implementation-dependent, it is not significant which of the duplicates is retained.
If an attribute A in the sequence has the same name as another attribute B that appears later in the sequence, then attribute A is discarded from the sequence. Before discarding attribute A, the processor may signal any type errors that would be signaled if attribute B were not present.
Each node in the resulting sequence is attached as a namespace, attribute,
or child of the newly constructed element or document node. Conceptually
this involves making a deep copy of the node; in practice, however, copying
the node will only be necessary if the existing node can be referenced
independently of the parent to which it is being attached. When copying an
element or processing instruction node, its base URI property is changed to
be the same as that of its new parent, unless it has an
xml:base
attribute (see [XML Base]) that
overrides this. If the copied element has an xml:base
attribute, its base URI is the value of that attribute, resolved (if it is
relative) against the base URI of the new parent node.
Except for the handling of base URI, the copying
of a node follows the rules of the xsl:copy-of
instruction
with attributes copy-namespaces="yes" copy-accumulators="no"
validation="preserve"
.
Note:
This has the consequence that the type annotation and the values of the
nilled
, is-id
, and is-idrefs
properties are retained. However, if the node under construction (the new
parent of the node being copied) uses a validation mode other than
preserve
, this will be transient: the values will be
recomputed when the new parent node is validated.
If the newly constructed node is an element node, then namespace fixup is applied to this node, as described in 5.7.3 Namespace Fixup.
If the newly constructed node is an element node, and if namespaces are inherited, then each namespace node of the newly constructed element (including any produced as a result of the namespace fixup process) is copied to each descendant element of the newly constructed element, unless that element or an intermediate element already has a namespace node with the same name (or absence of a name) or that descendant element or an intermediate element is in no namespace and the namespace node has no name.
Consider the following stylesheet fragment:
<td> <xsl:attribute name="valign">top</xsl:attribute> <xsl:value-of select="@description"/> </td>
This fragment consists of a literal result element td
, containing
a sequence constructor that consists of two instructions:
xsl:attribute
and xsl:value-of
. The
sequence constructor is evaluated to produce a sequence of two nodes: a
parentless attribute node, and a parentless text node. The td
instruction causes a td
element to be created; the new attribute
therefore becomes an attribute of the new td
element, while the
text node created by the xsl:value-of
instruction becomes a
child of the td
element (unless it is zero-length, in which case
it is discarded).
Consider the following stylesheet fragment:
<doc> <e><xsl:sequence select="1 to 5"/></e> <f> <xsl:for-each select="1 to 5"> <xsl:value-of select="."/> </xsl:for-each> </f> </doc>
This produces the output (when indented):
<doc> <e>1 2 3 4 5</e> <f>12345</f> </doc>
The difference between the two cases is that for the e
element,
the sequence constructor generates a sequence of five atomic values, which are
therefore separated by spaces. For the f
element, the content is a
sequence of five text nodes, which are concatenated without space
separation.
It is important to be aware of the distinction between
xsl:sequence
, which returns the value of its
select
expression unchanged, and xsl:value-of
,
which constructs a text node.
The instructions xsl:attribute
, xsl:comment
,
xsl:processing-instruction
, xsl:namespace
,
and xsl:value-of
all create nodes that cannot have children.
Specifically, the xsl:attribute
instruction creates an attribute
node, xsl:comment
creates a comment node,
xsl:processing-instruction
creates a processing instruction
node, xsl:namespace
creates a namespace node, and
xsl:value-of
creates a text node. The string value of the new
node is constructed using either the select
attribute of the
instruction, or the sequence
constructor that forms the content of the instruction. The
select
attribute allows the content to be specified by means of an
XPath expression, while the sequence constructor allows it to be specified by
means of a sequence of XSLT instructions. The select
attribute or
sequence constructor is evaluated to produce a result sequence, and the string value of the new node is derived from
this result sequence according to the rules below.
These rules are also used to compute the effective value of a value template. In this case the sequence being processed is the result of evaluating an XPath expression enclosed between curly brackets, and the separator is a single space character.
Zero-length text nodes in the sequence are discarded.
Adjacent text nodes in the sequence are merged into a single text node.
The sequence is atomized (which may cause a dynamic error).
Every value in the atomized sequence is cast to a string.
The strings within the resulting sequence are concatenated, with a (possibly zero-length) separator inserted between successive strings. The default separator depends on the containing instruction; except where otherwise specified, it is a single space.
In the case of xsl:attribute
and xsl:value-of
, the default separator is a single space
when the select
attribute is used, or a zero-length string otherwise;
a different separator can be specified
using the separator
attribute of the instruction.
In the case of xsl:comment
,
xsl:processing-instruction
, and
xsl:namespace
, and when expanding a value
template, the default separator cannot be changed.
In the case of xsl:processing-instruction
, any leading
spaces in the resulting string are removed.
The resulting string forms the string value of the new attribute, namespace, comment, processing-instruction, or text node.
Consider the following stylesheet fragment:
<doc> <xsl:attribute name="e" select="1 to 5"/> <xsl:attribute name="f"> <xsl:for-each select="1 to 5"> <xsl:value-of select="."/> </xsl:for-each> </xsl:attribute> <xsl:attribute name="g" expand-text="yes">{1 to 5}</xsl:attribute> </doc>
This produces the output:
<doc e="1 2 3 4 5" f="12345" g="1 2 3 4 5"/>
The difference between the three cases is as follows. For the
e
attribute, the sequence constructor generates a sequence of
five atomic values, which are therefore separated by spaces. For the
f
attribute, the content is supplied as a sequence of five text
nodes, which are concatenated without space separation. For the g
attribute, the text value template constructs a text node
using the rules for constructing simple content, which insert space separators
between atomic values; the text node is then atomized to form the value of the
attribute.
Specifying separator=""
on the first
xsl:attribute
instruction would cause the attribute value
to be e="12345"
. A separator
attribute on the second
xsl:attribute
instruction would have no effect, since the
separator only affects the way adjacent atomic values are handled: separators
are never inserted between adjacent text nodes. A
separator
on the third xsl:attribute
instruction would also have no effect, because text value templates are
evaluated without regard to the containing instruction.
Note:
If an attribute value template contains a sequence of fixed and variable parts,
no additional whitespace is inserted between the expansions of the fixed and
variable parts. For example, the effective
value of the attribute a="chapters{4 to 6}"
is
a="chapters4 5 6"
.
In a tree supplied to or constructed by an XSLT processor, the constraints relating to namespace nodes that are specified in [XDM 3.0] must be satisfied. For example:
If an element node has an expanded QName with a non-null namespace URI, then that element node must have at least one namespace node whose string value is the same as that namespace URI.
If an element node has an attribute node whose expanded QName has a non-null namespace URI, then the element must have at least one namespace node whose string value is the same as that namespace URI and whose name is non-empty.
Every element must have a namespace node whose expanded QName has local-part
xml
and whose string
value is http://www.w3.org/XML/1998/namespace
. The
namespace prefix xml
must not be associated with any other namespace URI, and
the namespace URI http://www.w3.org/XML/1998/namespace
must not be associated with any other prefix.
A namespace node must not have the name
xmlns
or the string value
http://www.w3.org/2000/xmlns/
.
[Definition: The rules for the individual XSLT instructions that construct a result tree (see 11 Creating Nodes and Sequences) prescribe some of the situations in which namespace nodes are written to the tree. These rules, however, are not sufficient to ensure that the prescribed constraints are always satisfied. The XSLT processor must therefore add additional namespace nodes to satisfy these constraints. This process is referred to as namespace fixup.]
The actual namespace nodes that are added to the tree by the namespace fixup process are implementation-dependent, provided firstly, that at the end of the process the above constraints must all be satisfied, and secondly, that a namespace node must not be added to the tree unless the namespace node is necessary either to satisfy these constraints, or to enable the tree to be serialized using the original namespace prefixes from the source document or stylesheet.
Namespace fixup must not result in an element having multiple namespace nodes with the same name.
Namespace fixup may, if necessary to resolve conflicts, change
the namespace prefix contained in the QName value that holds the name of an
element or attribute node. This includes the option to add or remove a prefix.
However, namespace fixup must not change the prefix component
contained in a value of type xs:QName
or xs:NOTATION
that forms the typed value of an element or attribute node.
Note:
Namespace fixup is not used to create namespace declarations for
xs:QName
or xs:NOTATION
values appearing in the
content of an element or attribute.
Where values acquire such types as the result of validation, namespace fixup does not come into play, because namespace fixup happens before validation: in this situation, it is the user’s responsibility to ensure that the element being validated has the required namespace nodes to enable validation to succeed.
Where existing elements are copied along with their existing type annotations
(validation="preserve"
) the rules require that existing
namespace nodes are also copied, so that any namespace-sensitive values remain
valid.
Where existing attributes are copied along with their existing type
annotations, the rules of the XDM data model require that a parentless
attribute node cannot contain a namespace-sensitive typed value; this means
that it is an error to copy an attribute using
validation="preserve"
if it contains namespace-sensitive
content.
Namespace fixup is applied to every element that is constructed using a literal result element, or one of the
instructions xsl:element
, xsl:copy
, or
xsl:copy-of
. An implementation is not
required to perform namespace fixup for elements in any
source document, that is, for a document in the initial match selection, documents loaded using the
document
, doc
FO30 or
collection
FO30 function, documents supplied as the value of
a stylesheet parameter, or
documents returned by an extension
function or extension
instruction.
Note:
A source document (an input document, a document returned by the
document
, doc
FO30 or
collection
FO30 functions, a document returned by an
extension function or extension instruction, or a document supplied as a
stylesheet parameter) is required to satisfy the constraints described in
[XDM 3.0], including the constraints imposed by the
namespace fixup process. The effect of supplying a pseudo-document that does
not meet these constraints is implementation-dependent.
In an Infoset (see [XML Information Set]) created from a document conforming
to [Namespaces in XML], it will always be true that if a parent element has
an in-scope namespace with a non-empty namespace prefix, then its child elements
will also have an in-scope namespace with the same namespace prefix, though
possibly with a different namespace URI. This constraint is removed in [Namespaces in XML 1.1]. XSLT 3.0 supports the
creation of result trees that do not satisfy this constraint: the namespace fixup
process does not add a namespace node to an element merely because its parent node
in the result tree has such a namespace
node. However, the process of constructing the children of a new element, which is
described in 5.7.1 Constructing Complex Content, does cause the
namespaces of a parent element to be inherited by its children unless this is
prevented using [xsl:]inherit-namespaces="no"
on the instruction that
creates the parent element.
Note:
This has implications on serialization, defined in [XSLT and XQuery Serialization]. It means that it is possible to create
final result trees that cannot
be faithfully serialized as XML 1.0 documents. When such a result tree is
serialized as XML 1.0, namespace declarations written for the parent element
will be inherited by its child elements as if the corresponding namespace nodes
were present on the child element, except in the case of the default namespace,
which can be undeclared using the construct xmlns=""
. When the
same result tree is serialized as XML 1.1, however, it is possible to undeclare
any namespace on the child element (for example, xmlns:foo=""
) to
prevent this inheritance taking place.
[Definition: Within this specification, the
term URI Reference, unless otherwise stated, refers to a string in
the lexical space of the xs:anyURI
datatype as defined in [XML Schema Part 2].] Note that this is a wider definition than that
in [RFC3986]: in particular, it is designed to accommodate
Internationalized Resource Identifiers (IRIs) as described in [RFC3987], and thus allows the use of non-ASCII characters without escaping.
URI References are used in XSLT with three main roles:
As namespace URIs
As collation URIs
As identifiers for resources such as stylesheet modules; these resources are
typically accessible using a protocol such as HTTP. Examples of such
identifiers are the URIs used in the href
attributes of
xsl:import
, xsl:include
, and
xsl:result-document
.
The rules for namespace URIs are given in [Namespaces in XML] and [Namespaces in XML 1.1]. Those specifications deprecate the use of relative URI references as namespace URIs.
The rules for collation URIs are given in [Functions and Operators 3.0].
URI references used to identify external resources must conform to the same rules
as
the locator attribute (href
) defined in section 5.4 of [XLink]. If the URI reference is relative, then it is resolved (unless
otherwise specified) against the base URI of the containing element node, according
to the rules of [RFC3986], after first escaping all characters that
need to be escaped to make it a valid RFC3986 URI reference. (But a relative URI
reference in the href
attribute of
xsl:result-document
is resolved against the Base Output URI.)
Other URI references appearing in an XSLT stylesheet document, for example the system
identifiers of external entities or the value of the xml:base
attribute,
must follow the rules in their respective specifications.
The base URI of an element node in the stylesheet
is determined as defined in Section
5.2 base-uri Accessor
DM30. Some
implementations may allow the output of the static analysis phase of stylesheet
processing (a “compiled stylesheet”) to be evaluated in a different location from
that where static analysis took place. Furthermore, stylesheet authors may in such
cases wish to avoid exposing the location of resources that are private to the
development environment. If the base URI of an element in the stylesheet is defined
by an absolute URI appearing in an xml:base
attribute within the
stylesheet, this value must be used as the static base URI. In
other cases where processing depends on the static base URI of a stylesheet module,
implementations may use different values for the static base URI
during static analysis and during dynamic evaluation (for example, an implementation
may use different base URIs for resolving
xsl:import
module references and for resolving a relative
reference used as an argument to the doc
FO30 function). In such
cases an implementation must document how the static base URI is
computed for each situation in which it is required.
Template rules define the processing that can be applied to items that match a particular pattern.
<!-- Category: declaration -->
<xsl:template
match? = pattern
name? = eqname
priority? = decimal
mode? = tokens
as? = sequence-type
visibility? = "public" | "private" | "final" | "abstract" >
<!-- Content: (xsl:context-item?, xsl:param*, sequence-constructor) -->
</xsl:template>
[Definition: An xsl:template
declaration defines a template, which contains a sequence constructor;
this sequence constructor is evaluated to determine
the result of the template. A template can serve either as a template rule, invoked by matching items against a pattern, or as a named
template, invoked explicitly by name. It is also possible for the
same template to serve in both capacities.]
[ERR XTSE0500] An xsl:template
element must have either a
match
attribute or a name
attribute, or both. An
xsl:template
element that has no match
attribute must have no mode
attribute and no
priority
attribute. An
xsl:template
element that has no name
attribute must have no visibility
attribute.
If an xsl:template
element has a match
attribute, then
it is a template rule. If it has a
name
attribute, then it is a named
template.
A template may be invoked in a number of ways,
depending on whether it is a template rule,
a named template, or both. The result of
invoking the template is the result of evaluating the sequence constructor contained in the
xsl:template
element (see 5.7 Sequence Constructors).
For details of the optional xsl:context-item
child
element, see 10.1.1 Declaring the Context Item for a Template.
If an as
attribute of the xsl:template
element is
present, the as
attribute defines the required type of the result. The
result of evaluating the sequence
constructor is then converted to the required type using the function conversion rules. If no
as
attribute is specified, the default value is item()*
,
which permits any value. No conversion then takes place.
[ERR XTTE0505] It is a type error if the result of evaluating the sequence constructor cannot be converted to the required type.
If the visibility
attribute is present with the value
abstract
then (a) the sequence constructor
defining the template body must be empty: that is, the only
permitted children are xsl:context-item
and
xsl:param
, and (b) there must be no
match
attribute.
If the parent of the xsl:template
element is an
xsl:override
element, then either or both of the following conditions
must be true:
There is a name
attribute, and the package identified by the containing
xsl:use-package
element contains among its components a named
template whose symbolic
identifier is the same as that of this named template, and which has a compatible signature.
Both the following conditions are true:
There is a match
attribute.
The value of the mode
attribute,
or in its absence the string #default
,
is a whitespace-separated sequence of tokens in which each token satisfies
one of the following conditions:
The token is an EQName representing the name of a mode that is exposed,
with visibility equal to public
, by the package identified by the containing
xsl:use-package
element.
The token is #default
, and there is an ancestor-or-self element with
a default-mode
attribute whose value is an EQName representing the name of a mode that is exposed,
with visibility equal to public
, by the package identified by the containing
xsl:use-package
element.
Note:
The token #unnamed
is not allowed because the unnamed mode never has public visibility.
The token #all
is not allowed because its intended meaning would not be obvious.
This section describes template rules. Named templates are described in 10.1 Named Templates.
A template rule is specified using the
xsl:template
element with a match
attribute. The
match
attribute is a Pattern that identifies
the items to which the rule applies. The result of
applying the template rule is the result of evaluating the sequence constructor
contained in the xsl:template
element, with the matching item used as the context item.
For example, an XML document might contain:
This is an <emph>important</emph> point.
The following template rule matches
emph
elements and produces a fo:wrapper
element with
a font-weight
property of bold
.
<xsl:template match="emph"> <fo:wrapper font-weight="bold" xmlns:fo="http://www.w3.org/1999/XSL/Format"> <xsl:apply-templates/> </fo:wrapper> </xsl:template>
A template rule is evaluated when an
xsl:apply-templates
instruction selects an item that matches the pattern specified in the match
attribute. The xsl:apply-templates
instruction is described in the
next section. If several template rules match a selected item, only one of them is evaluated, as described in 6.4 Conflict Resolution for Template Rules.
<!-- Category: instruction -->
<xsl:apply-templates
select? = expression
mode? = token >
<!-- Content: (xsl:sort | xsl:with-param)* -->
</xsl:apply-templates>
The xsl:apply-templates
instruction takes as input a sequence of
items (typically nodes in a source tree), and produces as output a sequence of
items; these will often be nodes to be added to a result tree.
If the instruction has one or more xsl:sort
children, then the input
sequence is sorted as described in 13 Sorting. The result of this sort
is referred to below as the sorted sequence; if there are no
xsl:sort
elements, then the sorted sequence is the same as the
input sequence.
Each item in the input sequence is processed by
finding a template rule whose pattern matches that item. If there is more than one such template rule, the best among them
is chosen, using rules described in 6.4 Conflict Resolution for Template Rules. If there is no
template rule whose pattern matches the item, a
built-in template rule is used (see 6.7 Built-in Template Rules). The chosen
template rule is evaluated. The rule that matches the Nth item in the sorted sequence is evaluated with that
item as the context item, with N as the context position, and with the length of the
sorted sequence as the context size. Each
template rule that is evaluated produces a sequence of items as its result. The
resulting sequences (one for each item in the
sorted sequence) are then concatenated, to form a single sequence. They are
concatenated retaining the order of the items in
the sorted sequence. The final concatenated sequence forms the result of the
xsl:apply-templates
instruction.
Suppose the source document is as follows:
<message>Proceed <emph>at once</emph> to the exit!</message>
This can be processed using the two template rules shown below.
<xsl:template match="message"> <p> <xsl:apply-templates select="child::node()"/> </p> </xsl:template> <xsl:template match="emph"> <b> <xsl:apply-templates select="child::node()"/> </b> </xsl:template>
There is no template rule for the document node; the built-in template rule for
this node will cause the message
element to be processed. The
template rule for the message
element causes a p
element
to be written to the result tree; the
contents of this p
element are constructed as the result of the
xsl:apply-templates
instruction. This instruction selects the
three child nodes of the message
element (a text node containing the
value Proceed
, an emph
element node, and a text node
containing the value to the exit!
). The two text nodes are
processed using the built-in template rule for text nodes, which returns a copy of
the text node. The emph
element is processed using the explicit
template rule that specifies match="emph"
.
When the emph
element is processed, this template rule constructs a
b
element. The contents of the b
element are
constructed by means of another xsl:apply-templates
instruction,
which in this case selects a single node (the text node containing the value
at once
). This is again processed using the built-in template
rule for text nodes, which returns a copy of the text node.
The final result of the match="message"
template rule thus consists
of a p
element node with three children: a text node containing the
value Proceed
, a b
element that is the parent of a
text node containing the value at once
, and a text node containing
the value to the exit!
. This result
tree might be serialized as:
<p>Proceed <b>at once</b> to the exit!</p>
The default value of the select
attribute is child::node()
,
which causes all the children of the context node to be processed.
[ERR XTTE0510] It is a type error if an
xsl:apply-templates
instruction with no select
attribute is evaluated when the context
item is not a node.
A select
attribute can be used to process items selected by an expression instead of processing all children. The
value of the select
attribute is an expression.
The following example processes all of the given-name
children of the
author
elements that are children of
author-group
:
<xsl:template match="author-group"> <fo:wrapper> <xsl:apply-templates select="author/given-name"/> </fo:wrapper> </xsl:template>
It is also possible to process elements that are not descendants of the context
node. This example assumes that a department
element has
group
children and employee
descendants. It finds an
employee’s department and then processes the group
children of
the department
.
<xsl:template match="employee"> <fo:block> Employee <xsl:apply-templates select="name"/> belongs to group <xsl:apply-templates select="ancestor::department/group"/> </fo:block> </xsl:template>
It is possible to write template rules that are matched according to the schema-defined type of an element or attribute. The following example applies different formatting to the children of an element depending on their type:
<xsl:template match="product"> <table> <xsl:apply-templates select="*"/> </table> </xsl:template> <xsl:template match="product/*" priority="3"> <tr> <td><xsl:value-of select="name()"/></td> <td><xsl:next-match/></td> </tr> </xsl:template> <xsl:template match="product/element(*, xs:decimal) | product/element(*, xs:double)" priority="2"> <xsl:value-of select="format-number(xs:double(.), '#,###0.00')"/> </xsl:template> <xsl:template match="product/element(*, xs:date)" priority="2"> <xsl:value-of select="format-date(., '[Mn] [D], [Y]')"/> </xsl:template> <xsl:template match="product/*" priority="1.5"> <xsl:value-of select="."/> </xsl:template>
The xsl:next-match
instruction is described in 6.8 Overriding Template Rules.
Multiple xsl:apply-templates
elements can be used within a single
template to do simple reordering. The following example creates two HTML tables.
The first table is filled with domestic sales while the second table is filled
with foreign sales.
<xsl:template match="product"> <table> <xsl:apply-templates select="sales/domestic"/> </table> <table> <xsl:apply-templates select="sales/foreign"/> </table> </xsl:template>
It is possible for there to be two matching descendants where one is a descendant of the other. This case is not treated specially: both descendants will be processed as usual.
For example, given a source document
<doc><div><div></div></div></doc>
the rule
<xsl:template match="doc"> <xsl:apply-templates select=".//div"/> </xsl:template>
will process both the outer div
and inner div
elements.
This means that if the template rule for the div
element processes
its own children, then these grandchildren will be processed more than once, which
is probably not what is required. The solution is to process one level at a time
in a recursive descent, by using select="div"
in place of
select=".//div"
This example reads a non-XML text file and processes it line-by-line, applying different template rules based on the content of each line:
<xsl:template name="main"> <xsl:apply-templates select="unparsed-text-lines('input.txt')"/> </xsl:template> <xsl:template match=".[starts-with(., '==')]"> <h2><xsl:value-of select="replace(., '==', '')"/></h2> </xsl:template> <xsl:template match=".[starts-with(., '::')]"> <p class="indent"><xsl:value-of select="replace(., '::', '')"/></p> </xsl:template> <xsl:template match="."> <p class="body"><xsl:value-of select="."/></p> </xsl:template>
Note:
The xsl:apply-templates
instruction is most commonly used to
process nodes that are descendants of the context node. Such use of
xsl:apply-templates
cannot result in non-terminating
processing loops. However, when xsl:apply-templates
is used to
process elements that are not descendants of the context node, the possibility
arises of non-terminating loops. For example,
<xsl:template match="foo"> <xsl:apply-templates select="."/> </xsl:template>
Implementations may be able to detect such loops in some cases, but the possibility exists that a stylesheet may enter a non-terminating loop that an implementation is unable to detect. This may present a denial of service security risk.
It is possible for a selected item to match more than one template rule with a given mode M. When this happens, only one template rule is evaluated for the item. The template rule to be used is determined as follows:
First, only the matching template rule or rules with the highest import precedence are considered. Other matching template rules with lower precedence are eliminated from consideration.
Next, of the remaining matching rules, only those with the highest priority are considered. Other matching template rules with lower priority are eliminated from consideration.
[Definition: The priority of a
template rule is specified by the priority
attribute on the
xsl:template
declaration. If no priority is specified
explicitly for a template rule, its default priority is used, as defined in 6.5 Default Priority for Template Rules.]
[ERR XTSE0530] The value of the priority
attribute
must conform to the rules for the
xs:decimal
type defined in [XML Schema Part 2].
Negative values are permitted.
If this leaves more than one matching template rule, then:
If the mode
M has an xsl:mode
declaration, and the
attribute value on-multiple-match="fail"
is specified in the
mode declaration, a dynamic error is signaled. The error is treated as
occurring in the xsl:apply-templates
instruction, and
can be recovered by wrapping that instruction in an
xsl:try
instruction.
[ERR XTDE0540] It is a dynamic error if the
conflict resolution algorithm for template rules leaves more than
one matching template rule when the
declaration of the relevant mode has an on-multiple-match
attribute with the value fail
.
Otherwise, of the matching template rules that remain, the one that occurs last in declaration order is used.
Note:
This was a recoverable error in XSLT 2.0, meaning that it was
implementation-defined whether the error was signaled, or whether the
ambiguity was resolved by taking the last matching rule in declaration
order. In XSLT 3.0 this situation is not an error unless the
attribute value on-multiple-match="fail"
is specified in the
mode declaration. It is also possible to request warnings when this
condition arises, by means of the attribute warning-on-multiple-match="yes"
.
[Definition: If no priority
attribute is specified on an xsl:template
element, a
default priority is computed, based on the syntax of the pattern supplied in the match
attribute.] The rules are as follows.
If the top-level pattern is a ParenthesizedExprP then the outer parentheses are effectively stripped; these rules are applied recursively to the UnionExprP contained in the ParenthesizedExprP.
If the top-level pattern is a UnionExprP consisting
of multiple alternatives separated by |
or union
,
then the template rule is treated equivalently to a set of template rules, one
for each alternative.
These template rules are adjacent to each
other in declaration order, and the declaration order within this set of
template rules (which affects the result of xsl:next-match
if the alternatives have the same default priority) is the order of
alternatives in the UnionExprP.
Note:
The splitting of a template rule into multiple rules occurs only if there is
no explicit priority
attribute.
If the top-level pattern is an IntersectExceptExprP containing two or more PathExprP operands separated by intersect
or
except
operators, then the priority of the pattern is that of
the first PathExprP.
If the pattern is a PredicatePattern then its priority is 1 (one), unless the PredicateListXP30 is empty, in which case the priority is −1 (minus one).
If the pattern is a PathExprP taking the form
/
, then the priority is −0.5 (minus 0.5).
If the pattern is a PathExprP taking the form of an
EQName optionally preceded by a ForwardAxisP or has the form
processing-instruction(
StringLiteralXP30
)
or processing-instruction(
NCNameNames
)
optionally preceded by a ForwardAxisP, then the priority is 0 (zero).
If the pattern is a PathExprP taking the form of an
ElementTestXP30 or AttributeTestXP30, optionally
preceded by a ForwardAxisP, then the priority is as
shown in the table below. In this table, the symbols E,
A, and T represent an arbitrary element name, attribute
name, and type name respectively, while the symbol *
represents
itself. The presence or absence of the symbol ?
following a type
name does not affect the priority.
Format | Priority | Notes |
---|---|---|
element()
|
−0.5 | (equivalent to * )
|
element(*)
|
−0.5 | (equivalent to * )
|
attribute()
|
−0.5 | (equivalent to @* )
|
attribute(*)
|
−0.5 | (equivalent to @* )
|
element(E)
|
0 | (equivalent to E) |
element(*,T)
|
0 | (matches by type only) |
attribute(A)
|
0 | (equivalent to @A )
|
attribute(*,T)
|
0 | (matches by type only) |
element(E,T)
|
0.25 | (matches by name and type) |
schema-element(E)
|
0.25 | (matches by substitution group and type) |
attribute(A,T)
|
0.25 | (matches by name and type) |
schema-attribute(A)
|
0.25 | (matches by name and type) |
If the pattern is a PathExprP taking the form of a DocumentTestXP30, then if it includes no ElementTestXP30 or SchemaElementTestXP30 the priority is −0.5. If it does include an ElementTestXP30 or SchemaElementTestXP30, then the priority is the same as the priority of that ElementTestXP30 or SchemaElementTestXP30, computed according to the table above.
If the pattern is a PathExprP taking the form of an
NCNameNames:*
or
*:
NCNameNames, optionally
preceded by a ForwardAxisP, then the priority is
−0.25.
If the pattern is a PathExprP taking the form of any other NodeTestXP30, optionally preceded by a ForwardAxisP, then the priority is −0.5.
In all other cases, the priority is +0.5.
Note:
In many cases this means that highly selective patterns have higher priority than less selective patterns. The most common kind of pattern (a pattern that tests for a node of a particular kind, with a particular expanded QName or a particular type) has priority 0. The next less specific kind of pattern (a pattern that tests for a node of a particular kind and an expanded QName with a particular namespace URI) has priority −0.25. Patterns less specific than this (patterns that just test for nodes of a given kind) have priority −0.5. Patterns that specify both the name and the required type have a priority of +0.25, putting them above patterns that only specify the name or the type. Patterns more specific than this, for example patterns that include predicates or that specify the ancestry of the required node, have priority 0.5.
However, it is not invariably true that a more selective pattern has higher
priority than a less selective pattern. For example, the priority of the pattern
node()[self::*]
is higher than that of the pattern
salary
. Similarly, the patterns attribute(*,
xs:decimal)
and attribute(*, xs:short)
have the same
priority, despite the fact that the latter pattern matches a subset of the nodes
matched by the former. Therefore, to achieve clarity in a stylesheet it is good practice to allocate
explicit priorities.
[Definition: A mode is a set of template rules;
when the xsl:apply-templates
instruction selects a set of items
for processing, it identifies the rules to be used for processing those items by
nominating a mode, explicitly or implicitly.] Modes allow a node in a
source tree (for example) to be processed
multiple times, each time producing a different result. They also allow different
sets of template rules to be active when
processing different trees, for example when processing documents loaded using the
document
function (see 20.1 fn:document).
Modes are identified by an expanded QName; in addition to any named modes, there is always one
unnamed mode available. Whether a mode is named or unnamed, its properties
may be defined in an xsl:mode
declaration. If
a mode name is used (for example in an xsl:template
declaration or
an xsl:apply-templates
instruction) and no declaration of that mode
appears in the stylesheet, the mode is implicitly declared with default
properties.
<!-- Category: declaration -->
<xsl:mode
name? = eqname
streamable? = boolean
use-accumulators? = tokens
on-no-match? = "deep-copy" | "shallow-copy" | "deep-skip" | "shallow-skip" | "text-only-copy"
| "fail"
on-multiple-match? = "use-last" | "fail"
warning-on-no-match? = boolean
warning-on-multiple-match? = boolean
typed? = boolean | "strict" | "lax" | "unspecified"
visibility? = "public" | "private" | "final" />
[Definition: The unnamed mode is the default mode used when no
mode
attribute is specified on an
xsl:apply-templates
instruction or
xsl:template
declaration, unless a different default mode
has been specified using the [xsl:]default-mode
attribute of a containing
element.]
Every mode other than the unnamed mode is identified by an expanded QName.
A stylesheet may contain multiple
xsl:mode
declarations and may include or import stylesheet modules that also contain
xsl:mode
declarations. The name of an
xsl:mode
declaration is the value of its name
attribute, if any.
[Definition: All the
xsl:mode
declarations in a package that share the same
name are grouped into a named mode definition; those that have no
name are grouped into a single unnamed mode definition.]
The declared-modes
attribute of
the xsl:package
element determines whether implicit mode
declarations are allowed, as described in 3.5.4.1 Requiring Explicit Mode Declarations. If the package allows implicit mode
declarations, then if a stylesheet does not contain a declaration of the unnamed mode, a
declaration is implied equivalent to an xsl:mode
element with
no attributes. Similarly, if there
is a mode that is named in an xsl:template
or
xsl:apply-templates
element, or in the [xsl:]default-mode
attribute of a containing
element, and the stylesheet
does not contain a declaration of that mode, then a declaration is implied
comprising an xsl:mode
element with a name
attribute
equal to that mode name, plus the attribute
visibility="private"
.
The attributes of the xsl:mode
declaration establish values for a
number of properties of a mode. The allowed values and meanings of the attributes
are given in the following table.
Attribute | Values | Meaning |
---|---|---|
name | An EQName | Specifies the name of the mode. If omitted, this
xsl:mode declaration provides properties of the
unnamed mode |
streamable | yes or no (default
no )
|
Determines whether template rules in this mode are to be
capable of being processed using streaming. If the
value yes is specified, then the body of any template rule that uses this mode
must conform to the rules for streamable templates
given in 6.6.4 Streamable Templates.
|
use-accumulators | List of accumulator names, or #all (default is an empty list)
|
Relevant only when this mode is the initial mode of the transformation, determines which accumulators are applicable to documents containing nodes in the initial match selection. For further details see 18.2.2 Applicability of Accumulators. |
on-no-match | One of deep-copy ,
shallow-copy , deep-skip ,
shallow-skip , text-only-copy or
fail (default
text-only-copy ) |
Determines selection of the built-in template rules that are used to
process an item when an
xsl:apply-templates instruction selects an item that does not match any
user-written template rule in
the stylesheet. For details, see
6.7 Built-in Template Rules.
|
on-multiple-match | One of fail or use-last (default
use-last )
|
Defines the action to be taken when
xsl:apply-templates is used in this mode and more
than one user-written template
rule is available to process an item, each having the same import precedence and priority. The value fail
indicates that it is a dynamic error if more
than one template rule matches an
item. The value use-last indicates that the
situation is not to be treated as an error (the last template in declaration order is the one that
is used).
|
warning-on-no-match | One of yes or no . The default is
implementation-defined
|
Requests the processor to output (or not to output) a warning message in
the case where an xsl:apply-templates instruction
selects an item that matches
no user-written template rule. The form and destination of such warnings
is implementation-defined. The processor
may ignore this attribute, for example if the
environment provides no suitable means of communicating with the user.
|
warning-on-multiple-match | One of yes or no . The default is
implementation-defined
|
Requests the processor to output a warning message in the case where an
xsl:apply-templates instruction selects an item that matches multiple
template rules having the same import
precedence and priority. The form and destination of such warnings is
implementation-defined. The processor
may ignore this attribute, for example if the
environment provides no suitable means of communicating with the
user.
|
typed | One of yes , no ,
strict , lax , or unspecified .
The default is unspecified .
|
See 6.6.3 Declaring the Type of Nodes Processed by a Mode. |
visibility | One of public , private , or
final . The default is private .
|
See 3.5.3.1 Visibility of Components. If the mode is unnamed, that is, if the
name attribute is absent, then the
visibility attribute if present
must have the value
private . A
named mode is not
eligible to be used as the initial mode if its
visibility is private . |
[Definition: A streamable
mode is a mode that is declared in
an xsl:mode
declaration with the attribute
streamable="yes"
.]
For any named mode, the effective value of each
attribute is taken from an xsl:mode
declaration that has a
matching name in its name
attribute, and that specifies an explicit
value for the required attribute. If there is
no such declaration, the default value of the attribute is used. If
there is more than one such declaration, the one with highest import precedence is used.
For the unnamed mode, the effective value
of each attribute is taken from an xsl:mode
declaration that has
no name
attribute, and that specifies an explicit value for the
required attribute. If there is no such declaration, the default value of the
attribute is used. If there is more than one such declaration, the one with
highest import precedence is
used.
[ERR XTSE0545] It is a static error if for any
named or unnamed mode, a package explicitly specifies two conflicting
values for the same attribute in different xsl:mode
declarations having the same import
precedence, unless there is another definition of the same
attribute with higher import precedence. The attributes in question are the
attributes other than name
on the xsl:mode
element.
[Definition: A template rule is applicable to one or more modes.
The modes to which it is applicable are defined by the mode
attribute of the xsl:template
element. If the attribute is
omitted, then the template rule is applicable to the default mode specified in the [xsl:]default-mode
attribute of the innermost containing
element that has such an attribute, which in turn defaults to
the unnamed mode. If the
mode
attribute is present, then its value
must be a non-empty whitespace-separated list of tokens,
each of which defines a mode to which the template rule is
applicable.]
Each token in the mode
attribute must be one of
the following:
an EQName, which is expanded as described in 5.1.1 Qualified Names to define the name of the mode
the token #default
, to indicate that the template rule is
applicable to the default mode that would apply if
the mode
attribute were absent
the token #unnamed
, to indicate that the
template rule is applicable to the unnamed
mode
the token #all
, to indicate that the template rule is
applicable to all modes (specifically, to the unnamed mode and to every mode that is named explicitly or implicitly in an
xsl:apply-templates
instruction anywhere in
the stylesheet).
When a template rule specifies mode="#all"
this is interpreted as meaning all modes declared
implicitly or explicitly within the declaring
package of the xsl:template
element. This value
cannot be used in the case of a template rule declared within an
xsl:override
element.
[ERR XTSE0550] It is a static error if the list of
modes is empty, if the same token is included more than once in the
list, if the list contains an invalid token, or if the token
#all
appears together with any other value.
[ERR XTSE3440] In the case of a template rule (that is, an
xsl:template
element having a match
attribute) appearing as a child of xsl:override
, it is a
static error if the list of
modes in the mode
attribute contains #all
or
#unnamed
, or if it contains #default
and the
default mode is the unnamed mode, or if the
mode
attribute is omitted when the default mode is the
unnamed mode.
The xsl:apply-templates
element also has an optional
mode
attribute. The value of this attribute
must be one of the following:
an EQName, which is expanded as described in 5.1.1 Qualified Names to define the name of a mode
the token #default
, to indicate that the default mode for the stylesheet
module
is to be used
the token #unnamed
, to indicate that the
unnamed mode is to be used
the token #current
, to indicate that the current mode is to be used
If the attribute is omitted, the default mode for the stylesheet module is used.
When searching for a template rule to process each item selected by the xsl:apply-templates
instruction, only those template rules that are applicable to the selected mode
are considered.
[Definition: At any point in the processing
of a stylesheet, there is a current mode. When the transformation
is initiated, the current mode is the initial mode, as described in 2.3 Initiating a Transformation. Whenever an xsl:apply-templates
instruction is evaluated, the current mode becomes the mode selected by this
instruction.] When a non-contextual function call is made, the current mode
is set to the unnamed mode. While
evaluating global variables and parameters, and the sequence constructor contained
in xsl:key
or xsl:sort
, the current mode is set
to the unnamed mode. No other instruction changes the current mode. The current
mode while evaluating an attribute set
is the same as the current mode of the caller. On completion of the
xsl:apply-templates
instruction, or on return from a
stylesheet function call, the current mode reverts to its previous value. The
current mode is used when an xsl:apply-templates
instruction uses
the syntax mode="#current"
; it is also used by the
xsl:apply-imports
and xsl:next-match
instructions (see 6.8 Overriding Template Rules).
Typically the template rules in a particular mode will be
designed to process a specific kind of input document. The typed
attribute of xsl:mode
gives the stylesheet author the opportunity
to provide information about this document to the processor. This information may
enable the processor to improve diagnostics or to optimize performance.
The typed
attribute of xsl:mode
informs the
processor whether the nodes to be processed by template rules in this mode are to
be typed or untyped.
If the value yes
is specified (synonyms true
or
1
), then all nodes processed in this mode must be typed. A
dynamic error occurs if xsl:apply-templates
in this mode
selects an element or attribute node whose type annotation is xs:untyped
or xs:untypedAtomic
.
If the value no
is specified (synonyms false
or
0
), then all nodes processed in this mode must be untyped. A
dynamic error occurs if xsl:apply-templates
in this mode
selects an element or attribute whose type annotation is
anything other than xs:untyped
or
xs:untypedAtomic
.
The value strict
is equivalent to yes
, with the
additional provision that in the match pattern of any template rule that is
applicable to this mode, any NameTest
used in the ForwardStepP
of the first StepExprP
of
a RelativePathExprP
is interpreted as follows:
If the NameTest
is an EQName
E, and the principal node kind of the axis of this step is
Element
, then:
It is a static error if the in-scope schema declarations do not include a global element declaration for element name E
When matching templates in this mode, the element name
E appearing in this step is interpreted as
schema-element(E)
. (Informally, this means
that it will only match an element if it has been validated
against this element declaration).
Otherwise (the NameTest
is a wildcard or the principal
node kind is Attribute
or Namespace
), the
template matching proceeds as if the typed
attribute were
absent.
The value lax
is equivalent to yes
, with the
additional provision that in the match pattern of any template rule that is
applicable to this mode, any NameTest
used in the ForwardStepP
of the first StepExprP
of
a RelativePathExprP
is interpreted as follows:
If the NameTest
is an EQName
E, and the principal node kind of the axis of this step is
Element
, and the in-scope schema declarations include
a global element declaration for element name E, then:
When matching templates in this mode, the element name
E appearing in this step is interpreted as
schema-element(E)
. (Informally, this means
that it will only match an element if it has been validated
against this element declaration).
Otherwise (the NameTest
is a wildcard, or the principal
node kind is Attribute
or Namespace
, or
there is no element declaration for E), the template
matching proceeds as if the typed
attribute were absent.
[ERR XTTE3100] It is a type error if an
xsl:apply-templates
instruction in a particular
mode
selects an element or attribute whose type is
xs:untyped
or xs:untypedAtomic
when the
typed
attribute of that mode specifies the value
yes
, strict
, or lax
.
[ERR XTSE3105] It is a static error if a template
rule applicable to a mode that is defined with typed="strict"
uses a match pattern that contains a RelativePathExprP
whose
first StepExprP
is an AxisStepP
whose
ForwardStepP
uses an axis whose principal node kind is
Element
and whose NodeTest
is an
EQName
that does not correspond to the name of any global
element declaration in the in-scope schema components.
[ERR XTTE3110] It is a type error if an
xsl:apply-templates
instruction in a particular
mode
selects an element or attribute whose type is anything
other than xs:untyped
or xs:untypedAtomic
when the
typed
attribute of that mode specifies the value
no
.
A template rule that is applicable to a mode M is guaranteed-streamable if and only if all the following conditions are satisfied:
Mode M is declared in an xsl:mode
declaration
that specifies streamable="yes"
.
The pattern defined in the
match
attribute of the xsl:template
element
is a motionless
pattern as defined in 19.8.10 Classifying Patterns.
The sweep of the sequence constructor forming the body of the xsl:template
element is either
motionless or consuming.
The type-adjusted
posture of the sequence constructor forming
the body of the xsl:template
element, with respect to the
U-type that corresponds to the declared return type of
the template (defaulting to item()*
), is grounded.
Note:
This means that either (a) the sequence constructor is grounded as written (that is, it does not return streamed nodes), or (b) it effectively becomes grounded because the declared result type of the template is atomic, leading to implicit atomization of the result.
Every expression and contained
sequence constructor in a contained
xsl:param
element (the construct that provides the
default value of the parameter) is
motionless.
Specifying streamable="yes"
on an
xsl:mode
declaration declares an intent that every template
rule that includes that mode (explicitly or implicitly, including by specifying
#all
), should be streamable,
either because it is guaranteed-streamable, or because it
takes advantage of streamability extensions offered by a particular
processor. The consequences of declaring the mode to be streamable
when there is such a template rule that is not guaranteed streamable depend on the
conformance level of the processor, and are explained in 19.10 Streamability Guarantees.
Processing of a document using streamable templates may be
initiated using code such as the following, where S
is a mode
declared with streamable="yes"
:
<xsl:source-document streamable="yes" href="bigdoc.xml"> <xsl:apply-templates mode="S"/> </xsl:source-document>
Alternatively, streamed processing may be initiated by invoking the transformation with an initial mode declared as streamable, while supplying the initial match selection (in an implementation-defined way) as a streamed document.
Note:
Invoking a streamable template using the construct
<xsl:apply-templates select="doc('bigdoc.xml')"/>
does
not ensure streamed processing. As always, processors may use streamed
processing if they are able to do so, but when the doc
FO30
or document
functions are used, processors are obliged to
ensure that the results are deterministic, which may be difficult to reconcile
with streaming (if the same document is read twice, the results must be
identical). The use of xsl:source-document
with streamable="yes"
does not offer the same guarantees of determinism.
For an example of processing a collection of documents by use of the function
uri-collection
FO30 in conjunction with
xsl:source-document
, see 18.1.2 Examples of xsl:source-document.
When an item is
selected by xsl:apply-templates
and there is no user-specified
template rule in the stylesheet that can be used to process that item, then a built-in template rule is
evaluated instead.
The built-in template rules have lower import precedence than all other template rules. Thus, the stylesheet author can override a built-in template rule by including an explicit template rule.
There are six sets of built-in template rules available. The set
that is chosen is a property of the mode selected by
the xsl:apply-templates
instruction. This property is set using the
on-no-match
attribute of the xsl:mode
declaration,
which takes one of the six values deep-copy
, shallow-copy
,
deep-skip
, shallow-skip
, text-only-copy
, or
fail
, the default being text-only-copy
. The effect of
these six sets of built-in template rules is explained in the following
subsections.
The effect of processing a
tree using a mode that specifies
on-no-match="text-only-copy"
is that the textual
content of the source document is retained while losing the markup, except where
explicit template rules dictate otherwise. When an element is encountered for
which there is no explicit template
rule, the processing continues with the children of that element. Text
nodes are copied to the output.
The built-in rule for document nodes and element nodes is equivalent to calling
xsl:apply-templates
with no select
attribute, and
with the mode
attribute set to #current
. If the built-in
rule was invoked with parameters, those parameters are passed on in the implicit
xsl:apply-templates
instruction.
This is equivalent to the following in the case where there are no parameters:
<xsl:template match="document-node()|element()" mode="M"> <xsl:apply-templates mode="#current"/> </xsl:template>
The built-in template rule for text and attribute nodes returns a text node containing the string value of the context node. It is effectively:
<xsl:template match="text()|@*" mode="M"> <xsl:value-of select="string(.)"/> </xsl:template>
Note:
This text node may have a string value that is zero-length.
The built-in template rule for atomic values returns a text node containing the value. It is effectively:
<xsl:template match=".[. instance of xs:anyAtomicType]" mode="M"> <xsl:value-of select="string(.)"/> </xsl:template>
Note:
This text node may have a string value that is zero-length.
The built-in template rule for processing instructions, comments, and namespace nodes does nothing (it returns the empty sequence).
<xsl:template match="processing-instruction()|comment()|namespace-node()" mode="M"/>
The built-in template rule for functions (including maps) does nothing (it returns the empty sequence).
<xsl:template match=".[. instance of function(*)]" mode="M"/>
The built-in template rule for
arrays (see 27.7.1 Arrays) is to apply templates to the members of the array.
It is equivalent to invoking xsl:apply-templates
with the select
attribute set to ?*
(which selects the members of the array), and with the
mode
attribute set to #current
. If the built-in
rule was invoked with parameters, those parameters are passed on in the implicit
xsl:apply-templates
instruction.
This is equivalent to the following in the case where there are no parameters:
<xsl:template match=".[. instance of array(*)]" mode="M"> <xsl:apply-templates mode="#current" select="?*"/> </xsl:template>
The following example illustrates the use of built-in template rules when there are parameters.
Suppose the stylesheet contains the following instruction:
<xsl:apply-templates select="title" mode="M"> <xsl:with-param name="init" select="10"/> </xsl:apply-templates>
If there is no explicit template rule that matches the title
element, then the following implicit rule is used:
<xsl:template match="title" mode="M"> <xsl:param name="init"/> <xsl:apply-templates mode="#current"> <xsl:with-param name="init" select="$init"/> </xsl:apply-templates> </xsl:template>
The effect of processing a tree using a
mode that specifies
on-no-match="deep-copy"
is that an unmatched element
in the source tree is copied unchanged to the output, together with its entire
subtree. Other unmatched items are also copied unchanged. The subtree is copied
unconditionally, without attempting to match nodes in the subtree against template
rules.
When this default action is selected for a mode M, all items (nodes, atomic values, and functions, including maps and arrays) are processed using a template rule that is equivalent to the following:
<xsl:template match="." mode="M"> <xsl:copy-of select="." validation="preserve"/> </xsl:template>
The effect of processing a tree using a
mode that specifies
on-no-match="shallow-copy"
is that the source tree is
copied unchanged to the output, except for nodes where different processing is
specified using an explicit template
rule.
When this default action is selected for a mode M, all items (nodes, atomic values, and functions, including maps and arrays) are processed
using a template rule that is equivalent to the following, except that all
parameters supplied in xsl:with-param
elements are passed on
implicitly to the called templates:
<xsl:template match="." mode="M"> <xsl:copy validation="preserve"> <xsl:apply-templates select="@*" mode="M"/> <xsl:apply-templates select="node()" mode="M"/> </xsl:copy> </xsl:template>
This rule is often referred to as the identity template, though it should be noted that it does not preserve node identity.
Note:
This rule differs from the traditional identity template rule by using two
xsl:apply-templates
instructions, one to process the
attributes and one to process the children. The only observable difference from
the traditional select="node() | @*"
is that with two separate
instructions, the value of position()
in the called templates
forms one sequence starting at 1 for the attributes, and a new sequence
starting at 1 for the children.
The following stylesheet transforms an input document by deleting all elements
named note
, together with their attributes and descendants:
<xsl:stylesheet version="3.0" xmlns:xsl="http://www.w3.org/1999/XSL/Transform"> <xsl:mode on-no-match="shallow-copy" streamable="true"/> <xsl:template match="note"> <!-- no action --> </xsl:template> </xsl:stylesheet>
The effect of processing a tree using a mode that specifies
on-no-match="deep-skip"
is that where no explicit template rule is
specified for an element, that element and all its descendants are ignored, and
are not copied to the result tree.
The effect of choosing on-no-match="deep-skip"
is as follows:
The built-in rule for document nodes is equivalent to calling
xsl:apply-templates
with no select
attribute, and with the mode
attribute set to
#current
. If the built-in rule was invoked with parameters,
those parameters are passed on in the implicit
xsl:apply-templates
instruction.
In the case where there are no parameters, this is equivalent to the following rule:
<xsl:template match="document-node()" mode="M"> <xsl:apply-templates mode="#current"/> </xsl:template>
The built-in rule for all items other than document nodes (that is, for all other kinds of node, as well as atomic values and functions, including maps and and arrays) is to do nothing, that is, to return an empty sequence (without applying templates to any children or ancestors).
This is equivalent to the following rule:
<xsl:template match="." mode="M"/>
The effect of processing a tree using a
mode that specifies
on-no-match="shallow-skip"
is to drop both the textual
content and the markup from the result document, except where there is an explicit
user-written template rule that dictates
otherwise.
The built-in rule for document nodes and element nodes applies templates (in the current mode) first to the node’s
attributes and then to its children. If the built-in rule was invoked
with parameters, those parameters are passed on in the implicit
xsl:apply-templates
instructions.
In the case where there are no parameters, this is equivalent to the following rule:
<xsl:template match="document-node()|element()" mode="M"> <xsl:apply-templates select="@*" mode="#current"/> <xsl:apply-templates mode="#current"/> </xsl:template>
The built-in template rule for all other kinds of node, and for atomic values and functions (including maps, but not arrays) is empty: that is, when the item is matched, the built-in template rule returns an empty sequence.
This is equivalent to the following rule:
<xsl:template match="." mode="M"/>
The built-in template rule for
arrays (see 27.7.1 Arrays) is to apply templates to the members of the array.
It is equivalent to invoking xsl:apply-templates
with the select
attribute set to ?*
(which selects the members of the array), and with the
mode
attribute set to #current
. If the built-in
rule was invoked with parameters, those parameters are passed on in the implicit
xsl:apply-templates
instruction.
This is equivalent to the following in the case where there are no parameters:
<xsl:template match=".[. instance of array(*)]" mode="M"> <xsl:apply-templates mode="#current" select="?*"/> </xsl:template>
The effect of choosing on-no-match="fail"
for a
mode is that every item selected in an xsl:apply-templates
instruction
must be matched by an explicit user-written template rule.
The built-in template rule is effectively:
<xsl:template match="." mode="M"> <xsl:message terminate="yes" error-code="err:XTDE0555"/> </xsl:template>
with an implementation-dependent message body.
[ERR XTDE0555] It is a dynamic error if
xsl:apply-templates
, xsl:apply-imports
or xsl:next-match
is used to process a node using a mode
whose declaration specifies on-no-match="fail"
when there is no
template rule in the stylesheet
whose match pattern matches that node.
<!-- Category: instruction -->
<xsl:apply-imports>
<!-- Content: xsl:with-param* -->
</xsl:apply-imports>
<!-- Category: instruction -->
<xsl:next-match>
<!-- Content: (xsl:with-param | xsl:fallback)* -->
</xsl:next-match>
A template rule that is being used to
override another template rule (see 6.4 Conflict Resolution for Template Rules) can use the
xsl:apply-imports
or xsl:next-match
instruction
to invoke the overridden template rule. The xsl:apply-imports
instruction only considers template rules in imported stylesheet modules; the
xsl:next-match
instruction considers all other template rules of
lower import precedence and/or
priority, and also declarations of the same
precedence and priority that appear earlier in declaration order. Both instructions will invoke the built-in template rule for the
context item (see 6.7 Built-in Template Rules) if no other template rule is found.
[Definition: At any point in
the processing of a stylesheet, there may
be a current template rule. Whenever a template rule is chosen as a result of
evaluating xsl:apply-templates
,
xsl:apply-imports
, or xsl:next-match
, the
template rule becomes the current template rule for the evaluation of the rule’s
sequence constructor.]
The current template rule is cleared (becomes absent) by any instruction that evaluates an operand with changed focus. It is therefore cleared when evaluating instructions contained within:
xsl:copy
if and only if there is a select
attribute
A global xsl:variable
or xsl:param
xsl:template
if and only if the called template specifies <xsl:context-item use="absent"/>
Note:
The current template rule is not affected by invoking named attribute sets (see 10.2 Named Attribute Sets), or named templates (see 10.1 Named Templates) unless <xsl:context-item use="absent"/>
is specified.
While evaluating a global variable or the default value of a stylesheet parameter (see 9.5 Global Variables and Parameters) the current template rule is absent.
These rules ensure that when xsl:apply-imports
or
xsl:next-match
is called, the context item is the same as when the current template rule was
invoked.
Both xsl:apply-imports
and xsl:next-match
search
for a template rule that matches the
context
item, and that is applicable to the current mode (see 6.6 Modes). In
choosing a template rule, they use the usual criteria such as the priority and
import precedence of the template
rules, but they consider as candidates only a subset of the template rules in the
stylesheet. This subset differs between the
two instructions:
The xsl:apply-imports
instruction considers as candidates only
those template rules contained in stylesheet
levels that are descendants in the import tree of the stylesheet
level that contains the current template rule.
Note:
This is not the same as saying that the search considers all template rules whose import precedence is lower than that of the current template rule.
[ERR XTSE3460] It is a static error if an
xsl:apply-imports
element appears in a template rule declared within an
xsl:override
element. (To invoke the template rule
that is being overridden, xsl:next-match
should
therefore be used.)
The xsl:next-match
instruction considers as candidates all
those template rules that come after the current template rule in the
ordering of template rules implied by the conflict resolution rules given in
6.4 Conflict Resolution for Template Rules. That is, it considers all template rules with
lower import precedence than the
current template rule,
plus the template rules that are at the same import precedence that have lower
priority than the current template rule, plus
the template rules with the same import precedence and priority
that occur before the current template rule in declaration order.
Note:
As explained in 6.4 Conflict Resolution for Template Rules, a template rule with no priority
attribute, whose match pattern contains multiple alternatives
separated by |
, is treated equivalently to a set of template
rules, one for each alternative. This means that where the same item matches more than one alternative, it is possible for an xsl:next-match
instruction to cause the current template rule to be invoked recursively.
This situation does not occur when the template rule has an explicit priority.
Note:
Because a template rule declared as a child of xsl:override
has higher precedence than any template rule declared in the used package
(see 3.5.4 Overriding Template Rules from a Used Package), the effect of
xsl:next-match
within such a template rule is to
consider as candidates first any other template rules for the same mode within the
same xsl:use-package
element (taking into account explicit and implicit
priority, and document order, in the usual way), and then all template rules in
the used package.
If a matching template rule R is found, then the result
of the xsl:next-match
or xsl:apply-imports
instruction is the
result of invoking R, with the values of parameters being set using the child
xsl:with-param
elements as described in 9.10 Setting Parameter Values.
The template rule R is evaluated with the same focus as the xsl:next-match
or xsl:apply-imports
instruction. The current template rule
changes to be R. The current mode does not change.
Note:
In the case where the current template rule T is
declared within an xsl:override
element in a using package P, while
the selected rule R is declared within a different package Q, and where
the current mode is MP (mode M in package P), the effect
is that the current mode for evaluation of R
remains MP rather than reverting to its corresponding mode MQ
(mode M in package Q).
If R contains an xsl:apply-templates
instruction that uses
mode="#current"
, then the set of template rules considered by this instruction
will therefore include any overriding template rules declared in P as well as the original
rules declared in Q.
If no matching template rule is found that satisfies these criteria, the built-in template rule for the context item is used (see 6.7 Built-in Template Rules).
An xsl:apply-imports
or xsl:next-match
instruction
may use xsl:with-param
child elements to pass parameters to the
chosen template rule (see 9.10 Setting Parameter Values). It also passes on any tunnel parameters as described in 10.1.3 Tunnel Parameters.
[ERR XTDE0560] It is a dynamic error if
xsl:apply-imports
or xsl:next-match
is
evaluated when the current template
rule is absent.
xsl:apply-imports
For example, suppose the stylesheet doc.xsl
contains a template rule for example
elements:
<xsl:template match="example"> <pre><xsl:apply-templates/></pre> </xsl:template>
Another stylesheet could import doc.xsl
and modify the treatment of
example
elements as follows:
<xsl:import href="doc.xsl"/> <xsl:template match="example"> <div style="border: solid red"> <xsl:apply-imports/> </div> </xsl:template>
The combined effect would be to transform an example
into an element
of the form:
<div style="border: solid red"><pre>...</pre></div>
An xsl:fallback
instruction appearing as a child of an
xsl:next-match
instruction is ignored by an XSLT 2.0 or 3.0 processor, but can be used to define fallback
behavior when the stylesheet is processed by an XSLT 1.0 processor with forwards
compatible behavior.
A template rule may have parameters. The parameters are declared in the body of the
template using xsl:param
elements, as described in 9.2 Parameters.
Values for these parameters may be supplied in the calling
xsl:apply-templates
, xsl:apply-imports
, or
xsl:next-match
instruction by means of
xsl:with-param
elements appearing as children of the calling
instruction. The expanded QName
represented by the name
attribute of the xsl:with-param
element must match the expanded QName
represented by the name
attribute of the corresponding
xsl:param
element.
It is not an error for these instructions to supply a parameter that does not match any parameter declared in the template rule that is invoked; unneeded parameter values are simply ignored.
A parameter may be declared as a tunnel
parameter by specifying tunnel="yes"
in the
xsl:param
declaration; in this case the caller must supply the
value as a tunnel parameter by specifying tunnel="yes"
in the
corresponding xsl:with-param
element. Tunnel parameters differ from
ordinary template parameters in that they are passed transparently through multiple
template invocations. They are fully described in 10.1.3 Tunnel Parameters.
XSLT offers two constructs for processing each item of a sequence:
xsl:for-each
and xsl:iterate
.
The main difference between the two constructs is that with
xsl:for-each
, the processing applied to each item in the sequence is
independent of the processing applied to any other item; this means that the items
may
be processed in any order or in parallel, though the order of the output sequence
is
well defined and corresponds to the order of the input (sorted if so requested). By
contrast, with xsl:iterate
, the processing is explicitly sequential:
while one item is being processed, values may be computed which are then available
for
use while the next item is being processed. This makes xsl:iterate
suitable for tasks such as creating a running total over a sequence of financial
transactions.
A further difference is that xsl:for-each
permits
sorting of the input sequence, while xsl:iterate
does not.
xsl:for-each
instruction<!-- Category: instruction -->
<xsl:for-each
select = expression >
<!-- Content: (xsl:sort*, sequence-constructor) -->
</xsl:for-each>
The xsl:for-each
instruction processes each item in a sequence of
items, evaluating the sequence
constructor within the xsl:for-each
instruction once
for each item in that sequence.
The select
attribute is required; it contains an
expression which is evaluated to produce a
sequence, called the input sequence. If there is an xsl:sort
element
present (see 13 Sorting) the input sequence is sorted to produce a
sorted sequence. Otherwise, the sorted sequence is the same as the input
sequence.
The xsl:for-each
instruction contains a sequence constructor. The sequence constructor is evaluated once for
each item in the sorted sequence, with the focus
set as follows:
The context item is the item being processed.
The context position is the position of this item in the sorted sequence.
The context size is the size of the sorted sequence (which is the same as the size of the input sequence).
For each item in the input sequence, evaluating the sequence constructor produces a sequence
of items (see 5.7 Sequence Constructors). These output sequences are
concatenated; if item Q follows item P in the sorted sequence,
then the result of evaluating the sequence constructor with Q as the
context item is concatenated after the result of evaluating the sequence constructor
with P as the context item. The result of the
xsl:for-each
instruction is the concatenated sequence of
items.
xsl:for-each
For example, given an XML document with this structure
<customers> <customer> <name>...</name> <order>...</order> <order>...</order> </customer> <customer> <name>...</name> <order>...</order> <order>...</order> </customer> </customers>
the following would create an HTML document containing a table with a row for each
customer
element
<xsl:template match="/"> <html> <head> <title>Customers</title> </head> <body> <table> <tbody> <xsl:for-each select="customers/customer"> <tr> <th> <xsl:apply-templates select="name"/> </th> <xsl:for-each select="order"> <td> <xsl:apply-templates/> </td> </xsl:for-each> </tr> </xsl:for-each> </tbody> </table> </body> </html> </xsl:template>
xsl:iterate
Instruction<!-- Category: instruction -->
<xsl:iterate
select = expression >
<!-- Content: (xsl:param*, xsl:on-completion?, sequence-constructor) -->
</xsl:iterate>
<!-- Category: instruction -->
<xsl:next-iteration>
<!-- Content: (xsl:with-param*) -->
</xsl:next-iteration>
<!-- Category: instruction -->
<xsl:break
select? = expression >
<!-- Content: sequence-constructor -->
</xsl:break>
<xsl:on-completion
select? = expression >
<!-- Content: sequence-constructor -->
</xsl:on-completion>
The select
attribute is required; it contains an
expression which is evaluated to produce a
sequence, called the input sequence.
The sequence constructor contained in the
xsl:iterate
instruction is evaluated once for each item in the
input sequence, in order, or until the loop exits by evaluating an
xsl:break
instruction, whichever is earlier. Within the sequence constructor that forms the body
of the xsl:iterate
instruction, the context item is set to each item from the value of the
select
expression in turn; the context position reflects the position of this item in the input
sequence, and the context size is the number
of items in the input sequence (which may be greater than the number of iterations,
if the loop exits prematurely using xsl:break
).
Note:
If xsl:iterate
is used in conjunction with
xsl:source-document
to achieve streaming, calls on the function
last
FO30 will be disallowed.
The xsl:break
and
xsl:on-completion
elements may have either a select
attribute or a non-empty contained sequence constructor but not
both. The effect of the element in both cases is obtained by evaluating the
select
expression if present or the contained sequence constructor
otherwise; if neither is present, the value is an empty sequence.
Note:
The xsl:on-completion
element appears before other children
of xsl:iterate
to ensure that variables declared in the sequence constructor are not in scope
within xsl:on-completion
, since such variables do not have a
defined value within xsl:on-completion
especially in the case
where the value of the select
attribute is an empty sequence.
The effect of xsl:next-iteration
is to cause the iteration to
continue by processing the next item in the input sequence, potentially with
different values for the iteration parameters. The effect of
xsl:break
is to cause the iteration to finish, whether or not all
the items in the input sequence have been processed. In both cases the affected
iteration is the one controlled by the innermost ancestor
xsl:iterate
element.
The instructions xsl:next-iteration
and xsl:break
are allowed only as descendants of an xsl:iterate
instruction, and
only in a tail position within the sequence constructor forming the body of
the xsl:iterate
instruction.
[Definition: An instruction J is in a tail position within a sequence constructor SC if it satisfies one of the following conditions:
J is the last instruction in SC, ignoring any
xsl:fallback
instructions.
J is in a tail position
within the sequence constructor that forms the body of an
xsl:if
instruction that is itself in a tail position within SC.
J is in a tail position
within the sequence constructor that forms the body of an
xsl:when
or xsl:otherwise
branch of an
xsl:choose
instruction that is itself in a tail position within SC.
J is in a tail position
within the sequence constructor that forms the body of an
xsl:try
instruction that is itself in a tail position within SC (that
is, it is immediately followed by an xsl:catch
element,
ignoring any xsl:fallback
elements).
J is in a tail position
within the sequence constructor that forms the body of an
xsl:catch
element within an xsl:try
instruction that is itself in a tail
position within SC.
]
[ERR XTSE3120] It is a static error if an
xsl:break
or xsl:next-iteration
element
appears other than in a tail position
within the sequence
constructor forming the body of an xsl:iterate
instruction.
[ERR XTSE3125] It is a static error if the
select
attribute of xsl:break
or
xsl:on-completion
is present and the instruction has
children.
[ERR XTSE3130] It is a static error if the
name
attribute of an xsl:with-param
child of
an xsl:next-iteration
element does not match the
name
attribute of an xsl:param
child of the
innermost containing
xsl:iterate
instruction.
Parameter names in xsl:with-param
must be unique: [see ERR XTSE0670].
The result of the xsl:iterate
instruction is the concatenation of
the sequences that result from the repeated evaluation of the contained sequence constructor, followed by the
sequence that results from evaluating the xsl:break
or
xsl:on-completion
element if any.
Any xsl:param
element that appears as a child of
xsl:iterate
declares a parameter whose value may vary from one
iteration to the next. The initial value of the parameter is the value obtained
according to the rules given in 9.3 Values of Variables and Parameters. The dynamic context
for evaluating the initial value of an xsl:param
element is the same
as the dynamic context for evaluating the select
expression of the
xsl:iterate
instruction (the context item is thus
not the first item in the input sequence).
On the first iteration a parameter always takes its initial value (which may depend on variables or other aspects of the dynamic context). Subsequently:
If an xsl:next-iteration
instruction is evaluated, then
parameter values for processing the next item in the input sequence can be set
in the xsl:with-param
children of that instruction; in the
absence of an xsl:with-param
element that names a particular
parameter, that parameter will retain its value from the previous
iteration.
If an xsl:break
instruction is evaluated, no further items in
the input sequence are processed.
If neither an xsl:next-iteration
nor an
xsl:break
instruction is evaluated, then the next item in
the input sequence is processed using parameter values that are unchanged from
the previous iteration.
The xsl:next-iteration
instruction contributes nothing to the result
sequence (technically, it returns an empty sequence). The instruction supplies
parameter values for the next iteration, which are evaluated according to the rules
given in 9.10 Setting Parameter Values; if there are no further items in the input
sequence then it supplies parameter values for use while evaluating the body of the
xsl:on-completion
element if any.
The xsl:break
instruction indicates that the iteration should
terminate without processing any remaining items from the input sequence. The select
expression or contained sequence
constructor is evaluated using the same context item, position, and size as the
xsl:break
instruction itself, and the result is appended to the
result of the xsl:iterate
instruction as a whole.
If neither an xsl:next-iteration
nor an xsl:break
instruction is evaluated, the next item in the input sequence is processed with
parameter values unchanged from the previous iteration; if there are no further items
in the input sequence, the iteration terminates.
The optional xsl:on-completion
element (which is not technically an
instruction and is not technically part of
the sequence constructor) is evaluated when the input sequence is
exhausted. It is not evaluated if the evaluation is terminated using
xsl:break
. During evaluation of its select
expression or sequence constructor
the context item, position, and size are absent
(that is, any reference to these values is an error). However, the values of the
parameters to xsl:iterate
are available, and take the values
supplied by the xsl:next-iteration
instruction evaluated while
processing the last item in the sequence.
If the input sequence is empty, then the result of the
xsl:iterate
instruction is the result of evaluating the select
attribute or sequence constructor forming the body of
the xsl:on-completion
element, using the initial values of the
xsl:param
elements. If there is no
xsl:on-completion
element, the result is an empty sequence.
Note:
Conceptually, xsl:iterate
behaves like a tail-recursive function.
The xsl:next-iteration
instruction then represents the recursive
call, supplying the tail of the input sequence as an implicit parameter. There are
two main reasons for providing the xsl:iterate
instruction. One
is that many XSLT users find writing recursive functions to be a difficult skill,
and this construct promises to be easier to learn. The other is that recursive
function calls are difficult for an optimizer to analyze. Because
xsl:iterate
is more constrained than a general-purpose
head-tail recursive function, it should be more amenable to optimization. In
particular, when the instruction is used in conjunction with
xsl:source-document
, it is designed to make it easy for the
implementation to use streaming techniques, processing the nodes in an input
document sequentially as they are read, without building the entire document tree
in memory.
The examples below use xsl:iterate
in conjunction with the
xsl:source-document
instruction. This is not the only way of using
xsl:iterate
, but it illustrates the way in which the two features
can be combined to achieve streaming of a large input document.
xsl:iterate
to Compute Cumulative Totals
Suppose that the input XML document has this structure
<transactions> <transaction date="2008-09-01" value="12.00"/> <transaction date="2008-09-01" value="8.00"/> <transaction date="2008-09-02" value="-2.00"/> <transaction date="2008-09-02" value="5.00"/> </transactions>
and that the requirement is to transform this to:
<account> <balance date="2008-09-01" value="12.00"/> <balance date="2008-09-01" value="20.00"/> <balance date="2008-09-02" value="18.00"/> <balance date="2008-09-02" value="23.00"/> </account>
This can be achieved using the following code, which is designed to process the transaction file using streaming:
<account> <xsl:source-document streamable="yes" href="transactions.xml"> <xsl:iterate select="transactions/transaction"> <xsl:param name="balance" select="0.00" as="xs:decimal"/> <xsl:variable name="newBalance" select="$balance + xs:decimal(@value)"/> <balance date="{@date}" value="{format-number($newBalance, '0.00')}"/> <xsl:next-iteration> <xsl:with-param name="balance" select="$newBalance"/> </xsl:next-iteration> </xsl:iterate> </xsl:source-document> </account>
The following example modifies this by only outputting the information for the first day’s transactions:
<account> <xsl:source-document streamable="yes" href="transactions.xml"> <xsl:iterate select="transactions/transaction"> <xsl:param name="balance" select="0.00" as="xs:decimal"/> <xsl:param name="prevDate" select="()" as="xs:date?"/> <xsl:variable name="newBalance" select="$balance + xs:decimal(@value)"/> <xsl:variable name="thisDate" select="xs:date(@date)"/> <xsl:choose> <xsl:when test="empty($prevDate) or $thisDate eq $prevDate"> <balance date="{$thisDate}" value="{format-number($newBalance, '0.00')}"/> <xsl:next-iteration> <xsl:with-param name="balance" select="$newBalance"/> <xsl:with-param name="prevDate" select="$thisDate"/> </xsl:next-iteration> </xsl:when> <xsl:otherwise> <xsl:break/> </xsl:otherwise> </xsl:choose> </xsl:iterate> </xsl:source-document> </account>
The following code outputs the balance only at the end of each day, together with the final balance:
<account> <xsl:source-document streamable="yes" href="transactions.xml"> <xsl:iterate select="transactions/transaction"> <xsl:param name="balance" select="0.00" as="xs:decimal"/> <xsl:param name="prevDate" select="()" as="xs:date?"/> <xsl:on-completion> <balance date="{$prevDate}" value="{format-number($balance, '0.00')}"/> </xsl:on-completion> <xsl:variable name="newBalance" select="$balance + xs:decimal(@value)"/> <xsl:variable name="thisDate" select="xs:date(@date)"/> <xsl:if test="exists($prevDate) and $thisDate ne $prevDate"> <balance date="{$prevDate}" value="{format-number($balance, '0.00')}"/> </xsl:if> <xsl:next-iteration> <xsl:with-param name="balance" select="$newBalance"/> <xsl:with-param name="prevDate" select="$thisDate"/> </xsl:next-iteration> </xsl:iterate> </xsl:source-document> </account>
If the sequence of transactions is empty, this code outputs a single element:
<balance date="" value="0.00"/>
.
Problem: Given a sequence of employee
elements, find the employees
having the highest and lowest salary, while processing each employee only
once.
Solution:
<xsl:source-document streamable="yes" href="si-iterate-035.xml"> <xsl:iterate select="employees/employee"> <xsl:param name="highest" as="element(employee)*"/> <xsl:param name="lowest" as="element(employee)*"/> <xsl:on-completion> <highest-paid-employees> <xsl:value-of select="$highest/name"/> </highest-paid-employees> <lowest-paid-employees> <xsl:value-of select="$lowest/name"/> </lowest-paid-employees> </xsl:on-completion> <xsl:variable name="this" select="copy-of()"/> <xsl:variable name="is-new-highest" as="xs:boolean" select="empty($highest[@salary ge current()/@salary])"/> <xsl:variable name="is-equal-highest" as="xs:boolean" select="exists($highest[@salary eq current()/@salary])"/> <xsl:variable name="is-new-lowest" as="xs:boolean" select="empty($lowest[@salary le current()/@salary])"/> <xsl:variable name="is-equal-lowest" as="xs:boolean" select="exists($lowest[@salary eq current()/@salary])"/> <xsl:variable name="new-highest-set" as="element(employee)*" select="if ($is-new-highest) then $this else if ($is-equal-highest) then ($highest, $this) else $highest"/> <xsl:variable name="new-lowest-set" as="element(employee)*" select="if ($is-new-lowest) then $this else if ($is-equal-lowest) then ($lowest, $this) else $lowest"/> <xsl:next-iteration> <xsl:with-param name="highest" select="$new-highest-set"/> <xsl:with-param name="lowest" select="$new-lowest-set"/> </xsl:next-iteration> </xsl:iterate> </xsl:source-document>
If the input sequence is empty, this code outputs an empty
highest-paid-employees
element and an empty
lowest-paid-employees
element.
When streaming, it is not possible to determine whether the item being processed
is the last in a sequence without reading ahead. The last
FO30
function therefore cannot be used in guaranteed-streamable
code. The xsl:iterate
instruction provides a solution to this
problem.
Problem: render the last paragraph in a section in some special way, for example
by using bold face. (The actual rendition is achieved by processing the paragraph
with mode last-para
.)
The solution uses xsl:iterate
together with the copy-of
function to maintain a one-element look-ahead by explicit coding:
<xsl:template match="section" mode="streaming"> <xsl:iterate select="para"> <xsl:param name="prev" select="()" as="element(para)?"/> <xsl:on-completion> <xsl:apply-templates select="$prev" mode="last-para"/> </xsl:on-completion> <xsl:if test="$prev"> <xsl:apply-templates select="$prev"/> </xsl:if> <xsl:next-iteration> <xsl:with-param name="prev" select="copy-of(.)"/> </xsl:next-iteration> </xsl:iterate> </xsl:template>
There are two instructions in XSLT that support conditional processing:
xsl:if
and xsl:choose
. The xsl:if
instruction provides simple if-then conditionality; the xsl:choose
instruction supports selection of one choice when there are several possibilities.
XSLT 3.0 also supports xsl:try
and
xsl:catch
which define conditional processing to handle dynamic errors.
xsl:if
<!-- Category: instruction -->
<xsl:if
test = expression >
<!-- Content: sequence-constructor -->
</xsl:if>
The xsl:if
element has a mandatory test
attribute,
which specifies an expression. The content is
a sequence constructor.
The result of the xsl:if
instruction depends on the effective boolean valueXP30 of the expression in
the test
attribute. The rules for determining the effective boolean
value of an expression are given in [XPath 3.0]: they are the same as
the rules used for XPath conditional expressions.
If the effective boolean value of the expression is true, then the sequence constructor is evaluated (see 5.7 Sequence Constructors), and the resulting sequence is returned as the result of the xsl:if
instruction; otherwise, the sequence constructor is not evaluated, and the empty
sequence is returned.
xsl:if
In the following example, the names in a group of names are formatted as a comma separated list:
<xsl:template match="namelist/name"> <xsl:apply-templates/> <xsl:if test="not(position()=last())">, </xsl:if> </xsl:template>
The following colors every other table row yellow:
<xsl:template match="item"> <tr> <xsl:if test="position() mod 2 = 0"> <xsl:attribute name="bgcolor">yellow</xsl:attribute> </xsl:if> <xsl:apply-templates/> </tr> </xsl:template>
xsl:choose
<!-- Category: instruction -->
<xsl:choose>
<!-- Content: (xsl:when+, xsl:otherwise?) -->
</xsl:choose>
<xsl:when
test = expression >
<!-- Content: sequence-constructor -->
</xsl:when>
<xsl:otherwise>
<!-- Content: sequence-constructor -->
</xsl:otherwise>
The xsl:choose
element selects one among a number of possible
alternatives. It consists of a sequence of one or more xsl:when
elements followed by an optional xsl:otherwise
element. Each
xsl:when
element has a single attribute, test
, which
specifies an expression. The content of the
xsl:when
and xsl:otherwise
elements is a
sequence constructor.
When an xsl:choose
element is processed, each of the
xsl:when
elements is tested in turn (that is, in the order that
the elements appear in the stylesheet), until one of the xsl:when
elements is satisfied. If none of the xsl:when
elements is
satisfied, then the xsl:otherwise
element is considered, as
described below.
An xsl:when
element is satisfied if the effective boolean valueXP30 of the expression in its test
attribute is
true
. The rules for determining the effective boolean value of an
expression are given in [XPath 3.0]: they are the same as the rules used
for XPath conditional expressions.
The content of the first, and only the first, xsl:when
element that
is satisfied is evaluated, and the resulting sequence is returned as the result of
the xsl:choose
instruction. If no xsl:when
element
is satisfied, the content of the xsl:otherwise
element is evaluated,
and the resulting sequence is returned as the result of the
xsl:choose
instruction. If no xsl:when
element
is satisfied, and no xsl:otherwise
element is present, the result of
the xsl:choose
instruction is an empty sequence.
Only the sequence constructor of the selected xsl:when
or
xsl:otherwise
instruction is evaluated. The test
expressions for xsl:when
instructions after the selected one are not
evaluated.
xsl:choose
The following example enumerates items in an ordered list using arabic numerals, letters, or roman numerals depending on the depth to which the ordered lists are nested.
<xsl:template match="orderedlist/listitem"> <fo:list-item indent-start='2pi'> <fo:list-item-label> <xsl:variable name="level" select="count(ancestor::orderedlist) mod 3"/> <xsl:choose> <xsl:when test='$level=1'> <xsl:number format="i"/> </xsl:when> <xsl:when test='$level=2'> <xsl:number format="a"/> </xsl:when> <xsl:otherwise> <xsl:number format="1"/> </xsl:otherwise> </xsl:choose> <xsl:text>. </xsl:text> </fo:list-item-label> <fo:list-item-body> <xsl:apply-templates/> </fo:list-item-body> </fo:list-item> </xsl:template>
The xsl:try
instruction can be used to trap
dynamic errors occurring within the expression it wraps; the recovery action if such
errors occur is defined using a child xsl:catch
element.
<!-- Category: instruction -->
<xsl:try
select? = expression
rollback-output? = boolean >
<!-- Content: (sequence-constructor, xsl:catch, (xsl:catch | xsl:fallback)*) -->
</xsl:try>
Note:
Because a sequence constructor may contain an xsl:fallback
element, the effect of this content model is that an xsl:fallback
instruction may appear as a child of xsl:try
in any position.
<xsl:catch
errors? = tokens
select? = expression >
<!-- Content: sequence-constructor -->
</xsl:catch>
An xsl:try
instruction evaluates either the expression contained in
its select
attribute, or its contained sequence constructor, and returns the
result of that evaluation if it succeeds without error. If a dynamic error occurs during the evaluation, the
processor evaluates the first xsl:catch
child element applicable to
the error, and returns that result instead.
If the xsl:try
element has a select
attribute, then it
must have no children other than xsl:catch
and
xsl:fallback
. That is, the select
attribute and the
contained sequence constructor are mutually exclusive. If neither is present, the
result of the xsl:try
is an empty sequence (no dynamic error can
occur in this case).
The rollback-output
attribute is described in
8.3.1 Recovery of Result Trees. The default value is yes
.
[ERR XTSE3140] It is a static error if the
select
attribute of the xsl:try
element is
present and the element has children other than xsl:catch
and
xsl:fallback
elements.
Any xsl:fallback
children of the xsl:try
element
are ignored by an XSLT 3.0 processor, but can be used to define the recovery action
taken by an XSLT 1.0 or XSLT 2.0 processor operating with forwards compatible behavior.
The xsl:catch
element has an optional errors
attribute,
which lists the error conditions that the xsl:catch
element is
designed to intercept. The default value is errors="*"
, which catches
all errors. The value is a whitespace-separated list of NameTestsXP30; an xsl:catch
element
catches an error condition if this list includes a NameTest
that matches
the error code associated with that error condition.
Note:
Error codes are QNames. Those defined in this specification and in related
specifications are all in the standard
error namespace, and may therefore be caught using an
xsl:catch
element such as <xsl:catch
errors="err:FODC0001 err:FODC0005">
where the namespace prefix
err
is bound to this namespace. Errors defined by implementers,
and errors raised by an explicit call of the error
FO30 function
or by use of the xsl:message
or xsl:assert
instruction, may
use error codes in other namespaces.
If more than one xsl:catch
element matches an error, the error is
processed using the first one that matches, in document order. If no
xsl:catch
matches the error, then the error is not caught (that
is, evaluation of the xsl:try
element fails with the dynamic
error).
An xsl:catch
element may have either a select
attribute, or a contained sequence
constructor.
[ERR XTSE3150] It is a static error if the
select
attribute of the xsl:catch
element is
present unless the element has empty content.
The result of evaluating the xsl:catch
element is the result of
evaluating the XPath expression in its select
attribute or the result of
evaluating the contained sequence constructor; if neither is present, the result is
an empty sequence. This result is delivered as the result of the xsl:try
instruction.
If a dynamic error occurs during the evaluation of xsl:catch
, it
causes the containing xsl:try
to fail with this error. The error is
not caught by other sibling xsl:catch
elements within the same
xsl:try
instruction, but it may be caught by an
xsl:try
instruction at an outer level, or by an
xsl:try
instruction nested within the xsl:catch
.
Within the select
expression, or within the sequence constructor
contained by the xsl:catch
element, a number of variables are
implicitly declared, giving information about the error that occurred. These are
lexically scoped to the xsl:catch
element. These variables are all in
the standard error namespace,
and they are initialized as described in the following table:
Variable | Type | Value |
---|---|---|
err:code | xs:QName | The error code |
err:description | xs:string? | A description of the error condition; an empty sequence if no description is available (for example, if
the error FO30 function was called with one
argument).
|
err:value | item()* | Value associated with the error. For an error raised by
calling the error FO30 function, this is the value of the
third argument (if supplied). For an error raised by evaluating
xsl:message with terminate="yes" , or a failing xsl:assert , this
is the document node at the root of the tree containing the XML message
body.
|
err:module | xs:string? | The URI (or system ID) of the stylesheet module containing the instruction where the error occurred; an empty sequence if the information is not available. |
err:line-number | xs:integer? | The line number within the stylesheet module of the instruction where the error occurred; an empty sequence if the information is not available. The value may be approximate. |
err:column-number | xs:integer? | The column number within the stylesheet module of the instruction where the error occurred; an empty sequence if the information is not available. The value may be approximate. |
Variables declared within the sequence constructor of the xsl:try
element (and not within an xsl:catch
) are not visible within the
xsl:catch
element.
Note:
Within an xsl:catch
it is possible to re-throw the error using
the function call error($err:code, $err:description, $err:value)
.
The following additional rules apply to the catching of errors:
All dynamic errors occurring during the evaluation of the
xsl:try
sequence constructor or select
expression are caught (provided they match one of the
xsl:catch
elements).
Note:
This includes errors occurring in functions or templates invoked in
the course of this evaluation, unless already caught by a nested
xsl:try
.
It also includes (for
example) errors caused by calling the
error
FO30 function, or the
xsl:message
instruction with
terminate="yes"
, or the
xsl:assert
instruction, or the xs:error
constructor
function.
It does not include errors that occur while evaluating references to
variables whose declaration and initialization is outside the
xsl:try
.
The existence of an xsl:try
instruction does not affect the
obligation of the processor to signal certain errors as static errors, or its
right to choose whether to signal some errors (such as type errors) statically or dynamically. Static
errors are never caught.
Some fatal errors arising in the processing environment, such as running out of
memory, may cause termination of the transformation despite the presence of an
xsl:try
instruction. This is implementation-dependent.
If the sequence constructor or select
expression of the
xsl:try
causes execution of
xsl:result-document
, xsl:message
, or xsl:assert
instructions and
fails with a dynamic error that is caught, it is implementation-dependent
whether these instructions have any externally visible effect. The processor is
not required to roll back any changes made by these
instructions. The same applies to any side effects caused by extension
functions or extension instructions.
A serialization error that occurs during the serialization of
a secondary result produced
using xsl:result-document
is treated as a dynamic error in the
evaluation of the xsl:result-document
instruction, and may be
caught (for example by an xsl:try
instruction that contains
the xsl:result-document
instruction). A serialization error
that occurs while serializing the principal result
is
treated as occurring after the transformation has finished, and cannot be
caught.
A validation error is treated as occurring in the instruction
that requested validation. For example, if the stylesheet is producing XHTML
output and requests validation of the entire result document by means of the
attribute validation="strict"
on the instruction that creates the
outermost html
element, then a validation failure can be caught
only at that level. Although the validation error might be detected, for
example, while writing a p
element at a location where no
p
element is allowed, it is not treated as an error in the
instruction that writes the p
element and cannot be caught at that
level.
A type error may be caught if the processor raises it dynamically; this does not affect the processor’s right to raise the error statically if it chooses.
The following rules are provided to define which expression is considered to fail when a type error occurs, and therefore where the error can be caught. The general principle is that where the semantics of a construct C place requirements on the type of some subexpression, a type error is an error in the evaluation of C, not in the evaluation of the subexpression.
For example, consider the following construct:
<xsl:variable name="v" as="xs:integer"> <xsl:sequence select="$foo"/> </xsl:variable>
The expected type of the result of the sequence constructor is
xs:integer
; if the value of variable $foo
turns
out to be a string, then a type error will occur. It is not possible to catch
this by writing:
<xsl:variable name="v" as="xs:integer"> <xsl:try> <xsl:sequence select="$foo"/> <xsl:catch>...</xsl:catch> </xsl:try> </xsl:variable>
This fails to catch the error because the xsl:sequence
instruction is deemed to evaluate successfully; the failure only occurs when
the result of this instruction is bound to the variable.
A similar rule applies to functions: if the body of a function computes a result which does not conform to the required type of the function result, it is not possible to catch this error within the function body itself; it can only be caught by the caller of the function. Similarly, if an expression used to compute an argument to a function returns a value of the wrong type for the function signature, this is not considered an error in this expression, but an error in evaluating the function call as a whole.
A consequence of these rules is that when a type error occurs while initializing a global variable (because the initializer returns a value of the wrong type, given the declared type of the variable), then this error cannot be caught.
Note:
Because processors are permitted to report type errors during static
analysis, it is unwise to attempt to recover from type errors dynamically.
The best strategy is generally to prevent their occurrence. For example,
rather than writing $p + 1
where $p
is a parameter
of unknown type, and then catching the type error that occurs if
$p
is not numeric, it is better first to test whether
$p
is numeric, perhaps by means of an expression such as
$p instance of my:numeric
, where my:numeric
is
a union type with xs:double
, xs:float
, and
xs:decimal
as its member types.
The fact that the application tries to catch errors does not prevent the
processor from organizing the evaluation in such a way as to prevent errors
occurring. For example exists(//a[10 div . gt 5])
may still do an
“early exit”, rather than examining every item in the sequence just to see if
it triggers a divide-by-zero error.
Except as specified above, the optimizer must not rearrange the evaluation (at compile time or at run time) so that expressions written to be subject to the try/catch are evaluated outside its scope, or expressions written to be external to the try/catch are evaluated within its scope. This does not prevent expressions being rearranged, but any expression that is so rearranged must carry its try/catch context with it.
The XSLT language is designed so that a processor that chooses to execute instructions in document order will always append nodes to the result tree in document order, and never needs to update a result tree in situ. As a result, it is normal practice for XSLT processors to stream the result tree directly to its final destination (for example, a serializer) without ever holding the tree in memory. This applies whether or not the processor is streamable, and whether or not source documents are streamed.
The language specification states (see 2.14 Error Handling) that when a transformation terminates with a dynamic error, the state of persistent resources affected by the transformation (for example, serialized result documents) is implementation-defined, so processors are not required to take any special steps to recover such resources to their pre-transformation state; at the same time, there is no guarantee that secondary result documents produced before the failure occurs will be in a usable state.
The situation becomes more complicated when dynamic errors occur while writing to
a result tree, and the dynamic error is caught by an
xsl:try
/xsl:catch
instruction. The semantics
of these instructions requires that when an error occurring during the evaluation
of xsl:try
is caught, the result of the xsl:try
instruction is the result of the relevant xsl:catch
. To achieve
this, any output written to the result tree during the execution of
xsl:try
until the point where the error occurs must
effectively be undone. There are two basic strategies for achieving this: either
the updates are not committed to persistent storage until the
xsl:try
instruction is completed, or the updates are written
in such a way that they can be rolled back in the event of a failure.
Both these strategies are potentially expensive, and both have an adverse effect
on streaming, in that they affect the amount of memory needed to transform large
amounts of data. XSLT 3.0 therefore provides an option to relax the requirement to
recover result trees when failures occur in the course of evaluating an
xsl:try
instruction. This option is invoked by specifying
rollback-output="no"
on the xsl:try
instruction.
The default value of the attribute is rollback-output="yes"
.
The effect of specifying rollback-output="no"
on
xsl:try
is as follows: if a dynamic error occurs in the course
of evaluating the xsl:try
instruction, and if the failing
construct is evaluated in final output state while writing to
some result document, then it is implementation-dependent
whether an attempt to catch this error using xsl:catch
will be
successful. If the attempt is successful, then the xsl:try
instruction succeeds, delivering the result of evaluating the
xsl:catch
clause, and the transformation proceeds as normal.
If the attempt is unsuccessful (typically, because non-recoverable updates have
already been made to the result tree), then the xsl:try
instruction as a whole fails with a dynamic error. The state of this result
document will then be undefined, but the transformation can ignore the failure and
continue to produce other result documents, for example by wrapping the
xsl:result-document
instruction in an xsl:try
instruction that catches the relevant error.
[ERR XTDE3530] It is a dynamic error if an xsl:try
instruction is unable to recover the state of a final result tree because
recovery has been disabled by use of the attribute
rollback-output="no"
.
For example, consider the following:
<xsl:result-document href="out.xml"> <xsl:try rollback-output="no"> <xsl:source-document streamable="yes" href="in.xml"> <xsl:copy-of select="."/> </xsl:source-document> <xsl:catch errors="*"> <error code="{$err:code}" message="{$err:description}" file="in.xml"/> </xsl:catch> </xsl:try> </xsl:result-document>
The most likely failure to occur here is a failure to read the streamed input file
in.xml
. In the common case where this failure is detected
immediately, for example if the file does not exist or the network connection is
down, no output will have been written to the result document, and the attempt to
catch the error is likely to be successful. If however a failure is detected after
several megabytes of data have been copied to out.xml
, for example an
XML well-formedness error in the input file, or a network failure that occurs
while reading the file, recovery of the output file may be impossible. In this
situation the xsl:result-document
instruction will fail with a
dynamic error. It is possible to catch this error, but the state of the file
out.xml
will be unpredictable.
Note that adding an xsl:try
instruction as a child of
xsl:source-document
does not help. Any error reading the input file
(such as a well-formedness error) is an error in the xsl:source-document
instruction and can only be caught at that level.
When rollback-output="no"
is specified, it is still possible to
ensure recovery of errors happens predictably by evaluating the
potentially-failing code in temporary output state: typically,
within an xsl:variable
. In effect the variable acts as an
explicit buffer for temporary results, which is only copied to the final output if
evaluation succeeds.
Note:
An application might wish to ensure that when a fatal error occurs while
reading an input stream, data written to persistent storage up to the point of
failure is available after the transformation terminates. Setting
rollback-output="no"
does not guarantee this, but a processor
might choose to interpret this as the intent.
Changing the attribute to rollback-output="yes"
makes the stylesheet
more robust and able to handle error conditions predictably, but the cost may be
substantial; for example it may be necessary to buffer the whole of the result
document in memory.
The following example divides an employee’s salary by the number of years they have served, catching the divide-by-zero error if the latter is zero.
<xsl:try select="salary div length-of-service"> <xsl:catch errors="err:FOAR0001" select="()"/> </xsl:try>
The following example generates a result tree and performs schema validation, outputting a warning message and serializing the invalid tree if validation fails.
<xsl:result-document href="out.xml"> <xsl:variable name="result"> <xsl:call-template name="construct-output"/> </xsl:variable> <xsl:try> <xsl:copy-of select="$result" validation="strict"/> <xsl:catch> <xsl:message>Warning: validation of result document failed: Error code: <xsl:value-of select="$err:code"/> Reason: <xsl:value-of select="$err:description"/> </xsl:message> <xsl:sequence select="$result"/> </xsl:catch> </xsl:try> </xsl:result-document>
The reason that the result tree is constructed in a variable in this example is
so that the unvalidated tree is available to be used within the
xsl:catch
element. An alternative approach would be to
repeat the logic for constructing the tree:
<xsl:try> <xsl:result-document href="out.xml" validation="strict"> <xsl:call-template name="construct-output"/> </xsl:result-document> <xsl:catch> <xsl:message>Warning: validation of result document failed: Error code: <xsl:value-of select="$err:code"/> Reason: <xsl:value-of select="$err:description"/> </xsl:message> <xsl:call-template name="construct-output"/> </xsl:catch> </xsl:try>
The facilities described in this section are designed to make it easier to generate result trees conditionally depending on what is found in the input, without violating the rules for streamability. These facilities are available whether or not streaming is in use, but they are introduced to the language specifically to make streaming easier.
The facilities are introduced first by example:
The following example generates an events
element if and only if
there are one or more event
elements. The code could be written like
this:
<xsl:if test="exists(event)"> <events> <xsl:copy-of select="event"/> </events> </xsl:if>
However, the above code would not be guaranteed-streamable,
because it processes the child event
elements more than once. To make
it streamable, it can be rewritten as:
<xsl:where-populated> <events> <xsl:copy-of select="event"/> </events> </xsl:where-populated>
The effect of the xsl:where-populated
instruction, as explained
later, is to avoid outputting the events
element if it would have no
children. A streaming implementation will typically hold the start tag of the
events
element in a buffer, to be sent to the output destination
only if and when a child node is generated.
The following example generates an h3
element and a summary paragraph
only if a list of items is non-empty. The code could be written like this:
<xsl:if test="exists(item-for-sale)"> <h1>Items for Sale</h1> </xsl:if> <xsl:apply-templates select="item-for-sale"/> <xsl:if test="exists(item-for-sale)"> <p>Total value: {accumulator-before('total-value')}</p> </xsl:if>
However, the above code would not be guaranteed-streamable,
because it processes the child item-for-sale
elements more than once.
To make it streamable, it can be rewritten as:
<xsl:sequence> <xsl:on-non-empty> <h1>Items for Sale</h1> </xsl:on-non-empty> <xsl:apply-templates select="item-for-sale"/> <xsl:on-non-empty> <p>Total value: {accumulator-before('total-value')}</p> </xsl:on-non-empty> </xsl:sequence>
The effect of the xsl:on-non-empty
instruction, as explained
later, is to output the enclosed content only if the containing sequence
constructor also generates “ordinary” content, that is, if there is content
generated by instructions other than xsl:on-empty
and
xsl:on-non-empty
instructions.
The following example generates a summary paragraph only if a list of items is empty. The code could be written like this:
<xsl:apply-templates select="item-for-sale"/> <xsl:if test="empty(item-for-sale)"> <p>There are no items for sale.</p> </xsl:if>
However, the above code would not be guaranteed-streamable,
because it processes the child item-for-sale
elements more than once
(the fact that the list is empty is irrelevant, because streamability is
determined statically). To make the code streamable, it can be rewritten as:
<xsl:sequence> <xsl:apply-templates select="item-for-sale"/> <xsl:on-empty> <p>There are no items for sale.</p> </xsl:on-empty> </xsl:sequence>
The effect of the xsl:on-empty
instruction, as explained later,
is to output the enclosed content only if the containing sequence constructor
generates no “ordinary” content, that is, if there is no content generated by
instructions other than xsl:on-empty
and
xsl:on-non-empty
instructions.
Note:
In some cases, similar effects can be achieved by using the
has-children
FO30 function, which tests whether an element
has child nodes without consuming the children. However, use of
has-children
FO30 has the drawback that the function is
unselective: it cannot be used to test whether there are any children of relevance
to the application. In particular, it returns true if an element contains comments
or whitespace text nodes that the application might consider to be
insignificant.
Note:
There are no special streamability rules for the three instructions
xsl:where-populated
, xsl:on-empty
, or
xsl:on-non-empty
. The general streamability rules apply. In many cases the
xsl:on-empty
and xsl:on-non-empty
instructions will generate content that does not depend on the source document,
and they will therefore be motionless, but this is not
required.
xsl:where-populated
instruction<!-- Category: instruction -->
<xsl:where-populated>
<!-- Content: sequence-constructor -->
</xsl:where-populated>
The xsl:where-populated
instruction encloses a sequence constructor. The result of the instruction is established
as follows:
The sequence constructor is evaluated in the usual way (taking into account
any xsl:on-empty
and xsl:on-non-empty
instructions) to produce a result $R.
The result of the instruction is the value of the expression
$R[not(deemed-empty(.))]
where the function
deemed-empty($item as item())
returns true if and only if
$item
is one of the following:
A document or element node that has no children.
Note:
If an element has attributes or namespaces, these do not prevent the element being deemed empty.
If a document or element node has children, the node is not deemed
empty, even if the children are empty. For example, a document node
created using an xsl:variable
instruction in the
form
<xsl:variable name="temp"><a/></xsl:variable>
is not deemed empty, even though the contained <a/>
element is empty.
A node, other than a document or element node, whose string value is zero-length.
Note:
A whitespace-only text node is not deemed empty.
An atomic value such that the result of casting the atomic value to a string is zero-length.
Note:
This can happen only when the atomic value is of type
xs:string
, xs:anyURI
,
xs:untypedAtomic
, xs:hexBinary
, or
xs:base64Binary
.
A map whose size (number of key/value pairs) is zero.
An array (see 27.7.1 Arrays) where the result
of flattening the array using the array:flatten
FO31 function is
either an empty sequence, or a sequence in which every item is deemed empty
(applying these rules recursively).
The following example generates an HTML unnumbered list, if and only if the
list is non-empty. Note that the presence of the class
attribute
does not make the list non-empty. The code is written to be streamable.
<xsl:where-populated> <ul class="my-list"> <xsl:for-each select="source-item"> <li><xsl:value-of select="."/></li> </xsl:for-each> </ul> </xsl:where-populated>
xsl:on-empty
instruction<!-- Category: instruction -->
<xsl:on-empty
select? = expression >
<!-- Content: sequence-constructor -->
</xsl:on-empty>
The xsl:on-empty
instruction has the same content model as
xsl:sequence
, and when it is evaluated, the same rules apply.
In particular, the select
attribute and the contained sequence
constructor are mutually exclusive [see ERR XTSE3185].
When an xsl:on-empty
instruction
appears in a sequence constructor, then:
It must be the only xsl:on-empty
instruction in the
sequence constructor, and
It must not be followed in the sequence constructor by any other instruction, other than xsl:fallback
, or by a
significant text node (that is, a text node that has not been discarded
under the provisions of 4.3 Stripping Whitespace from the Stylesheet), or by a
literal result element. It may, however, be followed
by non-instructions such as xsl:catch
where
appropriate.
[Definition: An item is vacuous if
it is one of the following: a zero-length text node; a document node with no children;
an atomic value which,
on casting to xs:string
, produces a zero-length string; or (when XPath 3.1 is supported) an array
which on flattening using the array:flatten
FO31 function produces either an empty sequence
or a sequence consisting entirely of vacuous items.]
An xsl:on-empty
instruction is triggered only if every
preceding sibling instruction, text node, and literal result element in the same sequence constructor
returns either an empty sequence, or a sequence consisting entirely of vacuous items.
If an xsl:on-empty
instruction is triggered, then the result
of the containing sequence constructor is the result of the xsl:on-empty
instruction.
Note:
This means that the (vacuous) results produced by other instructions in the sequence constructor are discarded. This is relevant mainly when the result of the sequence constructor is used for something other than constructing a node: for example if it forms the result of a function, or the value of a variable, and the function or variable specifies a required type.
When streaming, it may be necessary to buffer vacuous items in the result sequence until it is known whether the result will contain items that are non-vacuous. In many common situations, however — in particular, when the sequence constructor is being used to create the content of a node — vacuous items can be discarded immediately because they do not affect the content of the node being constructed.
Note:
In nearly all cases, the rules for xsl:on-empty
are aligned
with the rules for constructing complex content. If the sequence constructor within
a literal result element
or an xsl:element
instruction includes an xsl:on-empty
instruction,
then the content of the element will be the value delivered by the xsl:on-empty
instruction
if and only if the content would otherwise be empty.
There is one minor exception to this rule: if the sequence constructor delivers multiple
zero-length strings,
then in the absence of the xsl:on-empty
instruction the new element would contain whitespace,
made up of the separators between these zero-length strings; but xsl:on-empty
takes no account
of these separators.
Note:
Attribute and namespace nodes created by the sequence constructor
are significant; the xsl:on-empty
instruction will not be triggered if such nodes are present.
If this is not the desired effect, it is possible to partition the sequence constructor
to change the scope of
xsl:on-empty
, for example:
<ol> <xsl:attribute name="class" select="numbered-list"/> <xsl:sequence> <xsl:value-of select="xyz"/> <xsl:on-empty select="'The list is empty'"/> </xsl:sequence> </ol>
Note:
Where the sequence constructor is a child of an instruction with
an [xsl:]use-attribute-sets
attribute, any attribute nodes created by expanding the referenced
attribute set(s) are not part of the result of the sequence constructor and therefore
play no role in determining
whether an xsl:on-empty
or xsl:on-non-empty
instruction is triggered.
Equally, when the sequence constructor is a child
of a literal result element, attribute nodes generated by expanding the attributes
of the literal result element are not taken into account.
Note:
If xsl:on-empty
is the only instruction in a sequence
constructor then it is always evaluated.
If xsl:on-empty
and xsl:on-non-empty
appear
in the same sequence constructor, then the rules ensure that only one of them
will be evaluated.
xsl:on-non-empty
instruction<!-- Category: instruction -->
<xsl:on-non-empty
select? = expression >
<!-- Content: sequence-constructor -->
</xsl:on-non-empty>
The xsl:on-non-empty
instruction has the same content model as
xsl:sequence
, and when it is evaluated, the same rules apply.
In particular, the select
attribute and the contained sequence
constructor are mutually exclusive [see ERR XTSE3185].
An xsl:on-non-empty
instruction is evaluated only
if there is at least one sibling node in the same sequence constructor,
excluding xsl:on-empty
and xsl:on-non-empty
instructions,
whose evaluation yields a sequence containing an item that is not vacuous.
If this condition applies, then all xsl:on-non-empty
instructions in the
containing sequence constructor are evaluated, and their results are included in the
result
of the containing sequence constructor in their proper positions.
Note:
The xsl:on-non-empty
instruction is typically used to generate headers or
footers appearing before or after a list of items, where the header or footer is to
be
omitted if there are no items in the list.
Note:
Unlike xsl:on-empty
, the xsl:on-non-empty
instruction can appear anywhere in a sequence constructor, and can appear more
than once.
xsl:on-empty
and xsl:on-non-empty
InstructionsThe following non-normative algorithm explains one possible strategy for streamed
evaluation of a sequence constructor containing
xsl:on-empty
and/or xsl:on-non-empty
instructions.
The algorithm makes use of the following mutable variables:
L : a list of instructions awaiting evaluation. Initially empty.
R : a list of items to act as the result of the evaluation. Initially empty.
F : a boolean flag, initially false, to indicate whether any
non-vacuous items have been written to R by
ordinary instructions. The term ordinary instruction
means any node in the sequence constructor other than an
xsl:on-empty
or xsl:on-non-empty
instruction.
The algorithm is as follows:
The nodes in the sequence constructor are evaluated in document order.
When an xsl:on-non-empty
instruction is encountered,
then:
If F is true, the instruction is evaluated and the result is appended to R.
Otherwise, the instruction is appended to L.
When an ordinary instruction is evaluated:
The results of the evaluation are appended to R, in order.
When a non-vacuous item is about to be appended to R, and F is false, then before appending the item to R, the following actions are taken:
Any xsl:on-non-empty
instructions in
L are evaluated, in order, and their results are
appended to R.
F is set to true.
When an xsl:on-empty
instruction is encountered, then:
If F is true, the instruction is ignored.
Otherwise, the existing contents of R are discarded, the instruction is evaluated, and its results are appended to R.
Note:
The need to discard items from R arises only when all the items in R are vacuous. Streaming implementations may therefore need a limited amount of buffering to retain insignificant items until it is known whether they will be needed. However, in many common cases an optimized implementation will be able to discard vacuous items such as empty text nodes immediately, because when a node is being constructed using the rules in 5.7.1 Constructing Complex Content or 5.7.2 Constructing Simple Content, such items have no effect on the final outcome.
Otherwise, the instruction is evaluated and its results are appended to R.
The result of the sequence constructor is the list of items in R.
This example shows how the three instructions
xsl:where-populated
, xsl:on-empty
, and
xsl:on-non-empty
may be combined.
The following example generates a table containing the names and ages of a set of students; if there are no students, it substitutes a paragraph explaining this.
<div id="students"> <xsl:where-populated> <table> <xsl:on-non-empty> <thead> <tr><th>Name</th><th>Age</th></tr> </thead> </xsl:on-non-empty> <xsl:where-populated> <tbody> <xsl:for-each select="student/copy-of()"> <tr> <td><xsl:value-of select="name"/></td> <td><xsl:value-of select="age"/></td> </tr> </xsl:for-each> </tbody> </xsl:where-populated> </table> </xsl:where-populated> <xsl:on-empty> <p>There are no students</p> </xsl:on-empty> </div>
Explanation:
The xsl:where-populated
around the table
element ensures that if there is no thead
and no
tbody
, then there will be no table
.
The xsl:on-non-empty
surrounding the thead
element ensures that the thead
element is not output unless
the tbody
element is output.
The xsl:where-populated
around the tbody
element ensures that the tbody
element is not output unless
there is at least one table row (tr
).
The xsl:on-empty
around the p
element
ensures that if no table
is output, then the paragraph
There are no students
is output instead.
[Definition: The two
elements xsl:variable
and xsl:param
are referred to
as variable-binding elements
].
[Definition: The xsl:variable
element
declares a variable, which may be a global variable or a local
variable.]
[Definition: The xsl:param
element
declares a parameter, which may be a stylesheet parameter, a template parameter, a function parameter, or an xsl:iterate
parameter. A parameter is a
variable with the additional property that
its value can be set by the caller.]
[Definition: A variable is a binding between a name and a value. The value of a variable is any sequence (of nodes, atomic values, and/or function items), as defined in [XDM 3.0].]
<!-- Category: declaration -->
<!-- Category: instruction -->
<xsl:variable
name = eqname
select? = expression
as? = sequence-type
static? = boolean
visibility? = "public" | "private" | "final" | "abstract" >
<!-- Content: sequence-constructor -->
</xsl:variable>
The xsl:variable
element has a required
name
attribute, which specifies the name of the variable. The value of
the name
attribute is an EQName, which is expanded as described in
5.1.1 Qualified Names.
The xsl:variable
element has an optional as
attribute,
which specifies the required type of the
variable. The value of the as
attribute is a
SequenceType.
[Definition: The value of the variable is
computed using the expression given in the
select
attribute or the contained sequence constructor, as described in
9.3 Values of Variables and Parameters. This value is referred to as the
supplied value of the variable.] If the
xsl:variable
element has a select
attribute, then
the sequence constructor must be empty.
If the as
attribute is specified, then the supplied value of the variable is converted to
the required type, using the function
conversion rules.
[ERR XTTE0570] It is a type error if the supplied value of a variable cannot be converted to the required type.
If the as
attribute is omitted, the supplied value of the variable is used directly, and no conversion
takes place.
For the effect of the static
attribute, see 9.6 Static Variables and Parameters.
The visibility
attribute must not
be specified for a local variable: that is, it is allowed only when the parent
element is xsl:stylesheet
, xsl:transform
,
xsl:package
or
xsl:override
.
If the visibility
attribute is present with the value
abstract
then the select
attribute
must be absent and the contained sequence constructor
must be empty. In this situation there is no supplied value, and therefore the constraint
that the supplied value is consistent with the required type does not apply.
<!-- Category: declaration -->
<xsl:param
name = eqname
select? = expression
as? = sequence-type
required? = boolean
tunnel? = boolean
static? = boolean >
<!-- Content: sequence-constructor -->
</xsl:param>
The xsl:param
element may be used:
As a child of xsl:stylesheet
or xsl:package
, to
define a parameter to the transformation. Stylesheet parameters are set by the
calling application: see 2.3.2 Priming a Stylesheet.
As a child of xsl:template
to define a parameter to a
template, which may be supplied when the template is invoked using
xsl:call-template
, xsl:apply-templates
,
xsl:apply-imports
or xsl:next-match
.
Template parameters are set
by means of an xsl:with-param
child element of the invoking
instruction, as described in 9.10 Setting Parameter Values.
As a child of xsl:function
to define a parameter to a
stylesheet function, which may be supplied when the function is called from an
XPath expression. Function parameters are set
positionally by means of the argument list in an XPath function call.
As a child of xsl:iterate
to define a parameter that can vary
from one iteration to the next. Iteration parameters always take their default
values for the first iteration, and in subsequent iterations are set using an
xsl:with-param
child of the
xsl:next-iteration
instruction.
The attributes applicable to xsl:param
depend on its parent element in the stylesheet, as defined by the following
table:
Parent Element | name | select | as | required | tunnel | static |
---|---|---|---|---|---|---|
xsl:package |
mandatory | optional | optional | yes|no | no | yes|no |
xsl:stylesheet |
mandatory | optional | optional | yes|no | no | yes|no |
xsl:template |
mandatory | optional | optional | yes|no | yes|no | no |
xsl:function |
mandatory | disallowed | optional | yes | no | no |
xsl:iterate |
mandatory | mandatory | optional | no | no | no |
In the table, the entries for the name
,
select
, and as
attributes indicate whether the attribute
must appear, is optional, or must be absent; the entries for the
required
, tunnel
, and static
attributes
indicate the values that are permitted if the attribute is present, with the default
value shown in bold. (The value yes
can also be written
true
or 1
, while no
can also be written
false
or 0
.)
The name
attribute is mandatory: it specifies the name of the parameter.
The value of the name
attribute is an EQName, which is expanded as described in
5.1.1 Qualified Names.
[ERR XTSE0580] It is a static error if the values of
the name
attribute of two sibling
xsl:param
elements represent the same expanded QName.
If the xsl:param
element has a select
attribute, then
the sequence constructor must be empty.
The static
attribute can take the value yes
only on stylesheet parameters, and is explained in
9.5 Global Variables and Parameters.
Note:
Local variables may shadow template parameters and function parameters: see 9.9 Scope of Variables.
The optional tunnel
attribute may be used to indicate that a parameter
is a tunnel parameter. The default is
no
; the value yes
may be specified only for template parameters. Tunnel parameters are
described in 10.1.3 Tunnel Parameters
The xsl:param
element has an optional as
attribute,
which specifies the required type of the parameter. The value
of the as
attribute is a
SequenceType.
If the as
attribute is omitted, then the
required type is item()*
.
The supplied value of the parameter is the value supplied by the caller. If no value was supplied by the caller, and if the parameter is not mandatory, then the default value is used as the supplied value as described in 9.2.2 Default Values of Parameters.
The supplied value of the parameter is converted to the required type using the function conversion rules.
[ERR XTTE0590] It is a type error if the conversion of the supplied value of a parameter to its required type fails.
The optional required
attribute of
xsl:param
may be used to indicate that a stylesheet parameter or template parameter is
mandatory. The only value permitted for a function parameter
is yes
(these are always mandatory), and the only value permitted for
a parameter to xsl:iterate
is no
(these are always
initialized to a default value).
[Definition: A parameter is
explicitly mandatory if it is a function parameter, or if the
required
attribute is present and has the value
yes
.] If a parameter is explicitly mandatory, then the
xsl:param
element must be empty and
must not have a select
attribute.
If a parameter is not explicitly mandatory, then it may have a
default value. The default value is obtained by evaluating the expression given in the select
attribute or the contained sequence
constructor, as described in 9.3 Values of Variables and Parameters.
Note:
This specification does not dictate whether and when the default value of a
parameter is evaluated. For example, if the default is specified as
<xsl:param name="p"><foo/></xsl:param>
, then
it is not specified whether a distinct foo
element node will be
created on each invocation of the template, or whether the same
foo
element node will be used for each invocation. However, it
is permissible for the default value to depend on the values of other
parameters, or on the evaluation context, in which case the default must
effectively be evaluated on each invocation.
[Definition: An explicit
default for a parameter is indicated by the presence of either a
select
attribute or a non-empty sequence
constructor.]
[Definition: If a parameter that is
not explicitly mandatory has no explicit default value, then it has an implicit
default value, which is the empty sequence if there is an
as
attribute, or a zero-length string if not.]
[Definition: If a parameter
has an implicit default value which cannot be converted to
the required type (that is, if it has an as
attribute which does not permit the empty sequence), then the parameter is
implicitly mandatory.]
Note:
The effect of these rules is that specifying <xsl:param name="p"
as="xs:date" select="2"/>
is an error, but if the default value of
the parameter is never used, then the processor has discretion whether or not
to report the error. By contrast, <xsl:param name="p"
as="xs:date"/>
is treated as if required="yes"
had
been specified: the empty sequence is not a valid instance of
xs:date
, so in effect there is no default value and the
parameter is therefore treated as being mandatory.
Various errors can arise with regard to mandatory parameters when no value is
supplied. In the rules below, non-tunnel means: not having a
tunnel
attribute with the value yes
.
[ERR XTSE3520] It is a static error if a parameter to xsl:iterate
is
implicitly mandatory.
[ERR XTSE0690] It is a static error if a
package contains both (a) a
named template named T that is not overridden by another
named template of higher import precedence and that has an explicitly mandatory non-tunnel parameter named
P, and (b) an xsl:call-template
instruction whose name
attribute equals T and
that has no non-tunnel xsl:with-param
child element
whose name
attribute equals P. (All names are
compared as QNames.)
[ERR XTDE0700] It is a dynamic error if a template that has an explicitly mandatory or implicitly mandatory parameter is invoked without supplying a value for that parameter.
This includes the following cases:
The template is invoked using xsl:apply-templates
,
xsl:apply-imports
, or
xsl:next-match
and there is no
xsl:with-param
child whose name
and
tunnel
attributes match the corresponding attributes
of the mandatory parameter.
The mandatory parameter is a tunnel parameter, and the template is
invoked using xsl:call-template
, and there is no
xsl:with-param
child whose name
and
tunnel
attributes match the corresponding attributes
of the mandatory parameter.
The template is invoked as the entry point to the transformation, either by invoking an initial mode (2.3.3 Apply-Templates Invocation) or by invoking an initial template (2.3.4 Call-Template Invocation) and no value is supplied for the mandatory parameter by the calling application.
A variable-binding element may specify the supplied value of a variable or the default value of a parameter in four different ways.
If the variable-binding
element has a select
attribute, then the value of the
attribute must be an expression and the supplied
value of the variable is the value that results from evaluating
the expression. In this case, the content of the variable-binding element
must be empty.
If the variable-binding
element has empty content and has neither a select
attribute nor an as
attribute, then the supplied value of the variable is a
zero-length string. Thus
<xsl:variable name="x"/>
is equivalent to
<xsl:variable name="x" select="''"/>
If a variable-binding
element has no select
attribute and has non-empty
content (that is, the variable-binding element has one or more child nodes),
and has no as
attribute, then the content of the variable-binding
element specifies the supplied
value. The content of the variable-binding element is a sequence constructor; a new document
is constructed with a document node having as its children the sequence of
nodes that results from evaluating the sequence constructor and then applying
the rules given in 5.7.1 Constructing Complex Content. The value of
the variable is then a singleton sequence containing this document node. For
further information, see 9.4 Creating Implicit Document Nodes.
If a variable-binding
element has an as
attribute but no
select
attribute, then the supplied value is the sequence that results from evaluating the
(possibly empty) sequence
constructor contained within the variable-binding element (see
5.7 Sequence Constructors).
These combinations are summarized in the table below.
select attribute | as attribute | content | Effect |
---|---|---|---|
present | absent | empty | Value is obtained by evaluating the select
attribute
|
present | present | empty | Value is obtained by evaluating the select
attribute, adjusted to the type required by the as
attribute
|
present | absent | present | Static error |
present | present | present | Static error |
absent | absent | empty | Value is a zero-length string |
absent | present | empty | Value is an empty sequence, provided the as
attribute permits an empty sequence
|
absent | absent | present | Value is a document node whose content is obtained by evaluating the sequence constructor |
absent | present | present | Value is obtained by evaluating the sequence constructor,
adjusted to the type required by the as attribute
|
[ERR XTSE0620] It is a static error if a variable-binding element has a
select
attribute and has non-empty content.
The value of the following variable is the sequence of integers (1, 2, 3):
<xsl:variable name="i" as="xs:integer*" select="1 to 3"/>
The value of the following variable is an integer, assuming that the attribute
@size
exists, and is annotated either as an integer, or as
xs:untypedAtomic
:
<xsl:variable name="i" as="xs:integer" select="@size"/>
The value of the following variable is a zero-length string:
<xsl:variable name="z"/>
The value of the following variable is a document node containing an empty element as a child:
<xsl:variable name="doc"><c/></xsl:variable>
The value of the following variable is a sequence of integers (2, 4, 6):
<xsl:variable name="seq" as="xs:integer*"> <xsl:for-each select="1 to 3"> <xsl:sequence select=".*2"/> </xsl:for-each> </xsl:variable>
The value of the following variable is a sequence of parentless attribute nodes:
<xsl:variable name="attset" as="attribute()+"> <xsl:attribute name="x">2</xsl:attribute> <xsl:attribute name="y">3</xsl:attribute> <xsl:attribute name="z">4</xsl:attribute> </xsl:variable>
The value of the following variable is an empty sequence:
<xsl:variable name="empty" as="empty-sequence()"/>
The actual value of the variable depends on the supplied value, as described above, and the required type, which is
determined by the value of the as
attribute.
When a variable is used to select nodes by position, be careful not to do:
<xsl:variable name="n">2</xsl:variable> ... <xsl:value-of select="td[$n]"/>
This will output the values of all the td
elements, space-separated
(or with XSLT 1.0
behavior, the value of the first td
element), because the variable n
will be bound to a node, not a
number. Instead, do one of the following:
<xsl:variable name="n" select="2"/> ... <xsl:value-of select="td[$n]"/>
or
<xsl:variable name="n">2</xsl:variable> ... <xsl:value-of select="td[position()=$n]"/>
or
<xsl:variable name="n" as="xs:integer">2</xsl:variable> ... <xsl:value-of select="td[$n]"/>
A document node is created implicitly when evaluating an
xsl:variable
, xsl:param
, or
xsl:with-param
element that has non-empty content and that has no
as
attribute. The value of the variable is this newly constructed
document node.
The content of the
document node is formed from the result of evaluating the sequence constructor contained within the
variable-binding element, as described in 5.7.1 Constructing Complex Content.
Note:
The construct:
<xsl:variable name="tree"> <a/> </xsl:variable>
can be regarded as a shorthand for:
<xsl:variable name="tree" as="document-node()"> <xsl:document validation="preserve"> <a/> </xsl:document> </xsl:variable>
The base URI of the document node is taken from the base URI of the variable binding element in the stylesheet. (See Section 5.2 base-uri Accessor DM30 in [XDM 3.0])
No document-level validation takes place (which means, for example, that there is no checking that ID values are unique). However, type annotations on nodes within the new tree are copied unchanged.
Note:
The base URI of other nodes in the tree is determined by the rules for
constructing complex content (see 5.7.1 Constructing Complex Content).
The effect of these rules is that the base URI of a node in the temporary tree is
determined as if all the nodes in the temporary tree came from a single entity
whose URI was the base URI of the variable-binding element. Thus, the base URI of the document node
will be equal to the base URI of the variable-binding element, while an
xml:base
attribute within the temporary tree will change the base
URI for its parent element and that element’s descendants, just as it would
within a document constructed by parsing.
The document-uri
and unparsed-entities
properties of the
new document node are set to empty.
A temporary tree is available for
processing in exactly the same way as any source document. For example, its nodes
are
accessible using path expressions, and they can be processed using instructions such
as xsl:apply-templates
and xsl:for-each
. Also, the
key
and id
FO30 functions can be used to
find nodes within a temporary tree, by supplying the
document node at the root of the tree as an argument to the function or by making
it the context node.
The following stylesheet uses a temporary tree as the intermediate
result of a two-phase transformation, using different modes for the two phases (see 6.6 Modes). Typically,
the template rules in module phase1.xsl
will be declared with
mode="phase1"
, while those in module phase2.xsl
will
be declared with mode="phase2"
:
<xsl:stylesheet version="3.0" xmlns:xsl="http://www.w3.org/1999/XSL/Transform"> <xsl:import href="phase1.xsl"/> <xsl:import href="phase2.xsl"/> <xsl:variable name="intermediate"> <xsl:apply-templates select="/" mode="phase1"/> </xsl:variable> <xsl:template match="/"> <xsl:apply-templates select="$intermediate" mode="phase2"/> </xsl:template> </xsl:stylesheet>
Note:
The algorithm for matching nodes against template rules is exactly the same regardless which tree the nodes come from. If different template rules are to be used when processing different trees, then unless nodes from different trees can be distinguished by means of patterns, it is a good idea to use modes to ensure that each tree is processed using the appropriate set of template rules.
Both xsl:variable
and xsl:param
are allowed as
declaration elements: that is, they may
appear as children of the xsl:package
or
xsl:stylesheet
element.
[Definition: A top-level variable-binding element declares a global variable that is visible everywhere (except within its own declaration, and where it is shadowed by another binding).]
[Definition: A top-level
xsl:param
element declares a stylesheet
parameter. A stylesheet parameter is a global variable with the additional
property that its value can be supplied by the caller when a transformation is
initiated.] As described in 9.2 Parameters, a stylesheet
parameter may be declared as being mandatory, or may have a default value specified
for use when no value is supplied by the caller. The mechanism by which the caller
supplies a value for a stylesheet parameter is implementation-defined. An XSLT processor
must provide such a mechanism.
It is an error if no value is supplied for a mandatory stylesheet parameter [see ERR XTDE0050].
If a stylesheet contains more than one binding for a global variable of a particular name, then the binding with the highest import precedence is used.
[ERR XTSE0630] It is a static error if a package contains more than one non-hidden binding of a global variable with the same name and same import precedence, unless it also contains another binding with the same name and higher import precedence.
For a global variable or the default value of a stylesheet parameter, the expression or sequence constructor specifying the variable value is evaluated with a singleton focus as follows:
If the declaration appears within the top-level package
(including within an xsl:override
element in the top-level
package), then the focus is based on the global context item if supplied, or absent otherwise.
If the declaration appears within a library package, then the focus is absent.
An XPath error will be reported if the evaluation of a global variable or parameter references the context item, context position, or context size when the focus is absent. The values of other components of the dynamic context are the initial values as defined in 5.3.3 Initializing the Dynamic Context and 5.3.4 Additional Dynamic Context Components used by XSLT.
The visibility of a stylesheet parameter is always (implicitly) private
if the
parameter is static
, or public
if the parameter is
non-static.
Note:
This rule has the effect that after combining all the packages making up a stylesheet, the non-static stylesheet parameters whose values are required necessarily have distinct names, which simplifies the design of APIs.
For the effect of the static
attribute, see 9.6 Static Variables and Parameters.
The visibility
attribute must
not be specified for a local variable: that is, it is allowed only when
the parent element is xsl:package
, xsl:stylesheet
,
xsl:transform
, or xsl:override
.
If the visibility
attribute is present with the value
abstract
then the select
attribute
must be absent and the contained sequence constructor
must be empty. In this situation there is no supplied value, and therefore the constraint
that the supplied value is consistent with the required type does not apply.
The following example declares a global parameter para-font-size
,
which is referenced in an attribute
value template.
<xsl:param name="para-font-size" as="xs:string">12pt</xsl:param> <xsl:template match="para"> <fo:block font-size="{$para-font-size}"> <xsl:apply-templates/> </fo:block> </xsl:template>
The implementation must provide a mechanism allowing the user to supply a value
for the parameter para-font-size
when invoking the stylesheet; the
value 12pt
acts as a default.
Static variables and parameters are global variables and can be used in the same way
as other global variables. In addition, they can be used in
[xsl:]use-when
expressions and in shadow attributes.
[Definition: A top-level
variable-binding element
having the attribute static="yes"
declares a static
variable: that is, a global variable whose value is
known during static analysis of the stylesheet.]
[Definition: A static variable declared using an xsl:param
element
is referred to as a static parameter.]
The static
attribute must not
take the value yes
on an
xsl:variable
or xsl:param
element unless it is a
top-level element.
When the static
attribute is present with the value
yes
, the visibility
attribute must
not have a value other than private
.
Note:
This rule prevents static variables being overridden in another package. Since the
values of such variables may be used at compile time (for example, during
processing of [xsl:]use-when
expressions), the rule is necessary to
ensure that packages can be independently compiled.
It is possible to make the value of a static variable or parameter available in a using package by binding a non-static public variable to its value, for example:
<xsl:param name="DEBUG" static="yes" select="true()"/> <xsl:variable name="tracing" static="no" visibility="public" select="$DEBUG"/>
When the attribute static="yes"
is specified, the
xsl:variable
or xsl:param
element
must have empty content. In the case of
xsl:variable
the select
attribute must be present to
define the value of the variable [see ERR XTSE0010].
If the select
attribute is present, then it is evaluated using the rules
for static expressions.
The rules for the scope of static variables, and the
handling of duplicate declarations, are similar to the rules for non-static
variables, but with additional constraints designed to disallow forwards references.
The reason for disallowing forwards references is to ensure that
use-when
attributes can always be evaluated as early as possible, and
in particular to ensure that the value of a use-when
attribute never has
circular dependencies. The additional constraints are as follows:
The static context for evaluation of a static expression
only contains those static
variables visible within the containing package whose declarations
occur prior to the element containing the static expression in stylesheet tree
order. Stylesheet tree order is the order that results when all
xsl:import
and xsl:include
declarations
are replaced by the declarations in the imported or included stylesheet module.
A static variable is not in scope within its own declaration.
If two static variables declared within the same package have the same name,
the one that has higher import precedence is used (it is a
consequence of rules defined elsewhere that there cannot be more than one
declaration with highest import precedence). However, if the declaration with
higher import precedence occurs after the one with lower import precedence in
stylesheet tree order, then the two declarations must be consistent. For this
purpose two declarations are consistent if (a) they are either both
xsl:variable
elements, or both xsl:param
elements, and (b) if the variables are initialized (that is, if the elements
are xsl:variable
elements, or if they are
xsl:param
elements and no value for the parameter is
externally supplied) then the values of both variables must be identicalFO30, and must not contain
function items.
Note:
This rule ensures that when a static variable reference is encountered, the value of the most recently declared static variable with that name can be used, knowing that this value cannot be overridden by a subsequent declaration having higher import precedence.
[ERR XTSE3450] It is a static error if a
variable declared with static="yes"
is inconsistent with
another static variable of the same name that is declared earlier in
stylesheet tree order and that has lower import precedence.
[Definition: A static expression is an XPath expression whose value must be computed during static analysis of the stylesheet.]
Static expressions appear in a number of contexts, in particular:
In [xsl:]use-when
attributes (see 3.13.1 Conditional Element Inclusion);
In the select
attribute of static variable
declarations (xsl:variable
or xsl:param
with
static="yes"
);
In shadow attributes (see 3.13.2 Shadow Attributes).
There are no syntactic constraints on the XPath expression that can be used as a static expression. However, there are severe constraints on the information provided in its evaluation context. These constraints are designed to ensure that the expression can be evaluated at the earliest possible stage of stylesheet processing, without any dependency on information contained in the stylesheet itself or in any source document.
Specifically, the components of the static and dynamic context are defined by the following two tables:
Component | Value |
---|---|
XPath 1.0 compatibility mode | false |
Statically known namespaces | determined by the in-scope namespaces for the containing element in the stylesheet |
Default element/type namespace | determined by the xpath-default-namespace attribute if present
(see 5.1.2 Unprefixed Lexical QNames in Expressions and Patterns); otherwise the null namespace
|
Default function namespace | The standard function namespace |
In-scope schema types | The type definitions that would be available in the absence of any
xsl:import-schema declaration
|
In-scope element declarations | None |
In-scope attribute declarations | None |
In-scope variables | The static
variables visible within the containing package whose
declarations occur prior to the element containing the static expression in
stylesheet tree order. Stylesheet tree order is the order that results when
all xsl:import and xsl:include
declarations are replaced by the declarations in the imported or included
stylesheet module. A static variable is not in scope within its own
declaration, and it is in scope only within its
declaring package, not in any using packages. If two static
variables satisfying this rule have the same name and are both in scope, the
one that appears most recently in stylesheet tree order is used; as a
consequence of rules defined elsewhere this will always be consistent with
the declaration having highest import precedence.
|
Context item static type | Absent |
Statically known function signatures | The functions defined in [Functions and Operators 3.0] in the fn
and math namespaces, together with:
function-available will return false in
respect of such functions, and function-lookup FO30 will
fail to find them. The effect of this rule is to ensure that
function-available returns true in respect of
functions that can be called within the static expression. It also has the
effect that these extension functions will be recognized within the static
expression itself; however, the fact that a function is available in this
sense gives no guarantee that a call on the function will succeed.
|
Statically known collations | Implementation-defined |
Default collation | The Unicode Codepoint Collation |
Static Base URI | The base URI of the containing element in the stylesheet document (see Section 5.2 base-uri Accessor DM30) |
Statically known documents | Implementation-defined |
Statically known collections | Implementation-defined |
Statically known default collection type | Implementation-defined |
Statically known decimal formats | A single unnamed decimal format
equivalent to the decimal format that is created by an
xsl:decimal-format declaration with no attributes.
|
Component | Value |
---|---|
Context item, position, and size | Absent |
Variable values | A value for every variable present in the in-scope variables. For static parameters where an external value is supplied: the externally-supplied value of the parameter. In all other cases: the value of the variable as defined in 9.3 Values of Variables and Parameters. |
Named functions | The function implementation corresponding to each function signature in the statically known function signatures |
Current dateTime | Implementation-defined |
Implicit timezone | Implementation-defined |
Default language | Implementation-defined |
Default calendar | Implementation-defined |
Default place | Implementation-defined |
Available documents | Implementation-defined |
Available collections | Implementation-defined |
Default collection | Implementation-defined |
Environment variables | Implementation-defined |
Within a stylesheet module, all static
expressions are evaluated in a single execution scopeFO30. This need not be the same execution scope as that
used for static expressions in other stylesheet modules, or as that used when
evaluating XPath expressions appearing elsewhere in the stylesheet module. This means
that a function such as current-date
FO30 will return the same
result when called in different [xsl:]use-when
expressions within the
same stylesheet module, but will not necessarily return the same result as the same
call in an [xsl:]use-when
expression within a different stylesheet
module, or as a call on the same function executed during the transformation
proper.
If a static error is present in a static expression, it is treated in the same way as any other static error in the stylesheet module. If a dynamic error occurs during evaluation of a static expression, it is treated as a static error in the analysis of the stylesheet, while retaining its original error code.
[Definition: As well as being allowed as a
declaration, the
xsl:variable
element is also allowed in sequence constructors. Such a variable
is known as a local variable.]
An xsl:param
element may also be used to create a variable binding
with local scope:
[Definition: An
xsl:param
element may appear as a child of an
xsl:template
element, before any
non-xsl:param
children of that element. Such a parameter
is known as a template parameter. A template parameter is a
local variable with the
additional property that its value can be set when the template is called,
using any of the instructions xsl:call-template
,
xsl:apply-templates
, xsl:apply-imports
,
or xsl:next-match
.]
[Definition: An
xsl:param
element may appear as a child of an
xsl:function
element, before any
non-xsl:param
children of that element. Such a parameter
is known as a function parameter. A function parameter is a
local variable with the
additional property that its value can be set when the function is called,
using a function call in an XPath expression.]
An xsl:param
element may appear as a child
of an xsl:iterate
instruction, before any
non-xsl:param
children of that element. This defines a
parameter whose value may be initialized on entry to the iteration, and which
may be varied each time round the iteration by use of an
xsl:with-param
element in the
xsl:next-iteration
instruction.
The result of evaluating a local xsl:variable
or
xsl:param
element (that is, the contribution it makes to the
result of the sequence constructor it is part of) is an empty
sequence.
For any variable-binding element, there is a region (more specifically, a set of nodes) of the stylesheet within which the binding is visible. The set of variable bindings in scope for an XPath expression consists of those bindings that are visible at the point in the stylesheet where the expression occurs.
A global variable binding
element is visible everywhere in the containing package
(including other stylesheet modules) except within the xsl:variable
or
xsl:param
element itself and any region where it is shadowed by another variable binding.
(For rules regarding the visibility of the variable
in other packages, see 3.5.3.1 Visibility of Components.)
A local variable binding element is visible for all following siblings and their descendants, with the following exceptions:
It is not visible in any region where it is shadowed by another variable binding.
It is not visible within the subtree rooted at an xsl:fallback
instruction that is a sibling of the variable binding element.
It is not visible within the subtree rooted at an
xsl:catch
instruction that is a sibling of the variable
binding element.
The binding is not visible for the xsl:variable
or
xsl:param
element itself.
If a binding is visible for an element then it is visible for every attribute of that element and for every text node child of that element.
[Definition: A binding shadows another
binding if the binding occurs at a point where the other binding is visible, and
the bindings have the same name. ] It is not an error if a binding
established by a local xsl:variable
or xsl:param
shadows a global binding. In this case, the
global binding will not be visible in the region of the stylesheet where it is shadowed by the other binding.
The following is allowed:
<xsl:param name="x" select="1"/> <xsl:template name="foo"> <xsl:variable name="x" select="2"/> </xsl:template>
It is also not an error if a binding established by a local
xsl:variable
element shadows
a binding established by another local xsl:variable
or
xsl:param
.
The following is not an error, but the effect is probably not what was intended.
The template outputs <x value="1"/>
, because the declaration of
the inner variable named $x
has no effect on the value of the outer
variable named $x
.
<xsl:variable name="x" select="1"/> <xsl:template name="foo"> <xsl:for-each select="1 to 5"> <xsl:variable name="x" select="$x+1"/> </xsl:for-each> <x value="{$x}"/> </xsl:template>
Note:
Once a variable has been given a value, the value cannot subsequently be changed. XSLT does not provide an equivalent to the assignment operator available in many procedural programming languages.
This is because an assignment operator would make it harder to create an implementation that processes a document other than in a batch-like way, starting at the beginning and continuing through to the end.
As well as global variables and local variables, an XPath expression may also declare range variables for use locally within an expression. For details, see [XPath 3.0].
Where a reference to a variable occurs in an XPath expression, it is resolved first by reference to range variables that are in scope, then by reference to local variables and parameters, and finally by reference to global variables and parameters. A range variable may shadow a local variable or a global variable. XPath also allows a range variable to shadow another range variable.
<xsl:with-param
name = eqname
select? = expression
as? = sequence-type
tunnel? = boolean >
<!-- Content: sequence-constructor -->
</xsl:with-param>
Parameters are passed to templates using the xsl:with-param
element.
The required
name
attribute specifies the name of the template parameter (the variable the value
of whose binding is to be replaced). The value of the name
attribute is
an EQName,
which is expanded as described in 5.1.1 Qualified Names.
The xsl:with-param
element is also used
when passing parameters to an iteration of the xsl:iterate
instruction, or to a dynamic invocation of an XPath expression using
xsl:evaluate
. In consequence,
xsl:with-param
may appear within
xsl:apply-templates
, xsl:apply-imports
,
xsl:call-template
, xsl:evaluate
, xsl:next-iteration
,
and xsl:next-match
. (Arguments to stylesheet functions, however, are supplied
as part of an XPath function call: see 10.3 Stylesheet Functions.)
[ERR XTSE0670] It is a static error
if two or more sibling xsl:with-param
elements have
name
attributes that represent the same expanded QName.
The value of the parameter is specified in the same way as for
xsl:variable
and xsl:param
(see 9.3 Values of Variables and Parameters), taking account of the values of the select
and as
attributes and the content of the xsl:with-param
element, if any.
Note:
It is possible to have an as
attribute on the
xsl:with-param
element that differs from the as
attribute on the corresponding xsl:param
element.
In this situation, the supplied value of the parameter will first be processed
according to the rules of the as
attribute on the
xsl:with-param
element, and the resulting value will then be
further processed according to the rules of the as
attribute on the
xsl:param
element.
For example, suppose the supplied value is a node with type annotation
xs:untypedAtomic
, and the xsl:with-param
element
specifies as="xs:integer"
, while the xsl:param
element specifies as="xs:double"
. Then the node will first be
atomized and the resulting untyped atomic value will be cast to
xs:integer
. If this succeeds, the xs:integer
will
then be promoted to an xs:double
.
The focus used for computing the value specified by
the xsl:with-param
element is the same as that used for its parent instruction.
The optional tunnel
attribute may be used to indicate that a parameter
is a tunnel parameter. The default is
no
. Tunnel parameters are described in 10.1.3 Tunnel Parameters. They are used only when passing parameters to templates: for an
xsl:with-param
element that is a child of
xsl:evaluate
or xsl:next-iteration
the
tunnel
attribute must either be omitted or take
the value no
.
In other cases it is a dynamic error if the template that is
invoked declares a template parameter
with required="yes"
and no value for this parameter is supplied by the
calling instruction. [see ERR XTDE0700]
[Definition: A circularity is said to exist if a construct such as a global variable, an attribute set, or a key, is defined in terms of itself. For example, if the expression or sequence constructor specifying the value of a global variable X references a global variable Y, then the value for Y must be computed before the value of X. A circularity exists if it is impossible to do this for all global variable definitions.]
The following two declarations create a circularity:
<xsl:variable name="x" select="$y+1"/> <xsl:variable name="y" select="$x+1"/>
The definition of a global variable can be circular even if no other variable is
involved. For example the following two declarations (see 10.3 Stylesheet Functions for an explanation of the
xsl:function
element) also create a circularity:
<xsl:variable name="x" select="my:f()"/> <xsl:function name="my:f"> <xsl:sequence select="$x"/> </xsl:function>
The definition of a variable is also circular if the evaluation of the variable
invokes an xsl:apply-templates
instruction and the variable is
referenced in the pattern used in the match
attribute of any template
rule in the stylesheet. For example the
following definition is circular:
<xsl:variable name="x"> <xsl:apply-templates select="//param[1]"/> </xsl:variable> <xsl:template match="param[$x]">1</xsl:template>
Similarly, a variable definition is circular if it causes a call on the
key
function, and the definition of that key refers to that variable in its match
or
use
attributes. So the following definition is circular:
<xsl:variable name="x" select="my:f(10, /)"/> <xsl:function name="my:f"> <xsl:param name="arg1"/> <xsl:param name="top"/> <xsl:sequence select="key('k', $arg1, $top)"/> </xsl:function> <xsl:key name="k" match="item[@code=$x]" use="@desc"/>
An attribute set is circular if its use-attribute-sets
attribute
references itself, directly or indirectly. So the following definitions establish
a circularity:
<xsl:attribute-set name="a" use-attribute-sets="b"/> <xsl:attribute-set name="b" use-attribute-sets="a"/>
Because attribute sets can invoke functions, global variables, or templates, and can also include instructions such as literal result elements that themselves invoke attribute sets, examples of circularity involving attribute sets can be more complex than this simple example illustrates. It is also possible to construct examples in which self-reference among attribute sets could be regarded as (terminating or non-terminating) recursion. However, because such self-references have no practical utility, any requirement to evaluate an attribute set in the course of its own evaluation is considered an error.
Note:
In previous versions of this specification, self-reference among attribute sets was defined as a static error. In XSLT 3.0 it is not always detectable statically, because attribute sets can bind to each other across package boundaries. Nevertheless, in cases where a processor can detect a static circularity, it can report this error during the analysis phase, under the general provision for reporting dynamic errors during stylesheet analysis if execution can never succeed.
[ERR XTDE0640] In general, a circularity in a stylesheet is a dynamic error. However, as with all other dynamic errors, an implementation will signal the error only if it actually executes the instructions and expressions that participate in the circularity. Because different implementations may optimize the execution of a stylesheet in different ways, it is implementation-dependent whether a particular circularity will actually be signaled.
For example, in the following declarations, the function declares a local variable
$b
, but it returns a result that does not require the variable to be
evaluated. It is implementation-dependent whether the value is actually evaluated, and
it is therefore implementation-dependent whether the circularity is signaled as an
error:
<xsl:variable name="x" select="my:f(1)"/> <xsl:function name="my:f"> <xsl:param name="a"/> <xsl:variable name="b" select="$x"/> <xsl:sequence select="$a + 2"/> </xsl:function>
Although a circularity is detected as a dynamic error,
there is no unique instruction whose evaluation triggers the error condition, and
the
result of any attempt to catch the error using an xsl:try
instruction is therefore implementation-dependent.
Circularities usually involve global variables or parameters, but they can also exist
between key definitions (see 20.2 Keys),
between named attribute sets (see 10.2 Named Attribute Sets), or between any combination of these constructs. For
example, a circularity exists if a key definition invokes a function that references
an attribute set that calls the key
function, supplying the name
of the original key definition as an argument.
Circularity is not the same as recursion. Stylesheet functions (see 10.3 Stylesheet Functions) and named templates (see 10.1 Named Templates) may call other functions and named templates without restriction. With careless coding, recursion may be non-terminating. Implementations are required to signal circularity as a dynamic error, but they are not required to detect non-terminating recursion.
The requirement to report a circularity as a dynamic error overrides the rule that dynamic errors in evaluating patterns are normally masked (by treating the pattern as not matching).
This section describes three constructs that can be used to provide subroutine-like functionality that can be invoked from anywhere in the stylesheet: named templates (see 10.1 Named Templates), named attribute sets (see 10.2 Named Attribute Sets), and stylesheet functions (see 10.3 Stylesheet Functions).
[Definition: The following constructs are classified as invocation constructs: the
instructions xsl:call-template
,
xsl:apply-templates
, xsl:apply-imports
, and
xsl:next-match
; XPath function calls that bind to stylesheet functions; XPath dynamic
function calls; the functions accumulator-before
and
accumulator-after
; the [xsl:]use-attribute-sets
attribute. These all have the characteristic that they can cause evaluation of
constructs that are not lexically contained within the calling
construct.]
<!-- Category: instruction -->
<xsl:call-template
name = eqname >
<!-- Content: xsl:with-param* -->
</xsl:call-template>
[Definition: Templates can be invoked by
name. An xsl:template
element with a name
attribute
defines a named template.] The value of the
name
attribute is an EQName, which is expanded as described in
5.1.1 Qualified Names. If an xsl:template
element has a
name
attribute, it may, but need not, also have a match
attribute. An xsl:call-template
instruction invokes a template by
name; it has a required
name
attribute that identifies the template to be invoked. Unlike
xsl:apply-templates
, the xsl:call-template
instruction does not change the focus.
The match
, mode
and priority
attributes on an
xsl:template
element have no effect when the template is invoked by an
xsl:call-template
instruction. Similarly, the name
and visibility
attributes on an
xsl:template
element have no effect when the template is invoked
by an xsl:apply-templates
instruction.
[ERR XTSE0650] It is a static error if a package contains an
xsl:call-template
instruction whose name
attribute does not match the name
attribute of any named template
visible in the containing package (this
includes any template defined in this package, as well as templates accepted
from used packages whose visibility in this package is not
hidden
). For more details of the process of binding the
called template, see 3.5.3.5 Binding References to Components.
[ERR XTSE0660] It is a static error if a package contains more than one non-hidden template with the same name and the same import precedence, unless it also contains a template with the same name and higher import precedence.
The target template
for an xsl:call-template
instruction is established using the
binding rules described in 3.5.3.5 Binding References to Components. This will always
be a template whose name
attribute matches the name
attribute of the xsl:call-template
instruction. It may be a
template defined in the same package that has higher import precedence than any other template
with this name, or it may be a template accepted from a used package, or (if the
template is not defined as private
or final
) it may be
an overriding template in a package that uses the containing package.
The result of evaluating an xsl:call-template
instruction is the
sequence produced by evaluating the sequence
constructor contained in its target template (see 5.7 Sequence Constructors).
The template name xsl:initial-template
is specially
recognized in that it provides a default entry point for stylesheet execution (see
2.3 Initiating a Transformation.)
The xsl:context-item
element is used as a child of
xsl:template
, to declare the required type of the context
item. It is intended particularly for use when the containing template is called
using an xsl:call-template
instruction, but it also constrains
the context item if the same template is invoked using
xsl:apply-templates
, xsl:apply-imports
, or
xsl:next-match
.
<xsl:context-item
as? = item-type
use? = "required" | "optional" | "absent" />
If the as
attribute is present then its value must be an ItemTypeXP30. If the attribute is
omitted this is equivalent to specifying as="item()"
.
[ERR XTSE3088] It is a static error if the as
attribute is
present when use="absent"
is specified.
A type error is signaled if the supplied
context item does not match its required type. No attempt is made to convert the
context item to the required type (using the function conversion rules or
otherwise). The error code is the same as for xsl:param
:
[see ERR XTTE0590].
If an xsl:context-item
element is present as
the first child element of xsl:template
, it defines whether the
template requires a context item to be supplied, and if so, what the type of the
context item must be. If this template is the initial named template, then this has the effect of placing
constraints on the global context
item for the transformation as a whole.
The use
attribute of
xsl:context-item
takes the value required
,
optional
, or absent
.
The default is
optional
.
If the containing xsl:template
element has no name
attribute then the only permitted value is required
.
If the value required
is specified, then there must be a
context item. (This will automatically be the case if the template is
invoked using xsl:apply-templates
,
xsl:apply-imports
, or xsl:next-match
,
but not if it is invoked using xsl:call-template
.)
If the value optional
is specified, or if the attribute is
omitted, or if the xsl:context-item
element is omitted,
then there may or may not be a context item when the template is
invoked.
If the value absent
is specified, then the contained sequence
constructor, and any xsl:param
elements, are evaluated with
an absent focus.
Note:
It is not an error to call such a template with a non-absent focus; the
context item is simply treated as absent. This option is useful when
streaming, since an xsl:call-template
instruction may
become streamable if the referenced template is declared to make no use
of the context item.
The processor may
signal a type error statically if the
required context item type is incompatible with the match
pattern,
that is, if no item that satisfies the match pattern can also satisfy the required
context item type.
The xsl:context-item
element plays no part in
deciding whether and when the template rule is invoked in response to an
xsl:apply-templates
instruction.
[ERR XTTE3090] It is a type error if the
xsl:context-item
child of xsl:template
specifies that a context item is required and none is supplied by the
caller, that is, if the context item is absent at the point where
xsl:call-template
is evaluated.
Parameters are passed to named templates using the xsl:with-param
element as a child of the xsl:call-template
instruction.
[ERR XTSE0680] In the case of xsl:call-template
, it is a static error to pass a non-tunnel
parameter named x to a template that does not have a non-tunnel
template
parameter named x, unless the xsl:call-template
instruction is processed with
XSLT 1.0
behavior. This is not an error in the case of xsl:apply-templates
,
xsl:apply-imports
, and xsl:next-match
; in
these cases the parameter is simply ignored.
The optional tunnel
attribute may be used to indicate that a
parameter is a tunnel parameter. The
default is no
. Tunnel parameters are described in 10.1.3 Tunnel Parameters.
This example defines a named template for a numbered-block
with a
parameter to control the format of the number.
<xsl:template name="numbered-block"> <xsl:param name="format">1. </xsl:param> <fo:block> <xsl:number format="{$format}"/> <xsl:apply-templates/> </fo:block> </xsl:template> <xsl:template match="ol//ol/li"> <xsl:call-template name="numbered-block"> <xsl:with-param name="format">a. </xsl:with-param> </xsl:call-template> </xsl:template>
[Definition: A parameter passed to a template may be defined as a tunnel parameter. Tunnel parameters have the property that they are automatically passed on by the called template to any further templates that it calls, and so on recursively.] Tunnel parameters thus allow values to be set that are accessible during an entire phase of stylesheet processing, without the need for each template that is used during that phase to be aware of the parameter.
Note:
Tunnel parameters are conceptually similar to the dynamically scoped variables found in some functional programming languages (for example, early versions of LISP), where evaluating a variable reference involves searching down the dynamic call stack for a matching variable name. There are two main use cases for the feature:
They provide a way to supply context information that might be needed by many
templates (for example, the fact that the output is to be localized for a particular
language),
but which cannot be placed in a global variable because it might vary from one phase
of processing
to another. Passing such information using conventional parameters is error-prone,
because
a single xsl:apply-templates
or xsl:call-template
instruction
that neglects to pass the information on will lead to failures that are difficult
to diagnose.
They are particularly useful when writing a customization layer for an existing stylesheet. For example, if you want to override a template rule that displays chemical formulae, you might want the new rule to be parameterized so you can apply the house-style of a particular scientific journal. Tunnel parameters allow you to pass this information to the overriding template rule without requiring modifications to all the intermediate template rules. Again, a global variable could be used, but only if the same house-style is to be used for all chemical formulae processed during a single transformation.
A tunnel parameter is created by
using an xsl:with-param
element that specifies
tunnel="yes"
. A template that requires access to the value of a
tunnel parameter must declare it using an xsl:param
element that
also specifies tunnel="yes"
.
On any template call using an xsl:apply-templates
,
xsl:call-template
, xsl:apply-imports
or
xsl:next-match
instruction, a set of tunnel parameters is passed from the
calling template to the called template. This set consists of any parameters
explicitly created using <xsl:with-param tunnel="yes">
,
overlaid on a base set of tunnel parameters. If the
xsl:apply-templates
, xsl:call-template
,
xsl:apply-imports
or xsl:next-match
instruction has an xsl:template
declaration as an ancestor
element in the stylesheet, then the base set consists of the tunnel parameters
that were passed to that template; otherwise (for example, if the instruction is
within a global variable declaration, an attribute
set declaration, or a stylesheet function), the base set is empty. If a parameter created
using <xsl:with-param tunnel="yes">
has the same expanded QName as a parameter in the base
set, then the parameter created using xsl:with-param
overrides
the parameter in the base set; otherwise, the parameter created using
xsl:with-param
is added to the base set.
When a template accesses the value of a tunnel
parameter by declaring it with <xsl:param
tunnel="yes">
, this does not remove the parameter from the base set
of tunnel parameters that is passed on to any templates called by this
template.
Two sibling xsl:with-param
elements must have
distinct parameter names, even if one is a tunnel parameter and the other is not. Equally, two sibling
xsl:param
elements representing template parameters
must have distinct parameter names, even if one is a tunnel parameter and the other is not.
However, the tunnel parameters that are implicitly passed in a template call
may have names that duplicate the names of non-tunnel
parameters that are explicitly passed on the same call.
Tunnel parameters are not passed in calls to stylesheet functions.
All other options of xsl:with-param
and
xsl:param
are available with tunnel parameters just as with non-tunnel
parameters. For example, parameters may be declared as mandatory or optional, a
default value may be specified, and a required type may be specified. If any
conversion is required from the supplied value of a tunnel parameter to the
required type specified in xsl:param
, then the converted value is
used within the receiving template, but the value that is passed on in any further
template calls is the original supplied value before conversion. Equally, any
default value is local to the template: specifying a default value for a tunnel
parameter does not change the set of tunnel parameters that is passed on in
further template calls.
Tunnel parameters are passed unchanged through a built-in template rule (see 6.7 Built-in Template Rules).
If a tunnel parameter is declared in an
xsl:param
element with the attribute
tunnel="yes"
, and if the
parameter is explicitly
or implicitly mandatory,
then a dynamic error occurs [see ERR XTDE0700] if the set of tunnel parameters passed to the template does not
include a parameter with a matching expanded
QName.
Suppose that the equations in a scientific paper are to be sequentially numbered, but that the format of the number depends on the context in which the equations appear. It is possible to reflect this using a rule of the form:
<xsl:template match="equation"> <xsl:param name="equation-format" select="'(1)'" tunnel="yes"/> <xsl:number level="any" format="{$equation-format}"/> </xsl:template>
At any level of processing above this level, it is possible to determine how the equations will be numbered, for example:
<xsl:template match="appendix"> ... <xsl:apply-templates> <xsl:with-param name="equation-format" select="'[i]'" tunnel="yes"/> </xsl:apply-templates> ... </xsl:template>
The parameter value is passed transparently through all the intermediate layers
of template rules until it reaches the rule with match="equation"
.
The effect is similar to using a global variable, except that the parameter can
take different values during different phases of the transformation.
<!-- Category: declaration -->
<xsl:attribute-set
name = eqname
use-attribute-sets? = eqnames
visibility? = "public" | "private" | "final" | "abstract"
streamable? = boolean >
<!-- Content: xsl:attribute* -->
</xsl:attribute-set>
Attribute sets generate named collections of attributes that can be used repeatedly on
different constructed elements. The xsl:attribute-set
declaration is
used to declare attribute sets. The required
name
attribute specifies the name of the attribute set. The value of the
name
attribute is an EQName
, which is expanded as
described in 5.1.1 Qualified Names.
[Definition: An attribute set is
defined as a set of xsl:attribute-set
declarations in the same
package that share the same expanded QName.]
The content of the xsl:attribute-set
element consists of zero or
more xsl:attribute
instructions that are evaluated to produce the
attributes in the set.
Attribute sets are used by specifying a
use-attribute-sets
attribute on the xsl:element
or xsl:copy
instruction, or by specifying an
xsl:use-attribute-sets
attribute on a literal result element. An
attribute set may be defined in terms of other attribute sets by using the
use-attribute-sets
attribute on the
xsl:attribute-set
element itself. The value of the
[xsl:]use-attribute-sets
attribute is in each case a
whitespace-separated list of names of attribute sets. Each name is specified as an
EQName,
which is expanded as described in 5.1.1 Qualified Names.
[ERR XTSE0710] It is a static error if the value
of the use-attribute-sets
attribute of an
xsl:copy
, xsl:element
, or
xsl:attribute-set
element, or the
xsl:use-attribute-sets
attribute of a literal result element, is not
a whitespace-separated sequence of EQNames, or if it contains an
EQName that does not match the name
attribute of any
xsl:attribute-set
declaration in the containing package.
An attribute set may be considered
as comprising a sequence of instructions, each of which is either an
xsl:attribute
instruction or an attribute set invocation. Starting with the declarations making up
an attribute set, this sequence of instructions can be generated by the following
rules:
The relevant attribute set declarations (that is, all declarations of attribute sets within a package sharing the same expanded QName) are considered in order: first in increasing order of import precedence, and within each precedence, in declaration order.
Each declaration is expanded to a sequence of instructions as follows.
First, one attribute set invocation is generated for
each EQName present in the use-attribute-sets
attribute, if
present, retaining the order in which the EQNames appear. This is followed
by the sequence of contained xsl:attribute
instructions, in
order.
[Definition: An
attribute set invocation is a pseudo-instruction
corresponding to a single EQName appearing within an
[xsl:]use-attribute-sets
attribute; the effect of the
pseudo-instruction is to cause the referenced attribute set to be evaluated.]
Similarly, an [xsl:]use-attribute-sets
attribute of an xsl:copy
, xsl:element
, or
xsl:attribute-set
element, or of a literal result element, is
expanded to a sequence of attribute set
invocations, one for each EQName in order.
An attribute set is a named component, and the binding of QNames appearing in an attribute set invocation to attribute set components follows the rules in 3.5.3.5 Binding References to Components.
The following two (mutually recursive) rules define how
an [xsl:]use-attribute-set
attribute is expanded:
An attribute set is evaluated by evaluating each of the
contained attribute set
invocations and xsl:attribute
instructions in
order, to deliver a sequence of attribute nodes.
An attribute set invocation is evaluated by evaluating the attribute set to which it is bound, as determined by the rules in 3.5.3.5 Binding References to Components.
For rules regarding cycles in attribute set declarations, see 9.11 Circular Definitions.
Note:
The effect of an attribute set invocation on the dynamic
context is the same as the effect of an xsl:call-template
instruction. In particular, it does not change the focus.
Although attribute sets are often defined with fixed values, or with values
that depend only on global variables, it is possible to define an attribute set
in such a way that the values of the constructed attributes are dependent on
the context item.
Note:
In all cases the result of evaluating an attribute set is subsequently used to create the attributes of an element node, using the rules in 5.7.1 Constructing Complex Content. The effect of those rules is that when the result of evaluating the attribute set contains attributes with duplicate names, the last duplicate wins. The optimization rules allow a processor to avoid evaluating or validating an attribute if it is able to determine that the attribute will subsequently be discarded as a duplicate.
The visibility
attribute determines the
potential visibility of the attribute set in packages other than the containing
package. If the visibility
attribute is present on any of the
xsl:attribute-set
declarations making up the definition of an
attribute set (that is, all declarations within the same
package sharing the same name), then it must be present, with
the same value, on every xsl:attribute-set
declaration making up
the definition of that attribute set.
If the visibility
attribute is present with the
value abstract
then there must be no xsl:attribute
children and no use-attribute-sets
attribute.
An attribute set may be designated as
streamable by including the attribute streamable="yes"
on each
xsl:attribute-set
declaration making up the attribute set. If
any xsl:attribute-set
declaration for an attribute set has the
attribute streamable="yes"
, then every
xsl:attribute-set
declaration for that attribute set
must have the attribute streamable="yes"
.
An attribute set is guaranteed-streamable if all the following conditions are satisfied:
Every xsl:attribute-set
declaration for the attribute set has the attribute
streamable="yes"
.
Every xsl:attribute-set
declaration for the attribute set
is grounded and motionless according to the analysis in 19.8.6 Classifying Attribute Sets.
Specifying streamable="yes"
on an
xsl:attribute-set
element declares an intent that the
attribute set should be streamable, either
because it is guaranteed-streamable, or because it takes
advantage of streamability extensions offered by a particular
processor. The consequences of declaring the attribute set to be
streamable when it is not in fact guaranteed streamable depend on the conformance
level of the processor, and are explained in 19.10 Streamability Guarantees.
[ERR XTSE0730] If an xsl:attribute
set element specifies
streamable="yes"
then every attribute set referenced in its
use-attribute-sets
attribute (if present) must also specify
streamable="yes"
.
Note:
It is common for attribute sets to create attributes with constant values, and
such attribute sets will always be grounded and motionless and therefore streamable.
Although such cases are fairly simple for a processor to detect, references to
attribute sets are not guaranteed streamable unless the attribute set is
declared with the attribute streamable="yes"
, which should
therefore be used if interoperable streaming is required.
Attribute sets are evaluated as follows:
The xsl:copy
and xsl:element
instructions
have a use-attribute-sets
attribute. The sequence of attribute
nodes produced by evaluating this attribute is prepended to the sequence
produced by evaluating the sequence
constructor contained within the instruction.
Literal result elements
allow an xsl:use-attribute-sets
attribute, which is evaluated
in the same way as the use-attribute-sets
attribute of
xsl:element
and xsl:copy
. The sequence
of attribute nodes produced by evaluating this attribute is prepended to the
sequence of attribute nodes produced by evaluating the attributes of the
literal result element, which in turn is prepended to the sequence produced
by evaluating the sequence
constructor contained with the literal result element.
The xsl:attribute
instructions are evaluated using the same
focus as is used for evaluating the
sequence constructor contained by the
element that is the parent of the [xsl:]use-attribute-sets
attribute forming
the initial input to the algorithm. However, the static context for the evaluation
depends on the position of the xsl:attribute
instruction in the
stylesheet: thus, only local variables declared within an
xsl:attribute
instruction, and global variables, are
visible.
Note:
The above rule means that for an xsl:copy
element with a select
attribute, the focus for evaluating any referenced attribute
sets is the node selected by the select
attribute, rather than the context item of
the xsl:copy
instruction.
The set of attribute nodes produced by expanding
xsl:use-attribute-sets
may include several attributes with the
same name. When the attributes are added to an element node, only the last of the
duplicates will take effect.
The way in which each instruction uses the results of expanding the
[xsl:]use-attribute-sets
attribute is described in the
specification for the relevant instruction: see 11.1 Literal Result Elements, 11.2 Creating Element Nodes Using xsl:element
, and 11.9 Copying Nodes.
The result of evaluating an attribute set is a sequence of attribute nodes. Evaluating the same attribute set more than once can produce different results, because although an attribute set does not have parameters, it may contain expressions or instructions whose value depends on the evaluation context.
Each attribute node produced by expanding an attribute set has a type annotation determined by the rules for the
xsl:attribute
instruction that created the attribute node: see
11.3.1 Setting the Type Annotation for a Constructed Attribute Node. These type annotations
may be preserved, stripped, or replaced as determined by the rules for the
instruction that creates the element in which the attributes are used.
The following example creates a named attribute
set
title-style
and uses it in a template rule.
<xsl:template match="chapter/heading"> <fo:block font-stretch="condensed" xsl:use-attribute-sets="title-style"> <xsl:apply-templates/> </fo:block> </xsl:template> <xsl:attribute-set name="title-style"> <xsl:attribute name="font-size">12pt</xsl:attribute> <xsl:attribute name="font-weight">bold</xsl:attribute> </xsl:attribute-set>
The following example creates a named attribute set base-style
and
uses it in a template rule with multiple specifications of the attributes:
is specified only in the attribute set
is specified in the attribute set, is specified on the literal result
element, and in an xsl:attribute
instruction
is specified in the attribute set, and on the literal result element
is specified in the attribute set, and in an
xsl:attribute
instruction
Stylesheet fragment:
<xsl:attribute-set name="base-style"> <xsl:attribute name="font-family">Univers</xsl:attribute> <xsl:attribute name="font-size">10pt</xsl:attribute> <xsl:attribute name="font-style">normal</xsl:attribute> <xsl:attribute name="font-weight">normal</xsl:attribute> </xsl:attribute-set> <xsl:template match="o"> <fo:block xsl:use-attribute-sets="base-style" font-size="12pt" font-style="italic"> <xsl:attribute name="font-size">14pt</xsl:attribute> <xsl:attribute name="font-weight">bold</xsl:attribute> <xsl:apply-templates/> </fo:block> </xsl:template>
Result:
<fo:block font-family="Univers" font-size="14pt" font-style="italic" font-weight="bold"> ... </fo:block>
[Definition: An
xsl:function
declaration declares the name, parameters, and
implementation of a stylesheet function that can be called from any
XPath expression within the stylesheet
(subject to visibility
rules).]
<!-- Category: declaration -->
<xsl:function
name = eqname
as? = sequence-type
visibility? = "public" | "private" | "final" | "abstract"
streamability? = "unclassified" | "absorbing" | "inspection" | "filter" | "shallow-descent"
| "deep-descent" | "ascent" | eqname
override-extension-function? = boolean
[override]? = boolean
new-each-time? = "yes" | "true" | "1" | "no" | "false" | "0" | "maybe"
cache? = boolean >
<!-- Content: (xsl:param*, sequence-constructor) -->
</xsl:function>
The xsl:function
declaration defines a stylesheet function that can be called from
any XPath expression used in the stylesheet (including an XPath expression used
within a predicate in a pattern). The
name
attribute specifies the name of the function. The value of the
name
attribute is an EQName, which is expanded as described in
5.1.1 Qualified Names.
An xsl:function
declaration can only appear as a top-level element in a stylesheet module.
The content of the xsl:function
element consists of zero or more
xsl:param
elements that specify the formal arguments of the
function, followed by a sequence
constructor that defines the value to be returned by the function.
The name of the function is given by the name
attribute; the arguments are defined by child xsl:param
elements;
and the return type is defined by the as
attribute. Together these
definitions constitute the function signature.
[ERR XTSE0740] It is a static error if a stylesheet function has a name that is in no namespace.
Note:
To prevent the namespace declaration used for the function name appearing in
the result document, use the exclude-result-prefixes
attribute on
the xsl:stylesheet
element: see 11.1.3 Namespace Nodes for Literal Result Elements.
The name of the function must not be in a reserved namespace: [see ERR XTSE0080]
[Definition: The arity of a stylesheet
function is the number of xsl:param
elements in the function
definition.] Optional arguments are not allowed.
Note:
Functions are not polymorphic. Although the XPath function call mechanism allows two functions to have the same name and different arity, it does not allow them to be distinguished by the types of their arguments.
The xsl:param
elements define the formal parameters to the
function. These are interpreted positionally. When the function is called using a
function call in an XPath expression, the
first argument supplied is assigned to the first xsl:param
element, the second argument supplied is assigned to the second
xsl:param
element, and so on.
Because arguments to a stylesheet function call must all
be specified, the xsl:param
elements within an
xsl:function
element must not specify
a default value: this means they must be empty, and
must not have a select
attribute.
[ERR XTSE0760] It is a static error if an xsl:param
child of
an xsl:function
element has either a select
attribute or non-empty content.
The as
attribute of the xsl:param
element defines
the required type of the parameter. The rules for converting the values of the
actual arguments supplied in the function call to the types required by each
xsl:param
element, and the
errors that can occur, are defined in [XPath 3.0]. The
rules that apply are those for the case where XPath 1.0 compatibility mode is set to false
.
If the as
attribute is omitted, no conversion takes place and any
value is accepted.
The result of the function is the result of evaluating the contained sequence constructor.
Within the sequence constructor, the focus is initially absent; this means that any attempt to reference the context item, context position, or context size is a dynamic error. (See [ERR XPDY0002] XP30.)
It is not possible within the body of the stylesheet function to access the values of local variables that were in scope in the place where the function call was written. Global variables, however, remain available.
The optional as
attribute indicates the required type of the result of the function.
The value of the as
attribute is a
SequenceType.
[ERR XTTE0780] If the as
attribute is specified, then the result evaluated by the sequence constructor (see
5.7 Sequence Constructors) is converted to the required
type, using the function
conversion rules. It is a type
error if this conversion fails. If the as
attribute is omitted, the calculated result is
used as supplied, and no conversion takes place.
If the visibility
attribute is present with the
value abstract
then the sequence constructor
defining the function body must be empty.
The XPath specification states that the function that is executed as the result of a function call is identified by looking in the in-scope functions of the static context for a function whose name and arity matches the name and number of arguments in the function call. In XSLT 3.0, final determination of the function to be called cannot be made until all packages have been assembled: see 3.5.3.5 Binding References to Components.
An xsl:function
declaration defines a stylesheet function which forms a
component in its containing package,
unless
there is another stylesheet function with the same name and arity, and higher import precedence, or
the override-extension-function
or override
attribute has the value no
and there is already a function with
the same name and arity in the in-scope
functions.
The visibility of the
function in other packages depends on the value of the visibility
attribute and other factors, as described in 3.5 Packages.
The optional override-extension-function
attribute defines what
happens if this function has the same name and arity as a function provided by the implementer or made available in
the static context using an implementation-defined mechanism. If the override-extension-function
attribute
has the value yes
, then this function is used in preference; if it
has the value no
, then the other function is used in preference. The
default value is yes
.
Note:
Specifying override-extension-function="yes"
ensures
interoperable behavior: the same code will execute with all processors.
Specifying override-extension-function="no"
is useful when
writing a fallback implementation of a function that is available with some
processors but not others: it allows the vendor’s implementation of the
function (or a user’s implementation written as an extension function)
to be used in preference to the stylesheet implementation, which is useful when
the extension function is more efficient.
The override-extension-function
attribute does not
affect the rules for deciding which of several stylesheet functions with the same
name and arity takes precedence.
The override
attribute is a deprecated synonym of override-extension-function
,
retained for compatibility with XSLT 2.0. If both attributes are present then they
must have the same value.
[ERR XTSE0770] It is a static error for a package to
contain two or more xsl:function
declarations with the same expanded QName, the same arity, and the same import
precedence, unless there is another xsl:function
declaration with the same
expanded QName and arity, and
a higher import precedence.
When the xsl:function
declaration appears as a
child of xsl:override
, there must be a
stylesheet function with the same expanded
QName and arity in the package referenced by the containing
xsl:use-package
element; the visibility of that function must be public
or
abstract
, and the overriding and overridden functions
must have the same argument types and result type.
The streamability
attribute of xsl:function
is used
to assign the function to one of a number of streamability categories. The various
categories, and their effect on the streamability of function calls, are described
in 19.8.5 Classifying Stylesheet Functions.
The streamability category of a function characterizes the way in which the
function processes any streamed nodes supplied in the first argument to the
function. (In general, streamed nodes cannot be supplied in other arguments,
unless they are atomized by the function conversion rules.)
The streamability
attribute is therefore not applicable unless the
function takes at least one argument.
[ERR XTSE3155] It is a static error if an xsl:function
element with no
xsl:param
children has a streamability
attribute with any value other than unclassified
.
If a stylesheet
function with a particular expanded
QName and arity exists in the
stylesheet, then a call to the function-lookup
FO30 function
supplying that name and arity will return the function as a value. This applies
only if the static context for the call on function-lookup
FO30
includes the stylesheet function, which implies that the function is visible in
the containing package.
The function-available
function, when
called with a particular expanded QName
and arity, returns true if and only if a call on
function-lookup
FO30 with the same arguments, in the same
static context, would return a function item.
Note:
For legacy reasons there is also a single-argument version of
function-available
, which returns true if there is a
function with the given name regardless of arity.
The standard rules for
function-lookup
FO30 require that if the supplied name and
arity identify a context-dependent function such as name#0
FO30
or lang#1
FO30 (call it F), then the returned
function value includes in its closure a copy of the static and dynamic context of
the call to function-lookup
FO30, and the context item for a
subsequent dynamic call of F is taken from this saved context. In the
case where the context item is a node in a streamed input document, saving the
node is not possible. In this case, therefore, the context is saved with an absent
focus, so the call on F will fail with a dynamic error saying that
there is no context item available.
Stylesheet functions have been designed to be largely deterministic: unless a stylesheet function calls some extension function which is itself nondeterministic, the function will return results that depend only on the supplied arguments. This property (coupled with the fact that the effect of calling extension functions is entirely implementation-dependent) enables a processor to implement various optimizations, such as removing invariant function calls from the body of a loop, or combining common subexpressions.
One exception to the intrinsic determinism of stylesheet functions arises because
constructed nodes have distinct identity. This means that when a function that
creates a new node is called, two calls on the function will return nodes that can
be distinguished: for example, with such a function, f:make-node() is
f:make-node()
will return false.
Three classes of functions can be identified:
DeterministicFO31
functions: as the term is defined in [Functions and Operators 3.1],
these offer a guarantee that when a function is called repeatedly with the
same arguments, it returns the same results. A classic example is the
doc
FO30 function, which offers the guarantee that
doc($X) is doc($X)
: that is, two calls supplying the same
URI return the same node.
Proactive functions: these offer the guarantee that each invocation of the function causes a single execution of the function body, or behaves exactly as if it did so. In particular this means that when the function creates new nodes, it creates new nodes on each invocation. By default, stylesheet functions are proactive.
Elidable functions: these offer no guarantee of determinism, and no
guarantee of proactive evaluation. If the function creates new nodes, then
two calls on the function with the same arguments may or may not return the
same nodes, at the implementation’s discretion. Examples of elidable functions include
the [Functions and Operators 3.1] functions
analyze-string
FO30 and
json-to-xml
.
The new-each-time
attribute of xsl:function
allows a
stylesheet function to be assigned to one of these three categories. The value
new-each-time="no"
means the function is deterministic; the value
new-each-time="yes"
means it is proactive; and the value
new-each-time="maybe"
means it is elidable.
The definition of determinismFO31 requires a definition of what it means for a function to be called twice with “the same” arguments and to return “the same” result. This is defined in [Functions and Operators 3.1], specifically by the definition of the term identicalFO31.
Processors have considerable freedom to optimize execution of stylesheets, and of
function calls in particular, but the strategies that are adopted must respect the
specification as to whether functions are deterministic, proactive, or elidable.
For example, consider a function call that appears within an
xsl:for-each
instruction, where the supplied arguments to the
function do not depend on the context item or on any variables declared within the
xsl:for-each
instruction. A possible optimization is to
execute the function call only once, rather than executing it repeatedly each time
round the loop (this is sometimes called loop-lifting). This optimization is safe
when the function is deterministic or elidable, but it requires great care if the
function is proactive; it is permitted only if the processor is able to determine
that the results of stylesheet execution are equivalent to the results that would
be obtained if the optimization had not been performed. Declaring a function call
to be elidable (by writing new-each-time="maybe"
) makes it more
likely that an implementation will be able to apply this optimization, as well as
other optimizations such as caching or memoization.
The cache
attribute is an optimization hint which the processor can
use or ignore at its discretion; however it should be taken
seriously, because it may make a difference to whether execution of a stylesheet
is practically feasible or not.
The default value is cache="no".
The value cache="yes"
encourages the processor to retain memory of
previous calls of this function
during the same transformation and to reuse results from this memory whenever
possible. The default value cache="no"
encourages the
processor not to retain memory of previous calls.
In all cases the results must respect the semantics. If a function is proactive
(new-each-time="yes"
) then caching of results may be infeasible,
especially if the function result can include nodes; but it is not an error to
request it, since some implementations may be able to provide caching, or
analogous optimizations, even for proactive functions. (One possible strategy is
to return a copy of the cached result, thus creating the illusion that the
function has been evaluated anew.)
Note:
Memoization is essentially a trade-off between time and space; a memoized function can be expected to use more memory to deliver faster execution. Achieving an optimum balance may require configuring the size of the cache that is used; implementations may use additional extension attributes or other mechanisms to provide finer control of this kind.
Note:
Memoization of a function generally involves creating an associative table (for
example, a hash map) that maps argument values to function results. To get this
right, it is vital that the key for this table should correctly reflect what it
means for two function calls to have “the same arguments”. Does it matter, for
example, that one call passes the xs:string
value "Paris", while
another passes the xs:untypedAtomic
value "Paris"? If the function
is declared with new-each-time="maybe"
, then the rules say that
these cannot be treated as “the same arguments”: the definition of identicalFO31 requires them to have exactly the same type
as well as being equal. However, an implementation that is able to determine
that all references to the argument within the function body only make use of
its string value might be able to take advantage of this fact, and thus perform
more efficient caching.
The following example creates a recursive stylesheet function named str:reverse
that reverses
the words in a supplied sentence, and then invokes this function from within a
template rule.
<xsl:transform xmlns:xsl="http://www.w3.org/1999/XSL/Transform" xmlns:xs="http://www.w3.org/2001/XMLSchema" xmlns:str="http://example.com/namespace" version="3.0" exclude-result-prefixes="str"> <xsl:function name="str:reverse" as="xs:string"> <xsl:param name="sentence" as="xs:string"/> <xsl:sequence select="if (contains($sentence, ' ')) then concat(str:reverse(substring-after($sentence, ' ')), ' ', substring-before($sentence, ' ')) else $sentence"/> </xsl:function> <xsl:template match="/"> <output> <xsl:value-of select="str:reverse('DOG BITES MAN')"/> </output> </xsl:template> </xsl:transform>
An alternative way of writing the same function is to implement the conditional logic at the XSLT level, thus:
<xsl:function name="str:reverse" as="xs:string"> <xsl:param name="sentence" as="xs:string"/> <xsl:choose> <xsl:when test="contains($sentence, ' ')"> <xsl:sequence select="concat(str:reverse(substring-after($sentence, ' ')), ' ', substring-before($sentence, ' '))"/> </xsl:when> <xsl:otherwise> <xsl:sequence select="$sentence"/> </xsl:otherwise> </xsl:choose> </xsl:function>
The following example illustrates the use of the as
attribute in a
function definition. It returns a string containing the representation of its
integer argument, expressed as a roman numeral. For example, the function call
num:roman(7)
will return the string "vii"
. This
example uses the xsl:number
instruction, described in 12 Numbering. The xsl:number
instruction returns a text
node, and the function conversion
rules are invoked to convert this text node to the type declared
in the xsl:function
element, namely xs:string
. So
the text node is atomized to a
string.
<xsl:function name="num:roman" as="xs:string"> <xsl:param name="value" as="xs:integer"/> <xsl:number value="$value" format="i"/> </xsl:function>
XPath 3.0 introduces the ability to pass function items as arguments to a function. A function that takes function items as arguments is known as a higher-order function.
The following example is a higher-order function that operates on any tree-structured data, for example an organization chart. Given as input a function that finds the direct subordinates of a node in this tree structure (for example, the direct reports of a manager, or the geographical subdivisions of an administrative area), it determines whether one object is present in the subtree rooted at another object (for example, whether one person is among the staff managed directly or indirectly by a manager, or whether one parcel of land is contained directly or indirectly within another parcel). The function does not check for cycles in the data.
<xsl:function name="f:is-subordinate" as="xs:boolean"> <xsl:param name="superior" as="node()"/> <xsl:param name="subordinate" as="node()"/> <xsl:param name="get-direct-children" as="function(node()) as node()*"/> <xsl:sequence select=" some $sub in $get-direct-children($superior) satisfies ($sub is $subordinate or f:is-subordinate($sub, $subordinate, $get-direct-children))"/> </xsl:function>
Given source data representing an organization chart in the form of elements such as:
<employee id="P57832" manager="P68951"/>
the following function can be defined to get the direct reports of a manager:
<xsl:function name="f:direct-reports" as="element(employee)*"> <xsl:param name="manager" as="element(employee)"/> <xsl:sequence select="$manager/../employee [@manager = $manager/@id]"/> </xsl:function>
It is then possible to test whether one employee $E
reports
directly or indirectly to another employee $M
by means of the
function call:
f:is-subordinate($M, $E, f:direct-reports#1)
<!-- Category: instruction -->
<xsl:evaluate
xpath = expression
as? = sequence-type
base-uri? = { uri }
with-params? = expression
context-item? = expression
namespace-context? = expression
schema-aware? = { boolean } >
<!-- Content: (xsl:with-param | xsl:fallback)* -->
</xsl:evaluate>
The xsl:evaluate
instruction constructs an XPath expression in the
form of a string, evaluates the expression in a specified context, and returns the
result of the evaluation.
The expression given as the value of the xpath
attribute is evaluated
and the result is converted to a string using the function conversion rules.
[Definition: The string that results
from evaluating the expression in the xpath
attribute is referred to
as the target expression.]
[ERR XTDE3160] It is a dynamic error if the target expression is not a valid expression (that is, if a static error occurs when analyzing the string according to the rules of the XPath specification).
The as
attribute, if present, indicates the required type of the result.
If the attribute is absent, the required type is item()*
, which allows
any result. The result of evaluating the target
expression is converted to the required type using the function conversion rules. This may
cause a type error if conversion is not
possible. The result after conversion is returned as the result of the
xsl:evaluate
instruction.
The target expression may contain variable references; the values
of such variables may be supplied using an xsl:with-param
child
instruction if the names of the variables are known statically, or using a map
supplied as the value of the expression in the with-params
attribute if
the names are only known dynamically. If the with-params
attribute is
present then it must contain an expression whose value, when evaluated, is of type
map(xs:QName, item()*)
(see 21 Maps for details of
maps).
[ERR XTTE3165] It is a type error if the
result of evaluating the expression in the with-params
attribute of the xsl:evaluate
instruction is
anything other than a single map of type
map(xs:QName, item()*)
.
The static contextXP30 for the target expression is as follows:
XPath 1.0 compatibility mode is false
.
Statically known namespaces and default element/type namespace:
if the namespace-context
attribute is present, then its
value is an expression whose
required type is a single node. The expression is evaluated, and the
in-scope namespaces of the resulting node are used as the statically
known namespaces for the target expression. The binding for the
default namespace in the in-scope namespaces is used as the default
namespace for elements and types in the target expression.
[ERR XTTE3170] It is a type error if the
result of evaluating the namespace-context
attribute of the xsl:evaluate
instruction is
anything other than a single node.
if the namespace-context
attribute is absent, then the
in-scope namespaces of the xsl:evaluate
instruction
(with the exception of any binding for the default namespace) are used
as the statically known namespaces for the target expression, and the
value of the innermost [xsl:]xpath-default-namespace
attribute, if any, is used as the default namespace for elements and
types in the target expression.
Note:
XPath 3.0 allows expanded names to be written in a context-independent
way using the syntax Q{namespace-uri}local-name
Default function namespace: the standard function namespace.
In-scope schema definitions: if the schema-aware
attribute is
present and has the effective
value
yes
, then the in-scope schema definitions from the stylesheet
context (that is, the schema definitions imported using
xsl:import-schema
). Otherwise, the built-in types (see
3.14 Built-in Types).
In-scope variables: the names of the in-scope variables
are the union of the names appearing in the name
attribute of
the contained xsl:with-param
elements, and the names
present as keys in the map obtained by evaluating the
with-params
attribute, if present. The corresponding type is
item()*
in the case of a name found as a key in the
with-params
map, or the type named in the as
attribute of xsl:with-param
child (defaulting to
item()*
) otherwise.
If a variable name is present both the static
xsl:with-param
children and also in the dynamic
with-params
map, the value from the latter takes
precedence.
Note:
Variables declared in the stylesheet in xsl:variable
or
xsl:param
elements are not in-scope
within the target expression.
Function signatures:
All functions defined in [Functions and Operators 3.0] in the
fn
and math
namespaces;
All functions in the fn
and map
namespaces whose definitions
appear both in this specification and also in [Functions and Operators 3.1];
If the processor supports XPath 3.1, all functions defined in [Functions and Operators 3.1]
in the fn
, math
, map
, and array
namespaces;
Constructor functions for named simple types included in the in-scope schema definitions;
All user-defined functions present in the containing package provided their visibility
is
not hidden
or private
;
An implementation-defined set of extension functions.
Note that this set deliberately excludes XSLT-defined functions in the
standard function
namespace including for example, key
,
current-group
, and
system-property
. A list of these functions is in
G.2 List of XSLT-defined functions.
Statically known collations: the same as the collations available at this point in the stylesheet.
Default collation: the same as the default collation defined at this point
in the stylesheet (for example, by use of the
[xsl:]default-collation
attribute)
Base URI: if the base-uri
attribute is present, then its
effective value; otherwise,
the base URI of the xsl:evaluate
instruction.
Statically known documents: the empty set
Statically known collections: the empty set
Statically known default collection type: node()*
The dynamic context for evaluation of the target expression is as follows:
The context item, position, and size depend on the result of evaluating the
expression in the context-item
attribute. If this attribute is
absent, or if the result is an empty sequence, then the context item,
position, and size for evaluation of the target expression are all absent. If the result of evaluating the
context-item
expression is a single item, then the target
expression is evaluated with a singleton focus based on
this item.
[ERR XTTE3210] If the result of evaluating the context-item
expression
is a sequence containing more than one
item, then a type error is signaled.
The variable values consists of the values
bound to parameters defined either in the contained
xsl:with-param
elements, which are evaluated as
described in 9.3 Values of Variables and Parameters, or in the map that results
from evaluation of the expression in the with-params
attribute;
if the same QName is bound in both, the value in the
with-params
map takes precedence.
The XSLT-specific aspects of the dynamic context described in 5.3.4 Additional Dynamic Context Components used by XSLT are all absent.
The named functionsXP30
(representing the functions accessible using function-available
or function-lookup
FO30)
include all the functions available in the static context, and may also include an
additional
implementation-defined set of functions that are available dynamically but not statically.
All other aspects of the dynamic context are the same as the dynamic context
for the xsl:evaluate
instruction itself, except that an implementation may
restrict
the availability of external resources (for example, available documents)
or provide options to restrict their availability, for security
reasons.
Note:
For example, a processor may disallow access using the
doc
FO30 or collection
FO30 functions
to documents in local filestore.
xsl:evaluate
instructionThe XPath expression is evaluated in the same execution scopeFO30 as the calling XSLT transformation; this
means that the results of deterministicFO30 functions such as doc
FO30 or
current-dateTime
FO30 will be consistent between the calling
stylesheet and the called XPath expression.
It is a dynamic error if evaluation of the XPath expression fails with a dynamic error. The XPath-defined error code is used unchanged.
Note:
Implementations wanting to avoid the cost of repeated compilation of the same XPath expression should cache the compiled form internally.
Stylesheet authors need to be aware of the security risks
associated with the use of xsl:evaluate
. The instruction should
not be used to execute code from an untrusted source. To avoid the risk of code
injection, user-supplied data should never be inserted into the expression using
string concatenation, but should always be referenced by use of parameters.
xsl:evaluate
as an optional featureThe xsl:evaluate
instruction is newly introduced in XSLT 3.0. It
is part of the dynamic evaluation feature, which is an optional feature of the
specification (see 27.6 Dynamic Evaluation Feature). An XSLT 3.0
processor may disable the feature, or allow users to disable
the feature. The processor may be able to determine during
static analysis whether or not the feature is available, or it
may only be able to determine this during dynamic
evaluation. In the first case we refer to the feature being statically
disabled, in the second case to it being dynamically
disabled.
If the feature is statically disabled, then:
A call to element-available('xsl:evaluate')
returns false,
wherever it appears;
A call to system-property('xsl:supports-dynamic-evaluation')
returns the string "no"
, wherever it appears;
If an xsl:evaluate
instruction has an
xsl:fallback
child, fallback processing takes place;
No static error is raised if an xsl:evaluate
instruction is
present in the stylesheet (an error occurs only if it is actually
evaluated).
If the feature is dynamically disabled, then:
A call to element-available('xsl:evaluate')
appearing in a
static expression (for
example, in an [xsl:]use-when
attribute) returns true;
A call to element-available('xsl:evaluate')
appearing anywhere
else returns false;
A call to system-property('xsl:supports-dynamic-evaluation')
appearing in a static
expression (for example, in an [xsl:]use-when
attribute) returns the string "yes"
;
A call to system-property('xsl:supports-dynamic-evaluation')
appearing anywhere else returns the string "no"
;
If an xsl:evaluate
instruction has an
xsl:fallback
child, fallback processing takes place;
In the absence of an xsl:fallback
child, a dynamic error is
raised if an xsl:evaluate
instruction is evaluated. The
dynamic error may be caught using xsl:try
and
xsl:catch
.
If a processor supports the dynamic evaluation feature, it is implementation-defined how the processor allows users to disable dynamic evaluation and it is implementation-defined whether the mechanism is static or dynamic.
[ERR XTDE3175] It is a dynamic error if an
xsl:evaluate
instruction is evaluated when use of
xsl:evaluate
has been statically or dynamically
disabled.
In consequence of these rules, the recommended approach for stylesheet authors to
write code that works whether or not xsl:evaluate
is enabled is
to use an xsl:fallback
child instruction. For example:
<xsl:variable name="isValid" as="xs:boolean"> <xsl:evaluate xpath="$validityCondition"> <xsl:fallback><xsl:sequence select="true()"/></xsl:fallback> </xsl:evaluate> </xsl:variable>
Note:
There may be circumstances where it is inappropriate to allow use of
xsl:evaluate
. For example:
There may be security risks associated with the ability to execute code from an untrusted source, which cannot be inspected during static analysis.
There may be environments where the available computing resources are sufficient to enable pre-compiled stylesheets to be executed, but not to enable XPath expressions to be compiled into executable code.
Processors that implement xsl:evaluate
should provide
mechanisms allowing calls on xsl:evaluate
to be disabled.
Implementations may disable the feature by default, and they may disable it
unconditionally.
xsl:evaluate
A common requirement is to sort a table on the value of an expression which is selected at run-time, perhaps by supplying the expression as a string-valued parameter to the stylesheet. Suppose that such an expression is supplied to the parameter:
<xsl:param name="sortkey" as="xs:string" select="'@name'"/>
Then the data may be sorted as follows:
<xsl:sort> <xsl:evaluate xpath="$sortkey" as="xs:string" context-item="."/> </xsl:sort>
Note the importance in this use case of caching the compiled expression, since it is evaluated repeatedly, once for each item in the list being sorted.
If the function-lookup
FO30 function were not available
in the standard library, then a very similar function could be implemented like this:
<xsl:function name="f:function-lookup"> <xsl:param name="name" as="xs:QName"/> <xsl:param name="arity" as="xs:integer"/> <xsl:try> <xsl:evaluate xpath="'Q{' || namespace-uri-from-QName($name) || '}' || local-name-from-QName($name) || '#' || $arity"> <xsl:with-param name="name" as="xs:QName" select="$name"/> <xsl:with-param name="arity" as="xs:integer" select="$arity"/> </xsl:evaluate> <xsl:catch errors="err:XTDE3160" select="()"/> </xsl:try> </xsl:function>
Note:
The main difference between this function and the standard function-lookup
FO30
function is that there are differences in the functions that are visible: for example
function-lookup
FO30
gives access to user-defined functions with private visibility, whereas xsl:evaluate
does not.
The xsl:evaluate
instruction uses the supplied QName and arity
to construct an expression of the form
Q{namespace-uri}local#arity
, which is then evaluated to return a
function item representing the requested function.
This section describes instructions that directly create new nodes, or sequences of nodes, atomic values, and/or function items.
[Definition: In a sequence constructor, an element in the stylesheet that does not belong to the XSLT namespace and that is not an extension instruction (see 24.2 Extension Instructions) is classified as a literal result element.] A literal result element is evaluated to construct a new element node with the same expanded QName (that is, the same namespace URI, local name, and namespace prefix). The result of evaluating a literal result element is a node sequence containing one element, the newly constructed element node.
The content of the element is a sequence constructor (see 5.7 Sequence Constructors). The sequence obtained by evaluating this sequence constructor, after prepending any attribute nodes produced as described in 11.1.2 Attribute Nodes for Literal Result Elements and namespace nodes produced as described in 11.1.3 Namespace Nodes for Literal Result Elements, is used to construct the content of the element, following the rules in 5.7.1 Constructing Complex Content
The base URI of the new element is copied from the base URI of the literal result
element in the stylesheet, unless the content of the new element includes an
xml:base
attribute, in which case the base URI of the new element is
the value of that attribute, resolved (if it is a relative URI reference) against the base URI of the literal result element in
the stylesheet. (Note, however, that this is only relevant when creating a parentless
element. When the literal result element is copied to form a child of an element or
document node, the base URI of the new copy is taken from that of its new
parent.)
The attributes xsl:type
and xsl:validation
may be used
on a literal result element to invoke validation of the contents of the element
against a type definition or element declaration in a schema, and to determine the
type annotation that the new element node will carry. These
attributes also affect the type annotation carried by any elements and attributes
that have the new element node as an ancestor. These two attributes are both
optional, and if one is specified then the other must be
omitted.
The value of the xsl:validation
attribute, if present, must be one of
the values strict
, lax
, preserve
, or
strip
. The value of the xsl:type
attribute, if
present, must be an EQName identifying a type definition that is present in
the in-scope schema
components for the stylesheet. Neither attribute may be specified as
an attribute value template.
The effect of these attributes is described in 25.4 Validation.
Attribute nodes for a literal result element may be created by including
xsl:attribute
instructions within the sequence constructor. Additionally,
attribute nodes are created corresponding to the attributes of the literal result
element in the stylesheet, and as a result of expanding the
xsl:use-attribute-sets
attribute of the literal result element, if
present.
The sequence that is used to construct the content of the literal result element (as described in 5.7.1 Constructing Complex Content) is the concatenation of the following four sequences, in order:
The sequence of namespace nodes produced as described in 11.1.3 Namespace Nodes for Literal Result Elements.
The sequence of attribute nodes produced by expanding the
xsl:use-attribute-sets
attribute (if present) following the
rules given in 10.2 Named Attribute Sets
The attributes produced by processing the attributes of the literal result element itself, other than attributes in the XSLT namespace. The way these are processed is described below.
The sequence produced by evaluating the contained sequence constructor, if the element is not empty.
Note:
The significance of this order is that an attribute produced by an
xsl:attribute
, xsl:copy
, or
xsl:copy-of
instruction in the content of the literal
result element takes precedence over an attribute produced by expanding an
attribute of the literal result element itself, which in turn takes precedence
over an attribute produced by expanding the xsl:use-attribute-sets
attribute. This is because of the rules in 5.7.1 Constructing Complex Content, which specify that when two or more
attributes in the sequence have the same name, all but the last of the
duplicates are discarded.
Although the above rules place namespace nodes before attributes, this is not strictly necessary, because the rules in 5.7.1 Constructing Complex Content allow the namespaces and attributes to appear in any order so long as both come before other kinds of node. The order of namespace nodes and attribute nodes in the sequence has no effect on the relative position of the nodes in document order once they are added to a tree.
Each attribute of the literal result element, other than an attribute in the XSLT namespace, is processed to produce an attribute for the element in the result tree.
The value of such an attribute is interpreted as an attribute value template: it can
therefore contain expressions contained in
curly brackets ({}
). The new attribute node will have the same
expanded QName (that is, the same
namespace URI, local name, and namespace prefix) as the attribute in the
stylesheet tree, and its string value
will be the same as the effective
value of the attribute in the stylesheet tree. The type annotation on the attribute will
initially be xs:untypedAtomic
, and the typed value of the attribute node will be the same as its string value.
Note:
The eventual type annotation of the attribute in the
result tree depends on the
xsl:validation
and xsl:type
attributes of the
parent literal result element, and on the instructions used to create its
ancestor elements. If the xsl:validation
attribute is set to
preserve
or strip
, the type annotation will be
xs:untypedAtomic
, and the typed
value of the attribute node will be the same as its string value. If the
xsl:validation
attribute is set to strict
or
lax
, or if the xsl:type
attribute is used, the
type annotation on the attribute will be set as a result of the schema
validation process applied to the parent element. If neither attribute is
present, the type annotation on the attribute will be
xs:untypedAtomic
.
If the name of a constructed attribute is xml:id
, the processor must
perform attribute value normalization by effectively applying the
normalize-space
FO30 function to the value of the attribute,
and the resulting attribute node must be given the is-id
property.
Note:
If the attribute name is xml:space
, it is not an
error when the value is something other than default
or
preserve
. Although the XML specification states that other
values are erroneous, a document containing such values is well-formed; if
erroneous values are to be rejected, schema validation should be used.
Note:
The xml:base
, xml:lang
, xml:space
, and
xml:id
attributes have two effects in XSLT. They behave as
standard XSLT attributes, which means for example that if they appear on a
literal result element, they will be copied to the result tree in the same way as any other
attribute. In addition, they have their standard meaning as defined in the core
XML specifications. Thus, an xml:base
attribute in the stylesheet
affects the base URI of the element on which it appears, and an
xml:space
attribute affects the interpretation of whitespace text nodes within that
element. One consequence of this is that it is inadvisable to write these
attributes as attribute value templates: although an XSLT processor will
understand this notation, the XML parser will not. See also 11.1.4 Namespace Aliasing which describes how to use
xsl:namespace-alias
with these attributes.
The same is true of the schema-defined attributes xsi:type
,
xsi:nil
, xsi:noNamespaceSchemaLocation
, and
xsi:schemaLocation
. If the stylesheet is processed by a schema
processor, these attributes will be recognized and interpreted by the schema
processor, but in addition the XSLT processor treats them like any other
attribute on a literal result element: that is, their effective value (after expanding attribute value templates) is
copied to the result tree in the same way as any other attribute. If the
result tree is validated, the copied
attributes will again be recognized and interpreted by the schema
processor.
None of these attributes will be generated in the result tree unless the stylesheet writes them to the result tree explicitly, in the same way as any other attribute.
[ERR XTSE0805] It is a static error if an attribute on a literal result element is in the XSLT namespace, unless it is one of the attributes explicitly defined in this specification.
Note:
If there is a need to create attributes in the XSLT namespace, this can be
achieved using xsl:attribute
, or by means of the
xsl:namespace-alias
declaration.
The created element node will have a copy of the namespace nodes that were present on the element node in the stylesheet tree with the exception of any namespace node whose string value is designated as an excluded namespace. Special considerations apply to aliased namespaces: see 11.1.4 Namespace Aliasing.
The following namespaces are designated as excluded namespaces:
The XSLT namespace URI
(http://www.w3.org/1999/XSL/Transform
)
A namespace URI declared as an extension namespace (see 24.2 Extension Instructions)
A namespace URI designated by using an
[xsl:]exclude-result-prefixes
attribute either on the
literal result element itself or on an ancestor element. The attribute
must be in the XSLT namespace only if its parent
element is not in the XSLT namespace.
The value of the attribute is either #all
, or a
whitespace-separated list of tokens, each of which is either a namespace
prefix or #default
. The namespace bound to each of the prefixes
is designated as an excluded namespace.
[ERR XTSE0808] It is a static error if a
namespace prefix is used within the
[xsl:]exclude-result-prefixes
attribute and there is
no namespace binding in scope for that prefix.
The default namespace of the parent element of the
[xsl:]exclude-result-prefixes
attribute (see Section
6.2 Element Nodes
DM30) may be designated as an excluded
namespace by including #default
in the list of namespace
prefixes.
[ERR XTSE0809] It is a static error if the
value #default
is used within the
[xsl:]exclude-result-prefixes
attribute and the parent
element of the [xsl:]exclude-result-prefixes
attribute
has no default namespace.
The value #all
indicates that all namespaces that are in scope
for the stylesheet element that is the parent of the
[xsl:]exclude-result-prefixes
attribute are designated as
excluded namespaces.
The designation of a namespace as an excluded namespace is effective within
the subtree of the stylesheet module rooted at the element bearing the
[xsl:]exclude-result-prefixes
attribute; a subtree rooted at
an xsl:stylesheet
element does not include any stylesheet
modules imported or included by children of that
xsl:stylesheet
element.
The excluded namespaces, as described above, only affect namespace
nodes copied from the stylesheet when processing a literal result element. There
is no guarantee that an excluded namespace will not appear on the result tree for some other reason. Namespace
nodes are also written to the result tree as part of the process of namespace
fixup (see 5.7.3 Namespace Fixup), or as the result of instructions
such as xsl:copy
and xsl:element
.
Note:
When a stylesheet uses a namespace declaration only for the purposes of
addressing a source tree, specifying
the prefix in the [xsl:]exclude-result-prefixes
attribute will
avoid superfluous namespace declarations in the serialized result tree. The attribute is also useful to
prevent namespaces used solely for the naming of stylesheet functions or
extension functions from appearing in the serialized result tree.
Consider the following stylesheet:
<xsl:stylesheet version="1.0" xmlns:xsl="http://www.w3.org/1999/XSL/Transform" xmlns:a="a.uri" xmlns:b="b.uri" exclude-result-prefixes="#all"> <xsl:template match="/"> <foo xmlns:c="c.uri" xmlns:d="d.uri" xmlns:a2="a.uri" xsl:exclude-result-prefixes="c"/> </xsl:template> </xsl:stylesheet>
The result of this stylesheet will be:
<foo xmlns:d="d.uri"/>
The namespaces a.uri
and b.uri
are excluded by virtue
of the exclude-result-prefixes
attribute on the
xsl:stylesheet
element, and the namespace
c.uri
is excluded by virtue of the
xsl:exclude-result-prefixes
attribute on the foo
element. The setting #all
does not affect the namespace
d.uri
because d.uri
is not an in-scope namespace
for the xsl:stylesheet
element. The element in the result tree does not have a namespace node
corresponding to xmlns:a2="a.uri"
because the effect of
exclude-result-prefixes
is to designate the namespace URI
a.uri
as an excluded namespace, irrespective of how many
prefixes are bound to this namespace URI.
If the stylesheet is changed so that the literal result element has an
attribute b:bar="3"
, then the element in the result tree will typically have a namespace
declaration xmlns:b="b.uri"
(the processor may choose a different
namespace prefix if this is necessary to avoid conflicts). The
exclude-result-prefixes
attribute makes b.uri
an
excluded namespace, so the namespace node is not automatically copied from the
stylesheet, but the presence of an attribute whose name is in the namespace
b.uri
forces the namespace fixup process (see 5.7.3 Namespace Fixup) to introduce a namespace node for this
namespace.
A literal result element may have an optional xsl:inherit-namespaces
attribute, with the value yes
or no
. The default value
is yes
. If the value is set to yes
, or is omitted, then
the namespace nodes created for the newly constructed element are copied to the
children and descendants of the newly constructed element, as described in
5.7.1 Constructing Complex Content. If the value is set to
no
, then these namespace nodes are not automatically copied to the
children. This may result in namespace undeclarations (such as
xmlns=""
or, in the case of XML 1.1, xmlns:p=""
)
appearing on the child elements when they are serialized.
When a stylesheet is used to define a transformation whose output is itself a stylesheet module, or in certain other cases where the result document uses namespaces that it would be inconvenient to use in the stylesheet, namespace aliasing can be used to declare a mapping between a namespace URI used in the stylesheet and the corresponding namespace URI to be used in the result document.
[Definition: A namespace URI in the stylesheet tree that is being used to specify a namespace URI in the result tree is called a literal namespace URI.]
[Definition: The namespace URI that is to be used in the result tree as a substitute for a literal namespace URI is called the target namespace URI.]
Either of the literal namespace URI or the target namespace URI can be null: this is treated as a reference to the set of names that are in no namespace.
<!-- Category: declaration -->
<xsl:namespace-alias
stylesheet-prefix = prefix | "#default"
result-prefix = prefix | "#default" />
[Definition: A stylesheet can use the
xsl:namespace-alias
element to declare that a literal namespace URI is being used
as an alias for a target
namespace URI.]
The effect is that when names in the namespace identified by the literal namespace URI are copied to the result tree, the namespace URI in the result tree will be the target namespace URI, instead of the literal namespace URI. This applies to:
the namespace URI in the expanded QName of a literal result element in the stylesheet
the namespace URI in the expanded QName of an attribute specified on a literal result element in the stylesheet
The effect of an xsl:namespace-alias
declaration is local to the package in which
it appears: that is, it only affects the result of literal result elements within the
same package.
Where namespace aliasing changes the namespace URI part of the expanded QName containing the name of an
element or attribute node, the namespace prefix in that expanded QName is replaced
by the prefix indicated by the result-prefix
attribute of the
xsl:namespace-alias
declaration.
The xsl:namespace-alias
element declares that the namespace URI
bound to the prefix specified by the stylesheet-prefix
is the
literal namespace URI, and
the namespace URI bound to the prefix specified by the result-prefix
attribute is the target namespace
URI. Thus, the stylesheet-prefix
attribute specifies the
namespace URI that will appear in the stylesheet, and the
result-prefix
attribute specifies the corresponding namespace URI
that will appear in the result tree.
The default namespace (as declared by xmlns
) may be specified by
using #default
instead of a prefix. If no default namespace is in
force, specifying #default
denotes the null namespace URI. This
allows elements that are in no namespace in the stylesheet to acquire a namespace
in the result document, or vice versa.
If a literal namespace URI is declared to be an alias for multiple different target namespace URIs, then the declaration with the highest import precedence is used.
[ERR XTSE0810] It is a static error if within a package there is more than one such declaration
with the same literal namespace URI and the
same import precedence and
different values for the target
namespace URI, unless there is also an
xsl:namespace-alias
declaration with the same literal namespace URI and a
higher import precedence.
No error occurs if there is more than one such
xsl:namespace-alias
declaration having the same literal namespace URI and the same
target namespace URI, even if
the result-prefix
differs; in this case the
result-prefix
used is the one that appears last in declaration order.
[ERR XTSE0812] It is a static error if a value
other than #default
is specified for either the
stylesheet-prefix
or the result-prefix
attributes of the xsl:namespace-alias
element when there is
no in-scope binding for that namespace prefix.
When a literal result element is processed, its namespace nodes are handled as follows:
A namespace node whose string value is a literal namespace URI is not copied to the result tree.
A namespace node whose string value is a target namespace URI is copied to the result tree, whether or not the URI identifies an excluded namespace.
In the event that the same URI is used as a literal namespace URI and a target namespace URI, the second of these rules takes precedence.
Note:
These rules achieve the effect that the element generated from the literal
result element will have an in-scope namespace node that binds the
result-prefix
to the target namespace URI, provided that the namespace declaration
associating this prefix with this URI is in scope for both the
xsl:namespace-alias
instruction and for the literal result
element. Conversely, the stylesheet-prefix
and the literal namespace URI will not
normally appear in the result tree.
xsl:namespace-alias
to Generate a Stylesheet
When literal result elements are being used to create element, attribute, or namespace nodes that use the XSLT namespace URI, the stylesheet may use an alias.
For example, the stylesheet
<xsl:stylesheet version="3.0" xmlns:xsl="http://www.w3.org/1999/XSL/Transform" xmlns:fo="http://www.w3.org/1999/XSL/Format" xmlns:axsl="file://namespace.alias"> <xsl:namespace-alias stylesheet-prefix="axsl" result-prefix="xsl"/> <xsl:template match="/"> <axsl:stylesheet version="3.0"> <xsl:apply-templates/> </axsl:stylesheet> </xsl:template> <xsl:template match="elements"> <axsl:template match="/"> <axsl:comment select="system-property('xsl:version')"/> <axsl:apply-templates/> </axsl:template> </xsl:template> <xsl:template match="block"> <axsl:template match="{.}"> <fo:block><axsl:apply-templates/></fo:block> </axsl:template> </xsl:template> </xsl:stylesheet>
will generate an XSLT stylesheet from a document of the form:
<elements> <block>p</block> <block>h1</block> <block>h2</block> <block>h3</block> <block>h4</block> </elements>
The output of the transformation will be a stylesheet such as the following.
Whitespace has been added for clarity. Note that an implementation may output
different namespace prefixes from those appearing in this example; however, the
rules guarantee that there will be a namespace node that binds the prefix
xsl
to the URI
http://www.w3.org/1999/XSL/Transform
, which makes it safe to
use the QName xsl:version
in the content of the generated
stylesheet.
<xsl:stylesheet version="3.0" xmlns:xsl="http://www.w3.org/1999/XSL/Transform" xmlns:fo="http://www.w3.org/1999/XSL/Format"> <xsl:template match="/"> <xsl:comment select="system-property('xsl:version')"/> <xsl:apply-templates/> </xsl:template> <xsl:template match="p"> <fo:block><xsl:apply-templates/></fo:block> </xsl:template> <xsl:template match="h1"> <fo:block><xsl:apply-templates/></fo:block> </xsl:template> <xsl:template match="h2"> <fo:block><xsl:apply-templates/></fo:block> </xsl:template> <xsl:template match="h3"> <fo:block><xsl:apply-templates/></fo:block> </xsl:template> <xsl:template match="h4"> <fo:block><xsl:apply-templates/></fo:block> </xsl:template> </xsl:stylesheet>
Note:
It may be necessary also to use aliases for namespaces other than the XSLT
namespace URI. For example, it can be useful to define an alias for the
namespace http://www.w3.org/2001/XMLSchema-instance
, so that the
stylesheet can use the attributes xsi:type
, xsi:nil
,
and xsi:schemaLocation
on a literal result element, without
running the risk that a schema processor will interpret these as applying to
the stylesheet itself. Equally, literal result elements belonging to a
namespace dealing with digital signatures might cause XSLT stylesheets to be
mishandled by general-purpose security software; using an alias for the
namespace would avoid the possibility of such mishandling.
It is possible to define an alias for the XML namespace.
<xsl:stylesheet xmlns:axml="http://www.example.com/alias-xml" xmlns:xsl="http://www.w3.org/1999/XSL/Transform" version="3.0"> <xsl:namespace-alias stylesheet-prefix="axml" result-prefix="xml"/> <xsl:template match="/"> <name axml:space="preserve"> <first>James</first> <xsl:text> </xsl:text> <last>Clark</last> </name> </xsl:template> </xsl:stylesheet>
produces the output:
<name xml:space="preserve"><first>James</first> <last>Clark</last></name>
This allows an xml:space
attribute to be generated in the output
without affecting the way the stylesheet is parsed. The same technique can be
used for other attributes such as xml:lang
, xml:base
,
and xml:id
.
Note:
Namespace aliasing is only necessary when literal result elements are used. The
problem of reserved namespaces does not arise when using
xsl:element
and xsl:attribute
to construct
the result tree. Therefore, as an
alternative to using xsl:namespace-alias
, it is always
possible to achieve the desired effect by replacing literal result elements
with xsl:element
and xsl:attribute
instructions.
xsl:element
<!-- Category: instruction -->
<xsl:element
name = { qname }
namespace? = { uri }
inherit-namespaces? = boolean
use-attribute-sets? = eqnames
type? = eqname
validation? = "strict" | "lax" | "preserve" | "strip" >
<!-- Content: sequence-constructor -->
</xsl:element>
The xsl:element
instruction allows an element to be created with a
computed name. The expanded QName of the
element to be created is specified by a required
name
attribute and an optional namespace
attribute.
The result of evaluating the xsl:element
instruction, in usual circumstances, is the newly constructed
element node.
The content of the xsl:element
instruction is a sequence constructor for the children,
attributes, and namespaces of the created element. The sequence obtained by
evaluating this sequence constructor (see 5.7 Sequence Constructors)
is used to construct the content of the element, as described in 5.7.1 Constructing Complex Content.
The xsl:element
element may have a
use-attribute-sets
attribute, whose value is a
whitespace-separated list of QNames that identify
xsl:attribute-set
declarations. If this attribute is present,
it is expanded as described in 10.2 Named Attribute Sets to produce a
sequence of attribute nodes. This sequence is prepended to the sequence produced
as a result of evaluating the sequence constructor, as
described in 5.7.1 Constructing Complex Content.
The name
attribute is interpreted as an attribute value template, whose
effective value
must be a lexical
QName.
[ERR XTDE0820] It is a dynamic error if the effective value of the
name
attribute is not a
lexical QName.
[ERR XTDE0830] In the case of an xsl:element
instruction with no
namespace
attribute, it is a dynamic
error if the effective
value of the name
attribute is a lexical QName whose prefix is not
declared in an in-scope namespace declaration for the
xsl:element
instruction.
If the namespace
attribute is not present then the lexical QName is expanded into an expanded QName using the namespace
declarations in effect for the xsl:element
element, including any
default namespace declaration.
If the namespace
attribute is present, then it too is interpreted as
an attribute value template.
The effective value
must be in the lexical space of the xs:anyURI
type. If the string is zero-length, then the expanded QName of the element has a null namespace URI. Otherwise,
the string is used as the namespace URI of the expanded QName of the element to be created. The local part of the
lexical QName specified by the
name
attribute is used as the local part of the expanded QName of the element to be
created.
[ERR XTDE0835] It is a dynamic error if the effective value of the
namespace
attribute is not in the
lexical space of the xs:anyURI
datatype or if it is the string
http://www.w3.org/2000/xmlns/
.
Note:
The XDM data model requires the name of a node to be an instance of
xs:QName
, and XML Schema defines the namespace part of an
xs:QName
to be an instance of xs:anyURI
. However,
the schema specification, and the specifications that it refers to, give
implementations some flexibility in how strictly they enforce these
constraints.
The prefix of the lexical QName
specified in the name
attribute (or the absence of a prefix) is
copied to the prefix part of the expanded
QName representing the name of the new element node. In the event of
a conflict a prefix may subsequently be added, changed, or removed during the
namespace fixup process (see 5.7.3 Namespace Fixup). The term conflict
here means any violation of the constraints defined in [XDM 3.0], for example the use of the same prefix to refer to
two different namespaces in the element and in one of its attributes, the use of
the prefix xml
to refer to a namespace other than the XML namespace,
or any use of the prefix
xmlns
.
The xsl:element
instruction has an optional
inherit-namespaces
attribute, with the value yes
or
no
. The default value is yes
. If the value is set to
yes
, or is omitted, then the namespace nodes created for the newly
constructed element (whether these were copied from those of the source node, or
generated as a result of namespace fixup) are copied to the children and
descendants of the newly constructed element, as described in 5.7.1 Constructing Complex Content. If the value is set to no
,
then these namespace nodes are not automatically copied to the children. This may
result in namespace undeclarations (such as xmlns=""
or, in the case
of XML Namespaces 1.1, xmlns:p=""
) appearing on the child elements
when
the element is serialized.
The base URI of the new element is copied from the base URI of the
xsl:element
instruction in the stylesheet, unless the content
of the new element includes an xml:base
attribute, in which case the
base URI of the new element is the value of that attribute, resolved (if it is a
relative URI) against the base URI of the xsl:element
instruction
in the stylesheet. (Note, however, that this is only relevant when creating
parentless elements. When the new element is copied to form a child of an element
or document node, the base URI of the new copy is taken from that of its new
parent.)
The values of the nilled
,
is-id
, and is-idrefs
properties of the new element
depend on the type
and validation
attributes of the
xsl:element
instruction, as explained in 25.4 Validation.
The optional attributes type
and validation
may be used
on the xsl:element
instruction to invoke validation of the
contents of the element against a type definition or element declaration in a
schema, and to determine the type
annotation that the new element node will carry. These attributes
also affect the type annotation carried by any elements and attributes that have
the new element node as an ancestor. These two attributes are both optional, and
if one is specified then the other must be omitted. The
permitted values of these attributes and their semantics are described in 25.4 Validation.
Note:
The final type annotation of the element in the result tree also depends on the type
and
validation
attributes of the instructions used to create the
ancestors of the element.
xsl:attribute
<!-- Category: instruction -->
<xsl:attribute
name = { qname }
namespace? = { uri }
select? = expression
separator? = { string }
type? = eqname
validation? = "strict" | "lax" | "preserve" | "strip" >
<!-- Content: sequence-constructor -->
</xsl:attribute>
The xsl:attribute
element can be used to add attributes to result
elements whether created by literal result elements in the stylesheet or by
instructions such as xsl:element
or xsl:copy
. The
expanded QName of the attribute to be
created is specified by a required
name
attribute and an optional namespace
attribute. Except
in error cases, the result of evaluating an xsl:attribute
instruction is the newly constructed attribute node.
The string value of the new attribute node may be defined either by using the
select
attribute, or by the sequence constructor that forms the content of the
xsl:attribute
element. These are
mutually exclusive: if the select
attribute is present then the
sequence constructor must be empty, and if the sequence constructor is non-empty
then the select
attribute must be absent. If the select
attribute is absent and the sequence constructor is empty, then the
string value of the new attribute node will be a zero-length string. The way in which
the value is constructed is specified in 5.7.2 Constructing Simple Content.
[ERR XTSE0840] It is a static error if the
select
attribute of the xsl:attribute
element
is present unless the element has empty content.
If the separator
attribute is present, then the effective value of this attribute is used to
separate adjacent items in the result sequence, as described in 5.7.2 Constructing Simple Content. In the absence of this attribute, the default
separator is a single space (#x20) when the content is specified using the
select
attribute, or a zero-length string when the content is
specified using a sequence
constructor.
The name
attribute is interpreted as an attribute value template, whose
effective value
must be a lexical
QName.
[ERR XTDE0850] It is a dynamic error if the effective value of the name
attribute is not a lexical
QName.
[ERR XTDE0855] In the case of an xsl:attribute
instruction with no
namespace
attribute, it is a dynamic
error if the effective
value of the name
attribute is the string
xmlns
.
[ERR XTDE0860] In the case of an xsl:attribute
instruction with no
namespace
attribute, it is a dynamic
error if the effective
value of the name
attribute is a lexical QName whose prefix is not declared
in an in-scope namespace declaration for the xsl:attribute
instruction.
If the namespace
attribute is not present, then the lexical QName is expanded into an expanded QName using the namespace declarations
in effect for the xsl:attribute
element, not including
any default namespace declaration.
If the namespace
attribute is present, then it too is interpreted as an
attribute value template. The
effective value
must be in the lexical space of the xs:anyURI
type.
If the string is zero-length, then the expanded
QName of the attribute has a null namespace URI. Otherwise, the string
is used as the namespace URI of the expanded
QName of the attribute to be created. The local part of the lexical QName specified by the name
attribute is used as the local part of the expanded
QName of the attribute to be created.
[ERR XTDE0865] It is a dynamic error if the effective value of the
namespace
attribute is not in the
lexical space of the xs:anyURI
datatype or if it is the string
http://www.w3.org/2000/xmlns/
.
Note:
The same considerations apply as for elements: [see ERR XTDE0835] in 11.2 Creating Element Nodes Using xsl:element .
The prefix of the lexical QName specified
in the name
attribute (or the absence of a prefix) is copied to the
prefix part of the expanded QName
representing the name of the new attribute node. In the event of a conflict this
prefix may subsequently be added, changed, or removed during the namespace fixup
process (see 5.7.3 Namespace Fixup). If the attribute is in a non-null
namespace and no prefix is specified, then the namespace fixup process will invent
a
prefix. The term conflict here means any violation of the constraints
defined in [XDM 3.0], for example the use of the same prefix
to refer to two different namespaces in the element and in one of its attributes,
the
use of the prefix xml
to refer to a namespace other than the XML
namespace, or any use of the prefix xmlns
.
If the name of a constructed attribute is xml:id
, the processor must
perform attribute value normalization by effectively applying the
normalize-space
FO30 function to the value of the attribute, and
the resulting attribute node must be given the is-id
property. This
applies whether the attribute is constructed using the xsl:attribute
instruction or whether it is constructed using an attribute of a literal result
element. This does not imply any constraints on the value of the attribute, or on
its
uniqueness, and it does not affect the type
annotation of the attribute, unless the containing document is
validated.
Note:
The effect of setting the is-id
property is that the parent element
can be located within the containing document by use of the
id
FO30 function. In effect, XSLT when constructing a
document performs some of the functions of an xml:id
processor, as
defined in [xml:id]; the other aspects of xml:id
processing are performed during validation.
The following instruction creates the attribute colors="red green
blue"
:
<xsl:attribute name="colors" select="'red', 'green', 'blue'"/>
It is not an error to write:
<xsl:attribute name="xmlns:xsl" namespace="file://some.namespace" select="'http://www.w3.org/1999/XSL/Transform'"/>
However, this will not result in the namespace declaration
xmlns:xsl="http://www.w3.org/1999/XSL/Transform"
being output.
Instead, it will produce an attribute node with local name xsl
, and
with a system-allocated namespace prefix mapped to the namespace URI
file://some.namespace
. This is because the namespace fixup process
is not allowed to use xmlns
as the name of a namespace node.
As described in 5.7.1 Constructing Complex Content, in a sequence that is used to construct the content of an element, any attribute nodes must appear in the sequence before any element, text, comment, or processing instruction nodes. Where the sequence contains two or more attribute nodes with the same expanded QName, the one that comes last is the only one that takes effect.
Note:
If a collection of attributes is generated repeatedly, this can be done conveniently by using named attribute sets: see 10.2 Named Attribute Sets
The optional attributes type
and validation
may be used
on the xsl:attribute
instruction to invoke validation of the
contents of the attribute against a type definition or attribute declaration in a
schema, and to determine the type
annotation that the new attribute node will carry. These two
attributes are both optional, and if one is specified then the other
must be omitted. The permitted values of these attributes
and their semantics are described in 25.4 Validation.
The process of validation also determines the values of
the is-id
and is-idrefs
properties on the new attribute
node.
Note:
The final type annotation of the attribute in the result tree also depends on the
type
and validation
attributes of the instructions
used to create the ancestors of the attribute.
This section describes three different ways of creating text nodes: by means of
literal text nodes in the stylesheet, or by using the xsl:text
and
xsl:value-of
instructions. It is also possible to create text
nodes using the xsl:number
instruction described in 12 Numbering.
If and when the sequence that results from evaluating a sequence constructor is used to form the content of a node, as described in 5.7.2 Constructing Simple Content and 5.7.1 Constructing Complex Content, adjacent text nodes in the sequence are merged. Within the sequence itself, however, they exist as distinct nodes.
The following function returns a sequence of three text nodes:
<xsl:function name="f:wrap"> <xsl:param name="s"/> <xsl:text>(</xsl:text> <xsl:value-of select="$s"/> <xsl:text>)</xsl:text> </xsl:function>
When this function is called as follows:
<xsl:value-of select="f:wrap('---')"/>
the result is:
(---)
No additional spaces are inserted, because the calling
xsl:value-of
instruction merges adjacent text nodes before
atomizing the sequence. However, the result of the instruction:
<xsl:value-of select="data(f:wrap('---'))"/>
is:
( --- )
because in this case the three text nodes are atomized to form three strings, and spaces are inserted between adjacent strings.
It is possible to construct text nodes whose string value is zero-length. A zero-length text node, when atomized, produces a zero-length string. However, zero-length text nodes are ignored when they appear in a sequence that is used to form the content of a node, as described in 5.7.1 Constructing Complex Content and 5.7.2 Constructing Simple Content.
A sequence constructor can contain text nodes. Each text node in a sequence constructor remaining after whitespace text nodes have been stripped as specified in 4.3 Stripping Whitespace from the Stylesheet will construct a new text node with the same string value. The resulting text node is added to the result of the containing sequence constructor.
Text is processed at the tree level. Thus, markup of <
in a
template will be represented in the stylesheet tree by a text node that includes
the character <
. This will create a text node in the result tree that contains a <
character, which will be represented by the markup <
(or an
equivalent character reference) when the result tree is serialized as an XML
document, unless otherwise specified using character maps (see 26.1 Character Maps) or
disable-output-escaping
(see 26.2 Disabling Output Escaping).
xsl:text
<!-- Category: instruction -->
<xsl:text
[disable-output-escaping]? = boolean >
<!-- Content: #PCDATA -->
</xsl:text>
The xsl:text
element is evaluated to construct a new text
node.
If the element or one of its ancestors has an
[xsl:]expand-text
attribute, and the nearest ancestor with such an
attribute has the value yes
, then any unescaped curly brackets in the
value of the element indicate the presence of text value templates, which are expanded
as described in 5.6.2 Text Value Templates.
In the absence of such an attribute, or if the
effective value is no
, the content of the
xsl:text
element is a single text node whose value forms the
string value of the new text node. An
xsl:text
element may be empty, in which case the result of
evaluating the instruction is a text node whose string value is the zero-length
string.
The result of evaluating an xsl:text
instruction is the newly
constructed text node.
A text node that is an immediate child of an xsl:text
instruction
will not be stripped from the stylesheet tree, even if it consists entirely of
whitespace (see 4.4.2 Stripping Whitespace from a Source Tree).
For the effect of the deprecated
disable-output-escaping
attribute, see 26.2 Disabling Output Escaping
Note:
It is not always necessary to use the xsl:text
instruction to
write text nodes to the result tree.
Literal text can be written to the result tree by including it anywhere in a
sequence constructor, while computed text can be output
using the xsl:value-of
instruction. The principal reason for
using xsl:text
is that it offers improved control over
whitespace handling.
xsl:value-of
Within a sequence constructor, the
xsl:value-of
instruction can be used to generate computed text
nodes. The xsl:value-of
instruction computes the text using an
expression that is specified as the
value of the select
attribute, or by means of contained instructions.
This might, for example, extract text from a source
tree or insert the value of a variable.
<!-- Category: instruction -->
<xsl:value-of
select? = expression
separator? = { string }
[disable-output-escaping]? = boolean >
<!-- Content: sequence-constructor -->
</xsl:value-of>
The xsl:value-of
instruction is evaluated to construct a new text
node; the result of the instruction is the newly constructed text node.
The string value of the new text node may be defined either by using the
select
attribute, or by the sequence constructor (see 5.7 Sequence Constructors)
that forms the content of the xsl:value-of
element. These are mutually exclusive: if the select
attribute is present then the sequence constructor must be empty, and if the
sequence constructor is non-empty then the select
attribute must
be absent. If the select
attribute is absent and the sequence
constructor is empty, then the result of the instruction is a text node whose
string value is zero-length. The way in which the value is constructed
is specified in 5.7.2 Constructing Simple Content.
[ERR XTSE0870] It is a static error if the
select
attribute of the xsl:value-of
element is present when the content of the element is non-empty.
If the separator
attribute is present, then the effective value of this attribute is used to
separate adjacent items in the result sequence, as described in 5.7.2 Constructing Simple Content. In the absence of this attribute, the
default separator is a single space (#x20) when the content is specified using the
select
attribute, or a zero-length string when the content is
specified using a sequence
constructor.
Special rules apply when the instruction is processed
with XSLT 1.0 behavior.
If no separator
attribute is present, and if the select
attribute is present, then all items in the atomized result sequence other than the first are ignored.
The instruction:
<x><xsl:value-of select="1 to 4" separator="|"/></x>
produces the output:
<x>1|2|3|4</x>
Note:
The xsl:copy-of
element can be used to copy a sequence of
nodes to the result tree without
atomization. See 11.9.2 Deep Copy.
For the effect of the deprecated
disable-output-escaping
attribute, see 26.2 Disabling Output Escaping
<!-- Category: instruction -->
<xsl:document
validation? = "strict" | "lax" | "preserve" | "strip"
type? = eqname >
<!-- Content: sequence-constructor -->
</xsl:document>
The xsl:document
instruction is used to create a new document node.
The content of the xsl:document
element is a sequence constructor for the children of
the new document node. A document node is created, and the sequence obtained by
evaluating the sequence constructor is used to construct the content of the document,
as described in 5.7.1 Constructing Complex Content.
Except in error situations, the result of evaluating the
xsl:document
instruction is a single node, the newly constructed
document node.
Note:
The new document is not serialized. To construct a document that is to form a
final result rather than an intermediate result, use the
xsl:result-document
instruction described in 25.1 Creating Secondary Results.
The optional attributes type
and validation
may be used on
the xsl:document
instruction to validate the contents of the new
document, and to determine the type annotation that elements and
attributes within the result tree will carry.
The permitted values and their semantics are described in 25.4.2 Validating Document Nodes.
The base URI of the new document node is taken from the base URI of the
xsl:document
instruction.
The document-uri
and unparsed-entities
properties of the
new document node are set to empty.
The following example creates a temporary tree held in a variable. The use of an
enclosed xsl:document
instruction ensures that uniqueness
constraints defined in the schema for the relevant elements are checked.
<xsl:variable name="tree" as="document-node()"> <xsl:document validation="strict"> <xsl:apply-templates/> </xsl:document> </xsl:variable>
<!-- Category: instruction -->
<xsl:processing-instruction
name = { ncname }
select? = expression >
<!-- Content: sequence-constructor -->
</xsl:processing-instruction>
The xsl:processing-instruction
element is evaluated to create a
processing instruction node.
The xsl:processing-instruction
element has a
required
name
attribute that specifies the name of the processing instruction
node. The value of the name
attribute is interpreted as an attribute value template.
The string value of the new processing-instruction node may be defined either by
using the select
attribute, or by the sequence constructor that forms the
content of the xsl:processing-instruction
element. These are mutually exclusive: if the select
attribute is present then the sequence constructor must be empty, and if the
sequence constructor is non-empty then the select
attribute must be
absent. If the select
attribute is absent and the sequence
constructor is empty, then the string value of the new
processing-instruction node will be a zero-length string. The way in which the value
is constructed is specified in 5.7.2 Constructing Simple Content.
[ERR XTSE0880] It is a static error if the
select
attribute of the
xsl:processing-instruction
element is present unless the
element has empty content.
Except in error situations, the result of evaluating the
xsl:processing-instruction
instruction is a single node, the
newly constructed processing instruction node.
This instruction:
<xsl:processing-instruction name="xml-stylesheet" select="('href="book.css"', 'type="text/css"')"/>
creates the processing instruction
<?xml-stylesheet href="book.css" type="text/css"?>
Note that the xml-stylesheet
processing instruction contains
pseudo-attributes in the form name="value"
. Although
these have the same textual form as attributes in an element start tag, they are
not represented as XDM attribute nodes, and cannot therefore be constructed using
xsl:attribute
instructions.
[ERR XTDE0890] It is a dynamic error if the effective value of the name
attribute is not both an NCNameNames and a PITargetXML.
Note:
Because these rules disallow the name xml
, the
xsl:processing-instruction
cannot be used to output an XML
declaration. The xsl:output
declaration should be used to control
this instead (see 26 Serialization).
If the result of evaluating the content of the
xsl:processing-instruction
contains the string
?>
, this string is modified by inserting a space between the
?
and >
characters.
The base URI of the new processing-instruction is copied from the base URI of the
xsl:processing-instruction
element in the stylesheet. (Note,
however, that this is only relevant when creating a parentless processing
instruction. When the new processing instruction is copied to form a child of an
element or document node, the base URI of the new copy is taken from that of its new
parent.)
<!-- Category: instruction -->
<xsl:namespace
name = { ncname }
select? = expression >
<!-- Content: sequence-constructor -->
</xsl:namespace>
The xsl:namespace
element is evaluated to create a namespace node.
Except in error situations, the result of evaluating the
xsl:namespace
instruction is a single node, the newly constructed
namespace node.
The xsl:namespace
element has a required
name
attribute that specifies the name of the namespace node (that is,
the namespace prefix). The value of the name
attribute is interpreted as
an attribute value template. If
the effective value of the
name
attribute is a zero-length string, a namespace node is added for
the default namespace.
The string value of the new namespace node (that is, the namespace URI) may be
defined either by using the select
attribute, or by the sequence constructor that forms the
content of the xsl:namespace
element. These are mutually exclusive: if the select
attribute is present
then the sequence constructor must be empty, and if the sequence constructor is
non-empty then the select
attribute must be absent. Since
the string value of a namespace node cannot be a zero-length string, either a select
attribute or a non-empty sequence
constructor must be present. The way in which the
value is constructed is specified in 5.7.2 Constructing Simple Content.
[ERR XTDE0905] It is a dynamic error if the string value of
the new namespace node is not valid in the lexical space of the datatype
xs:anyURI
, or if it is the string
http://www.w3.org/2000/xmlns/
.
[ERR XTSE0910] It is a static error if the
select
attribute of the xsl:namespace
element
is present when the element has content other than one or more
xsl:fallback
instructions, or if the select
attribute is absent when the element has empty content.
Note the restrictions described in 5.7.1 Constructing Complex Content for the position of a namespace node relative to other nodes in the node sequence returned by a sequence constructor.
This literal result element:
<data xsi:type="xs:integer" xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance"> <xsl:namespace name="xs" select="'http://www.w3.org/2001/XMLSchema'"/> <xsl:text>42</xsl:text> </data>
would typically cause the output document to contain the element:
<data xsi:type="xs:integer" xmlns:xs="http://www.w3.org/2001/XMLSchema" xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance">42</data>
In this case, the element is constructed using a literal result element, and the
namespace xmlns:xs="http://www.w3.org/2001/XMLSchema"
could therefore
have been added to the result tree simply
by declaring it as one of the in-scope namespaces in the stylesheet. In practice,
the xsl:namespace
instruction is more likely to be useful in
situations where the element is constructed using an xsl:element
instruction, which does not copy all the in-scope namespaces from the
stylesheet.
[ERR XTDE0920] It is a dynamic error if the effective value of the name
attribute is neither a zero-length string nor an NCNameNames, or if it is xmlns
.
[ERR XTDE0925] It is a dynamic error if the
xsl:namespace
instruction generates a namespace node whose
name is xml
and whose string value is not
http://www.w3.org/XML/1998/namespace
, or a namespace node whose
string value is http://www.w3.org/XML/1998/namespace
and whose
name is not xml
.
[ERR XTDE0930] It is a dynamic error if evaluating the
select
attribute or the contained sequence constructor of an xsl:namespace
instruction results in a zero-length string.
For details of other error conditions that may arise, see 5.7 Sequence Constructors.
Note:
It is rarely necessary to use xsl:namespace
to create a namespace
node in the result tree; in most
circumstances, the required namespace nodes will be created automatically, as a
side-effect of writing elements or attributes that use the namespace. An example
where xsl:namespace
is needed is a situation where the required
namespace is used only within attribute values in the result document, not in
element or attribute names; especially where the required namespace prefix or
namespace URI is computed at run-time and is not present in either the source
document or the stylesheet.
Adding a namespace node to the result tree will never change the expanded QName of any element or attribute node in the result tree: that is, it will never change the namespace URI of an element or attribute. It might, however, constrain the choice of prefixes when namespace fixup is performed.
Namespace prefixes for element and attribute names are initially established by the rules of the instruction that creates the element or attribute node, and in the event of conflicts, they may be changed by the namespace fixup process described in 5.7.3 Namespace Fixup. The fixup process ensures that an element has in-scope namespace nodes for the namespace URIs used in the element name and in its attribute names, and the serializer will typically use these namespace nodes to determine the prefix to use in the serialized output. The fixup process cannot generate namespace nodes that are inconsistent with those already present in the tree. This means that it is not possible for the processor to decide the prefix to use for an element or for any of its attributes until all the namespace nodes for the element have been added.
If a namespace prefix is mapped to a particular namespace URI using the
xsl:namespace
instruction, or by using
xsl:copy
or xsl:copy-of
to copy a namespace
node, this prevents the namespace fixup process (and hence the serializer) from
using the same prefix for a different namespace URI on the same element.
Given the instruction:
<xsl:element name="p:item" xmlns:p="http://www.example.com/p"> <xsl:namespace name="p">http://www.example.com/q</xsl:namespace> </xsl:element>
a possible serialization of the result tree is:
<ns0:item xmlns:ns0="http://www.example.com/p" xmlns:p="http://www.example.com/q"/>
The processor must invent a namespace prefix for the URI p.uri
; it
cannot use the prefix p
because that prefix has been explicitly
associated with a different URI.
Note:
The xsl:namespace
instruction cannot be used to generate a
namespace undeclaration of the form xmlns=""
(nor the
new forms of namespace undeclaration permitted in [Namespaces in XML 1.1]).
Namespace undeclarations are generated automatically by the serializer if
undeclare-prefixes="yes"
is specified on
xsl:output
, whenever a parent element has a namespace node for
the default namespace prefix, and a child element has no namespace node for that
prefix.
<!-- Category: instruction -->
<xsl:comment
select? = expression >
<!-- Content: sequence-constructor -->
</xsl:comment>
The xsl:comment
element is evaluated to construct a new comment
node. Except in error cases, the result of evaluating the
xsl:comment
instruction is a single node, the newly constructed
comment node.
The string value of the new comment node may be defined either by using the
select
attribute, or by the sequence constructor that forms the content of the
xsl:comment
element. These are mutually
exclusive: if the select
attribute is present then the sequence
constructor must be empty, and if the sequence constructor is non-empty then the
select
attribute must be absent. If the select
attribute is absent and the sequence constructor is empty, then the
string value of the new comment node will be a zero-length string. The way in which
the value is constructed is specified in 5.7.2 Constructing Simple Content.
[ERR XTSE0940] It is a static error if the
select
attribute of the xsl:comment
element is
present unless the element has empty content.
For example, this
<xsl:comment>This file is automatically generated. Do not edit!</xsl:comment>
would create the comment
<!--This file is automatically generated. Do not edit!-->
In the generated comment node, the processor must insert a space
after any occurrence of x2D
(hyphen) that is followed by another occurrence of x2D
(hyphen) or
that ends the comment.
<!-- Category: instruction -->
<xsl:copy
select? = expression
copy-namespaces? = boolean
inherit-namespaces? = boolean
use-attribute-sets? = eqnames
type? = eqname
validation? = "strict" | "lax" | "preserve" | "strip" >
<!-- Content: sequence-constructor -->
</xsl:copy>
The xsl:copy
instruction provides a way of copying a selected item. The selected item is the item selected by
evaluating the expression in the select
attribute if present, or
the context item otherwise.
If the selected item is a node, evaluating the xsl:copy
instruction constructs a copy of the selected node, and the result of the
xsl:copy
instruction is this newly constructed node. By
default, the namespace nodes of the context node are automatically copied as well,
but the attributes and children of the node are not automatically copied.
[ERR XTTE0945] It is a type error to use the
xsl:copy
instruction with no select
attribute when the context item is absent.
If the select
expression returns an empty sequence,
the xsl:copy
instruction returns an empty sequence, and the
contained sequence constructor is not evaluated.
[ERR XTTE3180] It is a type error if the result of
evaluating the select
expression is a sequence of more
than one item.
When the selected item is an atomic value
or function item, the
xsl:copy
instruction returns this value. The sequence constructor is not evaluated.
When the selected item is an attribute node,
text node, comment node, processing instruction node, or namespace node, the
xsl:copy
instruction returns a new node that is a copy of the
context node. The new node will have the same node kind, name, and string value as
the context node. In the case of an attribute node, it will also have the same
values for the is-id
and is-idrefs
properties. The
sequence constructor is not evaluated.
When the selected item is a document node or
element node, the xsl:copy
instruction returns a new node that
has the same node kind and name as the selected
node. The content of the new node is formed by evaluating the sequence constructor contained in the
xsl:copy
instruction. If the
select
attribute is present then the sequence constructor is
evaluated with the selected item as the singleton focus; otherwise it is evaluated using the context of
the xsl:copy
instruction unchanged. The sequence
obtained by evaluating this sequence constructor is used (after prepending any
attribute nodes or namespace nodes as described in the following paragraphs) to
construct the content of the document or element node, as described in 5.7.1 Constructing Complex Content.
When the selected item is a document node, the
unparsed-entities
property of the existing document node is copied
to the new document node.
When the selected item is an element or attribute node,
the values of the is-id
, is-idrefs
, and
nilled
properties of the new element or attribute depend on the
values of the validation
and type
attributes, as defined
in 25.4 Validation.
The xsl:copy
instruction has an optional
use-attribute-sets
attribute, whose value is a
whitespace-separated list of QNames that identify
xsl:attribute-set
declarations. This attribute is used only
when copying element nodes. This list is expanded as described in 10.2 Named Attribute Sets to produce a sequence of attribute nodes. This sequence
is prepended to the sequence produced as a result of evaluating the sequence constructor.
The xsl:copy
instruction has an optional
copy-namespaces
attribute, with the value yes
or
no
. The default value is yes
. The attribute is used
only when copying element nodes. If the value is set to yes
, or is
omitted, then all the namespace nodes of the source element are copied as
namespace nodes for the result element. These copied namespace nodes are prepended
to the sequence produced as a result of evaluating the sequence constructor (it is immaterial
whether they come before or after any attribute nodes produced by expanding the
use-attribute-sets
attribute). If the value is set to
no
, then the namespace nodes are not copied. However, namespace
nodes will still be added to the result element as required by
the namespace fixup process: see 5.7.3 Namespace Fixup.
The xsl:copy
instruction has an optional
inherit-namespaces
attribute, with the value yes
or
no
. The default value is yes
. The attribute is used
only when copying element nodes. If the value is set to yes
, or is
omitted, then the namespace nodes created for the newly constructed element
(whether these were copied from those of the source node, or generated as a result
of namespace fixup) are copied to the children and descendants of the newly
constructed element, as described in 5.7.1 Constructing Complex Content. If the value is set to no
, then these namespace nodes are not
automatically copied to the children. This may result in namespace undeclarations
(such as xmlns=""
or, in the case of XML Namespaces 1.1,
xmlns:p=""
) appearing on the child elements when a final result tree is serialized.
[ERR XTTE0950] It is a type error to use the
xsl:copy
or xsl:copy-of
instruction to
copy a node that has namespace-sensitive content if the
copy-namespaces
attribute has the value no
and
its explicit or implicit validation
attribute has the value
preserve
. It is also a type error if either of these
instructions (with validation="preserve"
) is used to copy an
attribute having namespace-sensitive content, unless the parent element is
also copied. A node has namespace-sensitive content if its typed value
contains an item of type xs:QName
or xs:NOTATION
or a type derived therefrom. The reason this is an error is because the
validity of the content depends on the namespace context being
preserved.
Note:
When attribute nodes are copied, whether with xsl:copy
or with
xsl:copy-of
, the processor does not automatically copy any
associated namespace information. The namespace used in the attribute name
itself will be declared by virtue of the namespace fixup process (see 5.7.3 Namespace Fixup) when the attribute is added to an element in the
result tree, but if namespace
prefixes are used in the content of the attribute (for example, if the value of
the attribute is an XPath expression) then it is the responsibility of the
stylesheet author to ensure that suitable namespace nodes are added to the
result tree. This can be achieved by
copying the namespace nodes using xsl:copy
, or by generating
them using xsl:namespace
.
The optional attributes type
and validation
may be used
on the xsl:copy
instruction to validate the contents of an
element, attribute or document node against a type definition, element
declaration, or attribute declaration in a schema, and thus to determine the
type annotation that the new copy of an element or
attribute node will carry. These attributes are ignored when copying an item that
is not an element, attribute or document node. When the node being copied is an
element or document node, these attributes also affect the type annotation carried
by any elements and attributes that have the copied element or document node as an
ancestor. These two attributes are both optional, and if one is specified then the
other must be omitted. The permitted values of these attributes
and their semantics are described in 25.4 Validation.
Note:
The final type annotation of the node in the result tree also depends on the
type
and validation
attributes of the instructions
used to create the ancestors of the node.
When a node is copied, its base URI is copied, except
when the result of the xsl:copy
instruction is an element node
having an xml:base
attribute, in which case the base URI of the new
node is taken as the value of its xml:base
attribute, resolved if it
is relative against the base URI of the xsl:copy
instruction.
When an xml:id
attribute is copied, using either the
xsl:copy
or xsl:copy-of
instruction, it is
implementation-defined whether the value of the attribute
is subjected to attribute value normalization (that is, effectively applying the
normalize-space
FO30 function).
Note:
In most cases the value will already have been subjected to attribute value normalization on the source tree, but if this processing has not been performed on the source tree, it is not an error for it to be performed on the result tree.
<!-- Category: instruction -->
<xsl:copy-of
select = expression
copy-accumulators? = boolean
copy-namespaces? = boolean
type? = eqname
validation? = "strict" | "lax" | "preserve" | "strip" />
The xsl:copy-of
instruction can be used to construct a copy of a
sequence of nodes, atomic values, and/or function
items with each new node containing copies of all the children,
attributes, and (by default) namespaces of the original node, recursively. The
result of evaluating the instruction is a sequence of items corresponding
one-to-one with the supplied sequence, and retaining its order.
The required
select
attribute contains an expression, whose value may be any sequence of nodes, atomic values,
and/or function items. The items in this
sequence are processed as follows:
If the item is an element node, a new element is constructed and appended to the result sequence. The new element will have the same expanded QName as the original, and it will have deep copies of the attribute nodes and children of the element node.
The new element will also have namespace nodes copied from the original
element node, unless they are excluded by specifying
copy-namespaces="no"
. If this attribute is omitted, or takes
the value yes
, then all the namespace nodes of the original
element are copied to the new element. If it takes the value
no
, then none of the namespace nodes are copied: however,
namespace nodes will still be created in the result tree as required by the namespace
fixup process: see 5.7.3 Namespace Fixup. This attribute affects
all elements copied by this instruction: both elements selected directly by
the select
expression, and elements that are
descendants of nodes selected by the select
expression.
The values of the is-id
,
is-idrefs
, and nilled
properties of the new
element depend on the values of the validation
and
type
attributes, as defined in 25.4 Validation.
If the item is a document node, the instruction adds a new document node to
the result sequence; the children of this document node will be one-to-one
copies of the children of the original document node (each copied according
to the rules for its own node kind). The
unparsed-entities
property of the original document node
is copied to the new document node.
If the item is an attribute or namespace node, or a text node, a comment, or
a processing instruction, the same rules apply as with
xsl:copy
(see 11.9.1 Shallow Copy).
If the item is an atomic value or a function
item, the value is appended to the result sequence, as with
xsl:sequence
.
The optional attributes type
and validation
may be used
on the xsl:copy-of
instruction to validate the contents of an
element, attribute or document node against a type definition, element
declaration, or attribute declaration in a schema and thus to determine the
type annotation that the new copy of an element or
attribute node will carry. These attributes are applied individually to each
element, attribute, and document node that is selected by the expression in the
select
attribute. These attributes are ignored when copying an
item that is not an element, attribute or document node.
The specified type
and validation
apply directly only to
elements, attributes and document nodes created as copies of nodes actually
selected by the select
expression, they do not apply to nodes that
are implicitly copied because they have selected nodes as an ancestor. However,
these attributes do indirectly affect the type
annotation carried by such implicitly copied nodes, as a consequence
of the validation process.
These two attributes are both optional, and if one is specified then the other must be omitted. The permitted values of these attributes and their semantics are described in 25.4 Validation.
Errors may occur when copying namespace-sensitive elements or attributes using
validation="preserve"
. [see ERR XTTE0950].
If removal of namespaces is requested using
copy-namespaces="no"
, then any validation that is requested is
applied to the tree that remains after the relevant namespaces have been removed.
This will cause validation to fail if there is namespace-sensitive content that
depends on the presence of the removed namespaces.
The base URI of a node is copied, except in the case of an element node having an
xml:base
attribute, in which case the base URI of the new node is
taken as the value of the xml:base
attribute, resolved if it is
relative against the base URI of the xsl:copy-of
instruction. If
the copied node is subsequently attached as a child to a new element or document
node, the final copy of the node inherits its base URI from its parent node,
unless this is overridden using an xml:base
attribute.
The effect of the copy-accumulators
attribute is described in
18.2.2 Applicability of Accumulators.
<!-- Category: instruction -->
<xsl:sequence
select? = expression >
<!-- Content: sequence-constructor -->
</xsl:sequence>
The xsl:sequence
instruction may be used within a sequence constructor to construct a
sequence of nodes, atomic values, and/or function
items. This sequence is returned as the result of the instruction. Unlike
most other instructions, xsl:sequence
can return a sequence
containing existing nodes, rather than constructing new nodes. When
xsl:sequence
is used to select atomic values or function items, the effect is very similar to the
xsl:copy-of
instruction.
The items comprising the result sequence are evaluated either using
the select
attribute, or using the contained sequence constructor. These are mutually exclusive; if the instruction
has a select
attribute, then it must have no children
other than xsl:fallback
instructions. If there is no
select
attribute and no contained sequence constructor, the result is an empty sequence.
[ERR XTSE3185] It is a static error if the
select
attribute of xsl:sequence
is present
and the instruction has children other than xsl:fallback
.
Any contained xsl:fallback
instructions are ignored by an XSLT 2.0
or 3.0 processor, but can be used to define
fallback behavior for an XSLT 1.0 processor running in forwards compatibility
mode.
The following code:
<xsl:variable name="values" as="xs:integer*"> <xsl:sequence select="(1,2,3,4)"/> <xsl:sequence select="(8,9,10)"/> </xsl:variable> <xsl:value-of select="sum($values)"/>
produces the output: 37
The following code constructs a sequence containing the value of the
@price
attribute for selected elements (which we assume to be
typed as xs:decimal
), or a computed price for those elements that
have no @price
attribute. It then returns the average price:
<xsl:variable name="prices" as="xs:decimal*"> <xsl:for-each select="//product"> <xsl:choose> <xsl:when test="@price"> <xsl:sequence select="@price"/> </xsl:when> <xsl:otherwise> <xsl:sequence select="@cost * 1.5"/> </xsl:otherwise> </xsl:choose> </xsl:for-each> </xsl:variable> <xsl:value-of select="avg($prices)"/>
Note that the existing @price
attributes could equally have been
added to the $prices
sequence using xsl:copy-of
or
xsl:value-of
. However, xsl:copy-of
would
create a copy of the attribute node, which is not needed in this situation, while
xsl:value-of
would create a new text node, which then has to
be converted to an xs:decimal
. Using xsl:sequence
,
which in this case atomizes the existing attribute node and adds an
xs:decimal
atomic value to the result sequence, is a more direct
way of achieving the same result.
This example could alternatively be solved at the XPath level:
<xsl:value-of select="avg(//product/(+@price, @cost*1.5)[1])"/>
The apparently redundant +
operator is there to atomize the attribute
value: the expression on the right hand side of the /
operator must
not return a sequence containing both nodes and
non-nodes (atomic values or function items).
Note:
The main use case for allowing xsl:sequence
to contain a sequence
constructor is to allow the instructions within an xsl:fork
element to be divided into groups.
It can also be used to limit the scope of local variables or of standard
attributes such as [xsl:]default-collation
.
<!-- Category: instruction -->
<xsl:number
value? = expression
select? = expression
level? = "single" | "multiple" | "any"
count? = pattern
from? = pattern
format? = { string }
lang? = { language }
letter-value? = { "alphabetic" | "traditional" }
ordinal? = { string }
start-at? = { string }
grouping-separator? = { char }
grouping-size? = { integer } />
The xsl:number
instruction is used to create a formatted number. The
result of the instruction is a newly constructed text node containing the formatted
number as its string value.
[Definition: The xsl:number
instruction performs two tasks: firstly, determining a place marker
(this is a sequence of integers, to allow for hierarchic numbering schemes such as
1.12.2
or 3(c)ii
), and secondly, formatting the place
marker for output as a text node in the result sequence.] The place marker
to be formatted can either be supplied directly, in the value
attribute, or
it can be computed based on the position of a selected node within the tree that
contains it.
[ERR XTSE0975] It is a static error if the
value
attribute of xsl:number
is present unless
the select
, level
, count
, and
from
attributes are all absent.
Note:
The facilities described in this section are specifically designed to enable the
calculation and formatting of section numbers, paragraph numbers, and the like. For
formatting of other numeric quantities, the format-number
FO30
function may be more suitable.
Furthermore, formatting of integers where there is no requirement to calculate the
position of a node in the document can now be accomplished using the
format-integer
FO30 function, which borrows many concepts from
the xsl:number
specification.
start-at
AttributeThe effective value of the
start-at
attribute must be a string representing a
whitespace-separated sequence of one or more integers, each one optionally preceded
by a minus sign, separated by whitespace. More specifically, the value must be a
string matching the regular expression -?[0-9]+(\s+-?[0-9]+)*
. This
sequence of integers is used to re-base the sequence of integers being
formatted. Specifically if $S is the sequence of integers represented by
the start-at
attribute, and $V is the sequence of integers to
be formatted, then the following transformation is applied to $V:
for $i in 1 to count($V) return if ($i le count($S)) then $V[$i] + $S[$i] - 1 else $V[$i] + $S[last()] - 1
Note:
This means that if there are N integers in the start-at
attribute, then these are used to re-base the first N numbers, while
numbers after the Nth are re-based using the last (Nth)
integer in the start-at
attribute. If the start-at
attribute contains more integers than are required, the surplus is ignored.
For example, if the attribute is given as
start-at="3 0 0"
, and the number sequence to be formatted is
(1, 1, 1, 1)
, then the re-based sequence is 3, 0, 0,
0
.
The place marker to be formatted may be
specified by an expression. The value
attribute contains the expression. The value of this expression is atomized using the procedure defined in [XPath 3.0], and each value $V in the atomized sequence is then
converted to the integer value returned by the XPath expression
xs:integer(round(number($V)))
. If
the start-at
attribute is present, this sequence is then re-based as
described in 12.1 The start-at Attribute. The resulting sequence of
integers is used as the place marker to be formatted.
If the instruction is processed with XSLT 1.0 behavior, then:
All items in the atomized sequence after the first are discarded;
If the atomized sequence is empty, it is replaced by a sequence containing the
xs:double
value NaN
as its only item;
If any value in the sequence cannot be converted to an integer (this includes
the case where the sequence contains a NaN
value) then the string
NaN
is inserted into the formatted result string in its proper
position. The error described in the following paragraph does not apply in this
case.
[ERR XTDE0980] It is a dynamic error if any undiscarded item
in the atomized sequence supplied as the value of the value
attribute of xsl:number
cannot be converted to an integer, or
if the resulting integer is less than 0 (zero).
Note:
The value zero does not arise when numbering nodes in a source document, but it
can arise in other numbering sequences. It is permitted specifically because the
rules of the xsl:number
instruction are also invoked by functions
such as format-time
FO30: the minutes and seconds component of a
time value can legitimately be zero.
The resulting sequence is formatted as a string using the effective values of the attributes specified in
12.4 Number to String Conversion Attributes; each of these attributes is interpreted as an attribute value template. After
conversion, the xsl:number
element constructs a new text node
containing the resulting string, and returns this node.
If no value
attribute is specified, then the xsl:number
instruction returns a new text node containing a formatted place marker that is based on the position of a
selected node within its containing document. If the select
attribute is
present, then the expression contained in the select
attribute is
evaluated to determine the selected node. If the select
attribute is
omitted, then the selected node is the context
node.
[ERR XTTE0990] It is a type error if the
xsl:number
instruction is evaluated, with no
value
or select
attribute, when the context item is not a node.
[ERR XTTE1000] It is a type error if the result of
evaluating the select
attribute of the xsl:number
instruction is anything other than a single node.
The following attributes control how the selected node is to be numbered:
The level
attribute specifies rules for selecting the nodes that
are taken into account in allocating a number; it has the values
single
, multiple
or any
. The default
is single
.
The count
attribute is a pattern that specifies which nodes are to be counted at those
levels. If count
attribute is not specified, then it defaults to
the pattern that matches any node with the same node kind as the selected node
and, if the selected node has an expanded
QName, with the same expanded
QName as the selected node.
The from
attribute is a pattern that specifies where counting starts.
In addition, the attributes specified in 12.4 Number to String Conversion Attributes are used for number
to string conversion, as in the case when the value
attribute is
specified.
The xsl:number
element first constructs a sequence of positive
integers using the level
, count
and from
attributes. Where level
is single
or any
, this
sequence will either be empty or contain a single number; where level
is
multiple
, the sequence may be of any length. The sequence is
constructed as follows:
Let matches-count($node)
be a function that returns true if and only if
the given node $node
matches the pattern given in the count
attribute, or the implied pattern (according to the rules given above) if the
count
attribute is omitted.
Let matches-from($node)
be a function that returns true if and only if
the given node $node
matches the pattern given in the from
attribute, or if $node
is the root node of a tree. If the
from
attribute is omitted, then the function returns true if and only
if $node
is the root node of a tree.
Let $S
be the selected node.
When level="single"
:
Let $A
be the node sequence selected by the following
expression:
$S/ancestor-or-self::node()[matches-count(.)][1]
(this selects the innermost ancestor-or-self node that matches the
count
pattern)
Let $F
be the node sequence selected by the expression:
$S/ancestor-or-self::node()[matches-from(.)][1]
(this selects the innermost ancestor-or-self node that matches the
from
pattern)
Let $AF
be the value of:
$A[ancestor-or-self::node()[. is $F]]
(this selects $A if it is in the subtree rooted at $F, or the empty sequence otherwise)
If $AF
is empty, return the empty sequence, ()
Otherwise return the value of:
1 + count($AF/preceding-sibling::node()[matches-count(.)])
(the number of preceding siblings of the counted node that match the
count
pattern, plus one).
When level="multiple"
:
Let $A
be the node sequence selected by the expression:
$S/ancestor-or-self::node()[matches-count(.)]
(the set of ancestor-or-self nodes that match the count
pattern)
Let $F
be the node sequence selected by the expression:
$S/ancestor-or-self::node()[matches-from(.)][1]
(the innermost ancestor-or-self node that matches the from
pattern)
Let $AF
be the value of:
$A[ancestor-or-self::node()[. is $F]]
(the nodes selected in the first step that are in the subtree rooted at the node selected in the second step)
Return the result of the expression:
for $af in $AF return
1+count($af/preceding-sibling::node()[matches-count(.)])
(a sequence of integers containing, for each of these nodes, one plus the
number of preceding siblings that match the count
pattern)
When level="any"
:
Let $A
be the node sequence selected by the expression:
$S/(preceding::node()|ancestor-or-self::node())[matches-count(.)]
(the set of nodes consisting of the selected node together with all nodes,
other than attributes and namespaces, that precede the selected node in
document order, provided that they match the count
pattern)
Let $F
be the node sequence selected by the expression:
$S/(preceding::node()|ancestor-or-self::node())[matches-from(.)][last()]
(the last node in document order that matches the from
pattern and
that precedes the selected node, using the same definition)
Let $AF
be the node sequence $A[. is $F or . >>
$F]
(the nodes selected in the first step, excluding those that precede the node selected in the second step)
If $AF
is empty, return the empty sequence, ()
Otherwise return the value of the expression count($AF)
The resulting sequence of numbers is referred to as the place marker.
If the start-at
attribute is present, then the
place marker is re-based as described in 12.1 The start-at Attribute.
The sequence of numbers is then converted into a string using the effective values of the attributes specified in
12.4 Number to String Conversion Attributes; each of these attributes is interpreted as an attribute value template. After
conversion, the resulting string is used to create a text node, which forms the
result of the xsl:number
instruction.
The following will number the items in an ordered list:
<xsl:template match="ol/item"> <fo:block> <xsl:number/> <xsl:text>. </xsl:text> <xsl:apply-templates/> </fo:block> </xsl:template>
The following two rules will number title
elements. This is intended
for a document that contains a sequence of chapters followed by a sequence of
appendices, where both chapters and appendices contain sections, which in turn
contain subsections. Chapters are numbered 1, 2, 3; appendices are numbered A, B,
C; sections in chapters are numbered 1.1, 1.2, 1.3; sections in appendices are
numbered A.1, A.2, A.3. Subsections within a chapter are numbered 1.1.1, 1.1.2,
1.1.3; subsections within an appendix are numbered A.1.1, A.1.2, A.1.3.
<xsl:template match="title"> <fo:block> <xsl:number level="multiple" count="chapter|section|subsection" format="1.1 "/> <xsl:apply-templates/> </fo:block> </xsl:template> <xsl:template match="appendix//title" priority="1"> <fo:block> <xsl:number level="multiple" count="appendix|section|subsection" format="A.1 "/> <xsl:apply-templates/> </fo:block> </xsl:template>
Note:
This specification is aligned with that of the
format-integer
FO30 function, but there are differences; for
example grouping separators are part of the primary format token in
format-integer
FO30, but are indicated by separate attributes
in xsl:number
.
The following attributes are used to control conversion of a sequence of numbers into a string. The numbers are integers greater than or equal to 0 (zero). The attributes are all optional.
The main attribute is format
. The default value for the
format
attribute is 1
. The format
attribute
is split into a sequence of tokens where each token is a maximal sequence of
alphanumeric characters or a maximal sequence of non-alphanumeric characters.
Alphanumeric means any character that has a Unicode category of Nd,
Nl, No, Lu, Ll, Lt, Lm or Lo (see [UNICODE]). The alphanumeric tokens (format tokens)
indicate the format to be used for each number in the sequence; in most cases the
format token is the same as the required representation of the number 1 (one).
Each non-alphanumeric token is either a prefix, a separator, or a suffix. If there is a non-alphanumeric token but no format token, then the single non-alphanumeric token is used as both the prefix and the suffix. The prefix, if it exists, is the non-alphanumeric token that precedes the first format token: the prefix always appears exactly once in the constructed string, at the start. The suffix, if it exists, is the non-alphanumeric token that follows the last format token: the suffix always appears exactly once in the constructed string, at the end. All other non-alphanumeric tokens (those that occur between two format tokens) are separator tokens and are used to separate numbers in the sequence.
The nth format token is used to format the nth number in the
sequence. If there are more numbers than format tokens, then the last format token
is
used to format remaining numbers. If there are no format tokens, then a format token
of 1
is used to format all numbers. Each number after the first is
separated from the preceding number by the separator token preceding the format token
used to format that number, or, if that is the first format token, then by
.
(dot).
Given the sequence of numbers 5, 13, 7
and the format token
A-001(i)
, the output will be the string E-013(vii)
Format tokens are interpreted as follows:
Any token where the last character has a decimal digit value of 1 (as specified
in the Unicode character property database, see [UNICODE]), and the Unicode
value of preceding characters is one less than the Unicode value of the last
character generates a decimal representation of the number where each number is
at least as long as the format token. The digits used in the decimal
representation are the set of digits containing the digit character used in the
format token. Thus, a format token 1
generates the sequence
0 1 2 ... 10 11 12 ...
, and a format token 01
generates the sequence 00 01 02 ... 09 10 11 12 ... 99 100 101
. A
format token of ١
(Arabic-Indic digit one) generates the
sequence ١
then ٢
then
٣
...
A format token A
generates the sequence A B C ... Z AA AB
AC...
.
A format token a
generates the sequence a b c ... z aa ab
ac...
.
A format token i
generates the sequence i ii iii iv v vi vii
viii ix x ...
.
A format token I
generates the sequence I II III IV V VI VII
VIII IX X ...
.
A format token w
generates numbers written as lower-case words,
for example in English, one two three four ...
.
A format token W
generates numbers written as upper-case words,
for example in English, ONE TWO THREE FOUR ...
.
A format token Ww
generates numbers written as title-case words,
for example in English, One Two Three Four ...
.
Any other format token indicates a numbering sequence in which that token
represents the number 1 (one) (but see the note below).
It is implementation-defined which numbering sequences,
additional to those listed above, are supported. If an implementation does not
support a numbering sequence represented by the given token, it
must use a format token of 1
.
Note:
In some traditional numbering sequences additional signs are added to denote that the letters should be interpreted as numbers; these are not included in the format token. An example, see also the example below, is classical Greek where a dexia keraia and sometimes an aristeri keraia is added.
For all format tokens other than the first kind above (one that consists of decimal
digits), there may be implementation-defined lower and upper bounds on the range of numbers
that can be formatted using this format token; indeed, for some numbering sequences
there may be intrinsic limits. For example, the format
token ①
(circled digit one, ①) has a range imposed
by the Unicode character repertoire (zero to 20 in Unicode versions prior to 3.2,
or zero to 50 in subsequent versions). For the numbering sequences
described above any upper bound imposed by the implementation must
not be less than 1000 (one thousand) and any lower bound must not be
greater than 1. Numbers that fall outside this range must be
formatted using the format token 1
. The numbering sequence associated
with the format token 1
has a lower bound of 0 (zero).
The above expansions of numbering sequences for format tokens such as a
and i
are indicative but not prescriptive. There are various conventions
in use for how alphabetic sequences continue when the alphabet is exhausted, and
differing conventions for how roman numerals are written (for example,
IV
versus IIII
as the representation of the number 4).
Sometimes alphabetic sequences are used that omit letters such as i
and
o
. This specification does not prescribe the detail of any sequence
other than those sequences consisting entirely of decimal digits.
Many numbering sequences are language-sensitive. This applies especially to the
sequence selected by the tokens w
, W
and Ww
.
It also applies to other sequences, for example different languages using the
Cyrillic alphabet use different sequences of characters, each starting with the
letter #x410 (Cyrillic capital letter A). In such cases, the lang
attribute specifies which language’s conventions are to be used; its effective
value
must either be a string in the value space of
xs:language
, or a zero-length string. If no
lang
value is specified, or if the
value is a zero-length string, the language that is used is implementation-defined. The set of
languages for which numbering is supported is implementation-defined. If a language is
requested that is not supported, the processor may use a fallback language identified by removing
successive hyphen-separated suffixes from the supplied value until a supported
language code is obtained; failing this, the processor uses the language
that it would use if the lang
attribute were omitted.
The optional ordinal
attribute is used to
indicate whether cardinal or ordinal numbers are required, and to select other
options relating to the grammatical context of the number to be formatted. The
allowed set of values is implementation-defined. If the attribute
is absent, or if its value is zero-length, or if its value is no
or
0
or false
, then cardinal numbers appropriate to the
selected language are output. If the value is yes
or 1
or
true
, then ordinal numbers appropriate to the target language are
output. Other values are implementation-defined.
For example, in English, the value ordinal="yes"
when used with the
format token 1
outputs the sequence 1st 2nd 3rd 4th ...
,
and when used with the format token w
outputs the sequence first
second third fourth ...
.
Note:
In some languages, the form of numbers (especially ordinal numbers) varies
depending on the grammatical context: they may have different genders and may
decline with the noun that they qualify. In such cases the value of the
ordinal
attribute may be used to indicate the variation of the
cardinal or ordinal number required, in an implementation-defined way.
The way in which the variation is indicated will depend on the conventions of the language.
For inflected languages that vary the ending of the word, the approach recommended
in the previous version of this specification was to indicate the required ending,
preceded by a hyphen: for example in German, appropriate values might be
ordinal="-e"
, ordinal="-er"
,
ordinal="-es"
, ordinal="-en"
.
Another approach, which might usefully be adopted by an implementation based on
the open-source ICU localization library [ICU], or any other library
making use of the Unicode Common Locale Data Repository [Unicode CLDR], is
to allow the value of the attribute to be the name of a registered numbering rule
set for the language in question, conventionally prefixed with a percent sign: for
example, ordinal="%spellout-ordinal-masculine"
, or
ordinal="%spellout-cardinal-year"
. (The attribute name
ordinal
in this case is a misnomer, but serves the purpose.)
The specification format="1" ordinal="-º" lang="it"
, if supported,
should produce the sequence:
1º 2º 3º 4º ...
The specification format="Ww" ordinal="-o" lang="it"
, if supported,
should produce the sequence:
Primo Secondo Terzo Quarto Quinto ...
The letter-value
attribute disambiguates between numbering sequences
that use letters. In many languages there are two commonly used numbering sequences
that use letters. One numbering sequence assigns numeric values to letters in
alphabetic sequence, and the other assigns numeric values to each letter in some
other manner traditional in that language. In English, these would correspond to the
numbering sequences specified by the format tokens a
and i
.
In some languages, the first member of each sequence is the same, and so the format
token alone would be ambiguous. A value of alphabetic
specifies the
alphabetic sequence; a value of traditional
specifies the other
sequence. If the letter-value
attribute is not specified, then it is
implementation-dependent how
any ambiguity is resolved.
Note:
Implementations may use extension
attributes on xsl:number
to provide additional
control over the way in which numbers are formatted.
The grouping-separator
attribute gives the separator used as a grouping
(for example, thousands) separator in decimal numbering sequences, and the optional
grouping-size
specifies the size (normally 3) of the grouping. For
example, grouping-separator=","
and grouping-size="3"
would
produce numbers of the form 1,000,000
while
grouping-separator="."
and grouping-size="2"
would
produce numbers of the form 1.00.00.00
. If only one of the
grouping-separator
and grouping-size
attributes is
specified, then it is ignored.
The effective
value of the grouping-separator
attribute
may be any string, including a zero-length string.
The effective
value of the grouping-size
attribute
must be a string in the lexical space of
xs:integer
. If the resulting integer is positive then it defines the
number of digits between adjacent grouping separators; it if is zero or negative,
then no grouping separators are inserted.
These examples use non-Latin characters which might not display correctly in all browsers, depending on the system configuration.
Description | Format Token | Sequence |
---|---|---|
French cardinal words |
format="Ww" lang="fr"
|
Un, Deux, Trois, Quatre |
German ordinal words |
format="w" ordinal="-e" lang="de"
|
erste, zweite, dritte, vierte |
Katakana numbering |
format="ア"
|
ア, イ, ウ, エ, オ, カ, キ, ク, ケ, コ, サ, シ, ス, セ, ソ, タ, チ, ツ, テ, ト, ナ, ニ, ヌ, ネ, ノ, ハ, ヒ, フ, ヘ, ホ, マ, ミ, ム, メ, モ, ヤ, ユ, ヨ, ラ, リ, ル, レ, ロ, ワ, ヰ, ヱ, ヲ, ン |
Katakana numbering in iroha order |
format="イ"
|
イ, ロ, ハ, ニ, ホ, ヘ, ト, チ, リ, ヌ, ル, ヲ, ワ, カ, ヨ, タ, レ, ソ, ツ, ネ, ナ, ラ, ム, ウ, ヰ, ノ, オ, ク, ヤ, マ, ケ, フ, コ, エ, テ, ア, サ, キ, ユ, メ, ミ, シ, ヱ, ヒ, モ, セ, ス |
Thai numbering |
format="๑"
|
๑, ๒, ๓, ๔, ๕, ๖, ๗, ๘, ๙, ๑๐, ๑๑, ๑๒, ๑๓, ๑๔, ๑๕, ๑๖, ๑๗, ๑๘, ๑๙, ๒๐ |
Traditional Hebrew numbering |
format="א" letter-value="traditional"
|
א, ב, ג, ד, ה, ו, ז, ח, ט, י, יא, יב, יג, יד, טו, טז, יז, יח, יט, כ |
Traditional Georgian numbering |
format="ა" letter-value="traditional"
|
ა, ბ, გ, დ, ე, ვ, ზ, ჱ, თ, ი, ია, იბ, იგ, იდ, იე, ივ, იზ, იჱ, ით, კ |
Classical Greek numbering (see note) |
format="α" letter-value="traditional"
|
αʹ, βʹ, γʹ, δʹ, εʹ, ϛʹ, ζʹ, ηʹ, θʹ, ιʹ, ιαʹ, ιβʹ, ιγʹ, ιδʹ, ιεʹ, ιϛʹ, ιζʹ, ιηʹ, ιθʹ, κʹ |
Old Slavic numbering |
format="а" letter-value="traditional"
|
А, В, Г, Д, Е, Ѕ, З, И, Ѳ, Ӏ, АӀ, ВӀ, ГӀ, ДӀ, ЕӀ, ЅӀ, ЗӀ, ИӀ, ѲӀ, К |
Note that Classical Greek is an example where the format token is not the same as the representation of the number 1.
[Definition: A sort key
specification is a sequence of one or more adjacent
xsl:sort
elements which together define rules for sorting the
items in an input sequence to form a sorted sequence.]
[Definition: Within a sort key specification, each
xsl:sort
element defines one sort key
component.] The first xsl:sort
element specifies the
primary component of the sort key specification, the second xsl:sort
element specifies the secondary component of the sort key specification, and so on.
A sort key specification may occur immediately within an
xsl:apply-templates
, xsl:for-each
,
xsl:perform-sort
, or xsl:for-each-group
element.
Note:
When used within xsl:for-each
, xsl:for-each-group
,
or xsl:perform-sort
, xsl:sort
elements must occur
before any other children.
xsl:sort
Element<xsl:sort
select? = expression
lang? = { language }
order? = { "ascending" | "descending" }
collation? = { uri }
stable? = { boolean }
case-order? = { "upper-first" | "lower-first" }
data-type? = { "text" | "number" | eqname } >
<!-- Content: sequence-constructor -->
</xsl:sort>
The xsl:sort
element defines a sort key component. A sort key component specifies how a sort key value is to be computed for each item
in the sequence being sorted, and also how two sort key values are to be
compared.
The value of a sort key component is
determined either by its select
attribute or by the contained sequence constructor. If neither is
present, the default is select="."
, which has the effect of sorting on
the actual value of the item if it is an atomic value, or on the typed-value of the
item if it is a node. If a select
attribute is present, its value
must be an XPath expression.
[ERR XTSE1015] It is a static error if an
xsl:sort
element with a select
attribute has
non-empty content.
Those attributes of the xsl:sort
elements whose values are attribute value templates are
evaluated using the same focus as is used to
evaluate the select
attribute of the containing instruction
(specifically, xsl:apply-templates
, xsl:for-each
,
xsl:for-each-group
, or xsl:perform-sort
).
The stable
attribute is permitted only on the first
xsl:sort
element within a sort key specification.
[ERR XTSE1017] It is a static error if an
xsl:sort
element other than the first in a sequence of
sibling xsl:sort
elements has a stable
attribute.
[Definition: A sort
key specification is said to be stable if its first
xsl:sort
element has no stable
attribute, or has
a stable
attribute whose effective
value is yes
.]
[Definition: The sequence to be sorted is referred to as the initial sequence.]
[Definition: The sequence after sorting
as defined by the xsl:sort
elements is referred to as the
sorted sequence.]
[Definition: For each item in the initial sequence, a value is computed for each sort key component within the sort key specification. The value computed for an item by using the Nth sort key component is referred to as the Nth sort key value of that item.]
The items in the initial sequence are
ordered into a sorted sequence by
comparing their sort key values. The
relative position of two items A and B in the sorted
sequence is determined as follows. The first sort key value of A is
compared with the first sort key value of B, according to the rules of
the first sort key component. If,
under these rules, A is less than B, then A will
precede B in the sorted sequence, unless the order
attribute of this sort key
component specifies descending
, in which case
B will precede A in the sorted sequence. If, however, the
relevant sort key values compare equal, then the second sort key value of
A is compared with the second sort key value of B,
according to the rules of the second sort key
component. This continues until two sort key values are found that
compare unequal. If all the sort key values compare equal, and the sort key specification is stable, then A will precede B
in the sorted sequence if and only if
A preceded B in the initial sequence. If all the sort key values compare equal, and the
sort key specification is
not stable, then the relative order of
A and B in the sorted
sequence is implementation-dependent.
Note:
If two items have equal sort key
values, and the sort is stable,
then their order in the sorted
sequence will be the same as their order in the initial sequence, regardless of whether
order="descending"
was specified on any or all of the sort key components.
The Nth sort key value is computed by evaluating either the
select
attribute or the contained sequence constructor of the
Nth xsl:sort
element, or the expression
.
(dot) if neither is present. This evaluation is done with the
focus set as follows:
The context item is the item in the initial sequence whose sort key value is being computed.
The context position is the position of that item in the initial sequence.
The context size is the size of the initial sequence.
Note:
As in any other XPath expression, the current
function may
be used within the select
expression of xsl:sort
to refer to the item that is the context item for the expression as a whole;
that is, the item whose sort key
value is being computed.
The sort key values are atomized, and are then compared. The way they are compared depends on their datatype, as described in the next section.
It is possible to force the system to compare sort key values using the rules for a particular datatype by
including a cast as part of the sort key
component. For example, <xsl:sort
select="xs:date(@dob)"/>
will force the attributes to be compared as
dates. In the absence of such a cast, the sort key values are compared using the
rules appropriate to their datatype. Any values of type
xs:untypedAtomic
are cast to xs:string
.
For backwards compatibility with XSLT 1.0, the data-type
attribute
remains available. If this has the effective
value
text
, the atomized sort key
values are converted to strings before being compared. If it has the
effective value number
, the atomized sort key values are converted to
doubles before being compared. The conversion is done by using the
string
FO30 or number
FO30 function as
appropriate. If the data-type
attribute has
any other effective value, then
this value must be an EQName denoting an expanded
QName with a non-absent namespace, and the effect of the
attribute is implementation-defined.
[ERR XTTE1020] If any sort key value, after
atomization and any type
conversion required by the data-type
attribute, is a sequence containing more than one item, then the effect
depends on whether the xsl:sort
element is processed with XSLT 1.0
behavior. With XSLT 1.0 behavior, the effective
sort key value is the first item in the sequence. In other cases, this is a
type error.
The set of sort key values (after any conversion) is first divided into two categories: empty values, and ordinary values. The empty sort key values represent those items where the sort key value is an empty sequence. These values are considered for sorting purposes to be equal to each other, but less than any other value. The remaining values are classified as ordinary values.
[ERR XTDE1030] It is a dynamic error if, for any sort key component, the set of
sort key values evaluated for
all the items in the initial
sequence, after any type conversion requested, contains a pair
of ordinary values for which the result of the XPath lt
operator is an error. If the processor is
able to detect the error statically, it may optionally
signal it as a static
error.
Note:
The above error condition may occur if the values to be sorted are of a type
that does not support ordering (for example, xs:QName
) or if the
sequence is heterogeneous (for example, if it contains both strings and
numbers). The error can generally be prevented by invoking a cast or
constructor function within the sort key component.
The error condition is subject to the usual caveat that a processor is not required to evaluate any expression solely in order to determine whether it raises an error. For example, if there are several sort key components, then a processor is not required to evaluate or compare minor sort key values unless the corresponding major sort key values are equal.
In general, comparison of two ordinary values is performed according to the rules
of the XPath lt
operator. To ensure a total ordering, the same
implementation of the lt
operator must be used for
all the comparisons: the one that is chosen is the one appropriate to the most
specific type to which all the values can be converted by subtype substitution
and/or type promotion. For example, if the sequence contains both
xs:decimal
and xs:double
values, then the values are
compared using xs:double
comparison, even when comparing two
xs:decimal
values. NaN values, for sorting purposes, are
considered to be equal to each other, and less than any other numeric value.
Special rules also apply to the xs:string
and xs:anyURI
types, and types derived by restriction therefrom, as described in the next
section.
The rules given in this section apply when comparing values whose type is
xs:string
or a type derived by restriction from
xs:string
, or whose type is xs:anyURI
or a type
derived by restriction from xs:anyURI
.
[Definition: Facilities in XSLT 3.0 and XPath 3.0 that require strings to be ordered rely on the concept of a named collation. A collation is a set of rules that determine whether two strings are equal, and if not, which of them is to be sorted before the other.] A collation is identified by a URI, but the manner in which this URI is associated with an actual rule or algorithm is largely implementation-defined.
For more information about collations, see Section
5.3 Comparison of strings
FO30 in [Functions and Operators 3.0]. Some
specifications, for example [UNICODE TR10], use the term “collation”
to describe rules that can be tailored or parameterized for various purposes. In
this specification, a collation URI refers to a collation in which all such
parameters have already been fixed. Therefore, if a collation URI is specified,
other attributes such as case-order
and lang
are
ignored.
Every implementation must
recognize the collation URI
http://www.w3.org/2005/xpath-functions/collation/codepoint
, which
provides the ability to compare strings based on the Unicode codepoint values of
the characters in the string.
Furthermore, every implementation must recognize collation URIs representing tailorings of the Unicode Collation Algorithm (UCA), as described in 13.4 The Unicode Collation Algorithm. Although this form of collation URI must be recognized, implementations are not required to support every possible tailoring.
If the xsl:sort
element has a collation
attribute,
then the strings are compared according to the rules for the named collation: that is, they are compared using the
XPath function call compare($a, $b, $collation)
.
If the effective value of the
collation
attribute of xsl:sort
is a relative
URI, then it is resolved against the base URI of the xsl:sort
element.
[ERR XTDE1035] It is a dynamic error if the
collation
attribute of xsl:sort
(after
resolving against the base URI) is not a URI that is recognized by the
implementation as referring to a collation.
Note:
It is entirely for the implementation to determine whether it recognizes a particular collation URI. For example, if the implementation allows collation URIs to contain parameters in the query part of the URI, it is the implementation that determines whether a URI containing an unknown or invalid parameter is or is not a recognized collation URI. The fact that this situation is described as an error thus does not prevent an implementation applying a fallback collation if it chooses to do so.
The lang
and case-order
attributes are ignored if a
collation
attribute is present. But in the absence of a
collation
attribute, these attributes provide input to an implementation-defined algorithm to
locate a suitable collation:
The lang
attribute indicates that a collation suitable for a
particular natural language should be used. The effective value of the attribute
must
either be a string in the value space of
xs:language
, or a zero-length string. Supplying the
zero-length string has the same effect as omitting the attribute. If a
language is requested that is not supported, the processor
may use a fallback language identified by removing
successive hyphen-separated suffixes from the supplied value until a
supported language code is obtained; failing this, the processor behaves
as if the lang
attribute were omitted.
Note:
The fallback algorithm described above is identical to the rules in RFC4647 Basic Filtering used in BCP 47, and is specified in [RFC4647] in greater detail.
The case-order
attribute indicates whether the desired
collation should sort upper-case letters before
lower-case or vice versa. The effective
value of the attribute must be either
lower-first
(indicating that lower-case letters precede
upper-case letters in the collating sequence) or upper-first
(indicating that upper-case letters precede lower-case).
When lower-first
is requested, the returned collation
should have the property that when two strings differ
only in the case of one or more characters, then a string in which the first
differing character is lower-case should precede a string in which the
corresponding character is title-case, which should in turn precede a string
in which the corresponding character is upper-case. When upper-first is
requested, the returned collation should have the
property that when two strings differ only in the case of one or more
characters, then a string in which the first differing character is
upper-case should precede a string in which the corresponding character is
title-case, which should in turn precede a string in which the corresponding
character is lower-case.
So, for example, if lang="en"
, then A a B b
are
sorted with case-order="upper-first"
and a A b B
are sorted with case-order="lower-first"
.
As a further example, if lower-first
is requested, then a sorted sequence
might be “MacAndrew, macintosh, macIntosh, Macintosh, MacIntosh,
macintoshes, Macintoshes, McIntosh”. If upper-first
is requested, the same
sequence would sort as “MacAndrew, MacIntosh, Macintosh, macIntosh,
macintosh, MacIntoshes, macintoshes, McIntosh”.
If none of the collation
, lang
, or
case-order
attributes is present, the collation is chosen in an
implementation-defined way. It is not
required that the default collation for sorting should be
the same as the default collation
used when evaluating XPath expressions, as described in 5.3.1 Initializing the Static Context and 3.7.1 The default-collation Attribute.
Note:
It is usually appropriate, when sorting, to use a strong collation, that is, one that takes account of secondary differences (accents) and tertiary differences (case) between strings that are otherwise equal. A weak collation, which ignores such differences, may be more suitable when comparing strings for equality.
Useful background information on international sorting is provided in [UNICODE TR10]. The case-order
attribute may be
interpreted as described in section 6.6 of [UNICODE TR10].
<!-- Category: instruction -->
<xsl:perform-sort
select? = expression >
<!-- Content: (xsl:sort+, sequence-constructor) -->
</xsl:perform-sort>
The xsl:perform-sort
instruction is used to return a sorted sequence.
The initial sequence is obtained either
by evaluating the select
attribute or by evaluating the contained
sequence constructor (but not both). If there is no select
attribute and
no sequence constructor then the initial
sequence (and therefore, the sorted
sequence) is an empty sequence.
[ERR XTSE1040] It is a static error if an
xsl:perform-sort
instruction with a select
attribute has any content other than xsl:sort
and
xsl:fallback
instructions.
The result of the xsl:perform-sort
instruction is the result of
sorting its initial sequence using its
contained sort key
specification.
The following stylesheet function sorts a sequence of atomic values using the value itself as the sort key.
<xsl:function name="local:sort" as="xs:anyAtomicType*"> <xsl:param name="in" as="xs:anyAtomicType*"/> <xsl:perform-sort select="$in"> <xsl:sort select="."/> </xsl:perform-sort> </xsl:function>
The following example defines a function that sorts books by price, and uses this function to output the five books that have the lowest prices:
<xsl:function name="bib:books-by-price" as="schema-element(bib:book)*"> <xsl:param name="in" as="schema-element(bib:book)*"/> <xsl:perform-sort select="$in"> <xsl:sort select="xs:decimal(bib:price)"/> </xsl:perform-sort> </xsl:function> ... <xsl:copy-of select="bib:books-by-price(//bib:book) [position() = 1 to 5]"/>
When used within xsl:for-each
or
xsl:apply-templates
, a sort key specification indicates that the sequence of items selected by
that instruction is to be processed in sorted order, not in the order of the supplied
sequence.
For example, suppose an employee database has the form
<employees> <employee> <name> <given>James</given> <family>Clark</family> </name> ... </employee> </employees>
Then a list of employees sorted by name could be generated using:
<xsl:template match="employees"> <ul> <xsl:apply-templates select="employee"> <xsl:sort select="name/family"/> <xsl:sort select="name/given"/> </xsl:apply-templates> </ul> </xsl:template> <xsl:template match="employee"> <li> <xsl:value-of select="name/given"/> <xsl:text> </xsl:text> <xsl:value-of select="name/family"/> </li> </xsl:template>
When used within xsl:for-each-group
, a sort key specification indicates the
order in which the groups are to be processed. For the effect of
xsl:for-each-group
, see 14 Grouping.
The description of the Unicode Collation Algorithm in this section is technically identical to the description found in [XPath 3.1]. The description here is to be used by a processor that does not implement the XPath 3.1 Feature; if the processor does implement the XPath 3.1 Feature, the description in [XPath 3.1] applies.
XSLT 3.0 defines a family of collation URIs representing tailorings of the Unicode Collation Algorithm (UCA) as defined in [UNICODE TR10]. The parameters used for tailoring the UCA are based on the parameters defined in the Locale Data Markup Language (LDML), defined in [UNICODE TR35].
This family of URIs use the scheme and path
http://www.w3.org/2013/collation/UCA
followed by an optional query
part. The query part, if present, consists of a question mark followed by a sequence
of zero or more semicolon-separated parameters. Each parameter is a keyword-value
pair, the keyword and value being separated by an equals sign.
All implementations must recognize URIs in this family. This applies to all places
where collations are used, including (for example) the xsl:sort
,
xsl:key
, xsl:for-each-group
, and
xsl:merge-key
elements, the [xsl:]default-collation
attribute, and the collation
argument of functions such as contains
FO30,
max
FO30,
and collation-key
.
If the fallback
parameter is present with the
value no
, then the implementation must either use a
collation that conforms with the rules in the Unicode specifications for the
requested tailoring, or fail with a static or dynamic error indicating that it does
not provide the collation (the error code should be the same as if the collation URI
were not recognized). If the fallback
parameter is omitted or takes the
value yes
, and if the collation URI is well-formed according to the
rules in this section, then the implementation must accept the
collation URI, and should use the available collation that most
closely reflects the user’s intentions. For example, if the collation URI
requested is http://www.w3.org/2013/collation/UCA?lang=se;fallback=yes
and the implementation does not include a fully conformant version of the UCA
tailored for Swedish, then it may choose to use a Swedish
collation that is known to differ from the UCA definition, or one whose conformance
has not been established. It might even, as a last resort, fall back to using
codepoint collation.
If two query parameters use the same keyword then the last one wins. If a query
parameter uses a keyword or value which is not defined in this specification then
the
meaning is implementation-defined. If the implementation
recognizes the meaning of the keyword and value then it should
interpret it accordingly; if it does not recognize the keyword or value then if the
fallback
parameter is present with the value no
it
should reject the collation as unsupported, otherwise it should ignore the
unrecognized parameter.
The following query parameters are defined. If any parameter is absent, the default is implementation-defined except where otherwise stated. The meaning given for each parameter is non-normative; the normative specification is found in [UNICODE TR35].
Keyword | Values | Meaning |
---|---|---|
fallback | yes | no (default yes) | Determines whether the processor uses a fallback collation if a conformant collation is not available. |
lang | language code, as defined for the lang attribute of
xsl:sort |
The language whose collation conventions are to be used. |
version | string | The version number of the UCA to be used. |
strength | primary | secondary | tertiary | quaternary | identical, or 1|2|3|4|5 as synonyms | The collation strength as defined in UCA. Primary strength takes only the
base form of the character into account (so A=a=Â=â); secondary strength
ignores case but considers accents and diacritics as significant (so A=a and
Â=â but â!=a); tertiary considers case as significant (A!=a!=Â!=â);
quaternary considers spaces and punctuation that would otherwise be ignored
(for example data-base =database ).
|
maxVariable | space | punct | symbol | currency (default punct) |
Indicates that all characters in the specified group and earlier groups are treated
as "noise" characters
to be handled as defined by the alternate parameter.
For example, maxVariable=punct indicates
that characters classified as whitespace or punctuation get this treatment.
|
alternate | non-ignorable | shifted | blanked (default non-ignorable) | Controls the handling of characters such as spaces and hyphens;
specifically, the “noise” characters in the groups selected by the maxVariable parameter.
The value non-ignorable
indicates that such characters are treated as distinct at the primary level
(so data base sorts before datatype );
shifted indicates that they are are used to differentiate two strings only at the
quaternary level,
and blanked indicates that they are taken into account only at the identical level.
|
backwards | yes | no (default no) | The value backwards=yes indicates that the last accent in the
search term is the most significant.
|
normalization | yes | no (default no) | Indicates whether search terms are converted to normalization form D. |
caseLevel | yes | no (default no) | When used with primary strength, setting caseLevel=yes has the
effect of ignoring accents while taking account of case.
|
caseFirst | upper | lower | Indicates whether upper-case precedes lower-case or vice versa. |
numeric | yes | no (default no) | When numeric=yes is specified, a sequence of consecutive
digits is interpreted as a number, for example chap2 sorts
before chap12 .
|
reorder | a comma-separated sequence of reorder codes, where a reorder code is one of
space , punct , symbol ,
currency , digit , or a four-letter script code
defined in [ISO 15924 Register], the register of scripts
maintained by the Unicode Consortium in its capacity as registration
authority for [ISO 15924].
|
Determines the relative ordering of text in different scripts; for example
the value digit,Grek,Latn indicates that digits precede Greek
letters, which precede Latin letters.
|
Note:
This list excludes parameters that are inconvenient to express in a URI, or that are applicable only to substring matching.
The facilities described in this section are designed to allow items in a sequence to be grouped based on common values; for example it allows grouping of elements having the same value for a particular attribute, or elements with the same name, or elements with common values for any other expression. Since grouping identifies items with duplicate values, the same facilities also allow selection of the distinct values in a sequence of items, that is, the elimination of duplicates.
Note:
Simple elimination of duplicates can also be achieved using the function
distinct-values
FO30: see [Functions and Operators 3.0].
In addition these facilities allow grouping based on sequential position, for example
selecting groups of adjacent para
elements. The facilities also provide an
easy way to do fixed-size grouping, for example identifying groups of three adjacent
nodes, which is useful when arranging data in multiple columns.
For each group of items identified, it is possible to evaluate a sequence constructor for the group. Grouping is nestable to multiple levels so that groups of distinct items can be identified, then from among the distinct groups selected, further sub-grouping of distinct items in the current group can be done.
It is also possible for one item to participate in more than one group.
xsl:for-each-group
Element<!-- Category: instruction -->
<xsl:for-each-group
select = expression
group-by? = expression
group-adjacent? = expression
group-starting-with? = pattern
group-ending-with? = pattern
composite? = boolean
collation? = { uri } >
<!-- Content: (xsl:sort*, sequence-constructor) -->
</xsl:for-each-group>
This element is an instruction that may be used anywhere within a sequence constructor.
[Definition: The xsl:for-each-group
instruction allocates the items in an input sequence into groups of
items (that is, it establishes a collection of sequences) based either on common
values of a grouping key, or on a pattern that
the initial or final item in a group must
match.] The sequence
constructor that forms the content of the
xsl:for-each-group
instruction is evaluated once for each of
these groups.
[Definition: The sequence of items to be grouped,
which is referred to as the population, is determined by evaluating
the XPath expression contained in the
select
attribute.]
[Definition: The population is treated as a sequence; the order of items in this sequence is referred to as population order ].
A group is never empty. If the population is empty, the number of groups will be zero.
The assignment of items to groups depends on the group-by
,
group-adjacent
, group-starting-with
, and
group-ending-with
attributes.
[ERR XTSE1080] These four attributes are mutually exclusive: it is a static error if none of these four attributes is present or if more than one of them is present.
[ERR XTSE1090] It is a static error to specify the
collation
attribute or the
composite
attribute if neither the
group-by
attribute nor group-adjacent
attribute is
specified.
[Definition: If either of the
group-by
or group-adjacent
attributes is present,
then for each item in the population a set
of grouping keys is calculated, as follows: the expression contained
in the group-by
or group-adjacent
attribute is
evaluated; the result is atomized; and any xs:untypedAtomic
values
are cast to xs:string
. If
composite="yes"
is specified, there is a single grouping key
whose value is the resulting sequence; otherwise, there is a set of grouping
keys, consisting of the distinct atomic values present in the result
sequence.
]
When calculating grouping keys for an item in the population, the expression contained in the group-by
or
group-adjacent
attribute is evaluated with that item as the context item, with its position in population order as the context position, and with the size of the
population as the context size.
If the group-by
attribute is present, and if
the composite
attribute is omitted or takes the value
no
, then an item in the population may
have multiple grouping keys: that is, the group-by
expression evaluates
to a sequence, and each item in the sequence is treated as
a separate grouping key. The item is included in as many groups as there
are distinct grouping keys (which may be zero).
If the group-adjacent
attribute is used, and
if the composite
attribute is omitted or takes the value
no
, then each item in the population
must have exactly one grouping key value.
[ERR XTTE1100] It is a type error if the result of
evaluating the group-adjacent
expression is an empty sequence or a
sequence containing more than one item, unless
composite="yes"
is specified.
Grouping keys are compared using the rules
for the deep-equal
FO30 function. This
means that values of type xs:untypedAtomic
will be cast to
xs:string
before the comparison, and that items that are not
comparable using the eq
operator are considered to be not equal, that
is, they are allocated to different groups. It also means that the value
NaN
is considered equal to itself. If the values are
strings, or untyped atomic values, then if there is a collation
attribute the values are compared using the collation specified as the effective value of the collation
attribute, resolved if relative against the base URI of the
xsl:for-each-group
element. If there is no collation
attribute then the default collation is
used.
[ERR XTDE1110] It is a dynamic error if the collation URI
specified to xsl:for-each-group
(after resolving against the
base URI) is a collation that is not recognized by the implementation. (For
notes, [see ERR XTDE1035].)
For more information on collations, see 13.1.3 Sorting Using Collations.
The way in which an xsl:for-each-group
element is
evaluated depends on which of the four group-defining attributes is present:
If the group-by
attribute is present, the items in the population are examined, in population order.
For each item J, the expression in the group-by
attribute is evaluated to produce a sequence of zero or more grouping key values. If composite="yes"
is specified, there will be a single
grouping key, which will in general be a sequence of zero or more atomic
values; otherwise, there will be zero or more grouping keys, each of which
will be a single atomic value. For each one of these grouping keys, if there is already a group
created to hold items having that grouping key value, J is appended to that group; otherwise a new group is
created for items with that grouping key value, and J becomes its
first member.
An item in the population may thus be appended to zero, one, or many groups. An item will never be appended more than once to the same group; if two or more grouping keys for the same item are equal, then the duplicates are ignored. An item here means the item at a particular position within the population—if the population contains the same node at several different positions in the sequence then a group may indeed contain duplicate nodes.
The number of groups will be the same as the number of distinct grouping key values present in the population.
If the population contains values of different numeric types that differ from
each other by small amounts, then the eq
operator is not
transitive, because of rounding effects occurring during type promotion. The
effect of this is described in 14.5 Non-Transitivity.
If the group-adjacent
attribute is present, the items in the
population are examined, in
population order. If an item has the same value for the grouping key as its preceding item within
the population (in population order), then it is appended to the same group as its preceding item;
otherwise a new group is created and the item becomes its first member.
If the group-starting-with
attribute is present, then its value
must be a pattern.
The items in the population are examined in population order. If an item matches the pattern, or is the first item in the population, then a new group is created and the item becomes its first member. Otherwise, the item is appended to the same group as its preceding item within the population.
If the group-ending-with
attribute is present, then its value
must be a pattern.
The items in the population are examined in population order. If an item is the first item in the population, or if the previous item in the population matches the pattern, then a new group is created and the item becomes its first member. Otherwise, the item is appended to the same group as its preceding item within the population.
In all cases the order of items within each group is predictable, and reflects the original population order, in that the items are processed in population order and each item is appended at the end of zero or more groups.
Note:
As always, a different algorithm may be used if it achieves the same effect.
[Definition: For each group, the item within the group that is first in population order is known as the initial item of the group.]
The sequence constructor contained in the
xsl:for-each-group
element is evaluated once for each of the
groups, in processing order. The sequences that result are concatenated, in
processing order, to form the result
of the xsl:for-each-group
element. Within the sequence constructor, the context item is the initial item of the relevant group, the context position is the position of this
group in the processing order of the groups, and the context size is the number of groups This has the effect
that within the sequence constructor, a call on
position()
takes successive values 1, 2, ... last()
.
Two pieces of information are available during the processing of each group (that
is,
while evaluating the sequence constructor contained in the
xsl:for-each-group
instruction, and also while evaluating the
sort key of a group as expressed by the select
attribute or sequence
constructor of an xsl:sort
child of the
xsl:for-each-group
element):
[Definition: The current group is the group itself, as a sequence of items].
[Definition: The current grouping key is a single atomic value, or in the case of a composite key, a sequence of atomic values, containing the grouping key of the items in the current group.]
Information about the current group
and the current grouping key is held in the dynamic context, and
is available using the current-group
and
current-grouping-key
functions respectively.
In XSLT 2.0, the current group and the
current grouping key were passed unchanged through calls of
xsl:apply-templates
and xsl:call-template
, and
also xsl:apply-imports
and xsl:next-match
. This
behavior is retained in XSLT 3.0 except in the case where streaming is in use:
specifically, if the xsl:apply-templates
,
xsl:call-template
, xsl:apply-imports
, or
xsl:next-match
instruction occurs within a declared-streamable construct (typically, within an
xsl:source-document
instruction, or within a streamable template rule), then the current group and current grouping key are set
to absent in the called template. The reason for this is to allow
the streamability of an xsl:for-each-group
instruction to be
assessed statically, as described in 19.8.4.19 Streamability of xsl:for-each-group.
Returns the group currently being processed by an xsl:for-each-group
instruction.
This function is deterministicFO30, context-dependentFO30, and focus-independentFO30.
The evaluation context for XPath expressions includes a component called the current group, which is a sequence.
The function current-group
returns the sequence
of items making up the current group.
The current group is bound during evaluation of the
xsl:for-each-group
instruction. If no
xsl:for-each-group
instruction is being evaluated, the current group
will be absent: that is, any reference to it will cause a dynamic
error.
The effect of invocation constructs on the current group is as follows:
If the invocation construct is contained within a declared-streamable
construct (for example, if it is within an
xsl:source-document
instruction with the attribute streamable="yes"
,
or within a streamable template), then the
invocation construct sets the current group to absent. In this
situation the scope of the current group is effectively static; it can only be
referenced within the body of the xsl:for-each-group
instruction
to which it applies.
If the invocation construct is a (static or dynamic) function call, then the invocation construct sets the current group to absent.
Otherwise the invocation construct leaves the current group unchanged. In this situation the scope of the current group is effectively dynamic: it can be referenced within called templates and attribute sets.
The current group is initially absent
during the evaluation of global variables and stylesheet parameters, during the
evaluation of the use
attribute or contained sequence constructor of xsl:key
,
and during the evaluation of the initial-value
attribute of xsl:accumulator
and the select
attribute of contained sequence constructor of xsl:accumulator-rule
.
[ERR XTSE1060] It is a static error if the
current-group
function is used within a pattern.
[ERR XTDE1061] It is a dynamic error if the
current-group
function is used when the current group is
absent
, or when it is invoked in the course of evaluating a
pattern. The error may be reported statically if it
can be detected statically.
Like other XSLT extensions to the dynamic evaluation context,
the current group is not retained as part of the closure of a
function value. This means that the expression current-group#0
is valid and
returns a function value, but any invocation of this function will fail with a dynamic
error [see ERR XTDE1061].
Returns the grouping key of the group currently being processed using the
xsl:for-each-group
instruction.
This function is deterministicFO30, context-dependentFO30, and focus-independentFO30.
The evaluation context for XPath expressions includes a component called the current grouping key, which is a sequence of atomic values. The current grouping key is the grouping key shared in common by all the items within the current group.
The function current-grouping-key
returns the current grouping key.
The current grouping key is bound during evaluation of an
xsl:for-each-group
instruction that has a group-by
or
group-adjacent
attribute. If no
xsl:for-each-group
instruction is being evaluated, the current
grouping key will be absent, which means that any reference to it
causes a dynamic error. The current grouping key is also set to absent during the evaluation of an xsl:for-each-group
instruction with a group-starting-with
or group-ending-with
attribute.
The effect of invocation constructs on the current grouping key is as follows:
If the invocation construct is contained within a declared-streamable
construct (for example, if it is within an
xsl:source-document
instruction with the attribute streamable="yes"
,
or within a streamable template), then the
invocation construct sets the current grouping key to absent.
In this situation the scope of the current group is effectively static; it can
only be referenced within the body of the xsl:for-each-group
instruction to which it applies.
If the invocation construct is a (static or dynamic) function call, then the invocation construct sets the current grouping key to absent.
Otherwise the invocation construct leaves the current grouping key unchanged. In this situation the scope of the current group is effectively dynamic: it can be referenced within called templates and attribute sets.
The current grouping key is initially absent
during the evaluation of global variables and stylesheet parameters, during the
evaluation of the use
attribute or contained sequence constructor of xsl:key
,
and during the evaluation of the initial-value
attribute of xsl:accumulator
and the select
attribute of contained sequence constructor of xsl:accumulator-rule
.
While an xsl:for-each-group
instruction with a group-by
or
group-adjacent
attribute is being evaluated, the current grouping key will be a single atomic
value if composite="no"
is specified (explicitly
or implicitly), or a sequence of atomic values if composite="yes"
is
specified.
At other times, the current grouping key will be absent.
The grouping keys of
all items in a group are not necessarily identical. For example, one might be an
xs:float
while another is a numerically equal
xs:decimal
. The current-grouping-key
function returns the grouping key of the initial item in the group, after atomization and
casting of xs:untypedAtomic
values to xs:string
.
The function takes no arguments.
[ERR XTSE1070] It is a static error if the
current-grouping-key
function is used within a pattern.
[ERR XTDE1071] It is a dynamic error if the
current-grouping-key
function is used when the current
grouping key is absent, or when it is invoked in the course of evaluating a pattern.
The error may be reported statically if it can be detected
statically.
Like other XSLT extensions to the dynamic evaluation context,
the current grouping key is not retained as part of the closure of a
function value. This means that the expression current-grouping-key#0
is
valid and returns a function value, but any invocation of this function will fail
with a
dynamic error [see ERR XTDE1071].
[Definition: There is a total ordering among groups referred to as the order of first appearance. A
group G is defined to precede a group H in order of first
appearance if the initial item of
G precedes the initial item of H in population order. If
two groups G and H have the same initial item (because the
item is in both groups) then G precedes H if the grouping key of G precedes the
grouping key of H in the sequence that results from evaluating the
group-by
expression of this initial item.]
[Definition: There is another total ordering among groups referred to as
processing order. If group R precedes group
S in processing order, then in the result sequence returned by the
xsl:for-each-group
instruction the items generated by
processing group R will precede the items generated by processing group
S.]
If there are no xsl:sort
elements immediately within the
xsl:for-each-group
element, the processing order of the groups is the order of
first appearance.
Otherwise, the xsl:sort
elements immediately within the
xsl:for-each-group
element define the processing order of the
groups (see 13 Sorting). They do
not affect the order of items within each group. Multiple sort key components are allowed, and are
evaluated in major-to-minor order. If two groups have the same values for all their
sort key components, they are processed in order of first appearance if
the sort key specification is
stable, otherwise in an implementation-dependent order.
The select
expression of an xsl:sort
element is evaluated once for each group. During
this evaluation, the context item is the
initial item of the group, the context position is the position of this item
within the set of initial items (that is, one item for each group in the population) in population order, the context
size is the number of groups, the current group is
the group whose sort key value is being
determined, and the current grouping key is the grouping key for
that group. If the xsl:for-each-group
instruction uses the
group-starting-with
or group-ending-with
attributes,
then the current grouping key is absent.
For example, this means that if the grouping
key is @category
, you can sort the groups in order of
their grouping key by writing <xsl:sort
select="current-grouping-key()"/>
; or you can sort the groups in
order of size by writing <xsl:sort
select="count(current-group())"/>
The following example groups a list of nodes based on common values. The resulting groups are numbered and sorted, and a total is calculated for each group.
Source XML document:
<cities> <city name="Milano" country="Italia" pop="5"/> <city name="Paris" country="France" pop="7"/> <city name="München" country="Deutschland" pop="4"/> <city name="Lyon" country="France" pop="2"/> <city name="Venezia" country="Italia" pop="1"/> </cities>
More specifically, the aim is to produce a four-column table, containing one row
for each distinct country. The four columns are to contain first, a sequence
number giving the number of the row; second, the name of the country, third, a
comma-separated alphabetical list of the city names within that country, and
fourth, the sum of the pop
attribute for the cities in that
country.
Desired output:
<table> <tr> <th>Position</th> <th>Country</th> <th>List of Cities</th> <th>Population</th> </tr> <tr> <td>1</td> <td>Italia</td> <td>Milano, Venezia</td> <td>6</td> </tr> <tr> <td>2</td> <td>France</td> <td>Lyon, Paris</td> <td>9</td> </tr> <tr> <td>3</td> <td>Deutschland</td> <td>München</td> <td>4</td> </tr> </table>
Solution:
<table xsl:version="3.0" xmlns:xsl="http://www.w3.org/1999/XSL/Transform"> <tr> <th>Position</th> <th>Country</th> <th>City List</th> <th>Population</th> </tr> <xsl:for-each-group select="cities/city" group-by="@country"> <tr> <td><xsl:value-of select="position()"/></td> <td><xsl:value-of select="current-grouping-key()"/></td> <td> <xsl:for-each select="current-group()/@name"> <xsl:sort select="."/> <xsl:if test="position() ne 1">, </xsl:if> <xsl:value-of select="."/> </xsl:for-each> </td> <td><xsl:value-of select="sum(current-group()/@pop)"/></td> </tr> </xsl:for-each-group> </table>
Sometimes it is necessary to use a composite grouping key: for example, suppose the source document is similar to the one used in the previous examples, but allows multiple entries for the same country and city, such as:
<cities> <city name="Milano" country="Italia" year="1950" pop="5.23"/> <city name="Milano" country="Italia" year="1960" pop="5.29"/> <city name="Padova" country="Italia" year="1950" pop="0.69"/> <city name="Padova" country="Italia" year="1960" pop="0.93"/> <city name="Paris" country="France" year="1951" pop="7.2"/> <city name="Paris" country="France" year="1961" pop="7.6"/> </cities>
Now suppose we want to list the average value of @pop
for each
(country, name) combination. One way to handle this is to concatenate the parts of
the key, for example <xsl:for-each-group select="concat(@country, '/',
@name)">
. A second solution is to nest one
xsl:for-each-group
element directly inside another. XSLT 3.0
introduces a third option, which is to define the grouping key as composite:
<xsl:for-each-group select="cities/city" group-by="@name, @country" composite="yes"> <p> <xsl:value-of select="current-grouping-key()[1] || ', ' || current-grouping-key()[2] || ': ' || avg(current-group()/@pop)"/> </p> </xsl:for-each-group>
Note:
The string concatenation operator ||
is new in XPath 3.0.
The next example identifies a group not by the presence of a common value, but
rather by adjacency in document order. A group consists of an h2
element, followed by all the p
elements up to the next
h2
element.
Source XML document:
<body> <h2>Introduction</h2> <p>XSLT is used to write stylesheets.</p> <p>XQuery is used to query XML databases.</p> <h2>What is a stylesheet?</h2> <p>A stylesheet is an XML document used to define a transformation.</p> <p>Stylesheets may be written in XSLT.</p> <p>XSLT 2.0 introduces new grouping constructs.</p> </body>
Desired output:
<chapter> <section title="Introduction"> <para>XSLT is used to write stylesheets.</para> <para>XQuery is used to query XML databases.</para> </section> <section title="What is a stylesheet?"> <para>A stylesheet is used to define a transformation.</para> <para>Stylesheets may be written in XSLT.</para> <para>XSLT 2.0 introduces new grouping constructs.</para> </section> </chapter>
Solution:
<xsl:template match="body"> <chapter> <xsl:for-each-group select="*" group-starting-with="h2"> <section title="{self::h2}"> <xsl:for-each select="current-group()[self::p]"> <para><xsl:value-of select="."/></para> </xsl:for-each> </section> </xsl:for-each-group> </chapter> </xsl:template>
The use of title="{self::h2}"
rather than title="{.}"
is
to handle the case where the first element is not an h2
element.
The next example illustrates how a group of related elements can be identified by
the last element in the group, rather than the first. Here the absence of the
attribute continued="yes"
indicates the end of the group.
Source XML document:
<doc> <page continued="yes">Some text</page> <page continued="yes">More text</page> <page>Yet more text</page> <page continued="yes">Some words</page> <page continued="yes">More words</page> <page>Yet more words</page> </doc>
Desired output:
<doc> <pageset> <page>Some text</page> <page>More text</page> <page>Yet more text</page> </pageset> <pageset> <page>Some words</page> <page>More words</page> <page>Yet more words</page> </pageset> </doc>
Solution:
<xsl:template match="doc"> <doc> <xsl:for-each-group select="*" group-ending-with="page[not(@continued='yes')]"> <pageset> <xsl:for-each select="current-group()"> <page><xsl:value-of select="."/></page> </xsl:for-each> </pageset> </xsl:for-each-group> </doc> </xsl:template>
The next example shows how an item can be added to multiple groups. Book titles will be added to one group for each indexing term marked up within the title.
Source XML document:
<titles> <title>A Beginner's Guide to <ix>Java</ix></title> <title>Learning <ix>XML</ix></title> <title>Using <ix>XML</ix> with <ix>Java</ix></title> </titles>
Desired output:
<h2>Java</h2> <p>A Beginner's Guide to Java</p> <p>Using XML with Java</p> <h2>XML</h2> <p>Learning XML</p> <p>Using XML with Java</p>
Solution:
<xsl:template match="titles"> <xsl:for-each-group select="title" group-by="ix"> <h2><xsl:value-of select="current-grouping-key()"/></h2> <xsl:for-each select="current-group()"> <p><xsl:value-of select="."/></p> </xsl:for-each> </xsl:for-each-group> </xsl:template>
In this example, the membership of a node within a group is based both on adjacency of the nodes in document order, and on common values. In this case, the grouping key is a boolean condition, true or false, so the effect is that a grouping establishes a maximal sequence of nodes for which the condition is true, followed by a maximal sequence for which it is false, and so on.
Source XML document:
<p>Do <em>not</em>: <ul> <li>talk,</li> <li>eat, or</li> <li>use your mobile telephone</li> </ul> while you are in the cinema.</p>
Desired output:
<p>Do <em>not</em>:</p> <ul> <li>talk,</li> <li>eat, or</li> <li>use your mobile telephone</li> </ul> <p>while you are in the cinema.</p>
Solution:
This requires creating a p
element around the maximal sequence of
sibling nodes that does not include a ul
or ol
element.
This can be done by using group-adjacent
, with a grouping key that is
true if the element is a ul
or ol
element, and false
otherwise:
<xsl:template match="p"> <xsl:for-each-group select="node()" group-adjacent="self::ul or self::ol"> <xsl:choose> <xsl:when test="current-grouping-key()"> <xsl:copy-of select="current-group()"/> </xsl:when> <xsl:otherwise> <p> <xsl:copy-of select="current-group()"/> </p> </xsl:otherwise> </xsl:choose> </xsl:for-each-group> </xsl:template>
If the population contains values of different numeric types that differ from each
other by small amounts, then the eq
operator is not transitive, because
of rounding effects occurring during type promotion. It is thus possible to have
three values A, B, and C among the grouping keys of
the population such that A eq B
, B eq C
, but A ne
C
.
For example, this arises when computing
<xsl:for-each-group group-by="." select=" xs:float('1.0'), xs:decimal('1.0000000000100000000001'), xs:double('1.00000000001')"/>
because the values of type xs:float
and xs:double
both
compare equal to the value of type xs:decimal
but not equal to each
other.
In this situation the results must be equivalent to the results obtained by the following algorithm:
For each item J in the population in population order, for each of the grouping keys K for that item in sequence, the processor identifies those existing groups G such that the grouping key of the initial item of G is equal to K.
If there is exactly one group G, then J is added to this group, unless J is already a member of this group.
If there is no group G, then a new group is created with J as its first item.
If there is more than one group G (which can only happen in exceptional circumstances involving non-transitivity), then one of these groups is selected in an implementation-dependent way, and J is added to this group, unless J is already a member of this group.
The effect of these rules is that (a) every item in a non-singleton group has a grouping key that is equal to that of at least one other item in that group, (b) for any two distinct groups, there is at least one pair of items (one from each group) whose grouping keys are not equal to each other.
The xsl:merge
instruction allows a sorted sequence of items to be
constructed by merging several input sequences. Each
input sequence must have a merge key (one or more
atomic values that can be computed as a function of the items in the sequence); the
input sequence must either already be sorted on the value of
its merge keys, or pre-sorting on these values must be requested.
The merge keys for the different input sequences must be compatible in the sense that key
values from an item in one sequence are always comparable with key values from an
item in a different sequence.
For example, if two log files contain details of events sorted by date and time, then
the xsl:merge
instruction can be used to combine these into a single
sequence that is also sorted by date and time.
The data written to the output sequence can be computed in an arbitrary way from the data in the input sequences, provided it follows the ordering of the input sequences.
The xsl:merge
instruction can be used to merge several sequences of
items that all have the same structure (more precisely, sequences whose merge keys
are
computed in the same way): for example, log files created by the same application
running on different machines in a server farm. Alternatively,
xsl:merge
can be used to merge sequences that have different
structure (sequences whose merge keys are computed in different ways), provided that
the
computed merge keys are compatible: an example might be two log files created by
different applications, using different XML vocabularies, that both contain timestamped
events but represent the timestamp in different ways. The
xsl:merge-source
element represents a set
of input sequences that follow common rules, including the rules for
computing the merge key. The xsl:merge
operation may take any number of
xsl:merge-source
elements representing different rules for input sequences, and each xsl:merge-source
element may describe any number (zero or more) of input sequences. The number of input
sequences to the merging operation is thus fixed only at the
time the xsl:merge
instruction is evaluated, and
may vary from one evaluation to another.
The following examples illustrate some of the possibilities. The detailed explanation of the constructs used follows later in this section.
This example takes as input a homogeneous collection of XML log files each of which
contains a sorted sequence of event
elements with a
timestamp
attribute validated as an instance of
xs:dateTime
. It merges the events from the input files into a single
sorted output file.
<xsl:result-document href="merged-events.xml"> <events> <xsl:merge> <xsl:merge-source for-each-source="uri-collection('log-files')" select="events/event"> <xsl:merge-key select="@timestamp"/> </xsl:merge-source> <xsl:merge-action> <xsl:copy-of select="current-merge-group()"/> </xsl:merge-action> </xsl:merge> </events> </xsl:result-document>
The example assumes that there are several input files each
of which has a structure similar to the following, in which the
timestamp
attribute has a typed value that is an instance of
xs:dateTime
:
<events> <event timestamp="2009-08-20T12:01:01Z">Transaction T1234 started</event> <event timestamp="2009-08-20T12:01:08Z">Transaction T1235 started</event> <event timestamp="2009-08-20T12:01:12Z">Transaction T1235 ended</event> <event timestamp="2009-08-20T12:01:15Z">Transaction T1234 ended</event> </events>
The output file will have the same structure, and will contain copies of all the
event
elements from all of the input files, in sorted order. Note that multiple events with the same timestamp can occur
either within a single file or across multiple files: the order of appearance of
these events in the output file corresponds to the order of the log files within
the collection (which might or might not be predictable, depending on the
implementation).
This example takes as input two log files with different structure, producing a single merged output in which the entries have a common structure:
<xsl:result-document href="merged-events.xml"> <events> <xsl:merge> <xsl:merge-source select="doc('log-file-1.xml')/events/event"> <xsl:merge-key select="@timestamp"/> </xsl:merge-source> <xsl:merge-source select="doc('log-files-2.xml')/log/day/record"> <xsl:merge-key select="dateTime(../@date, time)"/> </xsl:merge-source> <xsl:merge-action> <xsl:apply-templates select="current-merge-group()" mode="standardize-log-entry"/> </xsl:merge-action> </xsl:merge> </events> </xsl:result-document>
Here the first input file has a structure similar to that shown in the previous example, while the second input has a different structure, of the form:
<log> <day date="2009-08-20"> <record> <time>12:01:09-05:00</time> <message>Temperature 15.4C</message> </record> <record> <time>12:03:00-05:00</time> <message>Temperature 18.2C</message> </record> </day> </log>
The templates in mode standardize-log-entry
convert the log entries to a
common output format, for example:
<xsl:template match="event" mode="standardize-log-entry" as="schema-element(event)"> <xsl:copy-of select="." validation="preserve"/> </xsl:template> <xsl:template match="record" mode="standardize-log-entry" as="schema-element(event)"> <event timestamp="{dateTime(../@date, time)}" xsl:validation="strict"> <xsl:value-of select="message"/> </event> </xsl:template>
Note:
The xsl:merge
instruction is designed to enable streaming of data,
so that there is no need to allocate memory to hold the input sequences. However, it can also be used in cases where streamed
processing is not possible, for example when the input needs to be
sorted.
[Definition: A merge
source definition is the definition of one kind of input to the merge
operation. It selects zero or more merge
input sequences, and it includes a merge key specification to define
how the merge key
values are computed for each such merge input
sequence.] A merge source definition corresponds to an
xsl:merge-source
element in the stylesheet.
[Definition: A merge input sequence is an arbitrary sequenceDM30 of items which is already sorted according to the merge key specification for the corresponding merge source definition.]
[Definition: A merge
key specification consists of one or more adjacent
xsl:merge-key
elements which together define how the merge input sequences selected by a
merge source definition are
sorted. Each xsl:merge-key
element defines one merge key component.] For
example, a merge key specification for a log file might specify two merge key
components, date
and time
.
[Definition: A merge key
component specifies one component of a merge key specification; it
corresponds to a single xsl:merge-key
element in the
stylesheet.]
[Definition: For each item in a merge input sequence, a value is computed for each merge key component within the merge key specification. The value computed for an item by using the Nth merge key component is referred to as the Nth merge key value of that item.]
[Definition: The ordered collection of merge key values computed for one item in a merge input sequence (one for each merge key component within the merge key specification) is referred to as a composite merge key value.]
[Definition: A merge
activation is a single evaluation of the sequence constructor contained
within the xsl:merge-action
element, which occurs once for each
distinct composite merge key
value.]
xsl:merge
Instruction<!-- Category: instruction -->
<xsl:merge>
<!-- Content: (xsl:merge-source+, xsl:merge-action, xsl:fallback*) -->
</xsl:merge>
The effect of the xsl:merge
instruction is to produce a sorted
result sequence from a number of input sequences.
The input sequences to the merge operation are defined by the
xsl:merge-source
child elements, as described in the next
section.
The sequence constructor contained in the
xsl:merge-action
element is evaluated once for each distinct
composite merge key value to form a partial result sequence.
The result of the xsl:merge
instruction is the concatenation of
these partial result sequences. For example, the action might be to copy the items
from all the input sequences to the result sequence without change; or it might be
to
select the items from one input sequence in preference to the others. In the general
case, the items in the partial result sequence are produced by an arbitrary
computation that has access to the items (from the various input sequences) that
share the same value for the composite merge key.
The xsl:merge-source
and
xsl:merge-action
elements are described in the following
sections.
Any xsl:fallback
children of the xsl:merge
instruction are ignored by an XSLT 3.0 processor, but are used by an XSLT 1.0 or XSLT
2.0 processor to perform fallback processing.
Note:
An xsl:merge
instruction that has no input sequences returns an
empty sequence. An xsl:merge
instruction with a single input
sequence performs processing that is very similar in concept to
xsl:for-each-group
with the group-adjacent
attribute, except that it requires the input to be sorted on the grouping key.
<xsl:merge-source
name? = ncname
for-each-item? = expression
for-each-source? = expression
select = expression
streamable? = boolean
use-accumulators? = tokens
sort-before-merge? = boolean
validation? = "strict" | "lax" | "preserve" | "strip"
type? = eqname >
<!-- Content: xsl:merge-key+ -->
</xsl:merge-source>
Each xsl:merge-source
element defines one or more merge input sequences.
The name
attribute provides a means of
distinguishing items from different merge sources within the
xsl:merge-action
instructions. If the name
attribute
is present on an xsl:merge-source
element, then it must not be equal
to the name
attribute of any sibling xsl:merge-source
element. If the name
attribute is absent, then an implementation-dependent name, different from all explicitly specified
names, is allocated to the merge source.
[ERR XTSE3195] If the for-each-item
is present then the
for-each-source
, use-accumulators
, and streamable
attributes
must both be absent. If the use-accumulators
attribute is present
then the for-each-source
attribute must be present. If the
for-each-source
attribute is present then the
for-each-item
attribute must be absent.
The use-accumulators
attribute defines the
set of accumulators that are applicable to the streamed document, as explained in
18.2.2 Applicability of Accumulators.
If neither of
for-each-item
and for-each-source
is
present, the xsl:merge-source
element defines a single
merge input sequence. This sequence is the result of evaluating the expression in
the
select
attribute. This is evaluated using the dynamic context of the
containing xsl:merge
instruction. This sequence will be merged with
the sequences defined by other xsl:merge-source
elements, if
present.
When the for-each-item
attribute is present, the xsl:merge-source
element defines a
collection of merge input sequences. The selection of items in these input sequences
is a two-stage process: the for-each-item
attribute of the
xsl:merge-source
element is an expression that selects a sequence
of anchor items, and for each anchor item, the select
attribute is evaluated to select the items that make up one merge input sequence.
The
for-each-item
expression is evaluated with
the dynamic context of the containing xsl:merge
instruction, while
the select
attribute is evaluated with the focus for the evaluation as follows:
The context item is the anchor item
The context position is the position of the anchor item within the sequence of anchor items
The context size is the number of anchor items.
When the for-each-source
attribute is
present, its value must be an expression that returns a sequence of URIs.
The expression is evaluated with the same
dynamic context as the containing xsl:merge
instruction. The
expected type of the expression is xs:string*
, and the actual result of
the expression is converted to this type using the function conversion rules. Each of these URIs is used to obtain a
document node. Each must be a valid URI reference. If it is an
absolute URI reference, it is used as is; if it is a relative URI reference, it is
made absolute by resolving it against the base URI of the
xsl:merge-source
element. The process of obtaining a document
node given a URI is the same as for the doc
FO30 function, and may trigger the same error conditions.
However, unlike the doc
FO30 function, the
xsl:merge
instruction offers no guarantee that the resulting
document will be stable (that is, that multiple calls specifying the same URI will
return the same document). The resulting document nodes act as the anchor
items. These anchor items are then used in the same way as a sequence of
anchor items selected directly using the for-each-item
attribute:
in particular, the focus is
determined in the same way.
Note:
Examples of expressions that return a sequence of URIs are:
for-each-source="'inputA.xml', 'inputB.xml'"
for-each-source="(1 to $N) ! ('input' || $N || '.xml')"
for-each-source="uri-collection('input/dir/')
Relative URIs are resolved relative to the base URI of the
xsl:merge-source
element.
The attributes validation
and
type
are used to control schema validation of documents read by
virtue of their appearance in the result of the for-each-source
expression. These attributes are mutually exclusive [see ERR XTSE1505]. The rules are the same as for an xsl:source-document
instruction specifying streamable="yes"
.
If the for-each-source
attribute is absent, then the
validation
and type
attributes must
both be absent.
If the sort-before-merge
attribute is absent or has
the value no
, then each input sequence must already
be in the correct order for merging (a dynamic error occurs if it is not). If the
attribute is present with the value yes
, then each input sequence will
first be sorted to ensure that it is in the correct order.
The following xsl:merge-source
element selects two anchor items
(the root nodes of two documents), and for each of these it selects an input
sequence consisting of selected event
elements within the relevant
document.
<xsl:merge-source for-each-source="'log-A.xml', 'log-B.xml'" streamable="yes" select="events/event"> <xsl:merge-key select="@timestamp" order="ascending"/> </xsl:merge-source>
This example can be extended to merge any number of input documents with the same structure:
<xsl:merge-source for-each-source="uri-collection('log-collection')" streamable="yes" select="events/event"> <xsl:merge-key select="@time" order="ascending"/> </xsl:merge-source>
In both the above examples the anchor items are document nodes, and the items in the input sequence are elements within the document that is rooted at this node. This is a common usage pattern, but by no means the only way in which the construct can be used.
The number of anchor items selected by an xsl:merge-source
element,
and therefore the number of input sequences, is variable, but the input sequences
selected by one xsl:merge-source
element must all use the same
expressions to select the items in the input sequence and to compute their merge
keys. If different expressions are needed for different input sequences, then
multiple xsl:merge-source
elements can be used.
The following code merges two log files having different internal structure:
<xsl:merge-source for-each-source="'event-log.xml'" streamable="yes" select="/*/event"> <xsl:merge-key select="@timestamp"/> </xsl:merge-source> <xsl:merge-source for-each-source="'error-log.xml'" streamable="yes" select="/*/error"> <xsl:merge-key select="dateTime(@date, @time)"/> </xsl:merge-source>
Although the merge keys are computed in different ways for the two input
sequences, the keys must be compatible across the two sequences: in this case they
are both atomic values of type xs:dateTime
.
In the common case where there is only one input sequence of a particular kind, the
for-each-item
attribute of
xsl:merge-source
may be omitted; the select
expression is then evaluated relative to the focus
of the xsl:merge
instruction itself.
Where one or more of the inputs to the merging process is not pre-sorted, a sort
can be requested using the sort-before-merge
attribute. For
example:
<xsl:merge-source select="doc('event-log.xml')/*/event"> <xsl:merge-key select="@timestamp"/> </xsl:merge-source> <xsl:merge-source select="doc('error-log.xml')//error" sort-before-merge="yes"> <xsl:merge-key select="dateTime(current-date(), @time)"/> </xsl:merge-source>
[ERR XTSE3190] It is a static error if two sibling
xsl:merge-source
elements have the same name.
Any input to a merging operation, provided it is selected
by means of the xsl:merge-source
element with a
for-each-source
attribute, may be designated as streamable by
including the attribute streamable="yes"
on the
xsl:merge-source
element.
When streamable="yes"
is specified on an
xsl:merge-source
element, then (whether or not streamed
processing is actually used, and whether or not the processor supports streaming)
the
expression appearing in the select
attribute is implicitly used as the
argument of a call on the snapshot
function, which means that
merge keys for each selected node are computed with reference to this snapshot, and
the current-merge-group
function, when used within the
xsl:merge-action
sequence constructor, delivers snapshots of the
selected nodes.
Note:
There are therefore no constraints on the navigation
that may be performed in computing the merge key, or in the course of evaluating
the xsl:merge-action
body. An attempt to navigate outside the
portion of the source document delivered by the snapshot
function will typically not cause an error, but will return empty results.
There is no
rule to prevent the select
expression returning atomic values, or grounded nodes from a
different source document, or newly constructed nodes, but they are still
processed using the snapshot
function.
Because the snapshot
copies
accumulator values as described in 18.2.10 Copying Accumulator Values, the
functions accumulator-before
and
accumulator-after
may be used to gain access to
information that is not directly available in the nodes that are present within
each snapshot (for example, information in a header section of the merge input
document).
An xsl:merge-source
element is guaranteed-streamable if it satisfies all the following conditions:
The xsl:merge-source
element has the
attribute value streamable="yes"
;
The for-each-source
attribute is
present on that xsl:merge-source
element;
The expression in the select
attribute of that
xsl:merge-source
element, assessed with a
context posture of striding
and a context item type of U{document-node()},
has striding or grounded posture
and motionless or consuming sweep;
The sort-before-merge
attribute of that
xsl:merge-source
element is either absent or takes its
default value of no
.
Specifying streamable="yes"
on an
xsl:merge-source
element declares an intent that the
xsl:merge
instruction should be streamable with respect to that particular source, either because it is guaranteed-streamable, or because it takes advantage of
streamability extensions offered by a particular processor. The
consequences of declaring the instruction to be streamable when it is not in fact
guaranteed streamable depend on the conformance level of the processor, and are
explained in 19.10 Streamability Guarantees.
The following example merges two log files, processing each of them using streaming.
<events> <xsl:merge> <xsl:merge-source for-each-source="'log-file-1.xml'" select="/events/event" streamable="yes"> <xsl:merge-key select="@timestamp"/> </xsl:merge-source> <xsl:merge-source for-each-source="'log-files-2.xml'" select="/log/day/record" streamable="yes"> <xsl:merge-key select="dateTime(../@date, time)"/> </xsl:merge-source> <xsl:merge-action> <events time="{current-merge-key()}"> <xsl:copy-of select="current-merge-group()"/> </events> </xsl:merge-action> </xsl:merge> </events>
Note that the merge key for the second merge source includes data from a child
element of the selected element and also from an attribute of the parent element.
This works because of the merge key is evaluated on the result of implicitly applying
the snapshot
function.
The following example merges two log files, one in text format and one in XML format.
<events> <xsl:merge> <xsl:merge-source name="fax" select="unparsed-text-lines('fax-log.txt')"> <xsl:merge-key select="xs:dateTime(substring-before(., ' '))"/> </xsl:merge-source> <xsl:merge-source name="mail" for-each-source="'mail-log.xml'" select="/log/day/message" streamable="yes"> <xsl:merge-key select="dateTime(../@date, @time)"/> </xsl:merge-source> <xsl:merge-action> <messages at="{current-merge-key()}"> <xsl:where-populated> <fax> <xsl:for-each select="current-merge-group('fax')"> <message xsl:expand-text="true">{ substring-after(., ' ') }</message> </xsl:for-each> </fax> <mail> <xsl:sequence select="current-merge-group('mail')/*"/> </mail> </xsl:where-populated> </messages> </xsl:merge-action> </xsl:merge> </events>
The keys on which the input sequences are sorted are referred to as merge keys. If
the attribute sort-before-merge
has the value yes
, the
input sequences will be sorted into the correct sequence before the merge operation
takes place (alternatively, the processor may use an algorithm
that has the same effect as sorting followed by merging). If the attribute is absent
or has the value no
, then the input sequences must
already be in the correct order.
The merge key for each type of input sequence (that is, for each
xsl:merge-source
element) is defined by a sequence of
xsl:merge-key
element children of the
xsl:merge-source
element. Each xsl:merge-key
element defines one merge key component. The syntax and semantics of an
xsl:merge-key
element are closely based on the rules for the
xsl:sort
element (the only exception being the absence of the
stable
attribute); the difference is that
xsl:merge-key
elements do not cause a sort to take place, they
merely declare the existing sort order of the input sequence.
<xsl:merge-key
select? = expression
lang? = { language }
order? = { "ascending" | "descending" }
collation? = { uri }
case-order? = { "upper-first" | "lower-first" }
data-type? = { "text" | "number" | eqname } >
<!-- Content: sequence-constructor -->
</xsl:merge-key>
The select
attribute and the contained sequence constructor are mutually
exclusive:
[ERR XTSE3200] It is a static error if an
xsl:merge-key
element with a select
attribute
has non-empty content.
The value of Nth merge key value of an item
J in a merge input
sequence
S is the result of the expression in the select
attribute of
the Nth xsl:merge-key
child of the corresponding
xsl:merge-source
element, or in the absence of the
select
attribute, the result of the contained sequence constructor. This is evaluated with a singleton focus based on J, or, if
streamable=yes
is specified on the xsl:merge-source
,
a singleton focus based on a snapshot
of
J (see 15.4 Streamable Merging).
Note:
This means that position()
and last()
return 1 (one).
This differs from the way xsl:sort
keys are evaluated, where
position()
is the position in the unsorted sequence, and
last()
is the size of the unsorted sequence.
The effect of the xsl:merge-key
elements is defined in terms of the
rules for an equivalent sequence of xsl:sort
elements: if the rules
for sorting (see 13.1.1 The Sorting Process) with stable="yes"
would place an item A before an item B in the sorted sequence produced by the sorting
process, then A must precede B in the input sequence to the
merging process.
The merge keys of the various input sequences to a merge operation must be compatible
with each other, since the merge operation will decide the ordering of the result
sequence by comparing merge key values across input sequences. This means that across
all the xsl:merge-source
children of an xsl:merge
instruction:
Each xsl:merge-source
element must have the
same number of xsl:merge-key
child elements; let this number
be N.
For each integer J in 1..N, consider the set of
xsl:merge-key
elements that are in position J
among the xsl:merge-key
children of their parent
xsl:merge-source
element. All the
xsl:merge-key
elements in this set must
have the same effective value for
their lang
, order
, collation
,
case-order
, and data-type
attributes, where having
the same effective value in this case means that either both attributes must be
absent, or both must be present and evaluate to the same value; and in addition
in the case of collation
the absolute URI must be the same after
resolving against the base URI.
If any of the attributes lang
, order
,
collation
, case-order
, or data-type
are
attribute value templates,
then their effective values are evaluated
using the focus of the containing
xsl:merge
instruction.
[ERR XTSE2200] It is a static error if the number of
xsl:merge-key
children of a
xsl:merge-source
element is not equal to the number of
xsl:merge-key
children of another
xsl:merge-source
child of the same
xsl:merge
instruction.
[ERR XTDE2210] It is a dynamic
error if there are two xsl:merge-key
elements
that occupy corresponding positions among the xsl:merge-key
children of two different xsl:merge-source
elements and that
have differing effective values for
any of the attributes lang
, order
,
collation
, case-order
, or data-type
.
Values are considered to differ if the attribute is present on one element and
not on the other, or if it is present on both elements with effective values that are not equal to
each other. In the case of the collation
attribute, the values are
compared as absolute URIs after resolving against the base URI. The error
may be reported statically if it is detected
statically.
[ERR XTDE2220] It is a dynamic error if any input
sequence to an xsl:merge
instruction contains two items that
are not correctly sorted according to the merge key values defined on the
xsl:merge-key
children of the corresponding
xsl:merge-source
element, when compared using the collation
rules defined by the attributes of the corresponding
xsl:merge-key
children of the xsl:merge
instruction, unless the attribute sort-before-merge
is present
with the value yes
.
[ERR XTTE2230] It is a type error if some item selected
by a particular merge key in one input sequence is not comparable using the
XPath le
operator with some item selected by the corresponding
sort key in another input sequence.
During processing of an xsl:merge
instruction, two additional values
are available within the dynamic context:
[Definition: The
current merge group is a map. During
evaluation of an xsl:merge
instruction, as each group of
items with equal composite merge
key values is processed, the current merge group is set to a
map whose keys are the names of the various merge sources, and whose
associated values are the items from each merge source having the relevant
composite merge key value.]
[Definition: The current
merge key is a sequence of atomic values. During evaluation of an
xsl:merge
instruction, as each group of items with equal
composite merge key
values is processed, the current merge key is set to the
composite merge key value that these items have in common. ]
These values are made available through the functions
current-merge-group
and
current-merge-key
.
The current merge group and current merge key are available within the sequence
constructor contained by an xsl:merge-action
element. The values are initially
absent during the evaluation of global variables and stylesheet parameters,
during the evaluation of the use
attribute or contained sequence constructor of
xsl:key
, and during the evaluation of the initial-value
attribute of
xsl:accumulator
and the select
attribute of contained sequence constructor of
xsl:accumulator-rule
. All invocation constructs
set the current merge group and current merge key to absent.
Note:
Taken together, these rules mean that any invocation of
current-merge-group
or current-merge-key
that is not lexically scoped by an
xsl:merge-action
element will raise a dynamic error.
When an inner xsl:merge
instruction is lexically nested within the
xsl:merge-action
element of an outer xsl:merge
instruction, any use of
current-merge-group
or current-merge-key
that appears within the
xsl:merge-action
of the inner xsl:merge
instruction is a reference to the
current merge group or current merge key of the inner
xsl:merge
instruction, while any such
reference that appears within the outer xsl:merge-action
element, but not
within the inner xsl:merge-action
, is a reference to the current merge group or current merge key
of the outer xsl:merge
instruction. This means, for example, that a
reference to the current merge group of the outer xsl:merge
can appear in the
select
attribute of an xsl:merge-source
child of the inner xsl:merge
.
On completion of the evaluation of the xsl:merge-action
sequence constructor, the current merge group
and current merge key revert to their previous values.
Returns the group of items currently being processed by an xsl:merge
instruction.
fn:current-merge-group
($source
as
xs:string
) as
item()*
This function is deterministicFO30, context-dependentFO30, and focus-independentFO30.
The current merge group is bound during evaluation of the
xsl:merge-action
child of an xsl:merge
instruction.
If no xsl:merge-action
is being
evaluated, then the current merge group is absent, in which case the
function raises a dynamic error (see below).
The current merge group (if not absent) is a map. It contains the set of items, from all merge inputs, that share a common value for
the merge key. This is structured as a map so that the items from each merge source
can
be identified. The key in the map is the value of the name
attribute of the
corresponding xsl:merge-source
element (or an invented name, in its
absence), and the associated value is the set of items contributed by that merge
group.
The map itself is not made visible, but this function returns values derived from the map. Specifically, if the map is denoted by $G:
The single-argument form of this function returns the value of the expression
if (map:contains($source)) then $G($source) else error()
.
Informally, if there is an xsl:merge-source
element whose
name
attribute matches $source
, the function returns
the items in the current merge group that are contributed by this merge source;
otherwise it raises a dynamic error (see below).
The zero-argument form of the function returns the value of the expression
sort(map:keys($G))!$G(.)
, where the sort()
function
sorts the names of xsl:merge-source
elements into the document
order of the xsl:merge-source
elements in the stylesheet.
Informally, it returns all the items in the current merge group regardless of
which merge source they derive from.
Within the current merge group, the ordering of items from the input sequences is as follows, in major-to-minor order:
Items are first ordered by the xsl:merge-source
element that
defined the input sequence from which the item was taken; items from
xsl:merge-source
A precede items from xsl:merge-source
B if A precedes B in document order within the
stylesheet.
Items from different input sequences selected by the same
xsl:merge-source
element are then ordered based on the order
of the anchor items in the sequence selected by evaluating the select
attribute of the xsl:merge-source
element.
Finally, duplicate items from the same input sequence retain their order from the input sequence.
Duplicates are not eliminated: for example, if the same node is selected in more than one input sequence, it may appear twice in the current merge group.
[ERR XTSE3470] It is a static error if the
current-merge-group
function is used within a pattern.
[ERR XTDE3480] It is a dynamic error if the
current-merge-group
function is used when the current
merge group is absent. The error
may be reported statically if it can be detected
statically.
[ERR XTDE3490] It is a dynamic error if the
$source
argument of the current-merge-group
function does not match the name
attribute of any
xsl:merge-source
element for the current merge operation. The
error may be reported statically if it can be detected
statically.
Because the current merge group is cleared by function calls and
template calls, the current-merge-group
function only has useful
effect when the call appears as a descendant of an xsl:merge-action
element.
If an xsl:merge-source
element has no name
attribute, then
it is not possible to discover the items in the current merge group that derive
specifically from that source, but these items will still be present in the current
merge group, and will be included in the result when the function is called with no
arguments.
Like other XSLT extensions to the dynamic evaluation context, the current merge group is not retained as part of the closure of a function
value. This means that the expression current-merge-group#0
is valid and
returns a function value, but any invocation of this function will fail with a dynamic
error [see ERR XTDE3480].
Returns the merge key of the
merge group currently being processed using the
xsl:merge
instruction.
This function is deterministicFO30, context-dependentFO30, and focus-independentFO30.
The evaluation context for XPath expressions includes a component called the current merge key, which is a sequence of atomic values. The current merge key is the composite merge key value shared in common by all the items within the current merge group.
The function current-merge-key
returns the current merge key.
While the xsl:merge-action
child of an
xsl:merge
instruction is being evaluated, the current merge key will be a single atomic
value if there is a single merge key, or a sequence of atomic values if there are
multiple merge keys.
At other times, the current merge key will be absent.
The merge keys of
all items in a group are not necessarily identical. For example, one might be an
xs:float
while another is a numerically equal
xs:decimal
. The current-merge-key
function returns the merge key of the
first item in the group, after atomization and
casting of xs:untypedAtomic
values to xs:string
.
[ERR XTSE3500] It is a static error if the
current-merge-key
function is used within a pattern.
[ERR XTDE3510] It is a dynamic error if the
current-merge-key
function is used when the current
merge key is absent, or when it is invoked
in the course of evaluating a pattern. The error may be
reported statically if it can be detected statically.
Like other XSLT extensions to the dynamic evaluation context, the current merge key is not retained as part of the closure of a function
value. This means that the expression current-merge-key#0
is valid and
returns a function value, but any invocation of this function will fail with a dynamic
error [see ERR XTDE3510].
xsl:merge-action
ElementThe xsl:merge-action
child of an xsl:merge
instruction defines the processing to be applied for each distinct composite merge key value found in the input sequences to the
xsl:merge
instruction.
<xsl:merge-action>
<!-- Content: sequence-constructor -->
</xsl:merge-action>
The merge key values for each item in an input sequence are calculated based on the
corresponding xsl:merge-key
elements, in the same way as sort key values are calculated using a sequence
of xsl:sort
elements (see 13.1.1 The Sorting Process). If
several items from the same or from different input sequences have the same values
for all their merge keys (comparing pairwise), then they are considered to form a
group. The sequence constructor contained in the xsl:merge-action
element is evaluated once for each such group of items, and the result of the
xsl:merge
instruction is the concatenation of the results
obtained by processing each group in turn.
The groups are processed one by one, based on the values of
the merge keys for the group. If group G has a set of merge
key values M, while group H has a set of merge key values
N, then in the result of the xsl:merge
instruction,
the result of processing group G will precede the result of processing
H if and only if M precedes N in the sort order
defined by the lang
, order
, collation
,
case-order
, and data-type
attributes of the merge key
definitions.
Generally, two sets of merge key values are distinct if any corresponding items in
the two sets of values do not compare equal under the rules for the XPath
eq
operator, under the collating rules for the corresponding merge
key definition. In rare cases, when considering more than two sets of merge key
values, ambiguities may arise because of the non-transitivity of the eq
operator when applied across different numeric types. In this situation, the
partitioning of items into sets having distinct key values is handled in the same
way
as for xsl:for-each-group
(see 14.5 Non-Transitivity),
and is to some extent implementation-dependent.
The focus for evaluation of the sequence
constructor contained in the xsl:merge-action
element is as
follows:
The context item is the first item in
the group being processed, that is
current-merge-group()[1]
The context position is the
position of the current group within the sequence of groups (so the first
evaluation of xsl:merge-action
has position()=1
,
the second has position()=2
, and so on).
The context size is as follows:
If any of the xsl:merge-source
elements within the xsl:merge
instruction specifies
streamable="yes"
(explicitly or implicitly), then absent.
Note:
This means that within the xsl:merge-action
of a streamable xsl:merge
,
calling last()
throws error [ERR XPDY0002] XP30.
Otherwise, the number of groups, that is, the number of distinct sets of merge key values.
Consider a situation where there are two merge sources, named "master"
and
"update"
; the master source identifies a single merge input file (the master
file), while the update source identifies a set of N update files,
perhaps one for each day of the week. The required logic is that if a merge key is
present only in the master file, then the corresponding item should be copied to
the output; if it is present in a single update file then that item replaces the
corresponding item from the master file; if it is present in several update files,
then an error is raised. This can be achieved as follows:
<xsl:merge> <xsl:merge-source name="master" for-each-source="'master.xml'" streamable="yes" select="/events/event"> <xsl:merge-key select="@key"/> </xsl:merge-source> <xsl:merge-source name="updates" for-each-source="uri-collection('updates')" streamable="yes" select="/events/event-change"> <xsl:merge-key select="@affected-key"/> </xsl:merge-source> <xsl:merge-action> <xsl:choose> <xsl:when test="empty(current-merge-group('master'))"> <xsl:message> Error: update is present with no matching master record! </xsl:message> </xsl:when> <xsl:when test="empty(current-merge-group('updates'))"> <xsl:copy-of select="current-merge-group('master')"/> </xsl:when> <xsl:when test="count(current-merge-group('updates')) = 1"> <xsl:copy-of select="current-merge-group('updates')"/> </xsl:when> <xsl:otherwise> <xsl:message> Conflict: multiple updates for the same master record! </xsl:message> </xsl:otherwise> </xsl:choose> </xsl:merge-action> </xsl:merge>
Some words of explanation:
Error messages are produced if there is an update element whose key does not correspond to any element in the master source, or if there is more than one update element corresponding to the same master element.
In the absence of errors, if there is a single update element then it is copied to the output; if there is none, then the master element is copied.
Previous sections introduced examples designed to illustrate some specific features
of the xsl:merge
instruction. This section provides some further
examples to illustrate different ways in which the instruction can be used.
This example applies transactions from a transaction file to a master file. Records in the master file for which there is no corresponding transaction are copied unchanged. The transaction file contains instructions to delete, replace, or insert records identified by an ID value. The master file is known to be sorted on the ID value; the transaction file is unsorted.
Master file document structure:
<data> <record ID="A0001">...</record> <record ID="A0002">...</record> <record ID="A0003">...</record> </data>
Transaction file document structure:
<transactions> <update record="A0004" action="insert">...</update> <update record="A0002" action="delete"/> <update record="A0003" action="replace">...</update> </transactions>
Solution:
<xsl:merge> <xsl:merge-source name="master" select="doc('master.xml')/data/record"> <xsl:merge-key select="@ID"/> </xsl:merge-source> <xsl:merge-source name="updates" sort-before-merge="yes" select="doc('transactions.xml')/transactions/update"> <xsl:merge-key select="@record"/> </xsl:merge-source> <xsl:merge-action> <xsl:choose> <xsl:when test="empty(current-merge-group('updates'))"> <xsl:copy-of select="current-merge-group('master')"/> </xsl:when> <xsl:when test="current-merge-group('updates')/@action=('insert', 'replace')"> <record ID="{current-merge-key()}"> <xsl:copy-of select="current-merge-group('updates')/*"/> </record> </xsl:when> <xsl:when test="current-merge-group('updates')/@action='delete'"/> </xsl:choose> </xsl:merge-action> </xsl:merge>
The xsl:merge
instruction can be used to determine the union,
intersection, or difference of two sequences of numbers (or other atomic values).
This code gives the union:
<xsl:merge> <xsl:merge-source select="1 to 30"> <xsl:merge-key select="."/> </xsl:merge-source> <xsl:merge-source select="20 to 40"> <xsl:merge-key select="."/> </xsl:merge-source> <xsl:merge-action> <xsl:sequence select="current-merge-key()"/> </xsl:merge-action> </xsl:merge>
While this gives the intersection:
<xsl:merge> <xsl:merge-source select="1 to 30"> <xsl:merge-key select="."/> </xsl:merge-source> <xsl:merge-source select="20 to 40"> <xsl:merge-key select="."/> </xsl:merge-source> <xsl:merge-action> <xsl:if test="count(current-merge-group()) eq 2"> <xsl:sequence select="current-merge-key()"/> </xsl:if> </xsl:merge-action> </xsl:merge>
Sometimes it is convenient to be able to compute multiple results during a single scan of the input data. For example, a transformation may wish to rename selected elements, and also to output a count of how many elements have been renamed. Traditionally in a functional language this means computing two separate functions of the input sequence, which (in the absence of sophisticated optimization) will result in the input being scanned twice. This is inconsistent with streaming, where the input is only available to be scanned once, and it can also lead to poor performance in non-streaming applications.
To meet this requirement, XSLT 3.0 introduces the instruction xsl:fork
.
The content of this instruction is a restricted form
of
sequence constructor, and in a formal
sense the effect of the instruction is simply to return the result of evaluating the
sequence constructor. However, the presence of the instruction affects the analysis
of
streamability (see 19 Streamability). In particular, when
xsl:fork
is used in a context where streaming is required, each
independent instruction within the sequence constructor must be streamable, but the
analysis assumes that these instructions can all be evaluated during a single pass
of
the streamed input document.
Note:
The semantics of the instruction require a number of result sequences to be computed during a single pass of the input. A processor may interpret this as a request to use multiple threads. However, implementations using a single thread are feasible, and this instruction is not intended primarily as a means for stylesheet authors to express their intentions with regard to multi-threaded execution.
Note:
Because multiple results are computed during a single pass of the input, and then concatenated into a single sequence, this instruction will generally involve some buffering of results. The amount of memory used should not exceed that needed to hold the results of the instruction. However, within this principle, implementations may adopt a variety of strategies for evaluation; for example, there may be cases where buffering of the input is more efficient than buffering of output.
Generally, stylesheet authors indicate that buffering of input is the preferred
strategy by using the copy-of
or snapshot
functions, and indicate that buffering of output is preferred by using
xsl:fork
. However, conformant processors are not constrained in
their choice of evaluation strategies.
The content model of the xsl:fork
instruction (given that an XSLT 3.0 processor ignores xsl:fallback
)
takes two possible forms:
A sequence of xsl:sequence
instructions
A single xsl:for-each-group
instruction. This will normally use
the group-by
attribute, because in all other cases the containing
xsl:fork
instruction has no useful effect.
The first form is appropriate when splitting a single input stream into a fixed number of output streams, known statically: for example, one output stream for credit transactions, a second for debit transactions. The second form is appropriate when the number of output streams depends on the data: for example, one output stream for each distinct city name found in the input data.
The following section describes the xsl:fork
instruction more
formally.
xsl:fork
Instruction<!-- Category: instruction -->
<xsl:fork>
<!-- Content: (xsl:fallback*, ((xsl:sequence, xsl:fallback*)* | (xsl:for-each-group, xsl:fallback*))) -->
</xsl:fork>
Note:
The content model can be described as follows: there is either a single
xsl:for-each-group
instruction, or a sequence of zero or more
xsl:sequence
instructions; in addition,
xsl:fallback
instructions may be added anywhere.
The result of the xsl:fork
instruction is the sequence formed by
concatenating the results of evaluating each of its contained instructions, in order.
That is, the result can be determined by treating the content as a sequence constructor and evaluating it as
such.
Note:
Any xsl:fallback
children will be ignored by an XSLT 3.0
processor.
By using the xsl:fork
instruction, the
stylesheet author is suggesting to the processor that buffering of output is acceptable even though this might
use unbounded memory and thus violate the normal expectations of streamable
processing
The presence of an xsl:fork
instruction affects the analysis of
streamability, as described in 19 Streamability.
This section gives examples of how splitting using xsl:fork
can be
used to enable streaming of input documents in cases where several results need to
be
computed during a single pass over the input data.
Consider a transaction file that contains a sequence of debits and credits:
<transactions> <transaction value="5.60"/> <transaction value="11.20"/> <transaction value="-3.40"/> <transaction value="8.90"/> <transaction value="-1.99"/> </transactions>
where the requirement is to split this into two separate files containing credits and debits respectively.
This can be achieved in guaranteed-streamable code as follows:
<xsl:source-document streamable="yes" href="transactions.xml"> <xsl:fork> <xsl:sequence> <xsl:result-document href="credits.xml"> <credits> <xsl:for-each select="transactions/transaction[@value >= 0]"> <xsl:copy-of select="."/> </xsl:for-each> </credits> </xsl:result-document> </xsl:sequence> <xsl:sequence> <xsl:result-document href="debits.xml"> <debits> <xsl:for-each select="transactions/transaction[@value < 0]"> <xsl:copy-of select="."/> </xsl:for-each> </debits> </xsl:result-document> </xsl:sequence> </xsl:fork> </xsl:source-document>
In the absence of the xsl:fork
instruction, this would not be
streamable, because the sequence constructor includes two consuming instructions. With the addition of the
xsl:fork
instruction, however, each
xsl:result-document
instruction is allowed to make a downwards
selection.
One possible implementation model for this is as follows: a single thread reads
the source document, and sends parsing events such as start-element and
end-element to two other threads, each of which is writing one of the two result
documents. Each of these implements the downwards-selecting path expression using
a process that waits until the next transaction
start-element event
is received; when this event is received, the process examines the
@value
attribute to determine whether or not this transaction is
to be copied; if it is, then all events until the matching
transaction
end-element event are copied to the serializer for the
result document; otherwise, these events are discarded.
Consider a transaction file that contains a sequence of debits and credits:
<transactions> <transaction value="5.60" account="01826370"/> <transaction value="11.20" account="92741838"/> <transaction value="-3.40" account="01826370"/> <transaction value="8.90" account="92741838"/> <transaction value="-1.99" account="43861562"/> </transactions>
where the requirement is to split this into a number of separate files, one for each account number found in the input.
This can be achieved in guaranteed-streamable code as follows:
<xsl:source-document streamable="yes" href="transactions.xml"> <xsl:fork> <xsl:for-each-group select="transactions/transaction" group-by="@account"> <xsl:result-document href="account{current-grouping-key()}.xml"> <transactions account="{current-grouping-key()}"> <xsl:copy-of select="current-group()"/> </transactions> </xsl:result-document> </xsl:for-each-group> </xsl:fork> </xsl:source-document>
In the absence of the xsl:fork
instruction, this would not be
streamable, because in the general case the output of
xsl:for-each-group
with a group-by
attribute
needs to be buffered. (The streamability rules do not recognize an
xsl:for-each-group
whose body comprises an
xsl:result-document
instruction as a special case.) With the
addition of the xsl:fork
instruction, however, the code becomes
guaranteed streamable.
One possible implementation model for this is as follows: the processor opens a
new serializer each time a new account number is encountered in the input, and
writes the <transactions>
start tag to the serializer. When a
transaction
element is encountered in the input, it is copied to
the relevant serializer, according to the value of the account
attribute. At the end of the input, a <transactions>
end tag is
written to each of the serializers, and each output file is closed.
In the more general case, where the body of the
xsl:for-each-group
instruction contributes output to the
principal result document, the output generated by processing each group needs to
be buffered in memory. The requirement to use xsl:fork
exists so
that this use of (potentially unbounded) memory has to be a conscious decision by
the stylesheet author.
The rules for streamability do not allow two instructions in a sequence
constructor to both read child or descendant elements of the context node, which
makes it tricky to perform a calculation in which multiple child elements act as
operands. This restriction can be avoided by using xsl:fork
, as
shown below, where each of the two branches of the xsl:fork
instruction selects children of the context node.
<xsl:template match="order" mode="a-streamable-mode"> <xsl:variable name="price-and-discount" as="xs:decimal+"> <xsl:fork> <xsl:sequence select="xs:decimal(price)"/> <xsl:sequence select="xs:decimal(discount)"/> </xsl:fork> </xsl:variable> <xsl:value-of select="$price-and-discount[1] - $price-and-discount[2]"/> </xsl:template>
A possible implementation strategy here is for events from the XML parser to be
sent to two separate agents (perhaps but not necessarily running in different
threads), one of which computes xs:decimal(price)
and the other
xs:decimal(discount)
; on completion the results computed by the
two agents are appended to the sequence that forms the value of the variable.
With this strategy, the processor would require sufficient memory to hold the results of evaluating each branch of the fork. If these results (unlike this example) are large, this could defeat the purpose of streaming by requiring large amounts of memory; nevertheless, this code is treated as streamable.
Note:
An alternative solution to this requirement is to use map constructors: see 21.4 Map Constructors.
In this example the input is a narrative document containing note
elements at any level of nesting. The requirement is to output a copy of the input
document in which (a) the note
elements have been removed, and (b) a
footnote
is added at the end indicating how many note
elements have been deleted.
<xsl:mode on-no-match="shallow-copy" streamable="yes"/> <xsl:template match="note"/> <xsl:template match="/*"> <xsl:fork> <xsl:sequence> <xsl:apply-templates/> </xsl:sequence> <xsl:sequence> <footnote> <p>Removed <xsl:value-of select="count(.//note)"/> note elements.</p> </footnote> </xsl:sequence> </xsl:fork> </xsl:template>
The xsl:fork
instruction contains two independent branches. These
can therefore be evaluated in the same pass over the input data. The first branch
(the xsl:apply-templates
instruction) causes everything except
the note
elements to be copied to the result; the second instruction
(the literal result element footnote
) outputs a count of the number
of descendant note
elements.
Note that although the processing makes a single pass over the input stream, there
is some buffering of results required, because the results of the instructions
within the xsl:fork
instruction need to be concatenated. In this
case an intelligent implementation might be able to restrict the buffered data to
a single integer.
In a formal sense, however, the result is exactly the same as if the
xsl:fork
element were not there.
An alternative way of solving this example problem would be to
count the number of note
elements using an accumulator: see 18.2 Accumulators.
The function library for XPath 3.0 defines several functions that make use of regular expressions:
matches
FO30 returns a boolean result that indicates whether or
not a string matches a given regular expression.
replace
FO30 takes a string as input and returns a string
obtained by replacing all substrings that match a given regular expression with a
replacement string.
tokenize
FO30 returns a sequence of strings formed by breaking a
supplied input string at any separator that matches a given regular
expression.
analyze-string
FO30 returns a tree of nodes that effectively add
markup to a string indicating the parts of the string that matched the regular
expression, as well as its captured groups.
These functions are described in [Functions and Operators 3.0].
Supplementing these functions, XSLT provides
an instruction xsl:analyze-string
, which is defined in this
section.
Note:
The xsl:analyze-string
instruction predates the
analyze-string
FO30 function, and provides very similar
functionality, though in a different way. The two constructs are not precisely
equivalent; for example, xsl:analyze-string
allows a regular
expression that matches a zero-length string while the
analyze-string
FO30 function does not. The
xsl:analyze-string
instruction (via the use of
regex-group
) provides information about the value of captured
substrings; the analyze-string
FO30 function additionally provides
information about the position of the captured substrings within the original
string.
The regular expressions used by this instruction, and the flags that control the interpretation of these regular expressions, must conform to the syntax defined in [Functions and Operators 3.0] (see Section 5.6.1 Regular expression syntax FO30), which is itself based on the syntax defined in [XML Schema Part 2].
xsl:analyze-string
Instruction<!-- Category: instruction -->
<xsl:analyze-string
select = expression
regex = { string }
flags? = { string } >
<!-- Content: (xsl:matching-substring?, xsl:non-matching-substring?, xsl:fallback*) -->
</xsl:analyze-string>
<xsl:matching-substring>
<!-- Content: sequence-constructor -->
</xsl:matching-substring>
<xsl:non-matching-substring>
<!-- Content: sequence-constructor -->
</xsl:non-matching-substring>
The xsl:analyze-string
instruction takes as input a string (the
result of evaluating the expression in the select
attribute) and a
regular expression (the effective value of the regex
attribute).
If the result of evaluating the select
expression is an empty sequence, it is treated as a zero-length string.
If the value is not a string, it is converted to a string by applying the
function conversion
rules.
The flags
attribute may be used to control the interpretation of the
regular expression. If the attribute is omitted, the effect is the same as supplying
a zero-length string. This is interpreted in the same way as the $flags
attribute of the functions matches
FO30,
replace
FO30, and tokenize
FO30. Specifically,
if it contains the letter m
, the match operates in multiline mode. If it
contains the letter s
, it operates in dot-all mode. If it contains the
letter i
, it operates in case-insensitive mode. If it contains the
letter x
, then whitespace within the regular expression is ignored. For
more detailed specifications of these modes, see [Functions and Operators 3.0]
(Section
5.6.1.1 Flags
FO30).
Note:
Because the regex
attribute is an attribute value template, curly
brackets within the regular expression must be doubled. For example, to match a
sequence of one to five characters, write regex=".{{1,5}}"
. For
regular expressions containing many curly brackets it may be more convenient to
use a notation such as regex="{'[0-9]{1,5}[a-z]{3}[0-9]{1,2}'}"
, or
to use a variable.
The xsl:analyze-string
instruction may have two child elements:
xsl:matching-substring
and
xsl:non-matching-substring
. Both elements are optional, and
neither may appear more than once. At least one of them must be present. If both are
present, the xsl:matching-substring
element must come first.
The content of the xsl:analyze-string
instruction must take one of
the following forms:
A single xsl:matching-substring
instruction, followed by zero
or more xsl:fallback
instructions
A single xsl:non-matching-substring
instruction, followed by
zero or more xsl:fallback
instructions
A single xsl:matching-substring
instruction, followed by a
single xsl:non-matching-substring
instruction, followed by
zero or more xsl:fallback
instructions
[ERR XTSE1130] It is a static error if the
xsl:analyze-string
instruction contains neither an
xsl:matching-substring
nor an
xsl:non-matching-substring
element.
Any xsl:fallback
elements among the children of the
xsl:analyze-string
instruction are ignored by an XSLT 2.0 or 3.0 processor, but allow fallback behavior to be
defined when the stylesheet is used with an XSLT 1.0 processor operating with
forwards-compatible behavior.
This instruction is designed to process all the non-overlapping substrings of the input string that match the regular expression supplied.
[ERR XTDE1140] It is a dynamic error if the effective value of the regex
attribute does not conform to the
required syntax for regular expressions, as specified in
[Functions and Operators 3.0]. If the regular expression is known
statically (for example, if the attribute does not contain any expressions enclosed in curly brackets) then
the processor may signal the error as a static error.
[ERR XTDE1145] It is a dynamic error if the effective value of the flags
attribute has a value other than the values defined in
[Functions and Operators 3.0]. If the value of the attribute is known
statically (for example, if the attribute does not contain any expressions enclosed in curly brackets) then
the processor may signal the error as a static error.
To explain the behavior of the instruction it is useful to consider
an input string of length N characters as having N+1
inter-character positions, including one just before the first character and one just
after the last. Each of these positions is a possible position for testing whether
the regular expression matches. These positions are numbered from zero to
N
.
Note:
The term character, here as elsewhere in this specification, means a Unicode codepoint. When strings are held in decomposed form, the multiple codepoints representing a composite character are considered to be multiple characters. A codepoint greater than 65535 is considered as one character, not as a surrogate pair.
The processor starts by setting the current position to position zero, and the current non-matching substring to a zero-length string. It then does the following repeatedly:
Test whether the regular expression matches at the current position.
If there is a match:
If the current non-matching substring has length greater than zero,
evaluate the xsl:non-matching-substring
sequence
constructor with the current non-matching substring as the context
item.
Reset the current non-matching substring to a zero-length string.
Evaluate the xsl:matching-substring
sequence constructor
with the matching substring as the context item.
Do the appropriate one of the following:
If the matching substring is non-zero length, set the current position to coincide with the end of the matching substring, exit, and repeat.
If the matching substring is zero length and the current position is at the end of the input string, exit.
If the matching substring is zero length and the current position is not at the end of the input string, add the character that immediately follows the current position to the current non-matching substring, set the current position to the position immediately after this character, exit, and repeat.
If there is no match:
If the current position is the last position (that is, just after the last character):
If the current non-matching substring has length greater than zero,
evaluate the xsl:non-matching-substring
sequence
constructor with the current non-matching substring as the context
item.
Exit.
Otherwise, add the character at the current position to the current non-matching substring, increment the current position, and repeat.
When the matcher is looking for a match at a particular
starting position and there are several alternatives within the regular
expression that match at this position in the input string, then the match that is
chosen is the first alternative that matches. For example, if the input string is
The quick brown fox jumps
and the regular expression is
jump|jumps
, then the match that is chosen is jump
.
The input string is thus partitioned into a sequence of substrings, some of which
match the regular expression, others which do not match it. Each non-matching substring will contain at least one character, but a matching
substring may be zero-length. This sequence of substrings is processed
using the instructions within the contained
xsl:matching-substring
and
xsl:non-matching-substring
elements. A matching
substring is processed using the xsl:matching-substring
element, a
non-matching substring using the xsl:non-matching-substring
element.
Each of these elements takes a sequence constructor as its
content. If the element is absent, the effect is the same as if it were present with
empty content. In processing each substring, the contents of the substring will be
the context item (as a value of type
xs:string
); the position of the substring within the sequence of
matching and non-matching substrings will be the context position; and the number of matching and non-matching
substrings will be the context size.
Returns the string captured by a parenthesized subexpression of the regular expression
used during evaluation of the xsl:analyze-string
instruction.
This function is deterministicFO30, context-dependentFO30, and focus-independentFO30.
[Definition: While
the xsl:matching-substring
instruction is active, a set of
current captured substrings is available, corresponding to the
parenthesized subexpressions of the regular expression.] These captured
substrings are accessible using the function regex-group
. This
function takes an integer argument to identify the group, and returns a string
representing the captured substring.
The Nth captured substring (where N > 0) is the string matched
by the subexpression contained by the Nth left parenthesis in the regex,
excluding any non-capturing groups, which are written as
(?:xxx)
. The zeroth captured substring is the string that
matches the entire regex. This means that the value of regex-group(0)
is
initially the same as the value of .
(dot).
The function returns the zero-length string if there is no captured substring with the relevant number. This can occur for a number of reasons:
The number is negative.
The regular expression does not contain a parenthesized subexpression with the given number.
The parenthesized subexpression exists, and did not match any part of the input string.
The parenthesized subexpression exists, and matched a zero-length substring of the input string.
The set of captured substrings is a context variable with dynamic scope. It is initially
an empty sequence. During the evaluation of an xsl:matching-substring
instruction it is set to the sequence of matched substrings for that regex match.
During
the evaluation of an xsl:non-matching-substring
instruction or a
pattern or a stylesheet function it is set to an empty
sequence. On completion of an instruction that changes the value, the variable reverts
to its previous value.
The value of the current captured
substrings is unaffected through calls of
xsl:apply-templates
, xsl:call-template
,
xsl:apply-imports
or xsl:next-match
, or by
expansion of named attribute sets.
Problem: replace all newline characters in the abstract
element by
empty br
elements:
Solution:
<xsl:analyze-string select="abstract" regex="\n"> <xsl:matching-substring> <br/> </xsl:matching-substring> <xsl:non-matching-substring> <xsl:value-of select="."/> </xsl:non-matching-substring> </xsl:analyze-string>
Problem: replace all occurrences of [...]
in the body
by
cite
elements, retaining the content between the square brackets
as the content of the new element.
Solution:
<xsl:analyze-string select="body" regex="\[(.*?)\]"> <xsl:matching-substring> <cite><xsl:value-of select="regex-group(1)"/></cite> </xsl:matching-substring> <xsl:non-matching-substring> <xsl:value-of select="."/> </xsl:non-matching-substring> </xsl:analyze-string>
Note that this simple approach fails if the body
element contains
markup that needs to be retained. In this case it is necessary to apply the
regular expression processing to each text node individually. If the
[...]
constructs span multiple text nodes (for example, because
there are elements within the square brackets) then it probably becomes necessary
to make two or more passes over the data.
Problem: the input string contains a date such as 23 March 2002
.
Convert it to the form 2002-03-23
.
Solution (with no error handling if the input format is incorrect):
<xsl:variable name="months" select="'January', 'February', 'March', ..."/> <xsl:analyze-string select="normalize-space($input)" regex="([0-9]{{1,2}})\s([A-Z][a-z]+)\s([0-9]{{4}})"> <xsl:matching-substring> <xsl:number value="regex-group(3)" format="0001"/> <xsl:text>-</xsl:text> <xsl:number value="index-of($months, regex-group(2))" format="01"/> <xsl:text>-</xsl:text> <xsl:number value="regex-group(1)" format="01"/> </xsl:matching-substring> </xsl:analyze-string>
Note the use of normalize-space
to simplify the work done by the
regular expression, and the use of doubled curly brackets because the
regex
attribute is an attribute value template.
This example removes all empty and whitespace-only lines from a file.
<xsl:analyze-string select="unparsed-text('in.txt')" regex="^[\t ]*$" flags="m" expand-text="yes"> <xsl:non-matching-substring>{.}</xsl:non-matching-substring> </xsl:analyze-string>
There are many variants of CSV formats. This example is designed to handle input where:
Each record occupies one line.
Fields are separated by commas.
Quotation marks around a field are optional, unless the field contains a comma or quotation mark, in which case they are mandatory.
A quotation mark within the value of a field is represented by a pair of two adjacent quotation marks.
For example, the input record:
Ten Thousand,10000,,"10,000","It's ""10 Grand"", mister",10K
contains six fields, specifically:
Ten Thousand
10000
<zero-length-string>
10,000
It's "10 Grand", mister
10K
The following code parses such CSV input into an XML structure containing
row
and col
elements:
<xsl:for-each select="unparsed-text-lines('in.csv')" expand-text="yes"> <row> <xsl:analyze-string select="." regex='(?:^|,)(?:"((?:[^"]|"")*)"|([^",]*))'> <xsl:matching-substring> <col>{replace(regex-group(1), '""', '"')||regex-group(2)}</col> </xsl:matching-substring> </xsl:analyze-string> </row> </xsl:for-each>
Note that because this regular expression matches a zero-length string, it is not permitted in XSLT 2.0.
XSLT 3.0 introduces a number of constructs that are specifically designed to enable streamed applications to be written, but which are also useful in their own right; it also includes some features that are very specialized to streaming.
xsl:source-document
Instruction<!-- Category: instruction -->
<xsl:source-document
href = { uri }
streamable? = boolean
use-accumulators? = tokens
validation? = "strict" | "lax" | "preserve" | "strip"
type? = eqname >
<!-- Content: sequence-constructor -->
</xsl:source-document>
The xsl:source-document
instruction reads a source document whose URI is
supplied, and processes the content of the document by evaluating the
contained sequence constructor.
The streamable
attribute (default "no"
)
allows streamed processing to be requested.
For example, if a document represents a book holding a sequence of chapters, then the following code can be used to split the book into multiple XML files, one per chapter, without allocating memory to hold the entire book in memory at one time:
<xsl:source-document streamable="yes" href="book.xml"> <xsl:for-each select="book"> <xsl:for-each select="chapter"> <xsl:result-document href="chapter{position()}.xml"> <xsl:copy-of select="."/> </xsl:result-document> </xsl:for-each> </xsl:for-each> </xsl:source-document>
Note:
In earlier drafts of this specification the xsl:source-document
element was named xsl:stream
. The instruction has been generalised to handle both streamed and unstreamed
input.
The document to be read is determined by the effective value of the href
attribute (which is defined as
an attribute value template).
This must be a valid URI reference.
If it is an absolute URI reference, it is used as is; if it is a relative URI
reference, it is made absolute by resolving it against the base URI of the
xsl:source-document
element. The process of obtaining a
document node given a URI is the same as for the doc
FO30 function.
However, unlike the doc
FO30 function, the
xsl:source-document
instruction offers no guarantee that the resulting
document will be stable (that is, that multiple calls specifying the same URI will
return the same document).
Specifically, if an xsl:source-document
instruction is evaluated several
times (or if different xsl:source-document
instructions are evaluated) with
the same URI (after making it absolute) as the
value of the href
attribute, it is implementation-dependent whether the
same nodes or different nodes are returned on each occasion; it is also possible that
the actual document content will be different.
Note:
A different node will necessarily be returned if there
are differences in attributes such as validation
, type
,
streamable
, or use-accumulators
, or if the calls are in different
packages with variations in the rules for whitespace
stripping or stripping of type annotations.
The result of the xsl:source-document
instruction is the same as the result
of the following (non-streaming) process:
The source document is read from the supplied URI and parsed to form an tree of nodes in the XDM data model.
The contained sequence constructor is evaluated with the root node of this tree
as the context item, and with the context
position and context size set to one; and the resulting sequence is returned as
the result of the xsl:source-document
instruction.
The xsl:source-document
instruction is guaranteed-streamable if both the following conditions are satisfied:
It is declared-streamable, by specifying
streamable="yes"
.
the contained sequence constructor is grounded, as assessed using the streamability analysis in 19 Streamability. The consequences of being or not being guaranteed streamable depend on the processor conformance level, and are explained in 19.10 Streamability Guarantees.
The use-accumulators
attribute defines the
set of accumulators that are applicable to the document, as explained in
18.2.2 Applicability of Accumulators.
Note:
The following notes apply specifically to streamed processing.
The rules for guaranteed streamability
ensure that the sequence constructor (and therefore the
xsl:source-document
instruction) cannot return any nodes from the
streamed document. For example,
it cannot contain the instruction <xsl:sequence
select="//chapter"/>
. If nodes from this document are to be returned,
they must first be copied, for example by using the
xsl:copy-of
instruction or by calling the
copy-of
or snapshot
functions.
Because the xsl:source-document
instruction cannot (if it satisfies the rules for guaranteed
streamability) return nodes from the streamed document, any nodes it
does return will be conventional (unstreamed) nodes that can be processed without
restriction. For example, if xsl:source-document
is invoked within a
stylesheet function
f:firstChapter
, and the sequence constructor consists of the
instruction <xsl:copy-of select="//chapter"/>
, then the calling
code can manipulate the resulting chapter
elements as ordinary trees
rooted at parentless element nodes.
If the sequence constructor in an
xsl:source-document
instruction were to return nodes from the document
for which streaming has been requested, the instruction would not be guaranteed
streamable. Processors which support the streaming feature would then not be
required to process it in a streaming manner, and this specification imposes no
restrictions on the processing of the nodes returned. (The ability of a streaming
processor to handle such stylesheets in a streaming manner might, of course,
depend on how the nodes returned are processed, but those details are out of scope
for this specification.)
The validation
and type
attributes of
xsl:source-document
may be used to control schema validation of the
input document. They have the same effect as the
corresponding attributes of the xsl:copy-of
instruction when
applied to a document node, except that
when streamable="yes"
is specified,
the copy that is produced is itself a
streamed document. The process is described in more detail in 25.4.2 Validating Document Nodes.
These two attributes are both optional, and if one is specified then the other must be omitted ([see ERR XTSE1505]).
The presence of a validation
or type
attribute on an
xsl:source-document
instruction causes any
input-type-annotations
attribute to have no effect on any document
read using that instruction.
Note:
In effect, setting validation
to strict
or
lax
, or supplying the type
attribute, requests
document-level validation of the input as it is read. Setting
validation="preserve"
indicates that if the incoming document
contains type annotations (for example, produced by validating the output of a
previous step in a streaming pipeline) then they should be retained, while the
value strip
indicates that any such type annotations should be
dropped.
It is a consequence of the way validation is defined in XSD that the type
annotation of an element node can be determined during the processing of its
start tag, although the actual validity of the element is not known until the
end tag is encountered. When validation is requested, a streamed document
should not present data to the stylesheet except to the extent that such data
could form the leading part of a valid document. If the document proves to be
invalid, the processor should not pass invalid data to the stylesheet to be
processed, but should immediately signal the appropriate error. For the
purposes of xsl:try
and xsl:catch
, this error
can only be caught at the level of the xsl:source-document
instruction
that initiated validation, not at a finer level. If validation errors are
caught in this way, any output that has been computed up to the point of the
error is not added to the final result tree; the mechanisms to achieve this may
use memory, which may reduce the efficacy of streaming.
The analysis of guaranteed streamability (see 19 Streamability)
takes no account of information that might be obtained from a schema-aware
static analysis of the stylesheet. Implementations may, however, be able to use
streaming strategies for stylesheets that are not guaranteed-streamable, by
taking advantage of such information. For example, an implementation might be
able to treat the expression .//title
as striding rather than crawling if it can
establish from knowledge of the schema that two title
elements
will never be nested one inside the
other.
xsl:source-document
The xsl:source-document
instruction can be used to initiate processing of
a document using streaming with a variety of coding styles, illustrated in the
examples below.
xsl:source-document
with Aggregate Functions
The following example computes the number of transactions in a transaction file
Input:
<transactions> <transaction value="12.51"/> <transaction value="3.99"/> </transactions>
Stylesheet code:
<xsl:source-document streamable="yes" href="transactions.xml"> <count> <xsl:value-of select="count(transactions/transaction)"/> </count> </xsl:source-document>
Result:
<count>2</count>
Analysis:
The literal result element count
has the same sweep as the
xsl:value-of
instruction.
The xsl:value-of
instruction has the same sweep as its
select
expression.
The call to count
has the same sweep as its argument.
The argument to count
is a RelativePathExpr
.
Under the rules in 19.8.8.8 Streamability of Path Expressions,
this expression is striding and consuming. The
call on count
is therefore grounded and consuming.
The entire body of the xsl:source-document
instruction is therefore
grounded and consuming.
The following example computes the highest-value transaction in the same input file:
<xsl:source-document streamable="yes" href="transactions.xml"> <maxValue> <xsl:value-of select="max(transactions/transaction/@value)"/> </maxValue> </xsl:source-document>
Result:
<maxValue>12.51</maxValue>
Analysis:
The literal result element maxValue
has the same sweep as
the xsl:value-of
instruction.
The xsl:value-of
instruction has the same sweep as its
select
expression.
The call to max
has the same sweep as its argument.
The argument to max
is a RelativePathExpr
whose
two operands are the RelativePathExpr
transactions/transaction
and the AxisStep
@value
. The left-hand operand transactions/transaction
has
striding
posture. The right-hand operand @value
, given
that it appears in a node value context, is motionless. The RelativePathExpr
argument to max
is
therefore consuming.
The entire body of the xsl:source-document
instruction is
therefore consuming.
To compute both the count and the maximum value in a single pass over the input, several approaches are possible. The simplest is to use maps (map constructors are exempt from the usual rule that multiple downward selections are not allowed):
<xsl:source-document streamable="yes" href="transactions.xml"> <xsl:variable name="tally" select="map{ 'count': count(transactions/transaction), 'max': max(transactions/transaction/@value)}"/> <value count="{$tally('count')}" max="{$tally('max')}"/> </xsl:source-document>
Other options include the use of xsl:fork
, or multiple xsl:accumulator
declarations, one for each value to be computed.
This example displays a list of the chapter titles extracted from each book in a collection of books.
Each input document is assumed to have a structure such as:
<book> <chapter number-of-pages="18"> <title>The first chapter of book A</title> ... </chapter> <chapter number-of-pages="15"> <title>The second chapter of book A</title> ... </chapter> <chapter number-of-pages="12"> <title>The third chapter of book A</title> ... </chapter> </book>
Stylesheet code:
<chapter-titles> <xsl:for-each select="uri-collection('books')"> <xsl:source-document streamable="yes" href="{.}"> <xsl:for-each select="book"> <xsl:for-each select="chapter"> <title><xsl:value-of select="title"/></title> </xsl:for-each> </xsl:for-each> </xsl:source-document> </xsl:for-each> </chapter-titles>
Output:
<chapter-titles> <title>The first chapter of book A</title> <title>The second chapter of book A</title> ... <title>The first chapter of book B</title> ... </chapter-titles>
Note:
This example uses the function uri-collection
FO30 to
obtain the document URIs of all the documents in a collection, so that each
one can be processed in turn using xsl:source-document
.
This example assumes that the input is a book with multiple chapters, as shown in the previous example, with the page count for each chapter given as an attribute of the chapter. The transformation determines the starting page number for each chapter by accumulating the page counts for previous chapters, and rounding up to an odd number if necessary.
<chapter-start-page> <xsl:source-document streamable="yes" href="book.xml"> <xsl:iterate select="book/chapter"> <xsl:param name="start-page" select="1"/> <chapter title="{title}" start-page="{$start-page}"/> <xsl:next-iteration> <xsl:with-param name="start-page" select="$start-page + @number-of-pages + (@number-of-pages mod 2)"/> </xsl:next-iteration> </xsl:iterate> </xsl:source-document> </chapter-start-page>
Output:
<chapter-start-page> <chapter title="The first chapter of book A" start-page="1"/> <chapter title="The second chapter of book A" start-page="19"/> <chapter title="The third chapter of book A" start-page="35"/> ... </chapter-start-page>
This example assumes that the input is a book with multiple chapters, and that each chapter belongs to a part, which is present as an attribute of the chapter (for example, chapters 1-4 might constitute Part 1, the next three chapters forming Part 2, and so on):
<book> <chapter part="1"> <title>The first chapter of book A</title> ... </chapter> <chapter part="1"> <title>The second chapter of book A</title> ... </chapter> ... <chapter part="2"> <title>The fifth chapter of book A</title> ... </chapter> </book>
The transformation copies the full text of the chapters, creating an extra level of hierarchy for the parts.
<book> <xsl:source-document streamable="yes" href="book.xml"> <xsl:for-each select="book"> <xsl:for-each-group select="chapter" group-adjacent="data(@part)"> <part number="{current-grouping-key()}"> <xsl:copy-of select="current-group()"/> </part> </xsl:for-each-group> </xsl:for-each> </xsl:source-document> </book>
Output:
<book> <part number="1"> <chapter part="1"> <title>The first chapter of book A</title> ... </chapter> <chapter part="1"> <title>The second chapter of book A</title> ... </chapter> ... </part> <part number="2"> <chapter part="2"> <title>The fifth chapter of book A</title> ... </chapter> ... </part> </book>
This example copies an XML document while deleting all the ednote
elements at any level of the tree, together with their descendants. This
example is a complete stylesheet, which is intended to be evaluated by
nominating main
as the initial named template.
The use of on-no-match="deep-copy"
in the
xsl:mode
declaration means that the built-in template rule
copies nodes unchanged, except where overridden by a user-defined template
rule.
<xsl:transform version="3.0" xmlns:xsl="http://www.w3.org/1999/XSL/Transform"> <xsl:mode name="delete-ednotes" streamable="yes" on-no-match="shallow-copy"/> <xsl:template name="main"> <xsl:source-document streamable="yes" href="book.xml"> <xsl:apply-templates mode="delete-ednotes"/> </xsl:source-document> </xsl:template> <xsl:template match="ednote" mode="delete-ednotes"/> </xsl:transform>
Additional template rules could be added to process other elements and
attributes in the same pass through the data: for example, to modify the value
of a last-updated
attribute (wherever it appears) to the current
date and time, the following rule suffices:
<xsl:template match="@last-updated" mode="delete-ednotes"> <xsl:attribute name="last-updated" select="current-dateTime()"/> </xsl:template>
Determines, as far as possible, whether a document is available for streamed processing
using xsl:source-document
.
This function is nondeterministicFO30, context-dependentFO30, and focus-independentFO30. It depends on available documents.
The intent of the stream-available
function is to allow a stylesheet author to determine,
before calling xsl:source-document
with streamable="yes"
and
with a particular URI as the value of its href
attribute, whether a document is available at that location for streamed processing.
If the $uri
argument is an empty sequence then the function returns false
.
If the function returns true
then the caller can conclude that the following conditions are true:
The supplied URI is valid;
A resource can be retrieved at that URI;
An XML representation of the resource can be delivered, which is well-formed at least to the extent that some initial sequence of octets can be decoded into characters and matched against the production:
prolog (EmptyElemTag | STag )
as defined in the XML 1.0 or XML 1.1 Recommendation.
Note:
That is, the XML is well-formed at least as far as the end of the first element start tag; to establish this, a parser will typically retrieve any external entities referenced in the Doctype declaration or DTD.If the function returns false
, the caller can conclude that either one of the above conditions is not satisfied,
or
the processor detected some other condition that would prevent a call on xsl:source-document
with
streamable="yes"
executing successfully.
Like xsl:source-document
itself, the function is not deterministic, which means that multiple calls during
the execution
of a stylesheet will not necessarily return the same result. The caller cannot make
any inferences about the point in time at which
the input conditions for stream-available
are present, and in particular there is no guarantee that because
stream-available
returns true, xsl:source-document
will necessarily succeed.
The value of the $uri
argument must be a URI in the form of a string. If it is a relative URI,
it is resolved relative to the static base URI of the function call.
If the URI is invalid, such that a call on doc-available
FO30 would signal an error, then
stream-available
signals the same error: [ERR FODC0005] FO30.
Accumulators are introduced in XSLT 3.0 to enable data that is read during streamed processing of a document to be accumulated, processed or retained for later use. However, they may equally be used with non-streamed processing.
[Definition: An
accumulator defines a series of
values associated with the nodes of the tree. If an accumulator is
applicable to a particular tree, then for each node in the tree, other than
attribute and namespace nodes, there will be two values available, called the
pre-descent and post-descent values. These two values are available via a pair of
functions, accumulator-before
and
accumulator-after
.]
There are two ways the values of an accumulator can be
established for a given tree: they can be computed by evaluating the rules appearing
in the xsl:accumulator
declaration, or they can be copied from the
corresponding nodes in a different tree. The second approach (copying the values)
is
available via the snapshot
and copy-of
functions, or by use of the xsl:copy-of
instruction specifying
copy-accumulators="yes"
. Accumulator values are also copied during
the implicit invocation of the snapshot function performed by the
xsl:merge
instruction.
Note:
Accumulators can apply to trees rooted at any kind of node. But because they are most often applied to trees rooted at a document node, this section sometimes refers to the “document” to which an accumulator applies; use of this term should be taken to include all trees whether or not they are rooted at a document node.
Accumulators can apply to trees rooted at nodes (such as text nodes) that cannot have children, though this serves no useful purpose. In the case of a tree rooted at an attribute or namespace node, there is no way to obtain the value of the accumulator.
The following sections give first, the syntax rules for defining an accumulator; then an informal description of the semantics; then a more formal definition; and finally, examples. But to illustrate the concept intuitively, the following simple example shows how an accumulator can be used for numbering of nodes:
This example assumes document input in which figure
elements can
appear within chapter
elements (which we assume are not nested), and
the requirement is to render the figures with a caption that includes the figure
number within its containing chapter.
When the document is processed using streaming, the xsl:number
instruction is not available, so a solution using accumulators is needed.
The required accumulator can be defined and used like this:
<xsl:accumulator name="figNr" as="xs:integer" initial-value="0" streamable="yes"> <xsl:accumulator-rule match="chapter" select="0"/> <xsl:accumulator-rule match="figure" select="$value + 1"/> </xsl:accumulator> <xsl:mode streamable="yes"/> <xsl:template match="figure"> <xsl:apply-templates/> <p>Figure <xsl:value-of select="accumulator-before('figNr')"/></p> </xsl:template>
<!-- Category: declaration -->
<xsl:accumulator
name = eqname
initial-value = expression
as? = sequence-type
streamable? = boolean >
<!-- Content: xsl:accumulator-rule+ -->
</xsl:accumulator>
<xsl:accumulator-rule
match = pattern
phase? = "start" | "end"
select? = expression >
<!-- Content: sequence-constructor -->
</xsl:accumulator-rule>
An xsl:accumulator
element is a declaration of an accumulator. The
name
attribute defines the name of the accumulator. The value of
the name
attribute is an EQName,
which is expanded as described in 5.1.1 Qualified Names.
An xsl:accumulator
declaration can only appear as a top-level element in a stylesheet module.
The functions accumulator-before
and accumulator-after
return, respectively, the
value of the accumulator before visiting the descendants of a given node, and the
value after visiting the descendants of a node. Each of these functions takes a single argument, the name of the
accumulator, and the function applies implicitly to the context node. The
type of the return value (for both functions) is determined by the as
attribute of the xsl:accumulator
element.
[Definition: The functions
accumulator-before
and
accumulator-after
are referred to as the
accumulator functions.]
For constructs that use accumulators to be guaranteed-streamable:
The accumulator-before
function for a streamed node can
be called at any time the node is available (it behaves like other
properties of the node such as name
FO30 or
base-uri
FO30).
The accumulator-after
function, however, is restricted
to appear after any instruction that reads the descendants
of the node in question. The constraints are expressed as static rules: see
19.8.9.1 Streamability of the accumulator-after Function for more details.
The initial value of the accumulator is obtained by evaluating the expression in
the initial-value
attribute. This
attribute is mandatory. The expression in the
initial-value
attribute is evaluated with a singleton focus based on the root node of
the streamed input tree to which the accumulator is being applied.
The values of the accumulator for individual nodes in a tree are obtained by
applying the xsl:accumulator-rule
rules contained within the
xsl:accumulator
declaration, as described in subsequent
sections. The match
attribute of
xsl:accumulator-rule
is a pattern which
determines which nodes trigger execution of the rule; the phase
attribute indicates whether the rule fires before descendants are processed
(phase="start"
, which is the default), or after descendants are
processed (phase="end"
).
The select
attribute and the contained sequence constructor of the
xsl:accumulator-rule
element are mutually exclusive: if the
select
attribute is present then the sequence constructor must be
empty. The expression in the select
attribute of xsl:accumulator-rule
or the contained sequence constructor
is evaluated with a static context that follows the normal rules for expressions
in stylesheets, except that:
An additional variable is present in the context. The name of this variable
is value
(in no namespace), and its type is the type that
appears in the as
attribute of the
xsl:accumulator
declaration.
The context item for evaluation of the expression or sequence constructor will always be a node
that matches the pattern in the
match
attribute.
The result of both the initial-value
and select
expressions (or contained sequence
constructor) is converted to the type declared in the as
attribute by applying the function conversion rules. A
type error occurs if conversion is not
possible. The as
attribute defaults to item()*
.
The effect of the streamable
attribute is defined in 18.2.9 Streamability of Accumulators.
It is not the case that every accumulator is applicable to every tree. The details depend on how the accumulator is declared, and how the tree is created. The rules are as follows:
An accumulator is applicable to a tree unless otherwise specified in these rules.
(For example, when a document is read using the document
,
doc
FO30, or collection
FO30 functions,
all accumulators are applicable. Similarly, all accumulators are applicable
to a temporary tree created using xsl:variable
.)
Regardless of the rules below, an accumulator is not applicable to a streamed document
unless the accumulator is declared with streamable="yes"
. (The converse
does not apply: for unstreamed documents, accumulators are applicable regardless
of the value of the streamable
attribute.)
For a document read using the
xsl:source-document
instruction, the accumulators that are applicable
are those determined by the use-accumulators
attribute of that instruction.
For a document read using the for-each-source
attribute of an
xsl:merge-source
child of an xsl:merge
instruction,
the accumulators that are applicable are those determined by the use-accumulators
attribute of the xsl:merge-source
element.
For a document containing nodes supplied in the
initial match selection, the accumulators that are
applicable are those determined by the xsl:mode
declaration of the initial mode. This means that in the
absence of an xsl:mode
declaration, no accumulators are applicable.
For a tree T created by copying a node in a tree S
using the copy-of
or snapshot
functions, or the instruction xsl:copy-of
with
copy-accumulators="yes"
, an accumulator is applicable to
T if and only if it is applicable to S.
If an accumulator is not applicable to the tree containing the context item, calls
to the functions accumulator-before
and
accumulator-after
, supplying the name of that accumulator,
will fail with a dynamic error.
Note:
The reason that accumulators are not automatically applicable to every streamed document is to avoid the cost of evaluating them, and to avoid the possibility of dynamic errors occuring if they are not designed to work with a particular document structure.
In the case of unstreamed documents, there are no compelling reasons to restrict which accumulators are applicable, because an implementation can avoid the cost of evaluating every accumulator against every document by evaluating the accumulator lazily, for example, by only evaluating the accumulator for a particular tree the first time its value is requested for a node in that tree. In the interests of orthogonality, however, restricting the applicable accumulators works in the same way for streamable and non-streamable documents.
The value of the use-accumulators
attribute of
xsl:source-document
, xsl:merge-source
,
or xsl:mode
must either a
whitespace-separated list of EQNames, or the
special token #all
. The list may be empty, and the default value is
an empty list. Every EQName
in the list must be the name of an
accumulator, visible in the containing package, and declared with
streamable="yes"
. The value #all
indicates that all
accumulators that are visible in the containing package are applicable (except
that for a streamable input document, an accumulator is not applicable unless
it specifies streamable="yes"
).
[ERR XTSE3300] It is a static error if the list of
accumulator names contains an invalid token, contains the same
token more than once, or contains the token #all
along with any
other value; or if any token (other than
#all
) is not the name of a declared-streamable accumulator visible in the containing
package.
This section describes how accumulator values are
established by evaluating the rules in an xsl:accumulator
declaration. This process does not apply to trees created with accumulator
values copied from another document, for example by using the
copy-of
or snapshot
functions.
Informally, an accumulator is evaluated by traversing a tree, as follows.
Each node is visited twice, once before processing its descendants, and once after processing its descendants. For consistency, this applies even to leaf nodes: each is visited twice. Attribute and namespace nodes, however, are not visited.
Before the traversal starts, a variable (called the accumulator variable) is
initialized to the value of the expression given as the initial-value
attribute.
On each node visit, the xsl:accumulator-rule
elements are
examined to see if there is a matching rule. For a match to occur, the pattern in
the match
attribute must match the node, and the phase
attribute must be start
if this is the first visit, and
end
if it is the second visit. If there is a matching rule, then a
new value is computed for the accumulator variable using the expression contained
in that rule’s select
attribute or the contained sequence constructor. If there is more than
one matching rule, the last in document order is used. If there is no matching
rule, the value of the accumulator variable does not change.
Each node is labeled with a pre-descent value for the accumulator, which is the value of the accumulator variable immediately after processing the first visit to that node, and with a post-descent value for the accumulator, which is the value of the accumulator variable immediately after processing the second visit.
The function accumulator-before
delivers
the pre-descent value of the accumulator at the context node; the function
accumulator-after
delivers the post-descent value of the
accumulator at the context node.
Although this description is expressed in procedural terms, it can be seen that the two values of the accumulator for any given node depend only on the node and its preceding and (in the case of the post-descent value) descendant nodes. Calculation of both values is therefore deterministic and free of side-effects; moreover, it is clear that the values can be computed during a streaming pass of a document, provided that the rules themselves use only information that is available without repositioning the input stream.
It is permitted for the select
expression of an accumulator rule, or the contained
sequence constructor, to invoke an accumulator function. For a streamable accumulator, the rules ensure that
a rule with phase="start"
cannot call the
accumulator-after
function. When such function calls
exist in an accumulator rule, they impose a dependency of one accumulator on
another, and create the possibility of cyclic dependencies. Processors are
allowed to report the error statically if they can detect it statically.
Failing this, processors are allowed to fail catastrophically in the event of a
cycle, in the same way as they might fail in the event of infinite function or
template recursion. Catastrophic failure might manifest itself, for example, as
a stack overflow, or as non-termination of the transformation.
This section describes how accumulator values are
established by evaluating the rules in an xsl:accumulator
declaration. This process does not apply to trees created with accumulator
values copied from another document, for example by using the
copy-of
or snapshot
functions.
[Definition: A traversal of a tree is a sequence of traversal events.]
[Definition: a traversal
event (shortened to event in this section) is a pair
comprising a phase (start or end) and a node.] It is modelled as a map
with two entries: map{"phase": p, "node": n}
where p is the string
"start"
or "end"
and n
is a node.
The traversal of a tree contains two traversal events for each node in the tree, other than attribute and namespace nodes. One of these events (the “start event”) has phase = "start", the other (the "end event") has phase = "end".
The order of traversal events within a traversal is such that, given any two nodes M and N with start/end events denoted by M0, M1, N0, and N1, :
For any node N, N0 precedes N1;
If M is an ancestor of N then M0 precedes N0 and N1 precedes M1;
If M is on the preceding axis of N then M1 precedes N0.
The accumulator defines a (private) delta function Δ. The delta function computes the value of the accumulator for one traversal event in terms of its value for the previous traversal event. The function is defined as follows:
The signature of Δ is function ($old-value as T,
$event as map(*)) as T
, where T is the sequence type
declared in the as
attribute of the accumulator
declaration;
The implementation of the function is equivalent to the following algorithm:
Let R be the set of xsl:accumulator-rule
elements among the children of the accumulator declaration whose
phase
attribute equals $event("phase")
and whose match
attribute is a pattern that matches $event("node")
If R is empty, return $old-value
Let Q be the xsl:accumulator-rule
in
R that is last in document order
Return the value of the expression in the select
attribute of Q, or the
contained sequence constructor, evaluating this with a
singleton focus set to
$event("node")
and with a dynamic context that binds
the variable whose name is $value
(in no namespace) to the value
$old-value
.
Note:
The argument names old-value
and event
are used here purely for definitional purposes; these names are not
available for use within the select
expression or contained sequence
constructor.
For every node N, other than attribute and namespace nodes, the accumulator defines a pre-descent value BN and a post-descent value AN whose values are as follows:
Let T be the traversal of
the tree rooted at fn:root(N)
.
Let SB be the subsequence of T starting at the first
event in T and ending with the start event for node N
(that is, the event map{ "phase":"start", "node":N }
).
Let SA be the subsequence of T starting at the first
event in T, and ending with the end event
for node N (that is, the event map{ "phase":"end", "node":N
}
).
Let Z be the result of evaluating the expression contained in the
initial-value
attribute of the
xsl:accumulator
declaration, evaluated with a singleton focus
based on root(N)
.
Then the pre-descent value BN is the value of
fn:fold-left(SB, Z, Δ)
, and the post-descent value
AN is the value of fn:fold-left(SA, Z,
Δ)
.
If a dynamic error occurs when evaluating the initial-value
expression
of xsl:accumulator
, or the select
expression of xsl:accumulator-rule
,
then the error is signaled as an error from any subsequent call on accumulator-before
or accumulator-after
that references the accumulator. If no such call on accumulator-before
or accumulator-after
happens, then the error goes unreported.
Note:
In the above rule, the phrase subsequent call is to be understood in terms of functional dependency; that is, a call to
accumulator-before
or accumulator-after
signals an error if the accumulator value at the node in question is
functionally dependent on a computation that fails with a dynamic error.
Note:
Particularly in the case of streamed accumulators, this may mean that the implementation
has to “hold back” the error
until the next time the accumulator is referenced, to give applications the opportunity
to catch the error using xsl:try
and xsl:catch
in a predictable way.
Note:
Errors that occur during the evaluation of the pattern in the match
attribute of
xsl:accumulator-rule
are handled as described in 5.5.4 Errors in Patterns:
specifically, the pattern does not match the relevant node, and no error is signaled.
Returns the pre-descent value of the selected accumulator at the context node.
This function is deterministicFO30, context-dependentFO30, and focus-dependentFO30.
The $name
argument specifies the name of the accumulator. The value of the argument must be a string containing an EQName. If it is a lexical QName, then it is expanded as described in
5.1.1 Qualified Names (no prefix means no namespace).
The function returns the pre-descent value B(N)of the selected accumulator where N is the context node, as defined in 18.2.4 Formal Model for Accumulators.
If the context item is a node in a streamed document, then the accumulator
must be declared with streamable="yes"
.
Note:
The converse is not true: an accumulator declared to be streamable is available on both streamed and unstreamed nodes.
[ERR XTDE3340] It is a dynamic error if the value of the first
argument to the accumulator-before
or
accumulator-after
function is not a valid
EQName, or if there is no namespace declaration in scope
for the prefix of the QName, or if the name obtained by expanding the QName is not
the same as the expanded name of any xsl:accumulator
declaration
appearing in the package in which the function
call appears. If the processor is able to detect the error statically (for
example, when the argument is supplied as a string literal), then the processor
may optionally signal this as a static error.
[ERR XTDE3350] It is a dynamic error to call the
accumulator-before
or
accumulator-after
function when there is no context item.
[ERR XTTE3360] It is a type error to call the
accumulator-before
or
accumulator-after
function when the context item is not a node, or when it is an attribute or namespace
node.
[ERR XTDE3362] It is a dynamic error to call the
accumulator-before
or
accumulator-after
function when the context
item is a node in a tree to which the selected accumulator is not
applicable (including the case where it is not applicable
because the document is streamed and the accumulator is not
declared with streamable="yes"
). Implementations
may raise this error but are not required to do so,
if they are capable of streaming documents without imposing this restriction.
[ERR XTDE3400] It is an error if there is a cyclic set of dependencies among accumulators such that the (pre- or post-descent) value of an accumulator depends directly or indirectly on itself. A processor may report this as a static error if it can be detected statically. Alternatively a processor may report this as a dynamic error. As a further option, a processor may fail catastrophically when this error occurs.
The accumulator-before
function can be applied to a node whether or not the accumulator
has a phase="start"
rule for that node. In effect, there is a phase="start"
rule
for every node, where the default rule is to leave the accumulator value unchanged;
the
accumulator-before
function delivers the value of the accumulator after processing
the explicit or implicit phase="start"
rule.
Given the accumulator:
<xsl:accumulator name="a" initial-value="0"> <xsl:accumulator-rule match="section" select="$value + 1"/> </xsl:accumulator>
and the template rule:
<xsl:template match="section"> <xsl:value-of select="accumulator-before('a')"/> <xsl:apply-templates/> </xsl:template>
The stylesheet will precede the output from processing each section with a section number that runs sequentially 1, 2, 3... irrespective of the nesting of sections.
Returns the post-descent value of the selected accumulator at the context node.
This function is deterministicFO30, context-dependentFO30, and focus-dependentFO30.
The $name
argument specifies the name of the accumulator. The value of the argument must be a string containing an EQName. If it is a
lexical QName, then it is expanded as
described in 5.1.1 Qualified Names (no prefix means no namespace).
The function returns the post-descent value A(N) of the selected accumulator where N is the context node, as defined in 18.2.4 Formal Model for Accumulators.
If the context item is a node in a streamed document, then the accumulator
must be declared with streamable="yes"
.
Note:
The converse is not true: an accumulator declared to be streamable is available on both streamed and unstreamed nodes.
The following errors apply: [see ERR XTDE3340], [see ERR XTDE3350], [see ERR XTTE3360], [see ERR XTDE3362], [see ERR XTDE3400].
For constraints on the use of accumulator-after
when streaming, see
19.8.9.1 Streamability of the accumulator-after Function.
The accumulator-after
function can be applied to a node whether or not the accumulator
has a phase="end"
rule for that node. In effect, there is a phase="end"
rule
for every node, where the default rule is to leave the accumulator value unchanged;
the
accumulator-after
function delivers the value of the accumulator after processing
the explicit or implicit phase="end"
rule.
Given the accumulator:
<xsl:accumulator name="w" initial-value="0" streamable="true" as="xs:integer"> <xsl:accumulator-rule match="text()" select="$value + count(tokenize(.))"/> </xsl:accumulator>
and the template rule:
<xsl:template match="section"> <xsl:apply-templates/> (words: <xsl:value-of select="accumulator-after('w') - accumulator-before('w')"/>) </xsl:template>
The stylesheet will output at the end of each section a (crude) count of the number of words in that section.
Note: the call on tokenize(.)
relies on XPath 3.1
If a package contains more than one
xsl:accumulator
declaration with a particular name, then the
one with the highest import precedence is used.
[ERR XTSE3350] It is a static error for a package to contain two or more non-hidden accumulators with the same expanded QName and the same import precedence, unless there is another accumulator with the same expanded QName, and a higher import precedence.
Accumulators cannot be referenced from, or overridden in, a different package from the one in which they are declared.
An accumulator is guaranteed-streamable if it satisfies all the following conditions:
The xsl:accumulator
declaration has the attribute
streamable="yes"
.
In every contained xsl:accumulator-rule
, the pattern in the match
attribute is
a motionless pattern (see 19.8.10 Classifying Patterns).
The expression in the
initial-value
attribute is grounded and
motionless.
The expression in the select
attribute or contained
sequence constructor is grounded and
motionless.
Specifying streamable="yes"
on an
xsl:accumulator
element declares an intent that the
accumulator should be streamable, either
because it is guaranteed-streamable, or because it takes
advantage of streamability extensions offered by a particular
processor. The consequences of declaring the accumulator to be
streamable when it is not in fact guaranteed streamable depend on the conformance
level of the processor, and are explained in 19.10 Streamability Guarantees.
When an accumulator is declared to be streamable, the
stylesheet author must ensure that the accumulator function
accumulator-after
is only called at appropriate points in
the processing, as explained in 19.8.9.1 Streamability of the accumulator-after Function.
When nodes (including streamed nodes) are copied using the
snapshot
or copy-of
functions, or
using the xsl:copy-of
instruction with the attribute
copy-accumulators="yes"
, then the pre-descent and post-descent
values of accumulators for that tree are not determined by traversing the tree as
described in 18.2.3 Informal Model for Accumulators and 18.2.4 Formal Model for Accumulators. Instead the values are the same as the values
on the corresponding nodes of the source tree.
This applies also to the implicit invocation of the snapshot
function that happens during the evaluation of xsl:merge
.
If an accumulator is not applicable to a tree S, then it is also not applicable to any tree formed by copying nodes from S using the above methods.
Note:
During streamed processing, accumulator values will typically be computed “on
the fly”; when the copy-of
or
snapshot
functions are applied to a streamed node, the
computed accumulator values for the streamed document will typically be
materialized and saved as part of the copy.
Accumulator values for a non-streamed document will often be computed lazily,
that is, they will not be computed unless and until they are needed. A call on
copy-of
or snapshot
on a
non-streamed document whose accumulator values have not yet been computed can
then be handled in a variety of ways. The implementation might interpret the
call on copy-of
or snapshot
as a
trigger causing the accumulator values to be computed; or it might retain a
link between the nodes of the copied tree and the nodes of the original tree,
so that a request for accumulator values on the copied tree can trigger
computation of accumulator values for the original tree.
Consider an XHTML document in which the title of the document is represented by
the content of a title
element appearing as a child of the
head
element, which in turn appears as a child of the
html
element. Suppose that we want to process the document in
streaming mode, and that we want to avoid outputting the content of the
h1
element if it is the same as the document title.
This can be achieved by remembering the value of the title in an accumulator variable.
<xsl:accumulator name="firstTitle" as="xs:string?" initial-value="()" streamable="yes"> <xsl:accumulator-rule match="/html/head/title/text()" select="string(.)"/> </xsl:accumulator>
Subsequently, while processing an h1
element appearing later in
the document, the value can be referenced:
<xsl:template match="h1"> <xsl:variable name="firstTitle" select="accumulator-before('firstTitle')"/> <xsl:variable name="thisTitle" select="string(.)"/> <xsl:if test="$thisTitle ne $firstTitle"> <div class="heading-1"><xsl:value-of select="$thisTitle"/></div> </xsl:if> </xsl:template>
Suppose that there is a requirement to output, at the end of the HTML rendition of a document, a paragraph giving the total number of words in the document.
An accumulator can be used to maintain a (crude) word count as follows:
<xsl:accumulator name="word-count" as="xs:integer" initial-value="0"> <xsl:accumulator-rule match="text()" select="$value + count(tokenize(.))"/> </xsl:accumulator>
Note: the call on tokenize#1
relies on XPath 3.1
The final value can be output at the end of the document:
<xsl:template match="/"> <xsl:apply-templates/> <p>Word count: <xsl:value-of select="accumulator-after('word-count')"/></p> </xsl:template>
Consider a document in which section
elements are nested within
section
elements to arbitrary depth, and there is a requirement
to render the document with hierarchic section numbers of the form
3.5.1.4
.
The current section number can be maintained in an accumulator in the form of a sequence of integers, managed as a stack. The number of integers represents the current level of nesting, and the value of each integer represents the number of preceding sibling sections encountered at that level. For convenience the first item in the sequence represents the top of the stack.
<xsl:accumulator name="section-nr" as="xs:integer*" initial-value="0"> <xsl:accumulator-rule match="section" phase="start" select="0, head($value)+1, tail($value)"/> <xsl:accumulator-rule match="section" phase="end" select="tail($value) (:pop:)"/> </xsl:accumulator>
To illustrate this, consider the values after processing a series of start and end tags:
events | accumulator value | required section number |
---|---|---|
<section> |
0, 1 |
1 |
<section> |
0, 1, 1 |
1.1 |
</section> |
1, 1 |
|
<section> |
0, 2, 1 |
1.2 |
</section> |
2, 1 |
|
<section> |
0, 3, 1 |
1.3 |
<section> |
0, 1, 3, 1 |
1.3.1 |
</section> |
1, 3, 1 |
|
<section> |
0, 2, 3, 1 |
1.3.2 |
</section> |
2, 3, 1 |
|
</section> |
3, 1 |
|
</section> |
1 |
The section number for a section can thus be generated as:
<xsl:template match="section"> <p> <xsl:value-of select="reverse(tail(accumulator-before('section-nr')))" separator="."/> </p> <xsl:apply-templates/> </xsl:template>
<xsl:accumulator name="histogram" as="map(xs:string, xs:integer)" initial-value="map{}"> <xsl:accumulator-rule match="book"> <xsl:choose> <xsl:when test="map:contains($value, @publisher)"> <xsl:sequence select="map:put($value, string(@publisher), $value(@publisher)+1)"/> </xsl:when> <xsl:otherwise> <xsl:sequence select="map:put($value, string(@publisher), 1)"/> </xsl:otherwise> </xsl:choose> </xsl:accumulator-rule> </xsl:accumulator>
The contained sequence constructor
is
evaluated with the variable $value
set to the current value, and
with the context node as the node being visited.
Note:
In the two calls on map:put()
, it is necessary to explicitly
convert @publisher
to an xs:string
value, because
this is the declared type of the keys in the result map. Relying on
atomization would produce keys of type xs:untypedAtomic
, which
would not satisfy the declared type of the map.
The accumulated histogram might be displayed as follows:
<xsl:source-document streamable="yes" href="booklist.xml"> ..... <h1>Number of books, by publisher</h1> <table> <thead> <th>Publisher</th> <th>Number of books</th> </thead> <tbody> <xsl:variable name="histogram" select="accumulator-after('histogram')"/> <xsl:for-each select="map:keys($histogram)"> <tr> <td><xsl:value-of select="."/></td> <td><xsl:value-of select="$histogram(.)"/></td> </tr> </xsl:for-each> </tbody> </table> </xsl:source-document>
Returns a deep copy of the sequence supplied as the $input
argument, or of the
context item if the argument is absent.
fn:copy-of
($input
as
item()*
) as
item()*
The zero-argument form of this function is nondeterministicFO30, focus-dependentFO30, and context-independentFO30.
The one-argument form of this function is nondeterministicFO30, focus-independentFO30, and context-independentFO30.
The zero-argument form of this function is defined so that copy-of()
returns the value of internal:copy-item(.)
, where internal:copy-item
(which
exists only for the purpose of this exposition) is defined below. Informally, copy-of()
copies the context item.
The single argument form of this function is defined in terms of the
internal:copy-item
as follows: copy-of($input)
is equivalent
to $input ! internal:copy-item(.)
. Informally, copy-of($input)
copies each item in the
input sequence in turn.
The internal:copy-item
function is defined as follows:
<xsl:function name="internal:copy-item" as="item()" new-each-time="maybe"> <xsl:param name="input" as="item()"/> <xsl:copy-of select="$input" copy-namespaces="yes" copy-accumulators="yes" validation="preserve"/> </xsl:function>
The streamability analysis, however, is different: see 19.8.9 Classifying Calls to Built-In Functions.
The use of new-each-time="maybe"
in the above definition means that
if the internal:copy-item
function is called more than once with the same node as argument
(whether or not these calls are part of the same call on copy-of
), then it is implementation-dependent whether each
call returns the same node, or whether multiple calls return different nodes.
Returning the original node, however, is not allowed, except as an optimization when
the processor
can determine that this is equivalent.
Note:
One case where such optimization might be possible is when the copy is immediately atomized.
The copy-of
function is available for use (and is primarily
intended for use) when a source document is processed using streaming. It can also
be
used when not streaming. The effect,
when applied to element and document nodes,
is to take a copy of the subtree rooted at the
current node, and to make this available as a normal tree: one that can be processed
without
any of the restrictions that apply while streaming, for example only being able to
process children once. The copy, of course, does not include siblings or ancestors
of
the context node, so any attempt to navigate to siblings or ancestors will result
in an
empty sequence being returned.
All nodes in the result sequence will be parentless.
If atomic values or functions (including maps and arrays) are present in the input sequence, they will be included unchanged at the corresponding position of the result sequence.
Accumulator values are taken from the copied document as described in 18.2.10 Copying Accumulator Values.
Using copy-of()
while streaming:
This example copies from the source document all employees who work in marketing and
are based in Dubai. Because there are two accesses using the child axis, it is not
possible to do this without buffering each employee in memory, which can be achieved
using the copy-of
function.
<xsl:source-document streamable="yes" href="employees.xml"> <xsl:sequence select="copy-of(employees/employee) [department='Marketing' and location='Dubai']"/> </xsl:source-document>
Returns a copy of a sequence, retaining copies of the ancestors and descendants of any node in the input sequence, together with their attributes and namespaces.
fn:snapshot
($input
as
item()*
) as
item()*
The zero-argument form of this function is nondeterministicFO30, focus-dependentFO30, and context-independentFO30.
The one-argument form of this function is nondeterministicFO30, focus-independentFO30, and context-independentFO30.
The zero-argument form of this function is defined so that snapshot()
returns the value of internal:snaphot-item(.)
, where internal:snapshot-item
(which
exists only for the purpose of this exposition) is defined below. Informally, snapshot()
takes a snapshot of the context item.
The single argument form of this function is defined in terms of the
internal:snapshot-item
as follows: snapshot($input)
is equivalent
to $input ! internal:snapshot-item(.)
. Informally, snapshot($input)
takes a snapshot of each item in the
input sequence in turn.
The internal:snapshot-item
function behaves as follows:
If the supplied item is an atomic value or a function item (including maps and arrays), then it returns that item unchanged.
If the supplied item is a node, then it returns a snapshot of that node, as defined below.
[Definition: A snapshot of a node N
is a deep copy of N, as produced by the xsl:copy-of
instruction with copy-namespaces
set to yes
,
copy-accumulators
set to yes
, and
validation
set to preserve
, with the additional property
that for every ancestor of N, the copy also has a corresponding ancestor
whose name, node-kind, and base URI are the same as the corresponding ancestor of
N, and that has copies of the attributes, namespaces and accumulator values of the
corresponding ancestor of N. But the ancestor has a type annotation of
xs:anyType
, has the properties nilled
,
is-id
, and is-idref
set to false, and has no children
other than the child that is a copy of N or one of its
ancestors.]
If the function is called more than once with the same argument, it is implementation-dependent whether each
call returns the same node, or whether multiple calls return different nodes. That
is,
the result of the expression snapshot($X) is snapshot($X)
is implementation-dependent.
Except for the effect on accumulators, the internal:snapshot-item
function can be expressed
as follows:
<xsl:function name="internal:snapshot-item" as="item()"> <xsl:param name="input" as="item()"/> <xsl:apply-templates select="$input" mode="internal:snapshot"/> </xsl:function> <!-- for atomic values and function items, return the item unchanged --> <xsl:template match="." mode="internal:snapshot" priority="1"> <xsl:sequence select="."/> </xsl:template> <!-- for a document node, or any other root node, return a deep copy --> <xsl:template match="root()" mode="internal:snapshot" priority="5"> <xsl:copy-of select="."/> </xsl:template> <!-- for an element, comment, text node, or processing instruction: --> <xsl:template match="node()" mode="internal:snapshot" as="node()" priority="3"> <xsl:sequence select="internal:graft-to-parent( ., .., function($n){$n/node()})"/> </xsl:template> <!-- for an attribute: --> <xsl:template match="@*" mode="internal:snapshot" as="attribute()" priority="3"> <xsl:variable name="name" select="node-name(.)"/> <xsl:sequence select="internal:graft-to-parent(., .., function($n){$n/@*[node-name(.) = $name]})"/> </xsl:template> <!-- for a namespace node: --> <xsl:template match="namespace-node()" mode="internal:snapshot" as="namespace-node()" priority="3"> <xsl:variable name="name" select="local-name(.)"/> <xsl:sequence select="internal:graft-to-parent(., .., function($n){$n/namespace-node()[local-name(.) = $name]})"/> </xsl:template> <!-- make a copy C of a supplied node N, grafting it to a shallow copy of C's original parent, and returning the copy C --> <xsl:function name="internal:graft-to-parent" as="node()"> <xsl:param name="n" as="node()"/> <xsl:param name="original-parent" as="node()?"/> <xsl:param name="down-function" as="function(node()) as node()"/> <xsl:choose> <xsl:when test="exists($original-parent)"> <xsl:variable name="p" as="node()"> <xsl:copy select="$original-parent"> <xsl:copy-of select="@*"/> <xsl:copy-of select="$n"/> </xsl:copy> </xsl:variable> <xsl:variable name="copied-parent" select="internal:graft-to-parent( $p, $original-parent/.., function($n){$n/node()}))"/> <xsl:sequence select="$down-function($copied-parent)"/> </xsl:when> <xsl:otherwise> <xsl:sequence select="$n"/> </xsl:otherwise> </xsl:choose> </xsl:function>
The snapshot
function is available for use (and is primarily
intended for use) when a source document is processed using streaming. It can also
be
used when not streaming. The effect is to take a copy of the subtree rooted at the
current node, along with copies of the ancestors and their attributes, and to make
this
available as a normal tree, that can be processed without any of the restrictions
that
apply while streaming, for example only being able to process children once. The copy,
of course, does not include siblings of the context node or of its ancestors, so any
attempt to navigate to these siblings will result in an empty sequence being
returned.
For parentless nodes, the effect of snapshot($x)
is identical to the effect
of copy-of($x)
.
Using snapshot()
while streaming:
This example copies from the source document all employees who work in marketing and
are based in Dubai. It assumes that employees are grouped by location. Because there
are two accesses using the child axis (referencing department
and
salary
), it is not possible to do this without buffering each
employee in memory. The snapshot
function is used in preference
to the simpler copy-of
so that access to attributes of the
parent location
element remains possible.
<xsl:source-document streamable="yes" href="employees.xml"> <xsl:for-each select="snapshot(locations/location[@name='Dubai'] /employee)[department='Marketing']"> <employee> <location code="{../@code}"/> <salary value="{salary}"/> </employee> </xsl:for-each> </xsl:source-document>
This section contains rules that can be used to determine properties of constructs in the stylesheet — specifically, the posture and sweep of a construct — which enable the streamability of the stylesheet to be assessed.
These properties are used to determine the streamability of:
The xsl:source-document
instruction: see 18.1 The xsl:source-document Instruction
Stylesheet functions: see 19.8.5 Classifying Stylesheet Functions
The xsl:merge
instruction: see 15.4 Streamable Merging
In each case, the conditions for constructs to be guaranteed-streamable are defined in terms of these properties. The result of this analysis in turn (see 19.10 Streamability Guarantees) imposes rules on how the constructs are handled by processors that implement the streaming feature. The analysis has no effect on the behavior of processors that do not implement this feature.
The analysis is relevant to constructs such as streamable template rules and the
xsl:source-document
instruction that process a single streamed input
document. The xsl:merge
instruction, which processes multiple streamed
inputs, has its own rules.
The rules in this section operate on the expression tree (more properly, construct tree) that is typically output by the XSLT and XPath parser. For the most part, the rules depend only on identifying the syntactic constructs that are present.
The rules in this section generally consider each component in the stylesheet (and in the case of template rules, each template rule) in isolation. The exception is that where a component contains references to other components (such as global variables, functions, or named templates), then information from the signature of the referenced component is sometimes used. This is invariably information that cannot be changed if a component is overridden in a different package. The analysis thus requires as a pre-condition that function calls and calls on named templates have been resolved to the extent that the corresponding function/template signature is known.
The detailed way in which the construct tree is derived from the lexical form of the stylesheet is not described in this specification. There are many ways in which the tree can be optimized without affecting the result of the rules in this section: for example, a sequence constructor containing a single instruction can be replaced by that instruction, and a parenthesized expression can be replaced by its content.
[Definition: The term construct refers to the union of the following: a sequence constructor, an instruction, an attribute set, a value template, an expression, or a pattern.]
These constructs are classified into
construct kinds: in particular, instructions are classified according to the name of the XSLT instruction,
and expressions are classified according to the
most specific production in the XPath grammar that the expression satisfies. (This
means, for example, that 2+2
is classified as an AdditiveExpr
,
rather than say as a UnionExpr
; although it also satisfies the production
rule for UnionExpr
, AdditiveExpr
is more specific.)
[Definition: For every construct kind, there is a
set of zero or more operand roles.] For example, an
AdditiveExpr
has two operand roles, referred to as the left-hand operand
and the right-hand operand, while an IfExpr
has three, referred to as the
condition, the then-clause, and the else-clause. A function call with three arguments
has three operand roles, called the first, second, and third arguments. The names
of the
operand roles for each construct kind are not formally listed, but should be clear
from
the context.
[Definition: In an actual instance of a construct, there will
be a number of operands. Each operand is itself a construct; the construct tree can be defined as the transitive relation
between constructs and their operands.] Each operand is associated with exactly one of
the operand roles for the construct type. There may be operand roles where the operand
is optional (for example, the separator
attribute of the
xsl:value-of
instruction), and there may be operand roles that can
be occupied by multiple operands (for example, the xsl:when/@test
condition
in xsl:choose
, or the arguments of the concat
FO30
function).
Operand roles have a number of properties used in the analysis:
The required type of the operand. This is explicit in the case of function calls (the required type is defined in the function signature of the corresponding function). In other cases it is implicit in the detailed rules for the construct in question. In practice streamability analysis makes only modest use of the required type; the main case where it is relevant is for a function or template call, where knowing that the required type is atomic enables the inference that the operand usage for a supplied node is absorption.
[Definition: The operand usage. This gives information, in the case where the operand value contains nodes, about how those nodes are used. The operand usage takes one of the values absorption, inspection, transmission, or navigation. ]The meanings of these terms are explained in 19.3 Operand Roles. If the required type of the operand does not permit nodes to be supplied (for example because the required type is a function item or a map), then the operand usage is inspection, because the only run-time operation on a supplied node will be to inspect it, discover it is a node, and raise a type error.
In the particular case where the required type is atomic, and any supplied nodes are atomized, the operand usage will be absorption, because atomize is a special case of absorption.
[Definition: Whether or not the operand is higher-order. For this purpose an operand O of a construct C is higher-order if the semantics of C potentially require O to be evaluated more than once during a single evaluation of C.] More specifically, O is a higher-order operand of C if any of the following conditions is true:
The context item for evaluation of O is different from the context item for evaluation of C.
C is an instruction and O is a
pattern (as with the from
and
count
attributes of xsl:number
, and the
group-starting-with
and group-ending-with
attributes of xsl:for-each-group
).
C is an XPath for
, some
, or
every
expression and O is the expression in its
return
or satisfies
clause.
C is an inline function declaration and O is the expression in its body.
Note:
There is one known case where this definition makes
an operand higher-order even though it is only evaluated once: specifically, the sequence
constructor contained in the body of an xsl:copy
instruction that has a
select
attribute. See 19.8.4.12 Streamability of xsl:copy for further details.
[Definition: For some construct
kinds, one or more operand roles may be defined to form a choice operand
group. This concept is used where it is known that operands are mutually exclusive (for example the
then
and else
clauses in a conditional
expression).]
[Definition: The combined posture of a choice operand group is determined by the postures of the operands in the group (the operand postures), and is the first of the following that applies:
If any of the operand postures is roaming, then the combined posture is roaming.
If all of the operand postures are grounded, then the combined posture is grounded.
If one or more of the operand postures is climbing and the remainder (if any) are grounded, then the combined posture is climbing.
If one or more of the operand postures is striding and the remainder (if any) are grounded, then the combined posture is striding.
If one or more of the operand postures is crawling and each of the remainder (if any) is either striding or grounded, then the combined posture is crawling.
Otherwise (for example, if the group includes both an operand with climbing posture and one with crawling posture), the combined posture is roaming.
]
[Definition: The
type-determined usage of an operand is as
follows: if the required type (ignoring occurrence indicator) is
function(*)
or a subtype thereof, then inspection; if the required type (ignoring occurrence indicator) is an atomic or union type, then absorption; otherwise navigation.]
[Definition: The type-adjusted posture and sweep of a construct C, with respect to a type T, are the posture and sweep established by applying the general streamability rules to a construct D whose single operand is the construct C, where the operand usage of C in D is the type-determined usage based on the required type T.]
Note:
In effect, the type-adjusted posture and sweep are the posture and sweep of the
implicit expression formed to apply the function conversion rules
to the argument of a function or template call, or to the result of a function or
template, given knowledge of the required type. For example, an expression such as
discount
in the function call abs(discount)
, which would
otherwise be striding and consuming, becomes
grounded and consuming because of the
implicit atomization triggered by the function conversion rules.
The process of determining whether a construct is streamable reduces to determining properties of the constructs in the construct tree. The properties in question (which are described in greater detail in subsequent sections) are:
The static type of the construct. When the construct is evaluated, its value will always be an instance of this type. The value is a U-type; although type inferencing is capable of determining information about the cardinality as well as the item type, the streamability analysis makes no use of this.
The context item type: that is, the static type of the context item potentially used as input to the construct. When the construct is evaluated, the context item used to evaluate the construct (if it is used at all) will be an instance of this type.
[Definition: The posture of the expression. This captures information about the way in which the streamed input document is positioned on return from evaluating the construct. The posture takes one of the values climbing, striding, crawling, roaming, or grounded.] The meanings of these terms are explained in 19.4 Determining the Posture of a Construct.
[Definition: The context posture. This captures information about how the context item used as input to the construct is positioned relative to the streamed input. The context posture of a construct C is the posture of the expression whose value sets the focus for the evaluation of C.] Rules for determining the context posture of any construct are given in 19.5 Determining the Context Posture.
The sweep of the construct. The sweep of a construct gives information about whether and how the evaluation of the construct changes the current position in a streamed input document. The possible values are motionless, consuming, and free-ranging. These terms are explained in 19.6 The Sweep of a Construct.
The values of these properties for a top-level construct such as the body of a template rule determine whether the construct is streamable.
The values of these properties are not independent. For example, if the static type is atomic, then the posture will always be grounded; if the sweep is free-ranging, then the posture will always be roaming.
The posture and sweep of a
construct, as defined above, are calculated in relation to a
particular streamed input document. If there is more than one streamed input document,
then a construct that is motionless with respect to one streamed input might be
consuming with respect to another. In practice, though, the streamability analysis
is
only ever concerned with one particular streamed input at a time; constructs are
analyzed in relation to the innermost containing xsl:template
,
xsl:source-document
, xsl:accumulator
, or
xsl:merge-source
element, and this container implicitly defines the
streamed input document that is relevant. The streamed input document affecting a
construct is always the document that contains the context item for evaluation of
that
construct.
[Definition: The static type of a construct is such that all values produced by evaluating the construct will conform to that type. The static type of a construct is a U-type.]
[Definition: A U-type is a set of fundamental item types.]
[Definition: There are 28
fundamental item types: the 7 node kinds defined in [XDM 3.0] (element, attribute, etc.), the 19 primitive atomic
types defined in [XML Schema Part 2], plus the types
function(*)
and xs:untypedAtomic
. The fundamental
item types are disjoint, and every item is an instance of exactly one of
them.]
More specifically, the fundamental item types are:
document-node()
, element()
, attribute()
,
text()
, comment()
,
processing-instruction()
, namespace-node()
;
xs:boolean
, xs:double
, xs:decimal
,
xs:float
, xs:string
, xs:dateTime
,
xs:date
, xs:time
, xs:gYear
,
xs:gYearMonth
, xs:gMonth
,
xs:gMonthDay
, xs:gDay
, xs:anyURI
,
xs:QName
, xs:NOTATION
,
xs:base64Binary
, xs:hexBinary
,
xs:duration
function(*)
xs:untypedAtomic
A value V (in general, a sequence) is an instance of a U-type
U if every item in V is an instance of one of the fundamental item types in U.
For example, the sequence (23, "Paris")
is an instance of the U-type
U{xs:string, xs:decimal, xs:date}
because both items in the sequence
belong to item types in this U-type.
Note:
It is a consequence of this rule that the empty sequence, ()
, is an
instance of every U-type.
A U-type is represented in this specification using the notation
U{t1, t2, t3, ...} where t1, t2, t3, ...
are the names of
the fundamental item types making up the U-type. The item types are represented using
the syntax of the ItemTypeXP30
production in XPath, for example comment()
or xs:date
.
Note:
This means that the order of t1, t2, t3, ...
has no significance:
U{A, B} is the same U-type as U{B, A}.
The smallest U-type is denoted U{}. This is not an empty type; like every
other U-type, it has the empty sequence ()
as an instance. For
convenience, the universal U-type is represented as U{*}; the U-type
corresponding to the set of 7 node kinds is written U{N}, and the U-type
corresponding to all atomic values (that is, the 19 primitive atomic types plus
xs:untypedAtomic
) is written U{A}.
Because a U-type is a set, the operations of union, intersection, and difference are defined over U-types, and the result is always a U-type. If one U-type U is a subset of another U-type V, then U is said to be a subtype of V, and V is said to be a supertype of U.
In some cases the inference of a static type depends on the declared types of variables or functions. Since declared types use the SequenceType syntax, there is therefore a mapping defined from SequenceTypes to U-types. The mapping is as follows:
The SequenceType
empty-sequence()
maps to U{}
For every other SequenceType, the mapping depends only on the item type and ignores the occurrence indicator. The mapping from item types is as follows:
item()
maps to U{*}
AnyKindTest
(node()
) maps to
U{N}
DocumentTest
maps to U{document-node()}
ElementTest
and SchemaElementTest
map to
U{element()}
AttributeTest
and SchemaAttributeTest
map to
U{attribute()}
TextTest
maps to U{text()}
CommentTest
maps to U{comment()}
PITest
maps to U{processing-instruction()}
NamespaceNodeTest
maps to U{namespace-node()}
FunctionTest
, MapTest
,
and (if the XPath 3.1 Feature
is implemented) ArrayTest
map to U{function(*)}
The QName xs:error
maps to U{}
A QName Q representing an atomic type that is a fundamental item type maps to U{Q}
A QName Q representing an atomic type derived from a fundamental item type F maps to U{F}
A QName Q representing a pure union type maps to a U-type containing the fundamental item types present in the transitive membership of the union, or from which the transitive members of the union are derived.
Although all constructs have a static type, the streamability analysis only needs to know the static type of XPath expressions, so the rules here are largely confined to that case. For patterns, the static type is deemed to be U{xs:boolean}, reflecting the fact that a pattern is essentially a function that can be applied to items to deliver a true or false (matching or non-matching) result. For constructs other than expressions and patterns, the static type for the purpose of streamability analysis is taken as U{*}.
The rules given here are deliberately simple. Implementations may well be able to compute a more precise static type, but this will rarely be useful for streamability analysis. The item type for each kind of XPath expression is determined by the rules below. In the first column, numbers in square brackets are production numbers from the XPath 3.0 and XPath 3.1 specifications respectively. In the second column, the Proforma uses an informal notation used both to provide a reminder of the syntax of the construct in question, and to attach labels to its operand roles so that they can be referred to in the text of the third column.
Construct | Proforma | Static Type |
---|---|---|
Expr [6,6] | E,F |
the union of the static types of E and F |
ForExpr [8,8] | for $x in S return E |
the static type of E |
LetExpr [11,11] | let $x := S return E |
the static type of E |
QuantifiedExpr [14,14] | some|every $x in S satisfies C |
U{xs:boolean} |
IfExpr [15,15] | if (C) then T else E |
the union of the static types of T and E |
OrExpr [16,16] | E or F |
U{xs:boolean} |
AndExpr [17,17] | E and F |
U{xs:boolean} |
ComparisonExpr [18,18] | E = F, E eq F, E is F |
U{xs:boolean} |
StringConcatExpr [19,19] | E || F |
U{xs:string} |
RangeExpr [20,20] | E to F |
U{xs:decimal} |
AdditiveExpr [21,21] | E + F |
U{A}. But if the expression is a predicate (that is, if it appears between square brackets in a filter expression or axis step), then U{xs:decimal, xs:double, xs:float} |
MultiplicativeExpr [22,22] | E * F |
U{A}. But if the expression is a predicate (that is, if it appears between square brackets in a filter expression or axis step), then U{xs:decimal, xs:double, xs:float} |
UnionExpr [23,23] | E | F |
the union of the static types of E and F |
IntersectExceptExpr [24,24] | E intersect F |
the intersection of the static types of E and F |
E except F |
the static type of E | |
InstanceOfExpr [25,25] | E instance of T |
U{xs:boolean} |
TreatExpr [26,26] | E treat as T |
the U-type corresponding to the SequenceType T |
CastableExpr [27,27] | E castable as T |
U{xs:boolean} |
CastExpr [28,28] | E cast as T |
if T is an atomic or pure union type, the corresponding U-type. Otherwise, for example if T is a list type, U{A}. |
UnaryExpr [29,30] | -N |
U{xs:decimal, xs:double, xs:float} |
SimpleMapExpr [34,35] | E ! F |
the static type of F |
PathExpr [35,36] | / |
U{document-node()} |
/P |
the static type of P | |
//P |
the static type of P | |
RelativePathExpr [36,37] | P/Q, P//Q |
the static type of Q |
AxisStep [38,39] | E[P] |
the static type of E: see 19.1.1 Static Type of an Axis Step |
ForwardStep [39,40], ReverseStep [42,43] | Axis::NodeTest |
See 19.1.1 Static Type of an Axis Step |
PostfixExpr [48,49] | Filter Expression E[P] |
the static type of E |
Dynamic Function Call F(X, Y) |
U{*}, unless ancillary information is available about the function signature of F: see below. | |
Literal [53,57] | "pH" , 93.7 |
U{xs:string}, U{xs:decimal}, or U{xs:double}, depending on the form of the literal |
VarRef [55,59] | $V |
For a variable declared using xsl:variable or
xsl:param , and for parameters of inline function
expressions: the declared type of the variable, defaulting to
U{*}. For variables declared using for ,
let , some , and every expressions:
the static type of the expression to which the variable is bound.
|
ParenthesizedExpr [57,61] | (E) |
the type of E |
() |
U{} (a type whose only instance is the empty sequence) | |
ContextItemExpr [58,62] | . |
the context item type: see below |
FunctionCall [59,63] | F(X, Y) |
In general: the U-type corresponding to
the declared result type of function F. But:
|
NamedFunctionRef [63,67] | F#n |
U{function(*)} |
InlineFunctionExpr [64,68] | function(P) {E} |
U{function(*)} |
MapConstructor [–,69] | map{"A":E, "B":F} |
U{function(*)} |
Postfix Lookup [–,49] | E ? K |
If the type of E is a map type map(K, V) or an
array type array(V) , then the U-type corresponding to the item
type of V; otherwise U{*} |
(Unary) Lookup [–,53] | ? K |
If the context item type is a map type map(K, V) or an array
type array(V) , then the U-type corresponding to the item type
of V; otherwise U{*} |
ArrowExpr [–,29] | X => F(Y, Z) |
The static type of the equivalent static or dynamic function call
F(X, Y, Z) |
SquareArrayConstructor [–,74] | [X, Y, ...] |
U{function(*)} |
CurlyArrayConstructor [–,75] | array{X, Y, ...} |
U{function(*)} |
Where the static type of an expression is
U{function(*)}, it is useful to retain additional information:
specifically, the signature of the function. This may be regarded as information
ancillary to the U-type of the expression; it does not play any role in operations
such as testing whether one U-type is a subtype of another, or forming the union of
two U-types. This ancillary information is available for a
NamedFunctionRef
, for an InlineFunctionExpr
, for a
MapConstructor
, for a FunctionCall
whose static type is
U{function(*)}, and for a VarRef
if the variable is bound
to any of the forgoing, or if it has a declared type corresponding to
U{function(*)}.
Note:
The special case type inference used for an AdditiveExpr
or
MultiplicativeExpr
appearing as a predicate is possible because if
an arithmetic operation within a predicate produces any other result, for example
an xs:duration
or xs:dateTime
, this would cause a type
error (on the grounds that an xs:duration
or xs:dateTime
has no effective boolean value), and static type inference only needs to consider
the type of non-error results. The benefit of this special rule is that filter
expressions such as /descendant::section[$i + 1]
can be recognized as
returning a singleton, and therefore as being striding, even
if the type of $i
is unknown.
An AxisStep
consists of either a ForwardStep
or ReverseStep
followed by zero or more predicates. The predicates have no effect on the inferred
type of the
AxisStep
.
The static type of an abbreviated step is the static type of its expansion, for example
the
static type of @*
is the same as the static type of attribute::*
.
Both the constructs ForwardStep
or ReverseStep
, in their
unabbreviated form, are written as Axis::NodeTest
. The static type depends
on both the Axis
and the NodeTest
, and also on the
context item type, determined as described in 19.2 Determining the Context Item Type.
If the context item type has an empty intersection with U{N}
(that is, if the context item type cannot be a node), then evaluation of the AxisStep
will always fail; it is permissible to raise a type error statically in this case,
but for the
sake of the analysis, the static type of the AxisStep
can be taken as U{}
.
In other cases, let CIT be the intersection of the context item type
with U{N}
.
Let K(A, CIT) be the set of reachable node kinds given an axis A (a U-type) as defined by the following table:
Axis | Reachable Node Kinds |
---|---|
self | CIT |
attribute | if CIT includes U{element()} then U{attribute()} else U{} |
namespace | if CIT includes U{element()} then U{namespace-node()} else U{} |
child, descendant | if CIT includes U{element()} or U{document-node()} then
U{element(), text(), comment(), processing-instruction()} else U{} |
following-sibling, preceding-sibling, following, preceding | if CIT is U{document-node()} then U{} else
U{element(), text(), comment(), processing-instruction()} |
parent, ancestor | if CIT is U{document-node()} then U{} else
U{element(), document-node()}
|
ancestor-or-self | the union of K(ancestor, CIT) and CIT |
descendant-or-self | the union of K(descendant, CIT) and CIT |
Let T(NT)
be the set of node kinds that are capable of satisfying a NodeTest
NT,
defined by the following table:
NodeTest | Possible Node Kinds |
---|---|
AnyKindTest (that is, node() )
|
U{N} (that is, any node) |
Any other KindTest |
The corresponding U-type (for example, U{text()}
for the KindTest text() )
|
NameTest | The U-type corresponding to the principal node kind of the specified axis |
The static type of an AxisStep
with axis A and node test NT
,
given a context item type CIT, is then defined to be the
intersection of K(A, CIT)
with T(NT)
.
current
The rules in this section define the static type of a call to the current
function.
If the call is within a pattern, the static type of the function call is the match type of the pattern.
Note:
There is no circularity in this definition: a call to current
in a pattern can only appear within a predicate, and
the match type of a pattern never depends on anything appearing in a predicate.
Otherwise (the function call is within an XPath expression), the static type of the function call is the context item type that applies to the outermost containing XPath expression, determined by the rules in 19.2 Determining the Context Item Type.
Note:
The streamability analysis in this chapter is not schema-aware. There are cases where use of schema type information might enable a processor to determine that a construct is streamable when it would be unable to make this determination otherwise. Two examples:
A processor might decide that a construct such as price +
salesTax
is streamable if both the child elements have a simple
type such as xs:decimal
, or if the order in which they appear
in the input document is known.
A processor might decide that a step using the descendant axis, such as
.//title
, has striding rather than
crawling
posture if it can establish that two title
elements will never be nested
(that is, a title
cannot contain another title
).
This would allow the instruction <xsl:apply-templates
select=".//title"/>
to be used in a streaming template rule.
Although such constructs are not guaranteed streamable according to this specification, there is nothing to prevent a processor providing a streamed implementation if it is able to do so.
[Definition: For every expression, it is possible to establish by static analysis, information about the item type of the context item for evaluation of that expression. This is called the context item type of the expression.]
The context item type of an expression is a U-type.
The semantics of every construct, defined in
this specification or in the XPath specification, describe how the focus for evaluating each operand of the construct
is determined. In most cases the focus is the same as that of the parent construct.
In some cases the focus is determined by evaluating some other expression, for
example in the expressions A/B
, A!B
, or A[B]
,
the focus for evaluating B is A. More generally:
[Definition: A focus-changing construct is a construct that has one or more operands that are evaluated with a different focus from the parent construct.]
Note:
Examples of focus-changing constructs include the instructions
xsl:for-each
, xsl:iterate
, and
xsl:for-each-group
; path expressions, filter
expressions, and simple mapping expressions; and all patterns.
[Definition: Within a focus-changing construct there is in many cases one operand whose value determines the focus for evaluating other operands; this is referred to as the controlling operand.]
Note:
For example, the controlling operand of an xsl:for-each
,
xsl:iterate
, or xsl:for-each-group
instruction is the expression in its select
attribute; the
controlling operand of a filter expression E[P]
is
E
, and the controlling operand of a simple mapping
expression A!B
is A
.
[Definition: Within a focus-changing construct there are one or more operands that are evaluated with a focus determined by the controlling operand
(or in some cases such as
xsl:on-completion
, with an absent
focus); these are referred to as
controlled operands.]
Note:
For example, the main controlled operand of an
xsl:for-each
, xsl:iterate
, or
xsl:for-each-group
instruction is the contained sequence
constructor; the controlled operand of a filter expression E[P]
is P
, and the controlled operand of a simple mapping expression
A!B
is B
.
[Definition: The
focus-setting container of a construct C is the
innermost focus-changing construct
F (if one exists) such that C is directly or
indirectly contained in a controlled operand of
F. If there is no such construct
F, then the focus-setting container is the containing
declaration, for example an
xsl:function
or xsl:template
element.]
Note:
For example, if an instruction appears as a child of
xsl:for-each
, then its focus-setting container is the
xsl:for-each
instruction; if an expression appears
within the predicate of a filter expression, its focus-setting container is
the filter expression.
The context item type of a construct C is the first of the following that applies:
If the focus-setting container of C is an
xsl:function
element, an inline function declaration, or an
xsl:on-completion
element, then the context item type is
U{}
.
Note:
This is essentially an error case; expressions that depend on the focus should not normally appear within a construct that sets the focus to absent.
If the focus-setting container of C is an
xsl:source-document
instruction, then the context item type is U{document-node()}
.
If the focus-setting container of C is a template rule, then the context item type is the match type of the match pattern of the template rule, defined below.
If the focus-setting container of C is a
PredicatePattern
, then the context item type is U{*}
.
If the focus-setting container is a global variable
declaration, the context item type is determined by the type
attribute
of the xsl:global-context-item
declaration, defaulting to U{*}
,
or U{}
if the xsl:global-context-item
declaration specifies
use="absent"
.
If the focus-setting container is any other declaration, for example xsl:key
or
xsl:accumulator
, the
context item type is U{*}
.
Otherwise, the context item type is the static type (see 19.1 Determining the Static Type of a Construct) of the controlling operand of the focus-setting container of C.
[Definition: The
match type of a pattern is the most specific
U-type that is known to match all items that the pattern can
match.] The match type of a pattern is the inferred static type of the pattern’s equivalent expression, determined
according to the rules in 19.1 Determining the Static Type of a Construct. For example, the
match type of the pattern para[1]
is U{element()}
, while
that of the pattern @code[.='x']
is U{attribute()}
An operand role gives information about the operands of a particular kind of construct. The two important properties of an operand role are the required type and the operand usage.
The usage of an operand role is relevant only when the value of an operand supplied in that role is a node, or a sequence that contains nodes. It is one of the following:
[Definition: An operand usage of
absorption indicates that the construct reads the subtree(s)
rooted at a supplied node(s).] Examples are constructs that atomize
their operands, or that obtain the string
value of a supplied node, or that copy the supplied node to a new tree. Another
example is the deep-equal
FO30 function, which compares the
subtrees rooted at the nodes supplied in its first two arguments.
[Definition: An operand usage of
inspection indicates that the construct accesses properties
of a supplied node that are available without reading its subtree.]
Examples are functions such as name
FO30 and
base-uri
FO30, and the instance of
expression
which tests the type of a node (or other item), or functions such as
count
FO30, exists
FO30, and
boolean
FO30 which are only interested in the existence of
the node, and not in its properties.
[Definition: An operand usage of transmission indicates that the construct will (potentially) return a supplied node as part of its result to the calling construct (that is, to its parent in the construct tree).] It also indicates that document order is preserved: if the input is in document order, then the result must be in document order. An example is a filter expression, where nodes in the base expression (the expression being filtered) will typically appear in the result of the filter expression, in their original order.
[Definition: An operand usage of
navigation indicates that the construct may navigate freely
from the supplied node to other nodes in the same tree, in a way that is not
constrained by the streamability rules.] This covers several cases:
cases where it is known that the construct performs impermissible navigation
(for example, the xsl:number
instruction) or reordering (the
reverse
FO30 function), or that require look-ahead (the
innermost
FO30 function) and also cases where the analysis
is unable to determine what use is made of the node, for example because it is
passed as an argument to a user-defined function, or retained in a
variable.
The concept of operand usage is not used for all constructs (for example, it is not used in the analysis of path expressions). Where it is used, the assignment of operand usages to each operand role of a construct is defined in 19.8 Classifying Constructs.
Consider the following construct:
<xsl:source-document streamable="yes" href="emps.xml"> <xsl:for-each select="*/emp"> <xsl:value-of select="."/> </xsl:for-each> </xsl:source-document>
To assess the streamability, we follow the following logic:
The top-level construct is a sequence constructor. It is evaluated with a document node as the context item, and with a striding posture.
The sequence constructor has one child instruction, which has an operand usage of transmission.
The xsl:for-each
instruction evaluates its
select
expression, with the context item and posture unchanged.
The step child::*
is evaluated with this context item and
posture. The posture transition rules permit this; we now have a sequence
of child elements, and still a striding posture.
The same applies to the next step, child::emp
The content of the xsl:for-each
instruction is a
sequence constructor which itself has a single
operand, the xsl:value-of
instruction.
The xsl:value-of
instruction is evaluated once for each
emp
child, with that child as context item and in a
striding posture. This instruction uses the
general streamability rules. The operand usage of the select
expression is
absorption. This means that the result of the
xsl:value-of
instruction is grounded and consuming.
The result of the trivial sequence constructor contained in the
xsl:for-each
instruction is therefore grounded and consuming
The result of the xsl:for-each
instruction (see 19.8.4.18 Streamability of xsl:for-each) is therefore grounded and consuming
The result of the trivial sequence constructor contained in the
xsl:source-document
instruction is therefore grounded and consuming
The xsl:source-document
instruction is therefore guaranteed-streamable.
Now consider a slightly different construct:
<xsl:source-document streamable="yes" href="emps.xml"> <xsl:for-each select="*/emp"> <xsl:sequence select="."/> </xsl:for-each> </xsl:source-document>
To assess the streamability, we follow the following logic:
The top-level construct is a sequence constructor. It is evaluated with a document node as the context item, and with a striding posture.
The sequence constructor has one child instruction, which has an operand usage of transmission.
The xsl:for-each
instruction evaluates its
select
expression, with the context item and posture unchanged.
The step child::*
is evaluated with this context item and
posture. The posture transition rules permit this; we now have a sequence
of child elements, and still a striding posture.
The same applies to the next step, child::emp
The content of the xsl:for-each
instruction is a
sequence constructor which itself has a single
operand, the xsl:sequence
instruction.
The xsl:sequence
instruction is evaluated once for each
emp
child, with that child as context item and in a
striding posture. This instruction uses the
general streamability rules. The operand usage of the select
expression is
transmission. This means that the result of the
xsl:sequence
instruction is striding and motionless.
The result of the trivial sequence constructor contained in the
xsl:for-each
instruction is therefore also striding and motionless.
The result of the xsl:for-each
instruction (see 19.8.4.18 Streamability of xsl:for-each) is therefore striding and consuming (the wider of the sweeps of the
select
expression and the sequence
constructor).
The result of the trivial sequence constructor contained in the
xsl:source-document
instruction is therefore striding and consuming.
Since the result is not grounded, the xsl:source-document
instruction is therefore not guaranteed-streamable.
Expressed informally, the result of a declared-streamable
xsl:source-document
instruction
(or of a declared-streamable template rule)
must not contain streamed nodes. The reason
for this is that once streamed nodes are returned to constructs that are not
declared streamable and therefore have no streamability constraints, there is
no way to analyze what happens to them, and thus to guarantee
streamability.
Consider the expression .//chapter
.
When this appears as an argument to the function count
FO30
or exists
FO30, it can be streamed (it is a consuming expression, meaning that the subtree rooted at the
context item needs to be read in order to evaluate the expression). A possible
strategy for performing a streamed evaluation is to read all descendants of the
context item in document order, checking each one to see whether its name is
chapter
. The sweep of the expression will
be consuming, and its posture will be
crawling.
The operand usage (the usage of the argument to
count
FO30 or exists
FO30) is defined as
inspection. The general streamability rules show that when the posture of an
operand is crawling and the operand usage is inspection, the resulting
expression is grounded
and consuming. This means that (in the absence of other
consuming expressions) the containing template or function will generally be
streamable.
In the expression tail(.//chapter)
, the
operand usage is classified as transmission, meaning that the nodes are simply passed up the
tree to the next containing expression. In general, when a crawling expression is passed as an argument and the operand role
is transmission, the containing expression will also be
crawling. However, there is an exception where the
expression is known to deliver a singleton (for example,
head(.//chapter)
). In this case the returned sequence cannot
contain any nested nodes, so it is crawling.
When the same expression appears as an argument to an atomizing function
string-join
FO30, the processor knows that it will need to
access the subtree of each selected section
element in order to
compute the result of the function (the argument to
string-join
FO30 is classified as having operand usage
absorption). The processor does not know whether these
subtrees will be nested (one
section
might contain another). In most cases they will not be nested, because atomizing a
sequence that contains nested nodes is not generally a useful thing to do.
The streamability analysis therefore makes an optimistic assumption, by
treating atomization of a crawling expression as a
streamable operation. In the worst case, where it turns out that the
selected nodes are indeed nested, the processor must handle this, typically
by buffering the content of inner nodes until the end tag of the outer nodes
is reached.
This treatment of nodes in a crawling expression applies to all cases in which the content of
the nodes is handled in a way defined entirely by the rules of this
specification: for example, operations such as atomization, obtaining the
string value of nodes, deep copy of nodes, and the
deep-equal
FO30 function. It does not extend to cases
where the processing applied to the nodes is user-defined: for example,
operations such as xsl:apply-templates
,
xsl:for-each
, or xsl:for-each-group
. In
these cases, the nodes selected for processing must not be nested (a crawling posture is not permitted in these contexts).
When a crawling expression appears as an argument to a call on a user-defined function, the effect depends on the streamability category of the function, as described in 19.8.5 Classifying Stylesheet Functions.
The posture of a construct indicates the relationship of the nodes selected by the construct to a streamed input document. The value is one of the following:
[Definition: Grounded: indicates that
the value returned by the construct does not contain nodes from the streamed
input document]. Atomic values and function items are always
grounded; nodes are grounded if it is known that they are in a non-streamed
document. For example the expressions doc('x')
and
copy-of(.)
both return grounded nodes.
[Definition: Climbing: indicates that
streamed nodes returned by the construct are reached by navigating the parent,
ancestor[-or-self], attribute, and/or namespace axes from the node at the
current streaming position.] When the context posture is climbing, use of certain
axes such as parent
and ancestor
is permitted, but
use of other axes such as child
or descendant
violates the streamability rules.
[Definition: Crawling: typically
indicates that streamed nodes returned by a construct are reached by navigating the
descendant[-or-self] axis.] Nodes reached in this way are potentially nested (one might be an ancestor
of another), so further downward navigation is not permitted.
Expressions that can be statically determined to
return a singleton node (for example head(.//title)
) generate a
result with no such nesting, so
they are striding rather than crawling.
[Definition: Striding: indicates that
the result of a construct contains a sequence of streamed nodes, in document order,
that
are peers in the sense that none of them is an ancestor or descendant of any
other.] This is typically achieved by using one or more steps
involving the child or attribute
axes only. Use of the outermost
FO30 function can also result
in a striding posture, as can functions such as
head
FO30 or zero-or-one
FO30 that
ensure the result will be a singleton node.
[Definition: Roaming: indicates that
the nodes returned by an expression could be anywhere in the tree, which
inevitably means that the construct cannot be evaluated using
streaming.] For example, the posture of an axis
step using the following
or preceding
axis will
typically be roaming, which leads the analysis to conclude
that the construct is not streamable.
Note:
One way to think about the posture values is as labels for states in a finite
state automaton, where the alphabet of symbols accepted by the automaton is the
set of 13 XPath axes, and the sentence being parsed is a path expression
containing a sequence of axis steps. For example, use of the
descendant
axis when the current state is striding
moves the new state to crawling, and use of the parent
axis then takes it to climbing.
The posture of a construct is determined in one of several ways:
For axis steps, the posture of the expression is determined by the context posture and the choice of axis. For example, an axis step using the ancestor axis always has a posture of climbing, while an axis step using the child axis, if the context posture is striding, will itself have a posture of striding. The rules for the posture transitions produced by axis steps are given in 19.8.8.9 Streamability of Axis Steps.
For many other constructs, the posture is determined by the general streamability rules. These determine the result posture in terms of the operands of the construct and the way in which each operand is used. For example, a construct that accepts a streamed node as the value of an operand, and atomizes that node, will generally have a posture of grounded.
Other constructs have their own special rules, which are all listed in this
chapter. For example, a call on the root
FO30 function
behaves analogously to an axis step, and is described in 19.8.9.18 Streamability of the root Function. Special rules are needed for:
Constructs that evaluate an operand more than once,
such as an XPath for
expression;
Constructs that have alternatives among their operands, such as an XPath
if
expression;
Constructs that navigate relative to the context item, such as axis steps;
Constructs with implicit inputs, such as the context item expression
.
(dot);
Constructs that change the focus, such as a filter expression;
Constructs that invoke functions or templates.
The characterization of an expression as striding, crawling, climbing, or
roaming applies only to the streamed nodes in the the result of the expression. The
result of the expression
may also contain non-streamed (grounded) nodes or atomic values. For example
if /x/y
is a striding expression, then (/x/y | $doc//x)
is also striding, given
that $doc
contains non-streamed nodes. The assertion that the nodes in the result of a striding
expression are in document order and are peers thus applies only to the subset of
the nodes that are streamed.
Note:
A consequence of this is that when striding expressions are used in a context that
requires sorting into
document order, for example (/x/y | $doc//x) / @price
, the fact that the expression is striding
does not eliminate the need for the sequence to be re-ordered. However, there will
never be a need for the relative
order of the streamed nodes in the value to change.
Since the data model leaves the relative order of nodes in different trees implementation-defined, and since streamed and unstreamed nodes will necessarily be in different trees, a useful implementation strategy might be to arrange that streamed nodes always precede unstreamed nodes in document order (or vice versa). An operation that needs to process the result of a striding expression in document order can then first deliver all the streamed nodes (by consuming the input stream) in the order they arrive, and then deliver the unstreamed nodes, suitably sorted.
In the same way as the type of the context item can be determined for any construct C by reference to the type of the construct that establishes the context for the evaluation of C, so the posture of the context item C can be determined by reference to the posture of the construct that establishes the context.
The context posture of a construct C is the first of the following that applies:
If the focus-setting container of C is an
xsl:function
declaration, an inline function declaration,
or an xsl:on-completion
element, then the context posture is
roaming.
Note:
This is essentially an error case; expressions that depend on the context item should not normally appear within these constructs.
If the focus-setting container of C is an
xsl:source-document
instruction, then the context posture is
striding if the
instruction is declared-streamable, or grounded otherwise.
If the focus-setting container of C is a
template rule whose mode is declared with
streamable="yes"
, then the context posture is striding.
If the focus-setting container of C is a pattern, then the context posture is striding.
If the focus-setting container of C is an
xsl:attribute-set
declaration with the attribute
streamable="yes"
, then the context posture is striding.
If the focus-setting container is any other declaration, for example a global variable declaration, a
named template, or a template rule or attribute set that
does not specify streamable="yes"
, then the context posture is
roaming.
Otherwise, the context posture is the posture of the controlling operand of the focus-setting container of C.
[Definition: Every construct has a sweep, which is a measure of the extent to which the current position in the input stream moves during the evaluation of the expression. The sweep is one of: motionless, consuming, or free-ranging .] This list of values is ordered: a free-ranging expression has wider sweep than a consuming expression, which has wider sweep than a motionless expression.
[Definition: A motionless construct is any construct deemed motionless by the rules in this section (19 Streamability).] Informally, a motionless construct is one that can be evaluated without changing the current position in the input stream.
Note:
The context item expression .
is classified as motionless; however a
construct that uses .
as an operand (for example,
string(.)
) might be consuming. The
streamability rules effectively consider expressions such as .
within
the context of the containing construct.
[Definition: A consuming construct is any construct deemed consuming by the rules in this section (19 Streamability).] Informally, a consuming construct is one whose evaluation requires repositioning of the input stream from the start of the current node to the end of the current node.
[Definition: A free-ranging construct is any construct deemed free-ranging by the rules in this section (19 Streamability).] Informally, a free-ranging construct is one whose evaluation may require access to information that is not available from the subtree rooted at the current node, together with information about ancestors of the current node and their attributes.
The table below shows some examples of expressions having different combinations of posture and sweep.
Motionless | Consuming | Free-Ranging | |
---|---|---|---|
Grounded | name() |
string(title) |
See Note |
Climbing | parent::* |
child::x/ancestor::y |
See Note |
Striding | @status |
child::* |
See Note |
Crawling | The subexpression . in //a/. |
descendant::* |
//x[child::y] |
Roaming | See Note | See Note | preceding::* |
Note:
In all cases where either the posture is roaming, or the sweep is free-ranging, or both, the effect is to make an expression non-streamable. For convenience, therefore, evaluation of the streamability rules in most cases returns the values roaming and free-ranging only in combination with each other. In cases where the rules return a posture of roaming combined with some other sweep, or a sweep of free-ranging with some other posture, the final result of the analysis is always the same as if the expression were both roaming and free-ranging.
For an example of a case where an expression is roaming but
not free-ranging, consider the right-hand operand of the
relative path expression (preceding::x/.)
. The rules for the
streamability of a context item expression (see 19.8.8.13 Streamability of the Context Item Expression) give ".
" in this
context a roaming posture, combined with motionless sweep. But the relative path expression as a whole is
roaming and free-ranging (see 19.8.8.8 Streamability of Path Expressions), so the apparent inconsistency is
transient.
A construct is grounded if the items it delivers do not include nodes from a streamed document; it is consuming if evaluation of the construct reads nodes from a streamed input in a way that requires advancing the current position in the input.
Grounded consuming constructs play an important role in streaming, and this section discusses some of their characteristics.
Examples of grounded consuming constructs (assuming the context item is a streamed node) include:
sum(.//transaction/@value)
copy-of(./account/history/event)
distinct-values(./account/@account-nr)
<xsl:for-each select="transaction"><t><xsl:value-of select="@value"/></t></xsl:for-each>
XSLT 3.0 provides the two functions copy-of
and snapshot
with the explicit purpose of creating a sequence of grounded nodes, that can be processed
one-by-one without the usual restrictions that apply to streamed processing, such
as the
rule permitting at most one downward selection. The processing style that exploits
these
functions is often called “windowed streaming”.
In general the result of a grounded consuming construct is a sequence. Depending on how this sequence is used, it may or may not be necessary for the processor to allocate sufficient memory to hold the entire sequence. The streamability rules in this specification place few constraints on how a grounded sequence is used. This is deliberate, because it gives users control: by creating a grounded sequence (for example, by use of the copy-of function) stylesheet authors create the possibility to process data in arbitrary ways (for example, by sorting the sequence), and accept the possibility that this may consume memory.
Pipelined evaluation of a sequence is analogous to streamed processing of a source
document.
Pipelined evaluation occurs when the items in a sequence can be processed one-by-one,
without
materializing the entire sequence in memory. Pipelining is a common optimization technique
in
all functional programming languages. Operations for which pipelined evaluation is
commonly
performed include filtering ($transactions[@value gt 1000]
), mapping
($transactions!(@value - @processing-fee)
), and aggregation
(sum($transactions)
). Operations that cannot be pipelined (because,
for example, the first item in the result sequence cannot be computed without knowing
the last item in the input sequence) include those that change the order of items
(reverse()
, sort()
). Other operations such as distinct-values()
allow the input to be processed one item at a time, but require memory that potentially
increases as the sequence length increases. Saving a grounded sequence in a variable
is
also likely in many cases to require allocation of memory to hold the entire sequence.
When the input to an operation is a grounded consuming sequence (more accurately, a sequence resulting from the evaluation of a grounded consuming construct), this specification does not attempt to dictate whether the operation is pipelined or not. The goal of interoperable streaming in finite memory can therefore only be achieved if stylesheet authors take care to avoid constructing grounded sequences that occupy large amounts of memory. In practice, however, users can expect that many grounded consuming constructs will be pipelined where the semantics permit this.
Note:
Some processors may recognize an opportunity for pipelining only if the expression
is written in a particular way. For example the constructs copy-of(/a/b/c)
and
/a/b/c/copy-of(.)
are to all intents and purposes equivalent, but some processors
might recognize the second form more easily as suitable for pipelining.
(There is one minor difference between these expressions: the order of nodes in copy-of(/a/b/c)
is required to reflect the document order of the nodes in /a/b/c
, while the result
of /a/b/c/copy-of(.)
can be in any order, in consequence of the rule that document order
for nodes in different trees is implementation-dependent.)
The use of the last
FO30 function requires particular care because of
its effect on pipelining. The streamability rules prevent the use of last()
in
conjunction with an expression that returns streamed nodes (because it would require
look-ahead
in the stream), but there is no similar constraint for grounded sequences. So for
example it
is not permitted (in a context that requires streaming) to write
<xsl:for-each select="transaction"> <xsl:value-of select="position(), ' of ', last()"/> </xsl:for-each>
but it is quite permissible to write
<xsl:for-each select="transaction/copy-of()"> <xsl:value-of select="position(), ' of ', last()"/> </xsl:for-each>
because the call on copy-of
makes the sequence grounded. This construct
cannot be pipelined because computing the first item in the result sequence depends
on knowing
the length of the input sequence; in consequence, a processor might be obliged to
buffer all
the transactions (or their copies) in memory.
In this simple example the impact of the call on last
FO30 is easily detected
both by the human reader and by the XSLT processor, but there are other cases where
the effect
is less obvious. For example if the stylesheet executes the instruction
<xsl:apply-templates select="transaction/copy-of(.)"/>
then the presence of a call on last
FO30 in one of the template rules
that gets invoked might not be easily spotted; yet the effect is exactly the same
in preventing the result being computed by processing input items strictly one at
a time. Avoiding such effects is entirely the responsibility of the stylesheet author.
By contrast, there is no intrinsic reason why use of the position
FO30 should
prevent pipelined processing: all it requires is for the processor to count how many
items have been
processed so far. Processors may also be able to handle the construct position() = last()
without storing the entire sequence in memory; rather than actually evaluating the
numeric values of
position()
and last()
, this can be done by testing whether the context item
is the last item in the sequence, which only requires a one-item lookahead.
This section defines the properties of every kind of construct that may appear in a stylesheet. It identifies the operand roles and their usage, and it gives the rules that define the posture and sweep of the construct. In cases where the general streamability rules apply, there is still an entry for the construct in order to define its operands and their usages, since this information is needed by the general rules.
The following sections describe this categorization for each kind of construct:
Sequence constructors: see 19.8.3 Classifying Sequence Constructors
Instructions: see 19.8.4 Classifying Instructions
Stylesheet functions: see 19.8.5 Classifying Stylesheet Functions
Attribute sets: see 19.8.6 Classifying Attribute Sets
Value templates: see 19.8.7 Classifying Value Templates
Expressions: see 19.8.8 Classifying Expressions
Patterns: see 19.8.10 Classifying Patterns
Calls to built-in functions: see 19.8.9 Classifying Calls to Built-In Functions
[Definition: Many constructs share the same streamability rules. These rules, referred to as the general streamability rules, are defined here.]
Examples of constructs that use these rules are: an arithmetic expression, an
attribute value template, a sequence constructor, the xsl:value-of
instruction,
and a call to the doc
FO30 function.
The rules determine both the posture and sweep of a construct. To determine the posture and sweep of a construct C, assuming these general rules are applicable to that kind of construct:
For each operand of C:
Establish:
The static type T of the operand (see 19.1 Determining the Static Type of a Construct).
Note:
The static type is a U-type. For example,
the static type of the expression (@*, *)
is
U{element(), attribute()}.
The sweep S and posture P of the operand (by applying the rules in this section 19.8 Classifying Constructs to that operand, recursively).
The operand usage U corresponding to the role of the operand within C (from the information in this section 19.8 Classifying Constructs).
Compute the adjusted sweep S′ of the operand by taking the first of the following that applies:
If S is free-ranging or P is roaming, then S′ is free-ranging. (In this case the posture and sweep of C are roaming and free-ranging, regardless of any other operands.)
If P is grounded, then S′ is S.
Otherwise (P is not grounded, which implies that the operand is capable of returning streamed nodes), compute S′ as follows:
Compute the adjusted usage U′ as follows:
If U is absorption and the intersection of T with U{element(), document-node()} is U{} (that is, if T is a type that does not allow nodes with children), then U′ is inspection.
Note:
This is because the entire subtree of nodes such as text nodes is available without reading further data from the input stream.
Otherwise, U′ is U.
Compute the adjusted sweep S′ from the table below:
Posture (P) | Adjusted Usage (U') | |||
---|---|---|---|---|
Absorption | Inspection | Transmission | Navigation | |
Climbing | Free-ranging | S | S | Free-ranging |
Striding | Consuming | S | S | Free-ranging |
Crawling | Consuming | S | S | Free-ranging |
[Definition: An operand is potentially consuming if at least one of the following conditions applies:
The operand usage is transmission and the operand is not grounded.
]
Having computed the adjusted sweep S′(o) of each operand o, the posture and sweep of C are the first of the following that applies:
If C has no operands, then grounded and motionless.
If any operand o has an adjusted sweep S′(o) of free-ranging, then roaming and free-ranging.
If more than one operand is potentially consuming, then:
If all these operands form part of a choice operand group, then the posture of C is the combined posture of the operands in this group, and the sweep of C is the widest sweep of the operands in this group
If all these operands have S′ = motionless, (which necessarily means they have U′ = U = transmission) and if they all have the same posture P0, then motionless with posture P0.
Note:
For example, the expression (@a, @b)
is
motionless and striding.
Otherwise, roaming and free-ranging.
If exactly one operand o is potentially consuming, then:
If o is a higher-order operand of C, then roaming and free-ranging.
If the operand usage of o is absorption or inspection, then grounded and consuming.
If the posture of o is crawling and C is a function call of a built-in function whose signature indicates a return type with a maximum cardinality of one then striding and the adjusted sweep of o.
Note:
Although this rule is written in
general terms, the only functions that it applies to (at the
time of publication) are head
FO30,
exactly-one
FO30, and
zero-or-one
FO30. This rule only
applies if the argument usage is transmission (other cases
having been handled by earlier rules); of the built-in
functions, the three functions listed are the only ones
having an argument with usage transmission and a return type
with maximum cardinality one.
Otherwise (the operand usage of o is transmission), the posture and adjusted sweep of o.
Otherwise (all operands are motionless) grounded and motionless.
Note:
The rules ensure that if more than one operand is consuming, that is, if more than one operand reads the subtree of the context node in a way that would cause the current position of the input stream to change, then the construct is not streamable.
The rules also prevent multiple streamed nodes being returned in the result of
an expression if they are delivered by
different operands. For example, the expression count((..,
*))
is not guaranteed streamable. This is to make static analysis
possible: the posture needs to be statically determined to ensure that
streaming does not fail at execution time. It is permitted, however, for
streamed nodes to be mixed in a sequence with non-streamed nodes or with atomic
values; in this case the posture of the result will be that of the streamed
nodes. It is also permitted to have multiple
operands delivering streamed nodes in different branches of a conditional,
provided the sweep and posture are compatible: for example if (X) then
@name else name
is guaranteed streamable.
Expressions that have more than one operand
with usage transmission, for example (A, B)
,
or (A | B)
, or insert-before(A, n, B)
, generally allow only one of these operands to select
streamed nodes. The result of the expression will contain
a mixture of streamed and grounded nodes, but its posture and sweep will be
that of the streamed operand. The nodes in the result will not necessarily be in document
order,
but the subset of the nodes that are streamed will always be in document order.
This section provides some examples of how the general streamability rules operate. In each example, the emphasis is on the outermost construct shown; explanations for how the sweep and posture of its operands are derived are not given, though in many cases they are explained in earlier examples.
The examples assume that the context item type for evaluation of the expression shown is an element node, and that its posture is striding.
2 + 2
is grounded and motionless, because both the operands are
grounded and motionless.
price * 2
is grounded and consuming, because one of the
operands is consuming and the relevant operand usage is absorption.
price - discount
is roaming and free-ranging, because both the
operands are consuming (and they are not members of a parallel operand
group).
price * @discount
is grounded and consuming. The left-hand operand is consuming and
the corresponding operand usage is absorption, while the right-hand operand is motionless, again with an
operand usage of absorption, and its item type is attribute()
which changes the effective usage to inspection.
a/b/c
is striding and consuming. This is determined not by the
general streamability rules, but by the rules for path expressions in
19.8.8.8 Streamability of Path Expressions.
a//c
is crawling and consuming. This is similarly determined by
the rules for path expressions in 19.8.8.8 Streamability of Path Expressions.
count(a/b/c)
is grounded and consuming, because the operand
(the argument to the count function) is striding and consuming (see earlier
example) and the operand usage is inspection.
sum(a/b/c)
is grounded and consuming, because the operand (the
argument to the sum
function) is striding and consuming (see earlier example) and the operand
usage is absorption.
count(descendant::c)
is grounded and
consuming, because the operand (the argument to the count
function) is crawling and consuming (see earlier example) and the operand
usage is inspection.
tail(descendant::c)
is crawling and
consuming. The operand is crawling, the operand usage is transmission, so
the posture and sweep of the result are the same as the posture and sweep of
the consuming operand.
unordered(a|b)
is crawling and
consuming. The operand (the argument to the unordered
function)
is crawling (see 19.8.8.4 Streamability of union, intersect, and
except Expressions), and
the operand usage is transmission, so the posture and sweep of the result
are the same as the posture and sweep of the consuming operand.
zero-or-one(descendant::c)
is
striding and consuming. Although the operand is crawling, the operand usage
is transmission and the cardinality of the expression is zero or one, so the
posture of the result is striding. The same analysis applies to
exactly-one(descendant::c)
and to
head(descendant::c)
.
sum(descendant::c)
is grounded and
consuming, because the operand (the argument to the sum
function) is crawling and consuming (see earlier example) and the operand
usage is absorption. In theory (although it is unlikely in practice) the
selected c
elements might be
nested one inside another. The processor is expected to handle
this situation, which may require some buffering. For example, given the
untyped source document
<a><c><c>1</c><c>2</c><c>3</c></c></a>
, the
result of the expression is 129
(123 + 1 + 2 + 3), and to
evaluate this, a streaming processor will typically maintain a stack of
buffers to accumulate the typed values of each of the four c
elements during a single pass of the source document.
"Q{" || namespace-uri(.) || "}" || local-name(.)
is grounded
and motionless. The two literal operands are grounded and motionless because
they have no operands; the two function calls are grounded and motionless
because they have a single operand that is striding and motionless, with an
operand usage of inspection.
copy-of(.)/head/following-sibling::*
is grounded and consuming.
The left-hand operand
copy-of(.)/head
is grounded and consuming because, under the
rules in 19.8.8.8 Streamability of Path Expressions, its left-hand operand
copy-of(.)
is grounded and consuming. This in turn is
because .
is striding and motionless, and the operand usage is
absorption.
if ($discounted) then price else discounted-price
is striding
and consuming, because the two branches of the conditional are both striding
and consuming, and they form a choice operand group with
usage transmission.
if ($gratis) then 0 else price
is striding and consuming
because there is only one consuming operand (the fact that it is part of a
choice operand group does not affect the
reasoning).
count((author, editor))
is roaming and free-ranging. The first
argument to the count
function is an expression with two
operands, both having usage=transmission, and neither being grounded.
count((author | editor))
is grounded and consuming. A union
expression is not subject to the general streamability rules; it has its own
rules, defined in 19.8.8.4 Streamability of union, intersect, and
except Expressions, which
establish in this case that the argument to the count
FO30
is crawling and consuming. The
count
FO30 function does follow the general
streamability rules, with an operand usage of inspection: under rule 1(b)(iii)(B) the adjusted sweep is consuming, and rule 2(d)(iii) then applies.
('{', author, '}')
is striding and consuming. Exactly one
operand is consuming; it has usage transmission, so the
result has the posture and sweep of that operand. (The formal analysis
treats comma as a binary operator, but the same result can be obtained by
treating the content of the parenthesized expression as an expression with
three operands.)
The posture and sweep of a sequence constructor are determined by the general streamability rules.
The operand roles and their usages are:
The immediately contained
instructions
and literal result elements,
including any xsl:on-empty
or
xsl:on-non-empty
instructions. The operand usage for these operands is transmission.
Any text value templates appearing in text nodes within the sequence constructor, if text value templates are enabled. The operand usage for these operands is absorption.
Note:
Some consequences of these rules are:
An empty sequence constructor is motionless, and its posture is grounded.
A sequence constructor containing a single instruction has the same sweep and posture as that instruction. (This means that sequence constructors containing a single instruction can usefully be dropped from the construct tree.)
Informally, a sequence constructor is not streamable if it contains more than one instruction that moves the position of the input stream.
xsl:on-empty
or xsl:on-non-empty
instructions are not treated specially. For example, there is no attempt
to take into account that they are mutually exclusive: if one is
evaluated, the other will not be evaluated. In most use cases for these
instructions, they will be motionless, so the additional complexity of
doing more advanced analysis would rarely be justified.
This section describes how instructions are classified with respect to their streamability. The criteria are given first for literal result elements and extension instructions,, then for each XSLT instruction, listed alphabetically.
The posture and sweep of a literal result element follow the general streamability rules. The operand roles and their usages are:
The contained sequence constructor (usage absorption)
Any expressions contained in attribute value templates among the literal result element’s attributes (usage absorption)
Any attribute sets named in the
xsl:use-attribute-sets
attribute (usage irrelevant, but can be taken as inspection).
Note:
In practice, a reference to an attribute set that is declared-streamable does not affect the analysis, while a reference to any other attribute set makes the literal result element roaming and free-ranging.
For a processor that recognizes an extension instruction, the posture and sweep of the instruction are implementation-defined.
For a processor that does not recognize an extension instruction, the posture and sweep of the instruction are determined by applying the general streamability rules, The operand roles and their usages are:
The sequence
constructors contained in any xsl:fallback
children (usage transmission)
Instructions in the XSLT namespace that are present under the provisions for forwards compatible behavior are treated in the same way as unrecognized extension instructions.
Note:
These rules mean that if there is no xsl:fallback
child
instruction, the containing construct will be classified as streamable.
However, any attempt to execute the instruction will lead to a dynamic
error, so in fact, neither streamed nor unstreamed evaluation is
possible.
xsl:analyze-string
The posture and sweep of
xsl:analyze-string
follow the general streamability rules. The operand roles and their usages are:
the select
expression (usage absorption);
the regex
attribute value template (usage absorption);
the sequence constructors contained in the
xsl:matching-substring
and
xsl:non-matching-substring
elements. These have usage
navigation, because they can be evaluated more
than once. The context posture for the two sequence
constructors is grounded, reflecting the fact that
their context item type is xs:string
.
Note:
In practice, the sweep of the
instruction will usually be the same as the sweep of the select
expression, and its posture will be grounded. Exceptions occur for example if the
regex
attribute is not motionless, or if
the contained sequence constructors refer to a grouping variable bound in a
contained xsl:for-each-group
instruction.
xsl:apply-imports
The rules in this section apply also to xsl:next-match
.
The posture and sweep of these two instructions follow the general streamability rules. The operand roles and their usages are:
An implicit operand: a context item expression (.
), with
usage absorption;
The select
attribute or contained sequence constructor of each
xsl:with-param
child element, with type-determined usage based on the type declared in the
xsl:with-param/@as
attribute, or item()*
if
absent.
xsl:apply-templates
If there is no select
attribute, the following
analysis assumes the presence of an implicit operand
select="child::node()"
.
The posture and sweep of the
xsl:apply-templates
instruction are the first of the
following that apply:
If the select
expression is grounded,
then the posture and sweep of the
xsl:apply-templates
instruction follow the general streamability rules, with the operand roles and their usages as follows:
The select
expression (the operand usage is irrelevant, but can be taken as
absorption)
The select
expressions and contained sequence
constructors of any child xsl:with-param
elements
(usage type-determined, based on the type in the
xsl:with-param/@as
attribute, defaulting to
item()*
)
Any attribute value templates appearing in attributes of a child
xsl:sort
instruction (usage absorption)
The select
expression or contained sequence
constructor of any xsl:sort
children, assessed
with a context posture of grounded (usage absorption).
For example, <xsl:apply-templates
select="copy-of(.)"/>
is grounded and
consuming.
If there is an xsl:sort
child element, then roaming and free-ranging.
If the implicit or explicit mode
attribute identifies a
mode that is not declared with
streamable="yes"
, then roaming and free-ranging.
Note:
When mode="#current"
is specified, this is treated as
equivalent to specifying a streamable mode; although it is not known
statically what the mode will be, it is always the case that if the
template is invoked with a streamed node as the context item, then the
current mode must be a streamable mode.
If the select
expression is climbing or
crawling, then roaming and
free-ranging
Otherwise, the posture and sweep
of the xsl:apply-templates
instruction follow the
general streamability rules. The operand roles and their usages are as follows:
The (explicit or implicit) select
expression, with
usage absorption;
The select
attribute or contained sequence constructor of each
xsl:with-param
child element, with type-determined usage based on the type declared in
the xsl:with-param/@as
attribute, or
item()*
if absent.
xsl:assert
The posture and sweep of
xsl:assert
follow the general streamability rules. The operand roles and their usages are as follows:
The test
expression (usage inspection)
The select
expression (usage absorption)
The error-code
attribute value template (usage absorption)
The contained sequence constructor (usage absorption).
xsl:attribute
The posture and sweep of
xsl:attribute
follow the general streamability rules. The operand roles and their usages are as follows:
The name
attribute value template (usage absorption)
The namespace
attribute value template (usage absorption)
The select
expression (usage absorption)
The separator
attribute value template (usage absorption)
The contained sequence constructor (usage absorption).
xsl:break
The posture and sweep of
xsl:break
follow the general streamability rules. The operand roles and their usages are as follows:
The select
expression (usage transmission)
The contained sequence constructor (usage transmission).
xsl:call-template
The posture and sweep of
xsl:call-template
follow the general streamability rules. The operand roles and their usages are as follows:
Unless the referenced template has a child
xsl:context-item
element with the attribute
use="prohibited"
, there is an implicit operand, a context
item expression (.
): its operand usage
is the type-determined usage based on the type
declared in the xsl:context-item/@as
attribute of the target
named template, defaulting to item()*
if absent.
The select
expression or sequence constructor content of any
contained xsl:with-param
child element: its operand usage is the type-determined usage based on the type declared in the
xsl:with-param/@as
attribute, or the
xsl:param/@as
attribute of the corresponding parameter on
the target named template, whichever is more restrictive, defaulting to
item()*
if both are absent.
Note:
Calling xsl:call-template
will usually make stylesheet code
unstreamable if a streamed node is passed explicitly or implicitly to the
called template, unless it is atomized by declaring the expected type to be
atomic.
xsl:choose
The posture and sweep of
xsl:choose
follow the general streamability rules. The operand roles and their usages are as follows:
The test
attribute of contained xsl:when
elements (usage inspection).
The sequence constructors contained within xsl:when
and
xsl:otherwise
child elements (usage transmission). These sequence constructor operands form a
choice operand group.
Note:
The effect is to allow either of the following:
Any or all of the sequence constructors in xsl:when
and
xsl:otherwise
branch may be consuming, in
which case the test
expressions must all be motionless.
Any one of the test
expressions may be consuming,
in which case all the other test
expressions, and all the sequence constructors, must be motionless.
xsl:comment
The posture and sweep of
xsl:comment
follow the general streamability rules. The operand roles and their usages are as follows:
The select
expression (usage absorption)
The contained sequence constructor (usage absorption).
xsl:copy
The posture and sweep of
xsl:copy
follow the general streamability rules. The operand roles and their usages are as follows:
The expression in the select
attribute, defaulting to a
context item expression (.
) (usage inspection)
The contained sequence constructor (usage absorption), assessed with context posture and context item
type based on the select
expression if present, or the outer
focus otherwise.
Any attribute sets named in the
use-attribute-sets
attribute (usage irrelevant, but can be taken as inspection).
Note:
In practice, a reference to an attribute set that is declared-streamable does not
affect the analysis, while a reference to any other attribute set makes the xsl:copy
instruction
roaming and free-ranging.
Note:
The effect of these rules is that when a select
attribute is present, the sequence constructor contained by the xsl:copy
instruction is deemed to be a higher-order operand of the instruction,
even though it can only be evaluated once.
This has the practical consequence that the following example is not guaranteed-streamable, even though it is possible to imagine a strategy for streamed evaluation:
<xsl:for-each-group select="product" group-adjacent="@category"> <xsl:copy select=".."> <xsl:copy-of select="current-group()"/> </xsl:copy> </xsl:for-each-group>
A workaround in this case might be to rewrite the code as follows:
<xsl:for-each-group select="product" group-adjacent="@category"> <xsl:element name="{name(..)}" namespace-uri="{namespace-uri(..)}"> <xsl:copy-of select="current-group()"/> </xsl:element> </xsl:for-each-group>
xsl:copy-of
The posture and sweep of
xsl:copy-of
follow the general streamability rules. The operand roles and their usages are as follows:
The select
expression (usage absorption).
xsl:document
The posture and sweep of
xsl:document
follow the general streamability rules. The operand roles and their usages are as follows:
The contained sequence constructor (usage absorption).
xsl:element
The posture and sweep of
xsl:element
follow the general streamability rules. The operand roles and their usages are as follows:
The name
attribute value template (usage absorption)
The namespace
attribute value template (usage absorption)
Any attribute sets named in the
use-attribute-sets
attribute (usage irrelevant, but can be taken as inspection).
Note:
In practice, a reference to an attribute set that is declared-streamable does not
affect the analysis, while a reference to any other attribute set makes the xsl:element
instruction
roaming and free-ranging.
The contained sequence constructor (usage absorption).
xsl:evaluate
The posture and sweep of
xsl:evaluate
follow the general streamability rules. The operand roles and their usages are as follows:
The xpath
expression (usage absorption)
The context-item
expression (usage navigation)
The with-params
expression (usage navigation)
The base-uri
attribute value template (usage absorption)
The namespace-context
expression (usage inspection)
The schema-aware
attribute value template (usage absorption)
The select
attributes and contained sequence constructors of any
xsl:with-param
child elements (usage type-determined, based on the
type in the xsl:with-param/@as
attribute, defaulting to
item()*
)
Note:
In practice, code containing an xsl:evaluate
instruction
will usually be streamable provided that streamed nodes are not passed to
the dynamic expression either as the context item or as the value of a
parameter.
xsl:fallback
The posture and sweep of the
xsl:fallback
instruction depend on whether the processor is
performing fallback (which is known statically).
If the processor is performing fallback, then the posture
and sweep of the xsl:fallback
instruction
are the posture and sweep of the contained sequence constructor.
If the processor is not performing fallback, then the instruction is grounded and motionless.
xsl:for-each
The posture and sweep of the
xsl:for-each
instruction are the first of the following
that applies:
If the select
expression is grounded,
then the posture and sweep of the
xsl:for-each
instruction follow the general streamability rules, with the operand roles and their usages as follows:
The select
expression (the operand usage is irrelevant, but can be taken as
inspection)
The contained sequence constructor (usage transmission). This is a higher-order operand; its context posture is grounded.
Any attribute value templates appearing in attributes of a child
xsl:sort
instruction (usage absorption)
The select
expression or contained sequence
constructor of any xsl:sort
children, assessed
with a context posture of grounded (usage absorption).
These are higher-order
operands; their context posture is grounded.
If there is an xsl:sort
child element, then roaming and free-ranging.
If the posture of the
select
expression is crawling and the
sweep of the contained sequence constructor is consuming, then
roaming and free-ranging.
Otherwise:
The posture of the instruction is the posture of the contained sequence constructor, assessed with the context posture
and context item type set to the posture and
type of the select
expression.
The sweep of the instruction is the wider of
the sweep of the select
expression
and the sweep of the contained sequence constructor.
Note:
The ordering of sweep values is in increasing order: motionless, consuming, free-ranging.
Note:
Because the body of the xsl:for-each
instruction is a
higher-order operand of the instruction, any
variable reference within the body that is bound to a streaming parameter of a containing stylesheet function will not be singular, which in many
cases will make the entire function non-streamable.
xsl:for-each-group
The posture and sweep of the
xsl:for-each-group
instruction are the first of the
following that applies:
If the select
expression is grounded,
then the posture and sweep of the
xsl:for-each-group
instruction follow the general streamability rules, with the operand roles and their usages as follows:
The select
expression (the operand usage is irrelevant, but can be taken as
inspection)
The collation
attribute value template (usage absorption)
Any attribute value templates appearing in attributes of a child
xsl:sort
instruction (usage absorption)
The group-by
or group-adjacent
expression, assessed with a context posture of
grounded (usage absorption).
The select
expression or contained sequence
constructor of any xsl:sort
children, assessed
with a context posture of grounded (usage absorption).
The group-starting-with
or
group-ending-with
patterns if present; these are
higher-order
operands with usage inspection.
If there is a group-by
attribute and the instruction is not a child of
xsl:fork
, then roaming and free-ranging.
If there is a group-by
or
group-adjacent
attribute that is not motionless, then roaming and free-ranging.
If there is an xsl:sort
child element
and the instruction is not a child of xsl:fork
, then roaming and free-ranging.
If the posture of the
select
expression is crawling and the
sweep of the contained sequence constructor is consuming, then
roaming and free-ranging.
Otherwise:
The posture of the instruction is the posture of the contained sequence constructor, assessed with the context posture
and context item type set to the posture and
type of the select
expression.
The sweep of the instruction is the wider of
the sweeps of the
select
expression and the contained sequence constructor, where the ordering of
increasing width is motionless, consuming, free-ranging.
Note:
Because the body of the xsl:for-each-group
instruction is a higher-order operand of the
instruction, any variable reference within the body that is bound to a
streaming parameter of a containing stylesheet function will not be singular, which in many
cases will make the entire function non-streamable.
Note:
The above rules do not explicitly mention any
constraints on the presence or absence of a call on the
current-group
function. In practice, however, this
plays an important role. In the most common case, the select
expression of xsl:for-each-group
is likely to be striding,
for example an expression such as select="*"
. Any call on
current-group
associated with this
xsl:for-each-group
instruction will ordinarily be
striding and consuming, which is
consistent with streaming provided there is only one such call, and if it
appears in a suitable context (for example, not within a predicate). If
there is more than one call, or if it appears in an unsuitable context (for
example, within a predicate), then this will have the same effect as
multiple appearances of other consuming expressions: the construct as a
whole will be free-ranging. These rules are not spelled out explicitly, but
rather emerge as a consequence of the general streamability rules.
xsl:fork
The posture and sweep of
xsl:fork
are the first of the following that applies:
If there is a child xsl:for-each-group
instruction, then
the posture and the sweep of that
instruction.
If there are no child xsl:sequence
instructions (other than
xsl:fallback
), then grounded and
motionless.
If there is a child xsl:sequence
instruction whose
posture is not grounded, then
roaming and free-ranging.
Otherwise, the posture is grounded, and the sweep is the widest sweep of the
xsl:sequence
child instructions.
Note:
None of the branches of xsl:fork
can return streamed nodes.
The reason for this is that xsl:fork
has to assemble its
results in the correct order, and streamed nodes cannot be re-ordered.
The effect of the rules is that each of the child
xsl:sequence
instructions can independently consume the
streamed input document, provided that the result of each child instruction
is grounded.
Thus the following example is streamable:
<xsl:fork> <xsl:sequence select="copy-of(author)"/> <xsl:sequence select="copy-of(editor)"/> </xsl:fork>
While the following is not streamable, because it returns streamed nodes in an order that might not be document order:
<xsl:fork> <xsl:sequence select="author"/> <xsl:sequence select="editor"/> </xsl:fork>
xsl:if
The posture and sweep of
xsl:if
follow the general streamability rules. The operand roles and their usages are as follows:
The test
expression (usage inspection)
The contained sequence constructor (usage transmission).
xsl:iterate
The posture and sweep of the
xsl:iterate
instruction are the first of the following that
applies:
If the select
expression is grounded,
then the posture and sweep of the
xsl:iterate
instruction follow the general streamability rules, with the operand roles and their usages as follows:
The select
expression (the operand usage is irrelevant, but can be taken as
inspection)
The select
expression or contained sequence
constructor of any xsl:param
children (usage
navigation)
The sequence constructor contained within the
xsl:iterate
instruction itself, assessed with
its context item type and context posture based
on the select
expression (usage transmission)
The select
expression or contained sequence
constructor of any child xsl:on-completion
element, assessed with a context item type of xs:error
and a context posture of roaming to reflect the fact that any attempt to
reference the context item within the
xsl:on-completion
element is an error (usage
transmission)
Note:
The on-completion
element can cause the instruction to become non-streamable if,
for example, it contains a call on
current-group
or a variable reference
bound to a streaming parameter.
If there is an xsl:param
child whose initializing
select
expression or sequence constructor is not grounded
and motionless, then roaming and
free-ranging.
If there is an xsl:on-completion
child whose
select
expression or sequence constructor is not grounded
and motionless, then roaming and
free-ranging.
If the posture of the
select
expression is crawling and the
sweep of the contained sequence constructor is consuming, then
roaming and free-ranging.
Otherwise:
The posture of the instruction is the posture of the contained sequence constructor, assessed with the context posture
and context item type set to the posture and
type of the select
expression.
The sweep of the instruction is the wider of
the sweeps of the select
expression and the
contained sequence constructor,
where the ordering of increasing width is motionless, consuming, free-ranging.
Note:
If any xsl:break
or xsl:next-iteration
instructions appear within the sequence constructor, their posture and sweep will be assessed in the
course of evaluating the posture and sweep of the sequence constructor, by reference to the rules
in 19.8.4.8 Streamability of xsl:break and 19.8.4.28 Streamability of xsl:next-iteration respectively.
Note:
Because the body of the xsl:iterate
instruction is a
higher-order operand of the instruction, any variable
reference within the body that is bound to a streaming parameter of a containing stylesheet function will not be singular, which in many cases
will make the entire function non-streamable.
xsl:map
The posture and sweep of the xsl:map
instruction are determined
by the first of the following that applies:
If the sequence constructor within the instruction consists exclusively
of xsl:map-entry
instructions (and
xsl:fallback
instructions, which are ignored),
then:
If any of these xsl:map-entry
children is roaming or free-ranging, then
roaming and free-ranging;
Otherwise, grounded and the widest sweep of the
xsl:map-entry
children.
Otherwise, the posture and sweep
of the xsl:map
instruction are the posture and sweep of
the contained sequence constructor.
Note:
See discussion in 21.6 Maps and Streaming.
The effect of the rules is that it is possible to compute multiple map entries in a single pass of the streamed input document. For example, the following is streamable:
<xsl:map> <xsl:map-entry key="'authors'" select="copy-of(author)"/> <xsl:map-entry key="'editors'" select="copy-of(editor)"/> </xsl:map>
The call on copy-of
is necessary to ensure that the
content of the map entry is grounded; it is not possible to create a map
whose entries contain references to streamed nodes.
xsl:map-entry
The posture and sweep of
xsl:map-entry
follow the general streamability rules. The operand roles and their usages are as follows:
The key
expression (usage absorption)
The select
expression (usage navigation)
Note:
This effectively means that the select
expression must not return nodes from a streamed input document.
The contained sequence constructor (usage navigation).
xsl:merge
Note:
This section is concerned with the (not very interesting) impact of the
xsl:merge
instruction on the streamability of its
containing template rule or xsl:source-document
instruction.
For the (more important) rules concerning the way in which
xsl:merge
performs streamed processing of its own
inputs, see 15.4 Streamable Merging.
The posture and sweep of xsl:merge
are as follows:
If every xsl:merge-source
child element satisfies all
the following conditions:
The expression in the for-each-item
attribute is
either absent, or grounded and motionless;
The expression in the for-each-source
attribute is
either absent, or grounded and motionless;
Either at least one of the attributes for-each-item
and for-each-source
is present, or the expression in
the select
attribute is grounded
and motionless
then the xsl:merge
instruction is grounded and motionless.
Otherwise, the xsl:merge
instruction roaming and free-ranging.
xsl:message
The posture and sweep of
xsl:message
follow the general streamability rules. The operand roles and their usages are as follows:
The select
expression (usage absorption)
The terminate
attribute value template (usage absorption)
The error-code
attribute value template (usage absorption)
The contained sequence constructor (usage absorption).
xsl:namespace
The posture and sweep of
xsl:namespace
follow the general streamability rules. The operand roles and their usages are as follows:
The name
attribute value template (usage absorption)
The select
expression (usage absorption)
The contained sequence constructor (usage absorption).
xsl:next-iteration
The posture and sweep of
xsl:next-iteration
follow the general streamability rules. The operand roles and their usages are as follows:
The select
expression or sequence constructor content of any contained
xsl:with-param
child element: its operand usage is the type-determined usage based on the type declared in the
xsl:with-param/@as
attribute, or the
xsl:param/@as
attribute of the corresponding parameter on
the containing xsl:iterate
instruction, whichever is
more restrictive, defaulting to item()*
if both are
absent.
xsl:next-match
The rules are the same as for xsl:apply-imports
: see 19.8.4.4 Streamability of xsl:apply-imports.
xsl:number
The posture and sweep of
xsl:number
follow the general streamability rules. The operand roles and their usages are as follows:
The value
attribute if present: usage absorption
The select
attribute if there is
no value
attribute, defaulting to the context item
expression (.
) if the select
attribute is also
absent: usage navigation
The attribute value templates in the format
,
lang
, letter-value
, ordinal
,
start-at
, grouping-separator
, and
grouping-size
attributes (usage absorption)
The from
and count
patterns if present. These can be treated as higher-order operands with
usage inspection, though neither of these
properties affects the outcome.
Note:
The effect of these rules is that xsl:number
can be used
for formatting of numbers supplied directly using the value
attribute, and also for numbering of nodes in a non-streamed document, but
it cannot be used for numbering streamed nodes.
In practice the rules depend very little on the from
and
count
patterns. This is because when the instruction is
applied to a streamed node, the instruction will be free-ranging regardless of these patterns; while if it is
applied to a grounded node or atomic value, the instruction will normally be
motionless regardless of the values of these
patterns. The pattern does matter,
however, if it contains a variable reference bound to a streaming parameter;
because such a reference occurs within a higher-order operand of the xsl:number
instruction, its presence automatically makes the variable reference
free-ranging, which in turn ensures that the
containing stylesheet function is not guaranteed-streamable.
xsl:on-empty
The streamability rules for the xsl:on-empty
instruction are
the same as the rules for xsl:sequence
: see 19.8.4.36 Streamability of xsl:sequence.
Note:
The streamability rules for a sequence constructor containing an
xsl:on-empty
instruction are given in 19.8.3 Classifying Sequence Constructors.
xsl:on-non-empty
The streamability rules for the xsl:on-non-empty
instruction
are the same as the rules for xsl:sequence
: see 19.8.4.36 Streamability of xsl:sequence.
Note:
The streamability rules for a sequence constructor containing an
xsl:on-non-empty
instruction are given in 19.8.3 Classifying Sequence Constructors.
xsl:perform-sort
The posture and sweep of
xsl:perform-sort
follow the general streamability rules. The operand roles and their usages are as follows:
The expression in the select
attribute: usage navigation (because order is not preserved)
The expressions in the attribute value templates of
xsl:sort
child elements: usage absorption
The expression in the select
attribute or contained sequence constructor in child
xsl:sort
child elements, with usage absorption, assessed with context posture based on the
expression in the xsl:perform-sort/@select
attribute.
Note:
In practice, the xsl:perform-sort
instruction cannot be
used to sort nodes from the streamed input document, but it can be used to
sort atomic values or grounded nodes, for example a copy
of nodes from the streamed document made using the
copy-of
function.
xsl:processing-instruction
The posture and sweep of
xsl:processing-instruction
follow the general streamability rules. The operand roles and their usages are as follows:
The name
attribute value template (usage absorption)
The select
expression (usage absorption)
The contained sequence constructor (usage absorption).
xsl:result-document
The posture and sweep of
xsl:result-document
follow the general streamability rules. The operand roles and their usages are as follows:
The href
attribute value template (usage absorption)
The attribute value templates containing serialization properties (usage absorption)
The contained sequence constructor (usage absorption).
xsl:sequence
The posture and sweep of
xsl:sequence
follow the general streamability rules. The operand roles and their usages are as follows:
The select
attribute value template (usage transmission)
The contained sequence constructor (usage transmission).
xsl:source-document
Note:
The concern here is with the impact of xsl:source-document
on any
streaming template, or ancestor xsl:source-document
instruction, and
not with the streamed processing of the document accessed using the
xsl:source-document/@href
attribute.
The streamability of the document opened by the xsl:source-document
instruction is not assessed using the rules in this section; it depends only
on the streamability properties of the contained sequence constructor, as
described in 18.1 The xsl:source-document Instruction
The posture and sweep of
xsl:source-document
are the first of the following that applies:
If the contained sequence constructor contains, at any depth, a call on the
current-group
function whose nearest
containing xsl:for-each-group
instruction
exists and is an ancestor of the xsl:source-document
instruction,
then roaming and free-ranging.
If the contained sequence constructor contains, at any depth, a call on the
current-merge-group
function whose nearest
containing xsl:merge
instruction exists and
is an ancestor of the xsl:source-document
instruction, then
roaming and free-ranging.
Otherwise, the posture is grounded and the sweep is the sweep of
the href
attribute value template.
xsl:text
The posture and sweep of
xsl:text
follow the general streamability rules. There are no operands.
Note:
The instruction is therefore grounded and motionless.
xsl:try
The posture and sweep of the xsl:try
instruction
follow the general streamability rules. The operand roles and usages are as follows:
The select
expression or contained sequence constructor of the xsl:try
element. This has operand usage
transmission. (Note that the
xsl:catch
children of xsl:try
are
not part of the sequence constructor and therefore not part of this
operand.)
The select
expressions and/or contained sequence constructor of the xsl:catch
child elements. These form a choice operand group
with operand usage
transmission.
xsl:value-of
The posture and sweep of
xsl:value-of
follow the general streamability rules. The operand roles and their usages are as follows:
The select
expression (usage absorption)
The separator
attribute value template (usage absorption)
The contained sequence constructor (usage absorption).
xsl:variable
The posture and sweep of
xsl:variable
follow the general streamability rules. The operand roles and their usages
depend on the as
attribute,
as follows:
If there is an as
attribute, then:
The select
expression (with type-determined usage based on the as
attribute).
The contained sequence constructor (with
type-determined usage based on the
as
attribute).
If there is no as
attribute,
then:
The select
expression (usage navigation).
The contained sequence constructor (usage absorption).
Note:
The effect of the initialization expression having usage navigation is that it is not possible in streamable constructs to bind a variable to a node in a streamed document.
xsl:where-populated
The posture and sweep of an
xsl:where-populated
instruction are the posture and sweep of the contained sequence constructor.
Under specific conditions, described in this section, a stylesheet function can be used to process nodes from a streamed input document.
[Definition: Stylesheet functions belong to one of a number of streamability categories: the choice of category characterizes the way in which the function handles streamed input.]
The category to which a
function belongs is declared in the streamability
attribute of the
xsl:function
declaration, and defaults to
unclassified
.
The streamability categories defined in this specification are:
unclassified
, absorbing
, inspection
,
filter
, shallow-descent
, deep-descent
,
and ascent
. It is also possible to specify the streamability category
as a QName in an implementation-defined namespace, in which
case the streamability rules are implementation-defined; a
processor that does not recognize a category defined in this way
must analyze the function as if
streamability="unclassified"
were specified.
A stylesheet function is declared-streamable if the
xsl:function
declaration has a streamability
attribute with a value other than unclassified
.
The only category permitted for
a zero-arity function (one with no arguments) is unclassified
. All
function calls to zero-arity stylesheet functions are grounded
and motionless.
In general (subject to more detailed rules below), a node belonging to a streamed document can be present within the value of an argument of a call on a stylesheet function only if one of the following conditions is true:
The stylesheet function is declared-streamable, and the argument in question is the first argument of the function call.
The corresponding function parameter is declared with a required type that triggers atomization of any supplied node.
[Definition: The first parameter of a declared-streamable stylesheet function is referred to as a streaming parameter.]
Note:
If a stylesheet function returns streamed nodes, then these nodes can only
derive from streamed nodes passed in an argument to the function. This is
because streamed nodes cannot be bound to global variables, and they cannot be
returned by an xsl:source-document
instruction within the function body
(the result of xsl:source-document
is always grounded).
The choice of category places constraints on the function body, and also on calls to the function. These constraints are defined below, separately for each category. A function is guaranteed-streamable only if the constraints are satisfied, and a static function call is guaranteed-streamable only if the function is guaranteed-streamable and the function call itself satisfies the constraints for the chosen category.
Dynamic function calls are guaranteed-streamable only in trivial cases, for example where the function signature indicates that an argument is required to be a text node or an attribute node. For details, see 19.8.8.11 Streamability of Dynamic Function Calls.
The constraints on the function body are expressed in terms of the posture and sweep of the function result. The
posture and sweep of the function
result are the type-adjusted posture and sweep of the sequence constructor contained within the
xsl:function
element, given the declared return type of the
function, which defaults to item()*
.
Note:
Determining the posture and sweep of the function result requires first determining the posture and sweep of the contained sequence constructor, which is done according to the rules in 19.8.3 Classifying Sequence Constructors. This in turn will usually involve examination of variable references that are bound to the function’s parameters. The analysis of these variable references is described in 19.8.8.12 Streamability of Variable References.
If the function is declared-streamable but does not satisfy the constraints that make it guaranteed-streamable, the consequences are explained in 19.10 Streamability Guarantees.
If a stylesheet function is overridden in another package (using
xsl:override
), then the overriding stylesheet function must
belong to the same streamability category as the function that
it overrides. This ensures that overriding a function cannot affect the
streamability of calls to that function.
The rules for each streamability category are given in the following sections.
Informal description: Functions in this category cannot be called with streamed nodes supplied in an argument, unless the function signature causes such nodes to be atomized.
Rules for the function signature: there are no constraints.
Rules for the function body: there are no constraints.
Rules for references to the streaming parameter: not applicable, because there is no streaming parameter.
Rules for function calls: the general streamability rules apply. The operands are the expressions appearing in the argument list of the function call, with the operand usage of each operand being the type-determined usage based on the declared type of the corresponding parameter in the function signature.
The streamability category is
unclassified
.
<xsl:function name="f:exclude-first" as="node()*"> <xsl:param name="nodes" as="node()*"/> <xsl:sequence select="$nodes[not(node-name() = preceding-sibling::*/node-name())]"/> </xsl:function>
The effect of the rules is that a call to this function is guaranteed
streamable if and only if the sequence supplied as the value of the
$nodes
argument is grounded (that is, it
contains no streamed nodes).
The streamability category is
unclassified
.
<xsl:function name="f:min" as="xs:integer"> <xsl:param name="arg0" as="xs:integer"/> <xsl:param name="arg1" as="xs:integer"/> <xsl:sequence select="min(($arg0, $arg1))"/> </xsl:function>
The effect of the rules is that a call to this function is streamable under
similar circumstances to those that apply to a binary operator such as
+
. For example, a call is streamable if two atomic values
are supplied, or if two attribute nodes are supplied, whether from streamed
or unstreamed documents. The main constraint is that it is not permitted for
both arguments to be consuming; for example, if the context node is a node
in a streamed document, then the function call f:min((price,
discount))
would not be guaranteed streamable.
Informal description: Functions in this category typically read the subtrees rooted at the node or nodes supplied in the first argument. These subtrees must not overlap each other. The function must not return any streamed nodes.
Rules for the function signature: there are no constraints.
Rules for the function body: For the function to be guaranteed-streamable, the type-adjusted posture of the function body with respect to the declared return type must be grounded, and the type-adjusted sweep of the function body with respect to the declared return type must be motionless or consuming.
Rules for references to the streaming parameter: If the declared type of the streaming parameter permits more than one node, then a variable reference referring to the streaming parameter is striding and consuming. Otherwise such a variable reference is striding and motionless.
Rules for function calls: If the first argument is crawling then the function call is roaming and free-ranging; otherwise the general streamability rules apply. The operands are the expressions appearing in the argument list of the function call. The operand usage of the first argument is absorption; the operand usage of other arguments is the type-determined usage based on the declared type of the corresponding parameter in the function signature.
Note:
Absorbing functions perform an operation analogous to atomization on their supplied arguments, in that they typically use information from the subtree rooted at a node to compute atomic values. Atomization can be seen as a special case of absorption. Calls on absorbing functions are therefore, from a streamability point of view, equivalent to calls on functions that implicitly atomize the supplied nodes.
An important difference, however, is that whereas atomization can be applied to any argument of a function call, absorption applies only to the first argument.
Another difference is that atomization is allowed on a sequence of nodes in
crawling posture, whereas generalized absorption is
not. Within a sequence, there may be nodes whose subtrees overlap, and the
code for atomization is expected to handle this, but more general absorption
operations are not. To write a function that accepts streamed nodes and
atomizes them, it is better to use the streamability category
unclassified
, and to declare the first argument with an
atomic type, rather than using the category absorbing
which
allows more general processing, but restricts what can be supplied in the
argument to the function call.
The following function is declared as absorbing, and the function body meets the rules for this category because it makes downward selections only, and returns an atomic value.
<xsl:function name="f:count-descendants" as="xs:integer" streamability="absorbing"> <xsl:param name="input" as="node()*"/> <xsl:sequence select="count($input//*)"/> </xsl:function>
The effect of the rules is that a call to this function is guaranteed-streamable provided that the sequence supplied as
the value of the $nodes
argument is motionless or consuming, and is either
grounded or striding.
The following function is declared as absorbing, and the function body meets the rules for this category because it makes downward selections only from the node supplied as the first argument, and returns an atomic value.
<xsl:function name="f:compare-size" as="xs:integer" streamability="absorbing"> <xsl:param name="input0" as="node()"/> <xsl:param name="input1" as="node()"/> <xsl:sequence select="count($input0//*) - count($input1//*)"/> </xsl:function>
This function takes two nodes as its arguments. Some examples of function calls include:
Streamable: f:compare-size(a, b)
where a
is
an element in a streamed document and b
is an element in
an unstreamed document
Streamable: f:compare-size(a, b)
where a
and
b
are both elements in unstreamed documents
Not streamable: f:compare-size(a, b)
where a
is an element in an unstreamed document and b
is an
element in a streamed document
The reason for the asymmetry is that for the first argument the operand usage is absorption, while for the second argument it is navigation. It is a consequence of the general streamability rules that when streamed nodes are supplied to an operand with usage navigation, the resulting expression is roaming and free-ranging.
The following function is declared as absorbing, and the function body meets
the rules for this category. Analysis of the function body reveals that it
is grounded and consuming; to establish this, it is necessary to analyze the
recursive call f:outline(*)
, and this is possible because it is
known to be a call on an absorbing stylesheet function.
<xsl:function name="f:outline" as="xs:string" streamability="absorbing"> <xsl:param name="input" as="element()*"/> <xsl:value-of select="$input ! (name() || '(' || f:outline(*) || ')')" separator=", "/> </xsl:function>
The effect of the rules is that a call to this function is guaranteed
streamable in the typical case where the sequence supplied as the value of
the $input
argument is striding and
consuming.
Informal description: Functions in this category typically return properties of the node supplied in the first argument, where these properties can be determined without advancing the input stream. This allows access to properties such as the name and type of each node, and also to its ancestors, attributes, and namespaces.
Rules for the function signature: If the declared type of the streaming parameter permits more than one node, the function is not guaranteed-streamable.
Rules for the function body: For the function to be guaranteed-streamable, the type-adjusted posture of the function body with respect to the declared return type must be grounded, and the type-adjusted sweep of the function body with respect to the declared return type must be motionless.
Rules for references to the streaming parameter: Such a variable reference is striding and motionless.
Rules for function calls: the general streamability rules apply. The operands are the expressions appearing in the argument list of the function call. The operand usage of the first argument is inspection; the operand usage of other arguments is the type-determined usage based on the declared type of the corresponding argument in the function signature.
Note:
The streaming parameter is restricted to be a single
node because if $input
were a sequence of nodes, then an
expression such as ($input/name(), $input/@id)
would not be
streamable.
The following function is declared with category inspection
,
and the function body meets the rules for this category because all
references to the supplied node are motionless.
<xsl:function name="f:depth" as="xs:integer" streamability="inspection"> <xsl:param name="input" as="node()"/> <xsl:sequence select="count($input/ancestor-or-self::*)"/> </xsl:function>
The effect of the rules is that a call to this function is guaranteed
streamable provided that the expression supplied as the value of the
$nodes
argument is motionless or
consuming.
The following function is declared with category inspection
,
and the function body meets the rules for this category because the function
signature ensures that the second argument cannot be a node.
<xsl:function name="f:get-attribute-value" as="xs:string"> <xsl:param name="element" as="node()"/> <xsl:param name="attribute-name" as="xs:string"/> <xsl:sequence select="string($element/@*[local-name() = $attribute-name])"/> </xsl:function>
Although the normal usage of this function might be to supply an element from a streamed document as the first argument, and a literal string as the second, it is also permissible (and guaranteed streamable) to supply an unstreamed element as the first argument, and an element node from a streamed document as the second. When applying the general streamability rules in this case, the first operand is grounded and motionless, while the second is grounded and consuming (by virtue of the rules for type-determined usage), and this makes the function call grounded and consuming.
Informal description: Functions in this category typically return either the node supplied in the first argument or nothing, depending on the values of properties that can be determined without advancing the input stream. This allows access to properties such as the name and type of each node, and also to its ancestors, attributes, and namespaces.
Rules for the function signature: If the declared type of the streaming parameter permits more than one node, the function is not guaranteed-streamable.
Rules for the function body: For the function to be guaranteed-streamable, the type-adjusted posture of the function body with respect to the declared return type must be striding, and the type-adjusted sweep of the function body with respect to the declared return type must be motionless.
Rules for references to the streaming parameter: Such a variable reference is striding and motionless.
Rules for function calls: The posture and sweep of a call to a function in this category are determined by applying the general streamability rules. The operands are the expressions supplied as arguments to the function call. The first argument has operand usage transmission; any further arguments have type-determined usage based on the declared type of the corresponding parameter in the function signature.
The following function is declared as filtering, and the function body meets the rules for this category because it selects nodes from the input based on motionless properties (namely, the existence of attributes).
<xsl:function name="f:large-regions" as="element(region)" streamability="filter"> <xsl:param name="input" as="element(region)"/> <xsl:sequence select="$input[@size gt 1000]"/> </xsl:function>
The effect of the rules is that the posture and sweep of a function call
f:large-regions(EXPR)
are the same as the posture and sweep of EXPR
.
Although the name filter
suggests that the result must always
be a subset of the input, this is not strictly required by the rules. The
function can also return atomic values, as well as attribute and namespace
nodes.
Informal description: Functions in this category typically return children of the nodes supplied in the first argument. They may also select deeper in the subtrees of these nodes, provided that no node in the result can possibly be an ancestor of any other node in the result.
Rules for the function signature: If the declared type of the streaming parameter permits more than one node, the function is not guaranteed-streamable.
Rules for the function body: For the function to be guaranteed-streamable, the type-adjusted posture of the function body with respect to the declared return type must be striding, and the type-adjusted sweep of the function body with respect to the declared return type must be motionless or consuming.
Rules for references to the streaming parameter: Such a variable reference is striding and motionless.
Rules for function calls: The rules are as follows, in order:
Let T0 be the U-type corresponding to the declared type of the streaming parameter in the function signature (defaulting to U{*}).
Let P0 and S0 be the type-adjusted posture and sweep of the first argument expression, based on type T0.
If P0 is not striding or grounded, the function call is roaming and free-ranging.
Consider a construct C whose operands are the argument expressions other than the first argument, with type-determined operand usage based on the declared type of the corresponding parameter in the function signature. Let P1 and S1 be the posture and sweep of C, assessed using the general streamability rules.
Note:
If there is only one argument, then P1 is grounded and S1 is motionless.
If P1 is not grounded, the function call is roaming and free-ranging.
If S0 and S1 are both consuming, or if either is free-ranging, then the function call is roaming and free-ranging.
If P0 is grounded, then the posture of the function call is grounded, and the sweep of the function call is the wider of S0 and S1.
Otherwise, the posture of the function call is P0, and the sweep of the function call is as follows:
If the intersection of T0 with U{document-node(), element()} is empty (that is, the declared type of the first argument does not permit document or element nodes) then S0.
Let A be the static type of the expression supplied as the first argument. If the intersection of A with U{document-node(), element()} is empty (that is, the inferred type of the expression supplied as the first argument does not permit document or element nodes) then S0.
Otherwise, consuming.
The following function is declared as shallow-descent, and the function body meets the rules for this category because it selects children of the supplied input node.
<xsl:function name="f:alternate-children" as="node()*" streamability="shallow-descent"> <xsl:param name="input" as="element()"/> <xsl:sequence select="$input/node()[position() mod 2 = 1]"/> </xsl:function>
The effect of the rules is that a call to this function is guaranteed
streamable in the typical case where the node supplied as the value of
the $input
argument is striding and
consuming.
Informal description: Functions in this category typically return descendants of the nodes supplied in the first argument.
Rules for the function signature: If the declared type of the streaming parameter permits more than one node, the function is not guaranteed-streamable.
Rules for the function body: For the function to be guaranteed-streamable, the type-adjusted posture of the function body with respect to the declared return type must be crawling, and the type-adjusted sweep of the function body with respect to the declared return type must be motionless or consuming.
Rules for references to the streaming parameter: Such a variable reference is striding and motionless.
Rules for function calls: The rules are as follows, in order:
Let T0 be the U-type corresponding to the declared type of the streaming parameter in the function signature (defaulting to U{*}).
Let P0 and S0 be the type-adjusted posture and sweep of the first argument expression, based on type T0.
If P0 is not striding or grounded, the function call is roaming and free-ranging.
Consider a construct C whose operands are the argument expressions other than the first argument, with type-determined operand usage based on the declared type of the corresponding parameter in the function signature. Let P1 and S1 be the posture and sweep of C, assessed using the general streamability rules
Note:
If there is only one argument, then P1 is grounded and S1 is motionless.
If P1 is not grounded, the function call is roaming and free-ranging.
If S0 and S1 are both consuming, or if either is free-ranging, the function call is roaming and free-ranging.
If P0 is grounded, then the posture of the function call is grounded, and the sweep of the function call is the wider of S0 and S1.
Otherwise, the posture of the function call is crawling, and the sweep of the function call is as follows:
If the intersection of T0 with U{document-node(), element()} is empty (that is, the declared type of the first argument does not permit document or element nodes) then S0.
Let A be the static type of the expression supplied as the first argument. If the intersection of A with U{document-node(), element()} is empty (that is, the inferred type of the expression supplied as the first argument does not permit document or element nodes) then S0.
Otherwise, consuming.
The following function is declared as deep-descent, and the function body meets the rules for this category because it selects descendants of the supplied input node.
<xsl:function name="f:all-comments" as="comment()*" streamability="deep-descent"> <xsl:param name="input" as="element()"/> <xsl:sequence select="$input//comment()"/> </xsl:function>
The effect of the rules is that a call to this function is guaranteed
streamable in the typical case where the node supplied as the value of
the $input
argument is striding and
consuming.
Informal description: Functions in this category typically return ancestors of the nodes supplied in the first argument.
Rules for the function signature: If the declared type of the streaming parameter permits more than one node, the function is not guaranteed-streamable.
Rules for the function body: For the function to be guaranteed-streamable, the type-adjusted posture of the function body with respect to the declared return type must be either climbing or grounded, and the type-adjusted sweep of the function body with respect to the declared return type must be motionless.
Rules for references to the streaming parameter: Such a variable reference is climbing and motionless.
Rules for function calls: The posture and sweep of a call to a function in this category are determined as follows:
Let P0 and S0 be the posture and sweep obtained by assessing the function call using the general streamability rules, where the operands are the arguments to the function call, with an operand usage for the first argument of inspection, and an operand usage for arguments after the first being the type-determined usage based on the declared type of the corresponding function parameter.
If P0 is roaming or S0 is free-ranging, then the function call is roaming and free-ranging.
If S0 is not motionless, then the function call is roaming and free-ranging.
If P0 is roaming, then the function call is roaming and free-ranging.
If P0 is grounded, then the function call is grounded and motionless.
Otherwise, the function call is climbing and motionless.
The following function is declared with category ascent
, and
the function body meets the rules for this category because it selects
ancestors of the supplied node.
<xsl:function name="f:containing-section" as="element(section)" streamability="ascent"> <xsl:param name="input" as="element(para)*"/> <xsl:sequence select="$input/ancestor::section[last()]"/> </xsl:function>
The effect of the rules is that a call to this function is guaranteed
streamable provided that the node supplied as the value of the
input
argument is not roaming or
free-ranging. There are no other constraints on the
node supplied in the input sequence.
The posture of an attribute set is always grounded (its result can never return streamed nodes).
The sweep of an attribute set is motionless if all the following conditions hold:
Every xsl:attribute
instruction within the declarations comprising the attribute set
is motionless when assessed as described in 10.2.3 Streamability of Attribute Sets,
using a context posture of striding.
Every attribute set referenced in the use-attribute-sets
attribute of an xsl:attribute-set
declaration of the attribute set has the attribute streamable="yes"
.
If the sweep of an attribute set is not motionless then it is free-ranging.
Note:
Attribute sets will always be grounded, because they return newly constructed attribute nodes.
Attribute sets will very often be motionless, but if they access the context item, they may be free-ranging. Although some attribute sets could theoretically be classified as consuming, this option has been excluded because it is unlikely to be useful; given the requirement to create attributes whose values are obtained by reading a streamed input document, use of a streamable template rule is a more versatile approach.
Because attribute sets can be overridden in another package, the streamability of a construct such as an
xsl:element
instruction containing a
use-attribute-sets
attribute is based on the declared
streamability of the named attribute sets, as defined by the
streamable
attribute of the xsl:attribute-set
element. If streamable="yes"
is specified, then there is a
requirement that any overriding attribute set should also specify
streamable="yes"
, and a streaming processor is required to
check that an attribute set containing such a declaration does in fact satisfy
the streamability rules.
A value template (that is, an attribute value template or text value template)
is a construct whose operands are the expressions contained
within curly brackets. The required type for this operand role is
xs:string
and the usage
is absorption.
The sweep and posture of a value template are determined using the general rules in 19.8.1 General Rules for Streamability.
If there are no expressions contained within curly brackets, the value template is motionless.
XPath expressions are classified using the rules in this section.
In the analysis that follows, expressions are classified according to the most specific production rule that they match for which there is an entry in this section. A production P is considered more specific than a production Q (Q ≠ P) if every expression that matches P also matches Q. For example:
The expression 3
satisfies the productions
NumericLiteral
, Literal
, and
ArithmeticExpression
; the most specific of these for which
there is an entry in this section is Literal
.
The expression text()
(appearing as an expression) is a
TextTest
, and therefore a KindTest
, which is
itself a NodeTest
, and therefore an AxisStep
with
a defaulted ForwardAxis
. The most specific of these for which
there is an entry in this section is AxisStep
. Although the
expression is also a RelativePathExpr
, that production is less
specific than AxisStep
so its rules do not apply.
The expression section/title
is a
RelativePathExpr
, for which there is an entry in this section.
Although the expression is also a PathExpr
, that production is
less specific than RelativePathExpr
so its rules do not
apply.
The production rules for different kinds of expression are listed (with their names and numbers) in the order in which they appear in Appendix A.1 of the XPath 3.0 specification; rules are also given for new constructs introduced by XPath 3.1. Where two numbers are given, they are the production rule numbers in XPath 3.0 and XPath 3.1 respectively; where there is a single number, it is the production rule number in XPath 3.1.
Many expressions can be analyzed using the general streamability rules. These are indicated in the table below
by means of a simple proforma in which the operand
roles are represented by a short code (A = absorption, I = inspection, T = transmission, N = navigation). For example the
proforma A + A
indicates that for an arithmetic expression, both
operands have operand usage
absorption, while I or I
indicates that for an
or
expression, both operands have operand usage
inspection. For expressions where further explanation is
needed, the table contains a link to the relevant section.
Construct | Proforma or Reference to Detailed Rules | Further Information |
---|---|---|
Expr [6,6] | T, T |
|
ForExpr [8,8] | See 19.8.8.1 Streamability of for Expressions | |
LetExpr [11,11] | let $var := N return T |
Binding of variables to streamed nodes is not allowed. |
QuantifiedExpr [14,14] | See 19.8.8.2 Streamability of Quantified Expressions | |
IfExpr [15,15] | if (I) then T else
T |
The then-clause and else-clause form a choice operand group with usage transmission |
OrExpr [16,16] | I or I |
|
AndExpr [17,17] | I and I |
|
StringConcatExpr [19,19] | A || A |
|
RangeExpr [20,20] | A to A |
|
AdditiveExpr [21,21] | A + A , A - A |
|
MultiplicativeExpr [22,22] | A * A , A div A , etc.
|
|
UnionExpr [23,23] | See 19.8.8.4 Streamability of union, intersect, and except Expressions | |
IntersectExceptExpr [24,24] | See 19.8.8.4 Streamability of union, intersect, and except Expressions | |
InstanceOfExpr [25,25] | See 19.8.8.5 Streamability of instance of Expressions | |
TreatExpr [26,26] | See 19.8.8.6 Streamability of treat as Expressions | |
CastableExpr [27,27] | A castable as TYPE |
|
CastExpr [28,28] | A cast as TYPE |
|
UnaryExpr [29,30] | +A , -A |
|
GeneralComp [31,32] | A = A , A < A , A != A ,
etc.
|
|
ValueComp [32,33] | A eq A , A lt A , A ne A , etc.
|
|
NodeComp [33,34] | I is I , I <<
I , I >> I |
See Note 1 below |
SimpleMapExpr [34,35] | See 19.8.8.7 Streamability of Simple Mapping Expressions | |
PathExpr [35,36] | See 19.8.8.8 Streamability of Path Expressions | |
RelativePathExpr [36,37] | See 19.8.8.8 Streamability of Path Expressions | |
AxisStep [38,39] | See 19.8.8.9 Streamability of Axis Steps | |
ForwardStep [39,40], ReverseStep [42,43] | See 19.8.8.9 Streamability of Axis Steps | |
PostfixExpr [48,49]: Filter Expression | See 19.8.8.10 Streamability of Filter Expressions | |
PostfixExpr [48,49]: Dynamic Function Call | See 19.8.8.11 Streamability of Dynamic Function Calls | |
Literal [53,57] | There are no operands, so the construct is grounded and motionless | |
VarRef [55,59] | See 19.8.8.12 Streamability of Variable References | |
ParenthesizedExpr [57,61] | (T) |
|
() |
There are no operands, so the construct is grounded and motionless | |
ContextItemExpr [58,62] | See 19.8.8.13 Streamability of the Context Item Expression | |
FunctionCall [59,63] | See 19.8.8.14 Streamability of Static Function Calls | |
NamedFunctionRef [63,67] | See 19.8.8.15 Streamability of Named Function References | |
InlineFunctionExpr [64,68] | See 19.8.8.16 Streamability of Inline Function Declarations | |
MapConstructor [–,69] | See 19.8.8.17 Streamability of Map Constructors | |
Lookup (Postfix [–,49] and Unary [–,53]) | See 19.8.8.18 Streamability of Lookup Expressions | |
ArrowExpr [–,29] | See 19.8.8.14 Streamability of Static Function Calls
and 19.8.8.11 Streamability of Dynamic Function Calls:
the rules for X => F(Y, Z) are the same as the rules for F(X, Y, Z) |
|
SquareArrayConstructor [–,74] | [N, N, ...] |
|
CurlyArrayConstructor [–,75] | array{N, N, ...} |
Note:
The operators is
, <<
, and
>>
apply to streamed nodes just as to any other
nodes, though there are few practical situations where they will be
useful. A streamed document conforms to the rules of the XDM data model,
and its nodes are therefore distinct and ordered. They follow the usual
rules, for example that a parent node precedes its children in document
order. Expressions such as .. is parent::X
or
ancestor::x[1] << ancestor::y[1]
are therefore
perfectly meaningful. The usefulness of the operators is limited by the
fact that variables cannot be bound to nodes in a streamed document. It
is permitted, though perhaps not useful, for one of the operands to be
consuming: one can write . <<
child::x
, and the resulting expression is (by applying the
general rules) consuming and grounded.
The restriction that variables cannot be bound to streamed nodes prevents
writing of expressions such as let $x := . return
descendant::x[ancestor::y[1] is $x]
. As a workaround, the
intended effect can be achieved by comparing node identity using the
generate-id
FO30 function: let $x :=
generate-id(.) return descendant::x[generate-id(ancestor::y[1]) =
$x]
for
ExpressionsWriting the expression as for $v in S return R
, the two operand
roles are S and R.
The posture and sweep are determined by the first of the following that applies:
If S is not grounded, then roaming and free-ranging.
Otherwise, the general streamability rules apply. The operand roles are:
The in
expression (S
). This has usage
navigation.
The return
expression (R
). This is a
higher-order operand with usage
transmission.
Note:
Expressions of the form for $i in 1 to 3 return $i*2
, where
there is no reference to a streamed node, are clearly streamable.
The in
expression can also be consuming,
for example for $e in copy-of(emp) return $e/salary
.
The rule that S must be grounded
prevents the variable being bound to a node in a streamed document. This
disallows expressions of the form for $x in child::section return
$x/para
, because this requires data flow analysis (tracing from
the binding of a variable to its usages), rather than purely syntactic
analysis. Some implementations may be able to stream such constructs.
The fact that the return clause is a higher-order operand prevents it from
being a consuming expression, for example for $i
in 1 to 3 return salary
. Use of a motionless expression that
accesses streamed nodes is however allowed, for example for $i in 1 to
3 return name(ancestor::x[$i])
.
An expression with multiple in-clauses is first rewritten using nested
quantified expressions: for example some $i in X, $j in Y satisfies $i eq
$j
can be rewritten as some $i in X satisfies (some $j in Y
satisfies $i eq $j)
. The analysis therefore only needs to consider
expressions with a single in-clause.
Writing such an expression as some|every $v in S satisfies C
, the
two operand roles are S and C.
The general streamability rules apply. The operand roles are:
The in
expression (S). This has usage navigation.
The satisfies
expression (C). This is a higher-order operand with usage inspection.
Note:
Expressions of the form some $i in 1 to 3 satisfies $i lt 2
,
where there is no reference to a streamed node, are clearly streamable.
The expression S can be consuming, so long as
it is grounded: for example some $e in emp/salary/number(.) satisfies
$e gt 10000
.
The rule that S has usage navigation prevents
the variable being bound to a node in a streamed document. This disallows
expressions of the form some $x in child::section satisfies
has-children($x)
, because this requires data flow analysis
(tracing from the binding of a variable to its usages), rather than purely
syntactic analysis. Some implementations may be able to stream such
constructs.
The fact that C is a higher-order operand prevents it from being
a consuming expression: for example some $i in 1
to 3 satisfies author[$i] eq "Kay"
is not streamable. Use of a
motionless expression that accesses streamed nodes is however allowed, for
example some $i in 1 to 3 satisfies @grade = $i
.
Quantified expressions that fail the streamability rules can often be
rewritten as filter expressions. For example, the expression some $x in
child::section satisfies has-children($x)
can be rewritten as
exists(child::section[has-children(.)])
, which is grounded
and consuming.
if
expressionsWriting the expression as if (C) then T else E
, there are three
operand roles: C, T, and E. The usage of C is inspection, while the usage of T and E is transmission. Operands T and E form a
choice operand group, meaning that they can both consume
the input stream, provided they have consistent posture.
The general streamability rules apply.
union
, intersect
, and
except
ExpressionsThe posture and sweep are the first of the following that applies:
If either of the two operands is free-ranging, then
roaming and free-ranging
(Example: . | following-sibling::*
).
If either of the two operands is grounded and
motionless, then the posture
and sweep of the other operand (Example: . |
doc('abc.com')//x
)
If both operands are climbing, then climbing and and the
wider of the sweeps of the two operands (Example: parent::A | */ancestor::B
).
If the left-hand operand is striding or crawling and the right-hand operand is also
striding or crawling, then crawling and the wider of the
sweeps of the two operands (Example: * | */*
).
Otherwise, roaming and free-ranging (Example: child::div |
parent::div
).
Note:
Essentially the principle is that if both operands are streamable, then the
result is streamable (this assumes an evaluation strategy where both
operands are evaluated during the same pass of the streamed input document,
and the results merged). But there are caveats because of the need for
static streamability analysis of the result. This prevents constructs such
as .. | *
that have heterogeneous posture.
Where the two operands are both striding, there are
cases where an implementation could determine that the result is also
striding: for example (author | editor)
.
In general, however, the combination of two striding operands may produce a
sequence of nodes that have nested subtrees (consider author | author/name
),
so the result is classified as crawling.
The expression (author | editor)
, although it is not striding, can be rewritten in the form *[self::author or
self::editor]
, which is striding.
instance of
ExpressionsFor an expression of the form X instance of ST (where X is an expression and ST is a SequenceType), the posture and sweep are determined by the general streamability rules. There is a single operand X, whose operand usage is as follows:
If the ItemType
of ST is a
DocumentTest
, optionally parenthesized, that contains an
ElementTest
or SchemaElementTest
then
absorption
Otherwise, inspection.
Note:
In general, it is possible to determine whether a node matches an
ItemType
without consuming the node. For example it can be
established whether an element matches the test element(para)
when positioned at the start tag.
An ItemType
of the form document-node(element(X))
is a exception to this rule because it matches a document node only if it
has exactly one element node child, and this cannot be determined without
consuming the document.
A processor may have knowledge that the document node cannot contain multiple element nodes, for example because it knows that the source of the streamed document is an XML parser that is not capable of generating such a stream. In such cases the processor may make a different assessment of the streamability of this construct. This comes under the general provision that a processor is always at liberty to use streaming even when the stylesheet is not guaranteed streamable.
Note:
As with other constructs that are evaluated with inspection usage, for
example the name
FO30 function or access to an attribute
node, evaluation of a construct such as $X instance of
schema-element(E)
as true or false may be invalidated if reading
of the input stream subsequently fails. Dynamic errors during streamed
processing of an input document invalidate all output generated prior to the
failure, and this case is no different.
Note:
Given an expression such as child::* instance of element(E)*
,
the expression as a whole is consuming and grounded. By
contrast, the expression . instance of element(E)*
is
motionless and grounded. This can be verified by applying the general
streamability rules to these cases.
treat as
ExpressionsFor an expression of the form X treat as ST (where X is an expression and ST is a SequenceType), the posture and sweep are determined as follows:
If the ItemType
of ST is a
DocumentTest
, optionally parenthesized, that contains an
ElementTest
or SchemaElementTest
then
roaming and free-ranging.
Otherwise, the general streamability rules apply. There is a single operand X, whose operand usage is transmission.
Note:
See the notes in 19.8.8.5 Streamability of instance of Expressions for
a discussion of the streamability difficulties associated with document-node()
tests.
The mapping operator !
is treated as a left-associative binary
operator, so the expression a!b!c
is processed as
(a!b)!c
.
The posture of the expression is the posture of the right-hand operand, assessed with a context posture and type set to the posture and type of the left-hand operand.
The sweep of the expression is the wider of the sweeps of the two operands.
The streamability analysis applies after the expansion of the //
pseudo-operator to /descendant-or-self::node()/
, and after
expanding ..
to parent::node()
, @X
to
attribute::X
, and an omitted axis to the default axis for the node kind.
Following the rules in XPath, a leading "/"
is converted to
(root(self::node()) treat as document-node())/
(with the final
"/"
omitted for the expression "/"
on its own).
This is followed by a rewrite of the call on root
FO30, as
described in 19.8.9.18 Streamability of the root Function.
Note:
Taken together, these rewrites have the effect that a path expression such
as //a
is streamable only if the statically-determined context
item type is document-node()
, which will be the case for
example immediately within xsl:source-document
, or in a template
rule with match="/"
.
A RelativePathExpr
with more than two operands (such as
a/b/c
) is taken as a tree of binary expressions (that is,
(a/b)/c
).
The sweep of a relative path expression is the wider sweep of the two operands, where the ordering of increasing width is motionless, consuming, free-ranging.
Note:
Examples:
The sweep of a/@code
is consuming (the wider of consuming
and motionless).
The sweep of a/descendant::b
is
consuming (the wider of consuming and consuming).
The sweep of ./@code
is motionless (the wider of motionless
and motionless).
The sweep of ./a
is consuming (the wider of motionless
and consuming).
The sweep of a/following::b
is
free-ranging (the wider of consuming and free-ranging).
The sweep of ./.
is motionless (the wider of motionless
and motionless).
The posture of a relative path expression is assessed in two phases, as follows:
First, the provisional posture is determined as follows: The provisional posture of the expression is the posture of the right-hand operand, assessed with a context posture and type set to the posture and type of the left-hand operand; and the provisional sweep is the wider of the sweeps of the two operands.
If the provisional posture is roaming, then it is reassessed as follows:
[Definition: A
RelativePathExpr
is a scanning expression
if and only if it is syntactically equivalent to some motionless
pattern.]
Note:
This means that a RelativePathExpr
is a scanning expression if it conforms to the grammar for a RelativePathExprP
in the grammar for patterns (see 5.5.2 Syntax of Patterns),
and if, when considered as a pattern, the pattern is motionless according to the
rules in 19.8.10 Classifying Patterns.
In practice, the test as to whether the construct is equivalent to a pattern is likely to be made by examining the structure of the expression tree, rather than by re-parsing the lexical form of the expression against the grammar for patterns; but the outcome is the same.
If the expression is a scanning expression then:
Otherwise (if the provisional posture is not roaming, or the expression is not a scanning expression), the posture of the expression is the provisional posture.
Note:
The special rules for scanning expressions are designed to ensure
that expressions such as //section/head
are streamable. The problem
with such an expression is that it is
possible to have two nested sections A and B, where A
is the parent of B and thus precedes B in document order,
but where there are children of A that come after
children of B in document order. This means that a nested-loop
strategy for the evaluation of /descendant::section/child::head
is not guaranteed to deliver nodes in document order without a sort, and is therefore
not
a viable strategy for streaming.
However, there is a different strategy for evaluating such an expression,
which is in effect to rewrite the expression as /descendant::head[parent::section]
;
specifically, it is possible to scan all descendants in document order, looking for
a head
element that has a section
parent. Hence the term scanning expressions.
The expressions that qualify as scanning expressions are paths that can be evaluated by scanning all descendants and testing each one (independently) to see whether the elements on its ancestor axis match the specified path. The subset of expressions that qualify as scanning expressions is therefore the same as the subset that qualify as motionless patterns.
Scanning expressions cannot use positional predicates: for example //section/head[1]
is not recognized as a scanning expression because this would require information
about a streamed node (specifically, about its preceding siblings) that is not retained
during streaming.
Note:
Perhaps surprisingly, the expression .//section/head
is not a scanning
expression and is therefore not guaranteed streamable. This is because it does not
take
the syntactic form of a pattern. To make it streamable, it can be rewritten as
descendant::section/head
or as self::node()//section/head
.
Similarly, within a streamable stylesheet function whose streaming parameter is
$node
, the expression $node//section/head
is not a scanning
expression. In this case the expression does have the syntactic form of a pattern,
but the
pattern is not classified as motionless. (See 19.8.10 Classifying Patterns — a
motionless pattern cannot contain a RootedPath
.) A workaround in this case
is to rewrite the expression as $node/(descendant::section/head)
. Assuming that the
function in question declares streamability="absorbing"
, the analysis here is
that the left-hand operand ($node
) is striding and consuming, while the right hand
operand (descendant::section/head
) is crawling and consuming (because it is a
scanning expression). The expression as a whole is therefore crawling and consuming.
These are cases where an implementation might reasonably choose to relax the rules, insofar as this is permitted by 19.10 Streamability Guarantees.
Note:
Examples:
In each of the following cases, assume that the context posture is striding.
The posture of the expression a/b/c
is striding, because (under the rules for AxisStep [38]) a child axis
step evaluated with striding context posture
creates a new striding posture.
The posture of the expression a/descendant::c
is
crawling, because a descendant axis step evaluated with striding
context posture creates a new crawling posture.
The posture of the expression
../@status
is striding, because a parent axis step
evaluated with striding context posture creates a new climbing
posture, and an attribute axis step evaluated with climbing context
posture creates a new striding posture.
The posture of the expression
copy-of(.)//a/following-sibling::*
is grounded,
because the copy-of
evaluated with striding
posture creates a grounded posture, and all subsequent axis steps
leave this posture unchanged.
The expression section//head
expands to
(section/descendant-or-self::node())/child::head
. The
posture of the left-hand operand
section/descendant-or-self::node()
is crawling,
because a descendant axis step evaluated with striding context posture
creates a new crawling posture. The provisional posture of the
expression as a whole is therefore roaming, because a child axis step
evaluated with crawling context posture gives a resulting roaming posture. However, the expression
is a scanning expression (both section//head
and its expansion are
motionless patterns), so the expression as a whole has
crawling posture.
The expression section//head[1]
is
free-ranging: unlike the previous example, it contains a positional
predicate, which means that the operands do not satisfy the rules for
scanning expressions.
The sweep and posture of an AxisStep S are determined by the first of the following rules that applies:
If the context posture is grounded, then the sweep is motionless and the posture is grounded;
If the context posture is roaming, then the sweep is free-ranging and the posture is roaming;
If the statically-inferred context item type is such
that the axis will always be empty (for example, applying the child axis
to a text node or the parent axis to a document node), or if the NodeTest
is one that can never
select nodes on the chosen axis (for example, selecting attribute
nodes on the child axis), then the sweep is motionless and the posture is grounded
(because the expression is statically known to return an empty
sequence);
If all the following conditions are satisfied:
The context posture is striding
The axis is descendant
or
descendant-or-self
There is a predicate P in the PredicateList
that satisfies all the following conditions:
The static type of P is a subtype of
U{xs:decimal, xs:double, xs:float}
Neither P, nor any operand of P, at any depth provided it has the AxisStep S as its focus-setting container, is a context item expression, an axis expression, or a call on a focus-dependent function;
If the PredicateList
contains a Predicate
that
is not motionless, then the sweep is free-ranging and the posture is roaming;
Otherwise, the sweep and posture of the expression are as determined by the table below, based on the context posture, the choice of axis, and the node test. The condition “Selects elements?” is true if the U-type of S has a non-empty intersection with U{element()}.
Context posture | Axis | Selects elements? | Result posture | Sweep |
---|---|---|---|---|
Grounded | any | Grounded | Motionless | |
Climbing | self, parent, ancestor-or-self, ancestor | Climbing | Motionless | |
Climbing | attribute, namespace | Striding | Motionless | |
Striding | parent, ancestor-or-self, ancestor | Climbing | Motionless | |
Striding | self, attribute, namespace | Striding | Motionless | |
Striding | child | Striding | Consuming | |
Striding | descendant, descendant-or-self | Yes | Crawling | Consuming |
Striding | descendant, descendant-or-self | No | Striding | Consuming |
Crawling | parent, ancestor-or-self, ancestor | Climbing | Motionless | |
Crawling | attribute, namespace | Striding | Motionless | |
Crawling | self | Yes | Crawling | Motionless |
Crawling | self | No | Striding | Motionless |
Any other combination | Roaming | Free-ranging |
Note:
This analysis does not attempt to classify para[title]
as a
consuming expression; an implementation might choose
to do so.
For a filter expression F of the form B[P]
(where
B might itself be a filter expression), the posture and sweep are the first of the
following that applies:
If all the following conditions are satisfied:
B is crawling;
The static type of P is a subtype of U{xs:decimal,
xs:double, xs:float}
, and
Neither P, nor any operand of P, at any depth provided it has F as its focus-setting container, is a context item expression, an axis expression, or a call on a focus-dependent function
then the posture is striding and the sweep is the sweep of B.
Note:
This rule captures cases where it can be statically determined that
the predicate is numeric and is independent of the focus. In such
cases, the filter expression selects at most one node, and the posture
can therefore be changed from crawling to striding (if there is only
one node, there can be no overlapping trees). Examples of filter
expressions that satisfy this test are (//x)[3]
,
(//x)[$i+1]
, (//x)[index-of($a,
$b)[last()]]
, and (//x)[1 to 5]
. The last
example will actually raise a type error because 1 to 5
has no effective boolean value; but if expressions are going to fail,
it does not matter what their streamability properties are.
If P is motionless, then the posture and sweep of B;
Note:
This includes the case where B is grounded. The predicate
P is assessed with the posture of B as its
context posture, and if this is grounded, then P will
almost invariably be motionless, making the filter expression as a
whole grounded and motionless. For example if $s
is
grounded, then $s[child::*]
is also grounded. A
counter-example is the expression $s[$n = 2]
where
$n
is a reference to the first argument of a stylesheet function
that is declared-streamable: here the predicate is
not motionless, so the filter expression is roaming and
free-ranging.
Otherwise, roaming and free-ranging.
Note:
The first rule allows a construct such as <xsl:apply-templates
select="(//title)[1]"/>
, where a crawling
operand would not be guaranteed streamable.
Note:
This section is not applicable to predicates forming part of an axis step,
such as //title[1]
, as these are not technically filter
expressions. See 19.8.8.9 Streamability of Axis Steps.
Note:
This section applies to dynamic function calls written using the traditional
syntax $F(X, Y, Z)
and equally to those using the new XPath 3.1 syntax X => $F(Y, Z)
The posture and sweep of a dynamic
function call such as $F(X, Y)
are determined by the 19.8.1 General Rules for Streamability. The operands and their usages are as
follows:
The base expression that computes the function value itself (here
$F
). This has usage inspection.
The argument expressions excluding any
?
placeholders (here X
and
Y
). These have type-determined usage
dependent on ancillary information
associated with the static type of the base
expression, where available (see 19.1 Determining the Static Type of a Construct). If this information indicates
that the base expression is a function with signature
function(A, B, ...) as R
, then the first argument
X
has type-determined usage based on
the first argument type A
, the second argument
Y
has type-determined usage based on
the second argument type B
, and so on. If no function signature is available, then the
usage of each of the argument expressions is navigation.
Note:
As explained in 10.3.6 Dynamic Access to Functions, use of a dynamic function
call where the function value is bound to a focus-dependent function such as
name#0
, lang#1
, or last#0
is
likely to lead to a dynamic error if the context item is a node in a
streamed document, but this does not affect the static streamability
analysis.
Note:
Maps and arrays are functions, and it is possible to look up a value in a map
or array using a dynamic function call of the form $map($key)
or
$array($index)
. If it is statically known that the function in question
is a map or array, then it is also known that the argument type is xs:anyAtomicType
,
and that the operand usage is therefore absorption. A call that
passes a streamed node will therefore be grounded and consuming.
However, if it is not known statically that the function is a map or array, then the
expression
will generally be roaming and free-ranging.
This means it is desirable to declare the type of any variable holding a map or array.
If streamable nodes are used to lookup a value in a map or array, then it may be advisable
to use
the map:get
or array:get
functions explicitly; or, if XPath 3.1 is available,
the lookup operator (?
).
For variable references that are bound to the streaming parameter of a declared-streamable stylesheet function, see the rules for the streamability category of the containing function, under 19.8.5 Classifying Stylesheet Functions.
In all other cases, variable references are grounded and motionless.
The posture of the expression is the context posture, and the sweep is motionless.
Note:
Although .
is intrinsically motionless, when used in certain
contexts (such as data(.)
) the containing expression will be
consuming. This arises because of the operand usage: the argument to data
FO30 has
usage absorption, and the combination of a motionless operand with usage absorption
leads to the containing expression being consuming.
Similarly, if .
is used where the operand usage is navigation, the
containing expression will be free-ranging.
Note:
This section applies to static function calls written using the traditional
syntax F(X, Y, Z)
and equally to those using the new XPath 3.1 syntax X => F(Y, Z)
For calls to built-in functions, see 19.8.9 Classifying Calls to Built-In Functions.
For calls to stylesheet functions, see 19.8.5 Classifying Stylesheet Functions.
For partial function applications (where one or more of the arguments is
supplied as a ?
placeholder), see the rules at the end of this
section.
For a call to a constructor function, the 19.8.1 General Rules for Streamability apply. There is a single operand role (the argument to the function), with operand usage absorption.
For a call to an extension function, the posture and sweep are implementation-defined.
If the function call is a partial function
application (that is, if one or more of the arguments is given as a
?
placeholder), then:
If the function is focus-dependent and the context posture is not grounded, then the function call is roaming and free-ranging.
If the target of the function call is a
stylesheet function
that is declared-streamable, and if the first argument is actually
supplied (that is, this argument is not supplied as a ?
placeholder), and if the expression
that is supplied as the first argument is not grounded, then the function call is roaming and free-ranging.
If the target is an extension function, the posture and sweep are implementation-defined.
Otherwise, the general streamability rules apply.
The operands of a partial function
application are the expressions actually supplied as arguments to the
function, ignoring ?
place-holders; the corresponding
operand usage is the type-determined usage based on the declared type of that
argument.
Let F be the function to which the NamedFunctionRef
refers.
If F is focus-dependent and the
context posture is not grounded, then the NamedFunctionRef
is roaming and free-ranging.
If F is an extension function, the posture and sweep are implementation-defined.
Otherwise, the NamedFunctionRef
is grounded and
motionless.
Note:
The main intent behind these rules is to ensure that the function item returned by a named function reference does not encapsulate a reference to a streamed node.
In the case of an expression such as local-name#0
,
implementations might be able to do better by pre-evaluating the function at
the point where the named function reference occurs.
In the case of extension functions, implementations may be able to distinguish whether the function is focus-dependent, and decide the streamability of the named function reference accordingly.
An inline function declaration that textually contains a variable reference bound to a streaming parameter (of some containing stylesheet function) is roaming and free-ranging.
All other inline function declarations are grounded and motionless.
Note:
It is not possible to pass a streamed node as an argument to a call to an inline function unless the declared type of the corresponding function parameter causes the node to be atomized: see 19.8.8.11 Streamability of Dynamic Function Calls. The only other way an inline function could access a streamed node is by having the streamed node in its closure, and this is prevented by the rule above.
The posture and sweep of a map
constructor (see 21.4 Map Constructors) are the same as the
posture and sweep of the equivalent
xsl:map
instruction. The equivalent
xsl:map
instruction is formed by creating a sequence of
xsl:map-entry
instructions, one for each key/value pair in
the map expression, where the key expression becomes the value of
xsl:map-entry/@key
, and the value expression becomes the value
of xsl:map-entry/@select
; this sequence of
xsl:map-entry
instructions is then wrapped in an
xsl:map
parent instruction.
For example, the map constructor map{'red':false(),
'green':true()}
translates to the instruction:
<xsl:map> <xsl:map-entry key="'red'" select="false()"/> <xsl:map-entry key="'green'" select="true()"/> </xsl:map>
The rules for the streamability of xsl:map
appear in 19.8.4.23 Streamability of xsl:map.
See also 21.6 Maps and Streaming.
Lookup expressions for maps are defined in 21.5 The Map Lookup Operator, and are available in XSLT 3.0 whether or not XPath 3.1 is supported. Lookup expressions for arrays are defined in the XPath 3.1 specification (see Section 3.11.3 The Lookup Operator ("?") for Maps and Arrays XP31), and are available only in XSLT 3.0 processors that provide the XPath 3.1 Feature (see 27.7 XPath 3.1 Feature).
For the unary lookup operator, the posture and sweep
of the expression ?X
are
defined to be the same as the posture and sweep
of the postfix lookup expression .?X
.
For the postfix lookup expression E?K
, the general streamability rules apply as follows:
In the wildcard form of the expression, E?*
, there is only one operand, E
.
This has operand usage inspection.
Where the construct K
is an NCName, the expression E?NAME
is treated as
equivalent to E?("NAME")
.
Where the construct K
is an integer, the expression E?N
is treated as
equivalent to E?(N)
.
In the general case where K
is a parenthesized expression, the lookup expression
E?(K)
has two operands. The first operand E
has operand usage
inspection, while the second operand K
has operand usage
absorption.
This section describes the rules that determine the streamability of calls to built-in functions. These differ from user-written functions because it is known (defined in the specification) how nodes supplied as operands are used. Knowledge of the usage of each operand, together with the posture of the actual operands, is in most cases enough to determine the posture and sweep of the function result.
All the built-in functions are listed below. For most functions, a simple proforma
is shown that indicates the operand usage of each argument, using the code (A =
absorption, I = inspection, T =
transmission, N = navigation). So, for
example, the entry fn:remove(T, A)
means that for the function
fn:remove#2
, the operand usage of the first
argument is transmission, and the operand usage of the second argument is absorption. By reference to the general rules in 19.8.1 General Rules for Streamability, this demonstrates that if the context posture is striding, the posture and sweep of the expression
sum(remove(*,1))
will be grounded
and
consuming
respectively.
For functions that default one of their arguments (typically to the context item), the relevant entry shows the equivalence, and the posture and sweep can in these cases be computed by filling in the default value for the relevant argument.
Some functions do not follow the general rules, and these are listed with a link to the section where the particular rules for that function are described.
array:append(I, N)
array:filter(I, I)
array:flatten(A)
array:fold-left(I, N, I)
array:fold-right(I, N, I)
array:for-each(I, I)
array:for-each-pair(I, I, I)
array:get(I, A)
array:head(I)
array:insert-before(I, A, N)
array:join(I)
array:put(I, I, N)
array:remove(I, A)
array:reverse(I)
array:size(I)
array:sort(I)
array:sort(I, A)
array:sort(I, A, I)
array:subarray(I, A)
array:subarray(I, A, A)
array:tail(I)
fn:abs(A)
fn:accumulator-after
– See 19.8.9.1 Streamability of the accumulator-after Function
fn:accumulator-before
– See 19.8.9.2 Streamability of the accumulator-before Function
fn:adjust-date-to-timezone(A)
fn:adjust-date-to-timezone(A, A)
fn:adjust-dateTime-to-timezone(A)
fn:adjust-dateTime-to-timezone(A, A)
fn:adjust-time-to-timezone(A)
fn:adjust-time-to-timezone(A, A)
fn:analyze-string(A, A)
fn:analyze-string(A, A, A)
fn:apply(A, I)
fn:available-environment-variables()
fn:available-system-properties()
fn:avg(A)
fn:base-uri()
– Equivalent to fn:base-uri(.)
fn:base-uri(I)
fn:boolean(I)
fn:ceiling(A)
fn:codepoint-equal(A, A)
fn:codepoints-to-string(A)
fn:collation-key(A)
fn:collation-key(A, A)
fn:collection()
fn:collection(A)
fn:compare(A, A)
fn:compare(A, A, A)
fn:concat(A, A, A)
fn:contains(A, A)
fn:contains(A, A, A)
fn:contains-token(A, A)
fn:contains-token(A, A, A)
fn:copy-of()
– Equivalent to fn:copy-of(.)
fn:copy-of(A)
fn:count(I)
fn:current
– See 19.8.9.3 Streamability of the current Function
fn:current-date()
fn:current-dateTime()
fn:current-group
– See 19.8.9.4 Streamability of the current-group Function
fn:current-grouping-key
– See 19.8.9.5 Streamability of the current-grouping-key
Function
fn:current-merge-group
– See 19.8.9.6 Streamability of the current-merge-group
Function
fn:current-merge-key
– See 19.8.9.7 Streamability of the current-merge-key Function
fn:current-output-uri()
fn:current-time()
fn:data()
– Equivalent to fn:data(.)
fn:data(A)
fn:dateTime(A, A)
fn:day-from-date(A)
fn:day-from-dateTime(A)
fn:days-from-duration(A)
fn:deep-equal(A, A)
fn:deep-equal(A, A, A)
fn:deep-equal(A, A)
fn:deep-equal(A, A, A)
fn:default-collation()
fn:default-language()
fn:distinct-values(A)
fn:distinct-values(A, A)
fn:doc(A)
fn:doc-available(A)
fn:document(A)
fn:document(A, I)
fn:document-uri()
– Equivalent to fn:document-uri(.)
fn:document-uri(I)
fn:element-available(A)
fn:element-with-id(x)
– Equivalent to fn:element-with-id(x, .)
fn:element-with-id(A, N)
fn:empty(I)
fn:encode-for-uri(A)
fn:ends-with(A, A)
fn:ends-with(A, A, A)
fn:environment-variable(A)
fn:error()
– Equivalent to fn:error(x, x, x, x, x, .)
fn:error(x)
– Equivalent to fn:error(x, x, x, x, .)
fn:error(x, x)
– Equivalent to fn:error(x, x, .)
fn:error(A, A, N)
fn:escape-html-uri(A)
fn:exactly-one(T)
fn:exists(I)
fn:false()
fn:filter(N, I)
fn:floor(A)
fn:fold-left(N, A, I)
fn:fold-right
– See 19.8.9.9 Streamability of the fold-right Function
fn:for-each(N, I)
fn:for-each-pair(N, N, I)
fn:format-date(A, A)
fn:format-date(A, A, A, A, A)
fn:format-dateTime(A, A)
fn:format-dateTime(A, A, A, A, A)
fn:format-integer(A, A)
fn:format-integer(A, A, A)
fn:format-number(A, A)
fn:format-number(A, A, A)
fn:format-time(A, A)
fn:format-time(A, A, A, A, A)
fn:function-arity(A)
fn:function-available(A)
fn:function-available(A, A)
fn:function-lookup
– See 19.8.9.12 Streamability of the function-lookup Function
fn:function-name(A)
fn:generate-id()
– Equivalent to fn:generate-id(.)
fn:generate-id(I)
fn:has-children()
– Equivalent to fn:has-children(.)
fn:has-children(I)
fn:head(T)
fn:hours-from-dateTime(A)
fn:hours-from-duration(A)
fn:hours-from-time(A)
fn:id(x)
– Equivalent to fn:id(x, .)
fn:id(A, N)
fn:idref(x)
– Equivalent to fn:idref(x, .)
fn:idref(A, N)
fn:implicit-timezone()
fn:in-scope-prefixes(I)
fn:index-of(A, A)
fn:index-of(A, A, A)
fn:innermost
– See 19.8.9.13 Streamability of the innermost Function
fn:insert-before(T, A, T)
fn:iri-to-uri(A)
fn:json-doc(A)
fn:json-doc(A, I)
fn:json-to-xml(A)
fn:json-to-xml(A, I)
fn:key(x, x)
– Equivalent to fn:key(x, x, /)
fn:key(A, A, N)
fn:lang(x)
– Equivalent to fn:lang(x, .)
fn:lang(A, I)
fn:last
– See 19.8.9.14 Streamability of the last Function
fn:load-xquery-module(A)
fn:load-xquery-module(A, I)
fn:local-name()
– Equivalent to fn:local-name(.)
fn:local-name(I)
fn:local-name-from-QName(A)
fn:lower-case(A)
fn:matches(A, A)
fn:matches(A, A, A)
fn:max(A)
fn:max(A, A)
fn:min(A)
fn:min(A, A)
fn:minutes-from-dateTime(A)
fn:minutes-from-duration(A)
fn:minutes-from-time(A)
fn:month-from-date(A)
fn:month-from-dateTime(A)
fn:months-from-duration(A)
fn:name()
– Equivalent to fn:name(.)
fn:name(I)
fn:namespace-uri()
– Equivalent to fn:namespace-uri(.)
fn:namespace-uri(I)
fn:namespace-uri-for-prefix(A, I)
fn:namespace-uri-from-QName(A)
fn:nilled()
– Equivalent to fn:nilled(.)
fn:nilled(I)
fn:node-name()
– Equivalent to fn:node-name(.)
fn:node-name(I)
fn:normalize-space()
fn:normalize-space(A)
fn:normalize-unicode(A)
fn:normalize-unicode(A, A)
fn:not(I)
fn:number()
– Equivalent to fn:number(.)
fn:number(A)
fn:one-or-more(T)
fn:outermost
– See 19.8.9.15 Streamability of the outermost Function
fn:parse-ietf-date(A)
fn:parse-json(A)
fn:parse-json(A, I)
fn:parse-xml(A)
fn:parse-xml-fragment(A)
fn:path()
– Equivalent to fn:path(.)
fn:path(N)
fn:position
– See 19.8.9.16 Streamability of the position Function
fn:prefix-from-QName(A)
fn:QName(A, A)
fn:random-number-generator()
fn:random-number-generator(A)
fn:regex-group(A)
fn:remove(T, A)
fn:replace(A, A, A)
fn:replace(A, A, A, A)
fn:resolve-QName(A, I)
fn:resolve-uri(A)
fn:resolve-uri(A, A)
fn:reverse
– See 19.8.9.17 Streamability of the reverse Function
fn:root
– See 19.8.9.18 Streamability of the root Function
fn:round(A)
fn:round(A, A)
fn:round-half-to-even(A)
fn:round-half-to-even(A, A)
fn:seconds-from-dateTime(A)
fn:seconds-from-duration(A)
fn:seconds-from-time(A)
fn:serialize(A)
fn:serialize(A, A)
fn:snapshot()
– Equivalent to fn:snapshot(.)
fn:snapshot(A)
fn:sort(N)
fn:sort(N, A)
fn:sort(N, A, I)
fn:starts-with(A, A)
fn:starts-with(A, A, A)
fn:static-base-uri()
fn:stream-available(A)
fn:string()
– Equivalent to fn:string(.)
fn:string(A)
fn:string-join(A)
fn:string-join(A, A)
fn:string-length()
fn:string-length(A)
fn:string-to-codepoints(A)
fn:subsequence(T, A)
fn:subsequence(T, A, A)
fn:substring(A, A)
fn:substring(A, A, A)
fn:substring-after(A, A)
fn:substring-after(A, A, A)
fn:substring-before(A, A)
fn:substring-before(A, A, A)
fn:sum(A)
fn:sum(A, A)
fn:system-property(A)
fn:tail(T)
fn:timezone-from-date(A)
fn:timezone-from-dateTime(A)
fn:timezone-from-time(A)
fn:tokenize(A)
fn:tokenize(A, A)
fn:tokenize(A, A, A)
fn:trace(A)
fn:trace(T, A)
fn:transform(I)
fn:translate(A, A, A)
fn:true()
fn:type-available(A)
fn:unordered(T)
fn:unparsed-entity-public-id(x)
– Equivalent to fn:unparsed-entity-public-id(x, /)
fn:unparsed-entity-public-id(A, I)
fn:unparsed-entity-uri(x)
– Equivalent to fn:unparsed-entity-uri(x, /)
fn:unparsed-entity-uri(A, I)
fn:unparsed-text(A)
fn:unparsed-text(A, A)
fn:unparsed-text-available(A)
fn:unparsed-text-available(A, A)
fn:unparsed-text-lines(A)
fn:unparsed-text-lines(A, A)
fn:upper-case(A)
fn:uri-collection()
fn:uri-collection(A)
fn:xml-to-json(A)
fn:xml-to-json(A, I)
fn:year-from-date(A)
fn:year-from-dateTime(A)
fn:years-from-duration(A)
fn:zero-or-one(T)
map:contains(I, A)
map:entry(A, N)
map:find(I, A)
map:for-each(I, I)
map:get(I, A)
map:keys(I)
map:merge(I)
map:merge(I, I)
map:put(I, A, N)
map:remove(I, A)
map:size(I)
math:acos(A)
math:asin(A)
math:atan(A)
math:atan2(A, A)
math:cos(A)
math:exp(A)
math:exp10(A)
math:log(A)
math:log10(A)
math:pi()
math:pow(A, A)
math:sin(A)
math:sqrt(A)
math:tan(A)
accumulator-after
FunctionSee also 18.2.9 Streamability of Accumulators.
The posture of the function call is in all cases grounded.
The sweep is determined by applying the following rules, in order:
If the first argument (the accumulator name) is not motionless, the function is free-ranging.
If the context posture is grounded, the function is motionless.
If the context item type has an empty intersection with U{document-node(), element()} (that is, if the context item cannot have children), the function is motionless.
If the function call is contained in the select
expression
or contained sequence constructor of an
xsl:accumulator-rule
specifying
phase="start"
, then it is free-ranging.
If the function call is contained in the select
expression
or contained sequence constructor of an
xsl:accumulator-rule
specifying
phase="end"
, then it is motionless.
If no enclosing node of the function call is part of a sequence constructor, then it is free-ranging. For this purpose, the enclosing nodes of a function call are the attribute or text node that immediately contains the XPath expression in which the function call appears, and its ancestors.
If the focus-setting container of the function call is different from the focus-setting container of the innermost containing instruction, then the function is free-ranging.
If no enclosing node N of the function call has a preceding sibling node P such that (a) N and P are part of the same sequence constructor, and (b) the sweep of P is consuming, then the function call is consuming. (The term enclosing node is defined above.)
Otherwise, the function call is motionless.
Note:
The following notes apply to the above rules with matching numbers:
This rule prevents the accumulator name being computed by reading the streamed source document. This is disallowed primarily because there is no conceivable use case for doing it.
If the context posture is grounded, then the target of the accumulator is not a streamed node, so no streaming restrictions apply.
If the context item is a childless node (such as a text node), then
both the pre-descent and post-descent values of the accumulator can be
computed before evaluating any user-written constructs that access
this node; there are therefore no constraints on where a call to
accumulator-after
can appear.
This rule ensures that when computing the pre-descent value of an accumulator for a particular streamed node, the post-descent values of accumulators for that node are not available.
This rule states that the post-descent value of an accumulator is allowed to depend on the post-descent values of other accumulators for the same node. There is a rule preventing cycles [see ERR XTDE3400].
This rule prevents the use of the function (when applied to a streamed
node) in contexts like the use
attribute of
xsl:key
. It
allows its use in the attributes of an instruction or literal result element, or in a text value template. It does not allow use in an
xsl:sort
or xsl:param
element,
as these elements do not form part of a sequence constructor (see
5.7 Sequence Constructors).
This rule prevents the use of the function (when applied to a streamed
node) in contexts such as predicates, or the right-hand side of the
/
operator. The focus for evaluation of the function must be the
same as the focus for a containing sequence constructor. Sequence
constructors are treated differently from all other constructs for
this purpose in that their operands (the contained instructions) are
treated as ordered: in conjunction with the next rule, this rule is
assuming that instructions in a sequence constructor that follow a
consuming instruction are evaluated after the
consuming instruction and therefore have access
to the post-descent accumulator value.
This rule is subtle, and has a number of consequences. In these notes, the term instruction should be read as including all nodes making up a sequence constructor, including XSLT instructions, extension instructions, literal result elements, and text nodes containing text value templates.
In a sequence constructor that contains a consuming instruction such as
<xsl:apply-templates/>
, it allows any
number of calls on accumulator-after
to
appear in instructions that follow the call on
<xsl:apply-templates/>
.
In such a sequence constructor it prevents a call on
accumulator-after
from appearing in an
instruction that precedes the
<xsl:apply-templates/>
, because there
would then be two consuming
instructions.
In a sequence constructor that contains calls on
accumulator-after
, and contains no other
consuming construct, the first
instruction that contains a call on
accumulator-after
is consuming (unless
it contains more than one such call, in which case it is
free-ranging), and subsequent instructions containing such a
call are motionless. So it is possible to have two or more calls
on accumulator-after
provided they appear
in different instructions, which allows the analysis to assume
an order of execution.
It prevents a call on accumulator-after
from appearing in the same instruction as another consuming
construct: for example it disallows concat(child::p,
accumulator-after('a'))
. This rule preserves the
ability to evaluate the arguments of the concat
function in any order.
It disallows a call on accumulator-after
from appearing in a sequence constructor that is required to be
motionless, for example within xsl:sort
.
The reference to a “preceding sibling node within the same
sequence constructor” is carefully worded to ensure that
preceding siblings among the children of
xsl:fork
are not taken into account; the
children of xsl:fork
are sibling instructions,
but do not constitute a sequence constructor. The term also excludes elements such as
xsl:param
and xsl:sort
that may precede a sequence constructor but are not part of
it.
The final rule states that if none of the previous rules apply, the
function is considered motionless. This applies when the
accumulator-after
appears after a consuming
instruction within the same sequence constructor.
Note also that a call to accumulator-after
can
safely appear within a construct such as a named template or
(non-streamable) stylesheet function; this is safe because the rules
ensure that in such situations, the context item cannot be a streamed
node.
Dynamic invocation of accumulator-after
is covered by the
rules in 10.3.6 Dynamic Access to Functions. These rules ensure that a function
item cannot include a streamed node in its closure; circumventing the
streamability rules for accumulator-after
by making a
dynamic call is therefore not possible.
accumulator-before
FunctionSee also 18.2.9 Streamability of Accumulators.
The posture and sweep of the function call are assessed as follows:
If the argument to accumulator-before
is motionless,
the function call is grounded and motionless.
Otherwise, the function call is roaming and free-ranging.
current
FunctionThe sweep and posture of a call to the
current
function are determined as follows:
If the call appears within a pattern, then climbing and motionless.
Note:
The call to current
will always be within a predicate of the pattern.
The use of climbing posture here allows predicates such as [@class = current()/@class]
,
while disallowing downwards navigation from the node returned by the function.
Otherwise, let E be the outermost containing XPath expression of the call
to the current
function.
If the context posture of E is grounded, then motionless and grounded.
If the path in the expression tree that connects the call on
current
to E (excluding E
itself) contains an expression that is a higher-order operand of its parent expression, then
motionless and climbing.
Note:
Many common uses of the current
, such as
//p[@class=current()/@class]
, fall into this category:
a predicate is a higher-order operand of its containing filter
expression.
The use of climbing posture here might seem
unrelated to its usual connection with the ancestor axis. The
explanation (apart from the fact that it happens to produce the right
results) lies in the fact that at the point where the
current
call is evaluated, the node it returns
will always be an ancestor-or-self of the context node, as a
consequence of the fact that the containing XPath expression is
required to be either motionless or consuming.
The effect of the rule is to allow
expressions such as //*[name() = name(current())]
or
//*[@ref = current()/@id]
.
Otherwise, the posture is the context posture, and the sweep is motionless.
current-group
FunctionThe sweep and posture of a call C to the
current-group
function are as follows:
If all the following conditions are true:
C has a containing xsl:for-each-group
instruction (call it F)
The path in the construct tree that connects C to the sequence constructor forming the body of F is such that no child construct is a higher-order operand of its parent
The focus-setting container of C is F
then the sweep and posture of
C are the sweep and posture of the select
expression of
F.
Otherwise, roaming and free-ranging.
Note:
Informally, for streamed evaluation to be possible, a call to
current-group
must not appear in a construct that is
evaluated repeatedly. For example, the expression for $i in 1 to 10
return current-group()
would not be streamable.
current-grouping-key
FunctionA call to the
current-grouping-key
function is grounded and
motionless.
current-merge-group
FunctionA call to the
current-merge-group
function is grounded and motionless.
Note:
This is because the nodes to be merged are always snapshots, and therefore grounded: see 15.4 Streamable Merging.
current-merge-key
FunctionA call to the current-merge-key
function is grounded and motionless.
fold-left
FO30 FunctionThe function call fold-left($seq, $zero, $f)
, follows the general streamability rules, with the first argument
$seq
having type-determined usage based on
the type of the second argument of the function supplied as
$f
.
For example, given the call fold-left(/*/transaction, 0, function($x as
xs:decimal, $y as xs:decimal) as xs:decimal {$x+$y})
, the operand usage of the argument /*/transaction
is
determined by the declared type of $y
, namely
xs:decimal
. Since this is an atomic type, the type-determined usage is absorption. Applying
this to the general streamability rules, the function call is grounded and consuming.
fold-right
FO30 FunctionThe function follows the general streamability rules, with the first argument having operand usage navigation to reflect the fact that the supplied sequence is processed in reverse order.
Note:
The same considerations apply as for the reverse
FO30
function: see 19.8.9.17 Streamability of the reverse Function.
for-each
FO30 FunctionThe function call for-each($seq, $f)
, follows the general streamability rules, with the first argument
$seq
having type-determined usage based on
the type of the (single) argument of the function supplied as
$f
.
For example, given the call for-each(/*/transaction, function($x as
xs:decimal) as xs:decimal {abs($x)})
, the operand usage of the argument /*/transaction
is
determined by the declared type of $x
, namely
xs:decimal
. Since this is an atomic type, the type-determined usage is absorption. Applying
this to the general streamability rules, the function call is grounded and consuming.
Note:
In practice, the filter
FO30 function is streamable if
either (a) the supplied sequence is grounded, or (b) the supplied function
is statically known to atomize its argument.
for-each-pair
FO30 FunctionThe function call for-each($seq1, $seq2, $f)
, follows the general streamability rules, where:
The first argument $seq1
has type-determined usage based on the type of the first
argument of the function supplied as $f
.
The second argument $seq2
has type-determined usage based on the type of the second
argument of the function supplied as $f
Note:
In practice, the for-each-pair
FO30 function is streamable
provided (a) at most one of the input sequences is consuming, and (b) either
(i) that input sequence is grounded, or (ii) the supplied function is
statically known to atomize the relevant argument.
If it is necessary to combine two sequences that are both streamed, consider
using xsl:merge
.
function-lookup
FO30 FunctionSee 10.3.6 Dynamic Access to Functions for special rules that relate to
streamability of calls to the function-lookup
FO30
function.
With the caveats given there, the function follows the general streamability rules, for a function with two arguments that both have operand usage absorption.
innermost
FO30 FunctionThe function follows the general streamability rules, with
the first argument having operand usage
navigation. This is to reflect the fact that the processing
is not strictly sequential: it cannot be determined that a node is part of the
result sequence of innermost
FO30 until all its descendants
have been read.
last
FO30 FunctionIf the context posture for a call on the
last
FO30 function is striding,
crawling, or roaming, then the
posture of the function is roaming,
and the sweep is free-ranging.
In all other cases the function is grounded and motionless.
Note:
The cases where last
FO30 can be used without affecting
streamability are where the context item is either grounded or climbing. The latter condition
makes expressions like ancestor::*[@xml:space][last()]
streamable.
There are special rules restricting the use of last
FO30
in the predicate of a pattern: see 19.8.10 Classifying Patterns.
Note that there are no restrictions preventing the
use of last()
when the context posture is grounded. The implications of
this are discussed in 19.7 Grounded Consuming Constructs. In the case where
the sequence being processed is delivered by a consuming expression, using last()
may result in this sequence being buffered in memory.
outermost
FO30 FunctionThe single argument to this function has operand usage transmission.
The streamability of the function call follows the general streamability rules with one exception: if the posture of the argument is crawling, then the posture of the result is striding.
Note:
There are cases where the streaming rules allow the construct
outermost(//para)
but do not allow //para
; the
function can therefore be useful in cases where it is known that
para
elements will not be nested, as well as cases where the
application actually wishes to process all para
elements except
those that are nested within another.
By contrast, the innermost
FO30 function offers no
streaming benefits. Although it delivers a subset of the input nodes as its
result, in the correct order, it is classed as navigational because it needs
to look ahead in the input stream before deciding whether a node can be
included in the result.
position
FO30 FunctionThe position
FO30 function follows the general streamability rules. Since it has no operands, this means
it is grounded and motionless.
Note:
Within an expression, there are no special difficulties in evaluating the
position
FO30 function.
It does have special treatment within a predicate of a pattern, however: a pattern is not motionless if it contains a
call to position
FO30, as explained in 19.8.10 Classifying Patterns.
reverse
FO30 FunctionThe reverse
FO30 function follows the general streamability rules, with its operand classified as
having operand usage
navigation.
Note:
This means in effect that a call on reverse
FO30 is not
streamable unless the operand is grounded. This may cause few surprises:
The expression reverse(/*/emp/copy-of())
is considered
streamable, although all the emp
elements will typically
need to be in memory at the same time. The explanation here is that
the streamability rules do not attempt to restrict the amount of
memory used for data that is explicitly copied by use of a function
such as copy-of
.
The expression reverse(ancestor::*)/name()
is considered
non-streamable, because the operand is not grounded. This problem can
be circumvented by rewriting the expression as
reverse(ancestor::*/name())
root
FO30 FunctionThe zero-argument function root()
is equivalent to
root(.)
.
Given the expression root(X)
, if the static type of X
is U{document-node()}, and if its posture is striding, then
root(X)
is rewritten as X
. Otherwise, it is
rewritten as head((X)/ancestor-or-self::node())
. Streamability
analysis is then applied to the rewritten expression.
Note:
Because path expressions starting with /
are rewritten to use
the root
FO30 function, this ensures that a leading slash
is ignored if the context item is a document node, for example within a
template rule with match="/"
. This improves streamability,
because upwards navigation followed by downward navigation is
disallowed.
Note:
Patterns differ from other kinds of construct in that they are not composable in the same way. It is best to think of a pattern as specialized syntax for a function that takes an item as its argument and returns a boolean: true if the pattern matches the item, otherwise false. The static type of a pattern is therefore taken as U{xs:boolean} (this is not to be confused with the type of the items that the pattern is capable of matching).
The sweep of a pattern is either motionless or free-ranging. (Although there are patterns that could in principle be evaluated by consuming the element node that they match, these are of no interest in the analysis, so they are classified as free-ranging.)
The posture of a pattern is grounded if the pattern is motionless, or roaming otherwise. (This reflects the fact that a pattern always returns a boolean result; it never returns a node in a streamed document.)
Informally, a motionless pattern is one that can be evaluated by a streaming processor when the input stream is positioned at the start of the node being matched, without advancing the input stream.
A pattern is motionless if and only if it satisfies all the following conditions:
The pattern does not contain a RootedPath.
If the pattern contains predicates, then every top-level
Predicate
in the pattern satisfies all the following
conditions:
The expression immediately contained in the predicate is motionless, when assessed with a context posture of striding, and a context item type set to the static type of the expression to which the predicate applies, determined using the rules in 19.1 Determining the Static Type of a Construct.
The predicate is a non-positional predicate.
The use of the term top-level in this rule means that predicates that are nested within other predicates do not themselves have to be non-positional, though they may play a role in the analysis of top-level predicates.
The pattern does not contain (at any depth) a variable reference that is bound to a streaming parameter. (See 19.8.8.14 Streamability of Static Function Calls).
[Definition: A predicate is a non-positional predicate if it satisfies both of the following conditions:
The predicate does not contain a function call or named function reference to any of the following functions, unless that call or reference occurs within a nested predicate:
position
FO30
last
FO30
function-lookup
FO30.
Note:
The exception for nested predicates is there to ensure that patterns
such as match="p[@code = $status[last()]]
are not disqualified.
The expression immediately contained in the predicate is a non-numeric expression. An expression is non-numeric if the intersection of its static type (see 19.1 Determining the Static Type of a Construct) with U{xs:decimal, xs:double, xs:float} is U{}.
]
Note:
A non-positional predicate can be evaluated by considering each item in the filtered sequence independently; the result never depends on the position of other items in the sequence or the length of the sequence.
A pattern that is not motionless is classified as free-ranging.
The following list shows examples of motionless patterns:
/
*
/*
p
p|q
p/q
p[@status='red']
p[base-uri()]
p[@class or @style]
p[@status]
p[@status = $status-codes[1]]
p[@class | @style]
p[contains(@class, ':')]
p[substring-after(@class, ':')]
p[ancestor::*[@xml:lang]]
text()[starts-with(., '$')]
@price
@price[starts-with(., '$')]
//p/text()[. = 'Introduction']
document-node(element(html))
(Note:
this is classified as motionless even though testing a document node against
the pattern might require a small amount of look-ahead.)
The following list shows examples of patterns that are not motionless, explaining why not:
id('abc')
(contains a RootedPath
)
$doc//p
(contains a RootedPath
)
p[b]
(the predicate is not motionless)
p[. = 'Introduction']
(the predicate is not motionless)
p[starts-with(., '$')]
(the predicate is not motionless)
p[preceding-sibling::p[1] = '']
(the predicate is not
motionless)
p[1]
(contains a positional predicate: return type is
numeric)
p[$pnum + 1]
(contains a positional predicate: return type is
numeric)
p[data(@status)]
(contains a positional predicate: return type
is potentially numeric)
p[position() gt 2]
(contains a positional predicate: calls
position()
)
p[last()]
(contains a positional predicate: calls
last()
)
The examples in this section are intended to illustrate how the streamability rules are applied “top down” to establish whether template rules are guaranteed streamable.
Consider the following template rule, where mode s
is defined with
streamable="yes"
:
<xsl:template match="para" mode="s"> <div class="para"> <xsl:apply-templates mode="s"/> </div> </xsl:template>
The processor is required to establish that this template meets the streamability rules. Specifically, as stated in 6.6.4 Streamable Templates, it must satisfy three conditions:
The match pattern must be motionless.
The body of the template rule must be grounded.
The initializers of any template parameters must be motionless.
The third condition is satisfied trivially because there are no parameters.
The first rule depends on the rules for assessing patterns, which are given in
19.8.10 Classifying Patterns. This pattern is motionless because (a)
it does not contain a RootedPath
, and (b) it contains no
predicates.
So it remains to determine that the body of the template is grounded. The proof of this is as follows:
The sequence constructor forming the body of the template is assessed
according to the rules in 19.8.3 Classifying Sequence Constructors, which tell us that there is a single operand (the
<div>
literal result element) which has operand usage
U = transmission.
The assessment of the sequence constructor uses the general streamability rules. These rules require us to determine the type T, sweep S, posture P, and usage U of each operand. We have already established that there is a single operand, with U = transmission. Section 19.1 Determining the Static Type of a Construct tells us that for all instructions, we can take T = U{*}. The posture P and sweep S of the literal result element are established as follows:
The rules for literal result elements (specifically the
<div>
element) are given in 19.8.4.1 Streamability of Literal Result Elements. This particular
literal result element has only one operand (its contained sequence
constructor), with operand usage
U = absorption.
The general streamability rules again apply. Again
the static type
T of the operand is U{*}
, and we need to
determine the posture
P and sweep
S.
To determine the posture and sweep of this sequence constructor (the
one that contains the xsl:apply-templates
instruction) we refer again to the general streamability rules.
The sequence constructor has a single operand (the
xsl:apply-templates
instruction); again
U = transmission, T
= U{*}.
The posture
P and sweep
S of the xsl:apply-templates
instruction are established as follows:
The rules that apply are in 19.8.4.5 Streamability of xsl:apply-templates.
Rule 1 does not apply because the select
expression (which defaults to child::node()
)
is not grounded. This is a consequence
of the rules in 19.8.8.9 Streamability of Axis Steps, specifically:
The context posture of the axis step is established by the template rule as a whole, as striding.
Therefore rules 1 and 2 do not apply.
The statically-inferred context item type is derived
from the match pattern (match="para"
).
This gives a type of U{element()}. The
child axis for element nodes is not necessarily
empty, so rule 3 does not apply.
Rule 4 does not apply because there are no predicates.
So the posture and sweep of the axis step
child::node()
are given by the table
in rule 5. The entry for (context posture =
striding, axis = child) gives a posture of striding and a sweep of consuming.
So the select
expression is not
grounded. (The same result can
be reached intuitively: an expression that selects
streamed nodes will never be grounded.)
Rule 2 does not apply because there is no
xsl:sort
element.
Rule 3 does not apply because the mode is declared with
streamable="yes"
.
So the posture
P and sweep
S of the xsl:apply-templates
instruction are established by the general streamability rules, as follows:
There is a single operand, the implicit
select="child::node()"
expression,
with usage U = absorption.
We have already established that for this operand, the posture P = striding and the sweep S = consuming.
By the rules in 19.1 Determining the Static Type of a Construct, the type
T of the select
expression
is node()
.
In the general streamability rules, the adjusted sweep S′ for an operand with (P = striding, U = absorption) is consuming,
Rule 2(d) then applies, so the
xsl:apply-templates
instruction
is consuming and grounded.
So the sequence constructor that contains the
xsl:apply-templates
instruction has one
operand with U = transmission,
T = item()
, P = grounded, S = consuming. Rule 2(d) of the general streamability rules applies, so the
sequence constructor itself has P = grounded, S = consuming.
So the literal result element has one operand with U =
absorption, T = item()
,
P = grounded, S =
consuming. Rule 2(d) of the general streamability rules applies, so the literal
result element has P = grounded,
S = consuming.
So the sequence constructor containing the literal result element has one
operand with U = transmission, T =
item()
, P = grounded,
S = consuming. Rule 2(d) of the general streamability rules applies, so this sequence
constructor itself has P = grounded,
S = consuming.
So we have established that the sequence constructor forming the body of the template rule is grounded.
Therefore, since the other conditions are also satisfied, the template is guaranteed-streamable.
The analysis presented above could have been simplified by taking into account the fact that the streamability properties of a sequence constructor containing a single instruction are identical to the properties of that instruction. This simplification will be exploited in the next example.
Consider the following template rule, where mode s
is defined with
streamable="yes"
:
<xsl:template match="transactions[@currency='USD']" mode="s"> <total><xsl:value-of select="sum(transaction/@value)"/></total> </xsl:template>
Again, as stated in 6.6.4 Streamable Templates, it must satisfy three conditions:
The match pattern must be motionless.
The body of the template rule must be grounded.
The initializers of any template parameters must be motionless.
The third condition is satisfied trivially because there are no parameters.
The first rule depends on the rules for assessing patterns, which are given in
19.8.10 Classifying Patterns. This pattern is motionless because (a)
it is not a RootedPath
, and (b) every predicate is motionless and non-positional. The analysis that proves the predicate is motionless
and non-positional proceeds as follows:
First establish that that the expression @currency='USD'
is
motionless, as follows:
The predicate is a general comparison (GeneralComp
) which
follows the general streamability rules.
There are two operands: an AxisStep
with a defaulted
ForwardAxis
, and a Literal
. Both operand
roles are absorption.
The left-hand operand has
type T = attribute()
. Its posture and sweep are determined by
the rules in 19.8.8.9 Streamability of Axis Steps. The
context posture is striding, so the posture and sweep
are determined by the entry in the table (rule 5) with context posture
= striding, axis = attribute
: that
is, the result posture is striding and the sweep
is motionless.
The right-hand operand, being a literal, is grounded and motionless.
In the general streamability rules, rule 2(e) applies, so the predicate is grounded and motionless
Now establish that that the expression @currency='USD'
is
non-positional, as
follows:
Rule 1 is satisfied: the predicate does not call
position
FO30, last
FO30, or
function-lookup
FO30.
Rule 2 is satisfied: the expression @currency='USD'
is
non-numeric. The static type of the expression is
determined using the rules in 19.1 Determining the Static Type of a Construct
as U{xs:boolean}, and this has no intersection with
U{xs:decimal, xs:double, xs:float}.
So both conditions in 19.8.10 Classifying Patterns are satisfied, and the pattern is therefore motionless.
It remains to show that the body of the template rule is grounded. The proof of this is as follows. Unlike the previous example, the analysis is shown in simplified form; in particular the two sequence constructors which each contain a single instruction are ignored, and replaced in the construct tree by their contained instruction.
We need to show that the <total>
literal result element is grounded.
The rules that apply are in 19.8.4.1 Streamability of Literal Result Elements.
These rules refer to the general streamability rules.
There is one operand, the xsl:value-of
child element, which
has operand usage
U = absorption, and type T =
item()
.
So we need to determine the posture and sweep of the xsl:value-of
instruction.
The rules are given in 19.8.4.40 Streamability of xsl:value-of.
The general streamability rules apply. There is
one operand, the expression sum(transaction/@value)
,
which has operand usage
U = absorption.
The type T of this operand is the return type defined in
the signature of the sum
FO30 function, that is,
xs:anyAtomicType
.
The posture P and sweep S are established as follows:
The rules that apply to the call on sum
FO30
are given in 19.8.9 Classifying Calls to Built-In Functions.
The relevant proforma is fn:sum(A)
, indicating that
the general streamability rules apply, and
that there is a single operand with usage U =
absorption.
The type T of the operand
transaction/@value
is determined (by the rules
in 19.1 Determining the Static Type of a Construct) as
attribute()
.
The posture
P and sweep
S of the operand transaction/@value
are
determined by the rules in 19.8.8.8 Streamability of Path Expressions, as follows:
The expression is expanded to
child::transaction/attribute::value
.
The posture and sweep of the left-hand operand
child::transaction
are determined by the
rules in 19.8.8.9 Streamability of Axis Steps, as
follows:
The context posture is striding, because the focus-setting container is the template rule itself.
The context item type is
element()
, based on the match type of the pattern
match="transactions[@currency='USD']"
.
Rules 1 and 2 do not apply because the context posture is striding.
Rule 3 does not apply because the child
axis applied to an element node is not necessarily
empty.
Rule 4 does not apply because there are no predicates.
Rule 5 applies, and the table entry with context
posture = striding, axis =
child
gives a result posture of striding
and a sweep of consuming.
The posture of the relative path
expression
child::transaction/attribute::value
is
therefore the posture of its right-hand operand
attribute::value
, assessed with a context posture of striding. This is determined by the rules in
19.8.8.9 Streamability of Axis Steps, as
follows:
The context posture, as we have seen, is striding.
The context item type is
element()
, based on the type of the
left-hand operand
child::transaction
.
Rules 1 and 2 do not apply because the context posture is striding.
Rule 3 does not apply because the
attribute
axis applied to an element
node is not necessarily empty.
Rule 4 does not apply because there are no predicates.
Rule 5 applies, and the table entry with context
posture = striding, axis =
attribute
gives a result posture of striding and a sweep of
motionless.
The posture of the relative path
expression
child::transaction/attribute::value
is
therefore striding.
The sweep of the relative path
expression
child::transaction/attribute::value
is the
wider of the sweeps of its two operands, namely consuming and motionless. That is, it is consuming.
So the first and only operand to the call on sum()
has U = absorption, T
= attribute()
, P = climbing, and S = consuming
Rule 1(b) of the general streamability rules computes the adjusted sweep S′. Rule 1(b)(iii)(A) applies, so the effective operand usage U′ is inspection. Rule 1(b)(iii)(A) then computes the adjusted sweep from the table entry for P = climbing, U′ = inspection; this shows S′ = S, that is, consuming.
Rule 2(d) now applies, so the call on sum()
is
grounded and consuming.
Since the xsl:value-of
instruction has one operand
with U = absorption, T =
xs:anyAtomicType
, P = grounded, and S = consuming, rule 2(d) again applies, and the xsl:value-of
instruction is grounded and consuming.
Since the literal result element has one operand with U =
absorption, T = item()
,
P = grounded, and S = consuming, rule 2(d) again applies, and the literal result
element is grounded and consuming.
Therefore the body of the template rule is grounded, and since the other conditions are also satisfied, it is guaranteed-streamable.
Consider the following code, which is designed to process a transaction file containing transactions in chronological order, and output the total value of the transactions for each day.
<xsl:template name="go"> <out> <xsl:source-document streamable="yes" href="transactions.xml"> <xsl:for-each-group select="/account/transaction" group-adjacent="xs:date(@timestamp)"> <total date="{current-grouping-key()}" value="{sum(current-group()/@value)}"/> </xsl:for-each-group> </xsl:source-document> </out> </xsl:template>
The rules for xsl:source-document
say that the instruction is guaranteed-streamable if the contained sequence constructor is grounded, and the task
of streamability analysis is to prove that this is the case. As in the previous
example, we will take a short-cut by making the assumption that a sequence
constructor containing a single instruction can be replaced by that instruction in
the construct tree.
So the task is to show that the xsl:for-each-group
instruction is
grounded, which we can do as follows:
The relevant rules are to be found in 19.8.4.19 Streamability of xsl:for-each-group.
Note:
Rule numbers may be different in a version of the specification with change markings.
Rule 1 applies only if the select
expression is grounded. It is easy to see informally that this is not the
case (an expression that returns streamed nodes is never grounded). More
formally:
The select
expression is a path expression; the rules in
19.8.8.8 Streamability of Path Expressions apply.
The expression is rewritten as ((root(.) treat as
document-node())/child::account)/child::transaction
The left-hand operand (root(.) treat as
document-node())/child::account
is also a path expression,
so the rules in 19.8.8.8 Streamability of Path Expressions
apply recursively:
The left-hand operand root(.) treat as
document-node()
follows the rules for a
TreatExpr
in 19.8.8 Classifying Expressions; the proforma T treat
as TYPE
indicates that the general streamability rules apply with a single
operand having usage transmission.
This single operand root(.)
follows the rules in
19.8.9.18 Streamability of the root Function. The item type of the
operand .
is the context item type, which is the type established
by the xsl:source-document
instruction, namely
document-node()
. Under these conditions
root(.)
is rewritten as .
, so the
posture is the context posture established by the
xsl:source-document
instruction, namely striding. The sweep is
motionless.
The posture and sweep of
the expression root(.) treat as document-node()
are
the same as the posture and sweep of root(.)
, namely striding and motionless
The right-hand operand child::account
is governed
by the rules in 19.8.8.9 Streamability of Axis Steps.
The context posture is striding, and the axis is child
, so
the result posture is striding and the sweep
is consuming.
The posture of the path expression is the posture of the right-hand operand, that is striding, and its sweep is the wider sweep of the two operands, that is consuming
Returning to the outer path expression, the posture of the right hand operand child::transaction
is
striding, and its sweep is consuming.
So the posture of the select
expression as a whole is the posture of the right hand operand, that
is striding; and its sweep is the wider of the
sweeps of the operands, which is consuming.
Rule 2 does not apply: there is no group-by
attribute.
Rule 3 does not apply: there is a group-adjacent
attribute, but
it is motionless. The reasoning is as follows:
The value is a call to the constructor function xs:date
.
The rules in 19.8.8.14 Streamability of Static Function Calls apply.
There is a single operand, whose required type is atomic, so the
operand usage is absorption.
These rules refer to the general streamability rules, so we need to determine the context item type,
posture, and sweep of the
operand expression @timestamp
. This is done as
follows:
The expression is an AxisStep
, so the relevant
rules are in 19.8.8.9 Streamability of Axis Steps.
The context posture is the posture of the controlling operand of the focus-setting container, that is, is the
select
expression of the containing
xsl:for-each-group
instruction, which as
established above is striding. The context item type is similarly the inferred type
of the select
expression, and is
element()
.
Rules 1 and 2 do not apply because the context posture is striding.
Rule 3 does not apply because the attribute axis for an element node is not necessarily empty.
Rule 4 does not apply because there is no predicate.
So the sweep and posture
of the expression @timestamp
are given by the table
in Rule 5 as striding and motionless.
Returning to the general streamability rules for
the expression xs:date(@timestamp)
, the operand @timestamp
has U = absorption, T =
attribute()
, P = striding, S
= motionless.
Under Rule 1(b)(iii)(A), because T =
attribute()
, the operand usage
U′ becomes inspection.
Under Rule 1(b)(iii)(A), S′ = S = motionless.
Under Rule 2(e), the expression xs:date(@timestamp)
is
grounded and motionless.
Rule 4 (under xsl:for-each-group
) does not apply, because
there is no xsl:sort
child.
So Rule 5 applies. This relies on knowing the posture of
the sequence constructor contained in the
xsl:for-each-group
instruction: that is, the posture of the total
literal result element. This is calculated as
follows:
The rules that apply are in 19.8.4.1 Streamability of Literal Result Elements. The general streamability rules apply; there are two
operands, the attribute value templates
{current-grouping-key()}
and
{sum(current-group()/@value)}
, and in each case the
usage is absorption. We can simplify the analysis
by observing that the empty sequence constructor
contained in the literal result element can be ignored, since it is
grounded and motionless.
Consider first the operand {current-grouping-key()}
.
Section 19.8.7 Classifying Value Templates applies. This refers to
the general streamability rules; there is a
single operand, the expression
current-grouping-key()
, with usage absorption.
Section 19.8.9.5 Streamability of the current-grouping-key Function applies. This establishes that the expression is grounded and motionless.
It follows that the operand
{current-grouping-key()}
expression is also
grounded and motionless.
Now consider the operand
{sum(current-group()/@value)}
.
Section 19.8.7 Classifying Value Templates applies. This refers to the
general streamability rules; there is a single
operand, the expression sum(current-group()/@value)
, with
usage absorption.
The rules for the sum
function appear in 19.8.9 Classifying Calls to Built-In Functions. The proforma is given there
as fn:sum(A)
, which means that the general streamability rules apply, and that the single
operand current-group()/@value
has usage absorption. So we need to establish the posture, sweep, and type of this
expression, which we can do as follows:
The expression is a RelativePathExpr
, so section
19.8.8.8 Streamability of Path Expressions
applies.
The expression is expanded to
current-group()/attribute::value
.
The posture and sweep of
the left-hand operand current-group()
are defined
in 19.8.9.4 Streamability of the current-group Function. Since all
the required conditions are satisfied, the posture of current-group()
is the
posture of the select
expression, that is striding, and its
sweep is the sweep of
the select
expression, that is consuming.
The posture and sweep of
the right hand operand @value
are defined in
19.8.8.9 Streamability of Axis Steps. The context posture is the posture
of the left-hand operand current-group()
, namely
striding; the table in Rule 5 applies,
giving the result climbing and motionless
The posture of the
RelativePathExpr
is the posture of the right hand operand, namely striding. The sweep of the
RelativePathExpr
is the wider of the sweeps of its operands, which is
consuming
The type of the expression current-group()/@value
is determined using the rules in 19.1 Determining the Static Type of a Construct as
attribute()
.
So the sum
function has a single operand with
U = absorption, P =
striding, S = consuming,
T = attribute()
.
In the general streamability rules, Rule
1(b)(iii)(A) gives the adjusted usage as U′ = inspection, and Rule 1(b)(iii)(B) gives the adjusted
sweep as S′ = S = consuming.
Rule 2(d) gives the posture and sweep of the call to sum
as grounded and consuming.
So the literal result element has two operands, one of which is grounded and motionless, the other grounded and consuming. Rule 2(d) of the general streamability rules determines that the literal result element is grounded and consuming.
So the content of the xsl:source-document
instruction is grounded, which means that the instruction is guaranteed-streamable.
Certain constructs allow a stylesheet author to declare that a construct is streamable. Specifically:
Specifying streamable="yes"
on xsl:mode
declares
that all template rules in that mode (and all
template rules that specify mode="#all"
) are
streamable;
Specifying streamable="yes"
on
xsl:source-document
declares that its
contained sequence constructor is streamable;
Specifying streamable="yes"
on xsl:function
declares that the stylesheet function in question is
streamable;
Specifying streamable="yes"
on xsl:attribute-set
declares that the attribute set in question is streamable;
Specifying streamable="yes"
(explicitly or implicitly) on xsl:merge-source
declares
that the merging process is streamable with respect to that particular input.
Specifying streamable="yes"
on xsl:accumulator
declares that the accumulator can be evaluated on a streamed document.
[Definition: The above constructs (template rules belonging to a
mode declared with streamable="yes"
; and xsl:source-document
,
xsl:attribute-set
, xsl:function
,
xsl:merge-source
, and xsl:accumulator
elements specifying
streamable="yes"
) are said to be
declared-streamable.]
In each case the construct in question is said to be guaranteed-streamable if it satisfies two conditions:
The construct is declared-streamable.
Streamability analysis following the rules defined in this specification determines that streamed processing is possible (the detailed conditions vary from one construct to another).
[Definition: A guaranteed-streamable construct is a construct that is declared to be streamable and that follows the particular rules for that construct to make streaming possible, as defined by the analysis in this specification.]
For a streaming processor, that is, a processor that claims conformance with the streaming feature:
If a construct is guaranteed-streamable and the input is provided in streamable form, then the input must be processed using streaming.
Note:
The requirement to process the input using streaming does not apply if the processor is able to determine that this would convey no benefit: for example, if the input is supplied as a tree in memory. However, this does not remove the requirement to verify that the relevant stylesheet constructs are guaranteed-streamable.
If a construct is declared as streamable but is not guaranteed-streamable (that is, if it fails to satisfy the conditions for streamability defined in this specification), then the processor must be prepared to do any one of the following at user option:
Signal a static error [see ERR XTSE3430]
Process the stylesheet as if it were a non-streaming processor (see below)
Process the stylesheet with streaming if it is able to do so, or signal a static error [see ERR XTSE3430] if it is not able to do so.
[ERR XTSE3430] It is a static error if a package contains a construct that is declared to be streamable but which is not guaranteed-streamable, unless the user has indicated that the processor is to handle this situation by processing the stylesheet without streaming or by making use of processor extensions to the streamability rules where available.
For a non-streaming processor, the processor must evaluate the construct
delivering the same results as if execution used streaming, but with no constraints
on the evaluation strategy. (Processing may, of
course, fail due to insufficient memory being available, or for other reasons.)
A non-streaming processor is not
required to assess whether constructs are guaranteed-streamable, or to apply restrictions such as the rules
for where calls on the functions accumulator-before
and
accumulator-after
may appear. However, a non-streaming
processor must enforce the constraint implied by a
use-accumulators
attribute restricting which accumulators can be
used with a particular document.
Note:
This specification does not attempt to legislate precisely what constitutes evaluation “using streaming”. The most important test is that the amount of memory needed should be for practical purposes independent of the size of the source document, and in particular that the finite size of memory available should not impose a limit on the size of source document that can be processed.
The rules are designed to ensure that streaming processors can analyze streamability using rules different from those in this specification, provided that all constructs that are guaranteed-streamable according to this specification are actually streamable by the implementation. Furthermore, non-streaming processors are not required to analyze streamability at all.
This section describes XSLT-specific additions to the XPath function library. Some of these additional functions also make use of information specified by declarations in the stylesheet; this section also describes these declarations.
Provides access to XML documents identified by a URI.
fn:document (
|
$uri-sequence |
as item()* ,
|
$base-node |
as node() ) as node()* |
The one-argument form of this function is deterministicFO30, focus-independentFO30, and context-dependentFO30. It depends on static base URI.
The two-argument form of this function is deterministicFO30, focus-independentFO30, and context-independentFO30.
The document
function allows access to XML documents identified by
a URI.
The first argument contains a sequence of URI references. The second argument, if present, is a node whose base URI is used to resolve any relative URI references contained in the first argument.
A sequence of absolute URI references is obtained as follows.
For an item in $uri-sequence
that is an instance of
xs:string
, xs:anyURI
, or
xs:untypedAtomic
, the value is cast to xs:anyURI
. If
the resulting URI reference is an absolute URI reference then it is used as
is. If it is a relative URI reference, then it is resolved as follows:
If $base-node
is supplied, then it is resolved against the base URI
of $base-node
.
Otherwise it is resolved against the static base URI from the static context of the
expression containing the call to the document
function. In cases where the source
code of the stylesheet is available at execution time, this will typically be the
location of the
relevant stylesheet module.
For an item in $uri-sequence
that is a node, the node is atomized. The result must be
a sequence whose items are all instances of xs:string
,
xs:anyURI
, or xs:untypedAtomic
. Each of these values
is cast to xs:anyURI
, and if the resulting URI reference is an
absolute URI reference then it is used as is. If it is a relative URI
reference, then it is resolved against the base URI of $base-node
if
supplied, or against the base URI of the node that contained it otherwise.
A relative URI is resolved against a base URI using the rules of the resolve-uri
FO30
function. A dynamic error occurs (see below) if no base URI is available.
If $uri-sequence
(after atomizing any nodes) contains an
item other than an atomic value of type xs:string
, xs:anyURI
, or
xs:untypedAtomic
then a type error is raised [ERR XPTY0004] XP30.
Each of these absolute URI references is then processed as follows. Any fragment
identifier that is present in the URI reference is removed, and the resulting absolute
URI is cast to a string and then passed to the doc
FO30 function
defined in [Functions and Operators 3.0]. This returns a document node. If an error
occurs during evaluation of the doc
FO30 function, the processor
may either signal this error in the normal way, or
may recover by ignoring the failure, in which case the failing URI
will not contribute any nodes to the result of the document
function.
If the URI reference contained no fragment identifier, then this document node is
included in the sequence of nodes returned by the document
function.
If the URI reference contained a fragment identifier, then the fragment identifier is interpreted according to the rules for the media type of the resource representation identified by the URI, and is used to select zero or more nodes that are descendant-or-self nodes of the returned document node. As described in 2.3 Initiating a Transformation, the media type is available as part of the evaluation context for a transformation.
The sequence of nodes returned by the function is in document order, with no duplicates.
This order has no necessary relationship to the order in which URIs were supplied
in the
$uri-sequence
argument.
[ERR XTDE1160] When a URI reference contains a fragment identifier, it is a dynamic error if the media type is not one that is recognized by the processor, or if the fragment identifier does not conform to the rules for fragment identifiers for that media type, or if the fragment identifier selects something other than a sequence of nodes (for example, if it selects a range of characters within a text node).
A processor may provide an option which, if selected, causes the processor instead of signaling this error, to ignore the fragment identifier and return the document node.
The set of media types recognized by a processor is implementation-defined.
[ERR XTDE1162] When a URI reference is a relative reference, it is a dynamic error if no base URI is available to resolve the relative reference. This can arise for example when the URI is contained in a node that has no base URI (for example a parentless text node), or when the second argument to the function is a node that has no base URI, or when the base URI from the static context is undefined.
One effect of these rules is that in an interpreted environment
where the source code of the stylesheet is available and its base URI is known, then unless
XML entities or xml:base
are used, the expression document("")
refers
to the document node of the containing stylesheet module (the definitive rules are
in [RFC3986]).
The XML resource containing the stylesheet module is then processed exactly as if
it were any
other XML document, for example there is no special recognition of xsl:text
elements,
and no special treatment of comments and processing instructions.
The XPath rules for function calling ensure that it is a type error if the supplied value of the second argument is anything other than a single node. If XPath 1.0 compatibility mode is enabled, then a sequence of nodes may be supplied, and the first node in the sequence will be used.
Keys provide a way to work with documents that contain an implicit cross-reference structure. They make it easier to locate the nodes within a document that have a given value for a given attribute or child element, and they provide a hint to the implementation that certain access paths in the document need to be efficient.
xsl:key
Declaration<!-- Category: declaration -->
<xsl:key
name = eqname
match = pattern
use? = expression
composite? = boolean
collation? = uri >
<!-- Content: sequence-constructor -->
</xsl:key>
The xsl:key
declaration is used to declare keys. The name
attribute specifies the name
of the key. The value of the name
attribute is an EQName, which is expanded as
described in 5.1.1 Qualified Names. The match
attribute is a Pattern; an xsl:key
element applies to
all nodes that match the pattern specified in the match
attribute.
[Definition: A key is defined as a set of
xsl:key
declarations in the same
package that share the same
name.]
The key name is scoped to the containing package, and is available for use in calls to the
key
function within that package.
The value of the key may be specified either using the use
attribute
or by means of the contained sequence
constructor.
[ERR XTSE1205] It is a static error if an
xsl:key
declaration has a use
attribute and
has non-empty content, or if it has empty content and no use
attribute.
If the use
attribute is present, its value is an expression specifying the values of the key. The
expression will be evaluated with a singleton focus based on the node that
matches the pattern. The result of evaluating the expression is
atomized.
Similarly, if a sequence constructor is present, it is used to determine the values of the key. The sequence constructor will be evaluated with the node that matches the pattern as the context node. The result of evaluating the sequence constructor is atomized.
[Definition: The expression in the
use
attribute and the sequence constructor within an xsl:key
declaration are referred to collectively as the key specifier. The
key specifier determines the values that may be used to find a node using this
key.]
When evaluation of the key
specifier results in a sequence (after atomization) containing more
than one atomic value, the effect depends on the value of the
composite
attribute:
When the attribute is absent or has the value no
, each atomic
value in the sequence acts as an individual key. For example, if
match="book" use="author" composite="no"
is specified, then
a book
element may be located using the value of any
author
element.
When the attribute is present and has the value yes
, the
sequence of atomic values is treated as a composite key that must be matched
in its entirety. For example, if match="book" use="author"
composite="yes"
is specified, then a book
element may
be located using the value of all its author
elements, supplied
in the correct order.
If there are several xsl:key
declarations in
the same package with the same key name, then
they must all have the same effective value for their composite
attribute. The effective value is the actual value of the attribute if present, or
"no"
if the attribute is absent.
Note:
There is no requirement that all the values of a key should have the same type.
The presence of an xsl:key
declaration makes it easy to find a
node that matches the match
pattern if the values of the key
specifier (when applied to that node) are known. It also provides a
hint to the implementation that access to the nodes by means of these values needs
to be efficient (many implementations are likely to construct an index or hash
table to achieve this).
Note:
An xsl:key
declaration is not bound to a specific source
document. The source document to which it applies is determined only when the
key
function is used to locate nodes using the key.
Keys can be used to locate nodes within any source document (including
temporary trees), but each use of the key
function
searches one document only.
Keys can only be used to search within a tree that is rooted at a document node.
The optional collation
attribute is used only when deciding whether
two strings are equal for the purposes of key matching. Specifically, two key
values $a
and $b
are considered equal if the result of
the function call deep-equal($a, $b,
$collation)
is true. The effective collation for an
xsl:key
declaration is the collation specified in its
collation
attribute if present, resolved against the base URI of
the xsl:key
element, or the default collation that is in scope for the xsl:key
declaration otherwise; the effective collation must be the same for all the
xsl:key
declarations making up a key.
[ERR XTSE1210] It is a static error if the
xsl:key
declaration has a collation
attribute whose value (after resolving against the base URI) is not a URI
recognized by the implementation as referring to a collation.
[ERR XTSE1220] It is a static error if there are
several xsl:key
declarations in the same package with the
same key name and different effective collations. Two collations are the
same if their URIs are equal under the rules for comparing
xs:anyURI
values, or if the implementation can determine
that they are different URIs referring to the same collation.
[ERR XTSE1222] It is a static error if there are
several xsl:key
declarations in a package with the same key name and
different effective values for the composite
attribute.
It is possible to have:
multiple xsl:key
declarations with the same name;
a node that matches the match
patterns of several different
xsl:key
declarations, whether these have the same key
name or different key names;
a node that returns more than one value from its key specifier (which can be treated either as separate individual key values, or as a single composite key value);
a key value that identifies more than one node (the key values for different nodes do not need to be unique).
An xsl:key
declaration with higher import precedence does not override
another of lower import precedence; all the xsl:key
declarations
in the stylesheet are effective regardless of their import precedence.
Returns the nodes that match a supplied key value.
fn:key (
|
$key-name |
as xs:string ,
|
$key-value |
as xs:anyAtomicType* ,
|
|
$top |
as node() ) as node()* |
The two-argument form of this function is deterministicFO30, focus-dependentFO30, and context-dependentFO30.
The three-argument form of this function is deterministicFO30, focus-independentFO30, and context-dependentFO30.
The key
function does for keys what the element-with-id
FO30 function does for IDs.
The $key-name
argument specifies the name of the key. The value of the argument must be a string containing an EQName. If it is
a lexical QName, then it is expanded as
described in 5.1.1 Qualified Names (no prefix means no namespace).
The $key-value
argument to the key
function is
considered as a sequence. The effect depends on the value of
the composite
attribute of the corresponding xsl:key
declaration.
If composite
is no
or
absent, the set of requested key values is formed by atomizing the
supplied value of the argument, using the standard function conversion rules. Each of
the resulting atomic values is considered as a requested key value. The result of
the function is a sequence of nodes, in document order and with duplicates
removed, comprising those nodes in the selected subtree (see below) that are
matched by an xsl:key
declaration whose name is the same as the
supplied key name, where the result of evaluating the key specifier contains a value that is equal
to one of these requested key values, under the rules appropriate to the XPath
eq
operator for the two values in question, using the
collation
attributes of the xsl:key
declaration
when comparing strings. No error is reported if two values are encountered that
are not comparable; they are regarded for the purposes of this function as being
not equal.
If the second argument is an empty sequence, the result of the function will be an empty sequence.
If composite
is yes
, the requested key
value is the sequence formed by atomizing the supplied value of the argument,
using the standard function conversion
rules. The result of the function is a sequence of nodes, in document
order and with duplicates removed, comprising those nodes in the selected subtree
(see below) that are matched by an xsl:key
declaration whose name
is the same as the supplied key name, where the result of evaluating the key specifier is deep-equal to the requested
key value, under the rules appropriate to the deep-equal
FO30
function applied to the two values in question, using the collation
attributes of the xsl:key
declaration when comparing strings.
Note that the deep-equal
FO30 function reports no error if two
values are encountered that are not comparable; they are regarded for the purposes
of this function as being not equal.
If the second argument is an empty sequence, the result of the function will be the set of nodes having an empty sequence as the value of the key specifier.
Different rules apply when XSLT 1.0 compatible behavior is enabled.
A key (that is, a set of xsl:key
declarations sharing the same key name) is processed in backwards compatible mode
if (a)
at least one of the xsl:key elements in the definition of the key enables backwards
compatible behavior, and (b) the effective value of the composite
attribute
is no
.
When a key is processed in backwards compatible mode, then:
The result of evaluating the key specifier in any xsl:key
declaration having this key name is converted after atomization to a sequence of
strings, by applying a cast to each item in the sequence.
When the first argument to the key
function specifies this key
name, then the value of the second argument is converted after atomization to a
sequence of strings, by applying a cast to each item in the sequence. The values are
then compared as strings.
The third argument is used to identify the selected subtree. If the argument is present,
the selected subtree is the set of nodes that have $top as an
ancestor-or-self node. If the argument is omitted, the selected subtree is the document
containing the context node. This means that the third argument effectively defaults
to
/
.
The result of the key
function can be described more specifically
as follows. The result is a sequence containing every node $N that satisfies
the following conditions:
$N/ancestor-or-self::node() intersect $top
is non-empty. (If the
third argument is omitted, $top
defaults to /
)
$N matches the pattern specified in the match
attribute of
an xsl:key
declaration whose name
attribute matches
the name specified in the $key-name
argument.
When composite="no"
, and the
key specifier of that
xsl:key
declaration is evaluated with a singleton focus based on $N, the
atomized value of the resulting
sequence includes a value that compares equal to at least one item in the atomized
value of the sequence supplied as $key-value
, under the rules of the
eq
operator with the collation selected as described above.
When composite="yes"
, and the
key specifier of that
xsl:key
declaration is evaluated with a singleton focus based on $N, the
atomized value of the resulting
sequence compares equal to the atomized value of the sequence supplied as
$key-value
, under the rules of the
deep-equal
FO30 function with the collation selected as
described above.
The sequence returned by the key
function will be in document
order, with duplicates (that is, nodes having the same identity) removed.
[ERR XTDE1260] It is a dynamic error if the value
is not a valid QName, or if there is no namespace
declaration in scope for the prefix of the QName, or if the name obtained by
expanding the QName is not the same as the expanded name of any
xsl:key
declaration in the containing package. If the
processor is able to detect the error statically (for example, when the argument
is supplied as a string literal), then the processor may
optionally signal this as a static
error.
[ERR XTDE1270] It is a dynamic
error to call the key
function with
two arguments if there is no context
node, or if the root of the tree containing the context node is not a
document node; or to call the function with three arguments if the root of the
tree containing the node supplied in the third argument is not a document
node.
Untyped atomic values are converted to strings, not to the type of the other operand.
This means, for example, that if the expression in the use
attribute
returns a date, supplying an untyped atomic value in the call to the
key
function will return an empty sequence.
Given a declaration
<xsl:key name="idkey" match="div" use="@id"/>
an expression key("idkey",@ref)
will return the same nodes as
id(@ref)
, assuming that the only ID attribute declared in the XML
source document is:
<!ATTLIST div id ID #IMPLIED>
and that the ref
attribute of the context node contains no
whitespace.
Suppose a document describing a function library uses a prototype
element to define functions
<prototype name="sqrt" return-type="xs:double"> <arg type="xs:double"/> </prototype>
and a function
element to refer to function names
<function>sqrt</function>
Then the stylesheet could generate hyperlinks between the references and definitions as follows:
<xsl:key name="func" match="prototype" use="@name"/> <xsl:template match="function"> <b> <a href="#{generate-id(key('func',.))}"> <xsl:apply-templates/> </a> </b> </xsl:template> <xsl:template match="prototype"> <p> <a name="{generate-id()}"> <b>Function: </b> ... </a> </p> </xsl:template>
When called with two arguments, the key
function always returns
nodes that are in the same document as the context node. To retrieve a node from any
other document, it is necessary either to change the context node, or to supply a
third argument.
For example, suppose a document contains bibliographic references in the form
<bibref>XSLT</bibref>
, and there is a separate XML
document bib.xml
containing a bibliographic database with entries in
the form:
<entry name="XSLT">...</entry>
Then the stylesheet could use the following to transform the bibref
elements:
<xsl:key name="bib" match="entry" use="@name"/> <xsl:template match="bibref"> <xsl:variable name="name" select="."/> <xsl:apply-templates select="document('bib.xml')/key('bib',$name)"/> </xsl:template>
Note:
This relies on the ability in XPath 2.0 to have a function call on the
right-hand side of the /
operator in a path expression.
The following code would also work:
<xsl:key name="bib" match="entry" use="@name"/> <xsl:template match="bibref"> <xsl:apply-templates select="key('bib', ., document('bib.xml'))"/> </xsl:template>
This example uses a composite key consisting of first name and last name to locate employees in an employee file.
The key can be defined like this:
<xsl:key name="emp-name-key" match="employee" use="name/first, name/last" composite="yes"/>
A particular employee can then be located using the function call:
key('emp-name-key', ('Tim', 'Berners-Lee'), doc('employees.xml'))
Keys are not applicable to streamed documents.
This is ensured by the rules for the streamability of the key
function
(see 19.8.9 Classifying Calls to Built-In Functions). These rules make the operand usage of the
third argument navigation, which has the consequence that when the key
function
is applied to a streamed input document, the call is roaming and free-ranging, which effectively makes
the containing construct non-streamable.
Returns the item that is the context item for the evaluation of the containing XPath expression
This function is deterministicFO30, context-dependentFO30, and focus-dependentFO30.
The current
function, used within an XPath expression, returns the item that was the context item at the point where the expression was
invoked from the XSLT stylesheet. This is
referred to as the current item. For an outermost expression (an expression not
occurring within another expression), the current item is always the same as the context
item. Thus,
<xsl:value-of select="current()"/>
means the same as
<xsl:value-of select="."/>
However, within square brackets, or on the right-hand side of the /
operator, the current item is generally different from the context item.
If the current
function is used within a pattern, its value is the item that is
being matched against the pattern.
[ERR XTDE1360] If the current
function is evaluated within an expression
that is evaluated when the context item is absent, a
dynamic error occurs.
When the current
is called by means of a
dynamic function call (for example, current#0()
), it is evaluated as if the
context item is absent ([see ERR XTDE1360]).
The instruction:
<xsl:apply-templates select="//glossary/entry[@name=current()/@ref]"/>
will process all entry
elements that have a glossary
parent
element and that have a name
attribute with value equal to the value of
the current item's ref
attribute. This is different from
<xsl:apply-templates select="//glossary/entry[@name=./@ref]"/>
which means the same as
<xsl:apply-templates select="//glossary/entry[@name=@ref]"/>
and so would process all entry
elements that have a
glossary
parent element and that have a name
attribute
and a ref
attribute with the same value.
Returns the URI (system identifier) of an unparsed entity
fn:unparsed-entity-uri (
|
$entity-name |
as xs:string ,
|
$doc |
as node() ) as xs:anyURI |
This function is deterministicFO30, focus-dependentFO30, and context-dependentFO30.
Calling the single-argument form of this function has the same effect as calling the two-argument form with the context item as the second argument.
The two-argument unparsed-entity-uri
function returns the URI of the unparsed
entity whose name is given by the value of the $entity-name
argument, in
the document containing the node supplied as the
value of the $doc
argument. It
returns the zero-length xs:anyURI
if there is no such entity. This function
maps to the dm:unparsed-entity-system-id
accessor defined in [XDM 3.0].
[ERR XTDE1370] It is a dynamic error if $node
,
or the context item if the second argument is omitted,
is a node in a tree whose root is not a document node.
The following errors may be raised when $node
is omitted:
If the context item is absent, dynamic error [ERR XPDY0002] XP30.
If the context item is not a node, type error [ERR XPTY0004] XP30.
The XDM accessor dm:unparsed-entity-system-id
is defined to return an absolute URI,
obtained by resolving the system identifier as written against the base URI of the
document. If no
base URI is available for the document, the unparsed-entity-uri
function
should return the system identifier as written, without any attempt to make
it absolute.
XML permits more than one unparsed entity declaration with the same name to appear, and says that the first declaration is the one that should be used. This rule should be respected during construction of the data model; the data model instance should not contain more than one unparsed entity with the same name.
Returns the public identifier of an unparsed entity
fn:unparsed-entity-public-id (
|
$entity-name |
as xs:string ,
|
$doc |
as node() ) as xs:string |
This function is deterministicFO30, focus-dependentFO30, and context-dependentFO30.
Calling the single-argument form of this function has the same effect as calling the two-argument form with the context item as the second argument.
The two-argument unparsed-entity-public-id
function returns the public
identifier of the unparsed entity whose name is given by the value of the
$entity-name
argument, in the document containing the node supplied as the
value of the $doc
argument. It returns the zero-length string if
there is no such entity, or if the entity has no public identifier. This function
maps
to the dm:unparsed-entity-public-id
accessor defined in [XDM 3.0].
[ERR XTDE1380] It is a dynamic error if $node
,
or the context item if the second argument is omitted,
is a node in a tree whose root is not a document node.
The following errors may be raised when $node
is omitted:
If the context item is absent, dynamic error [ERR XPDY0002] XP30.
If the context item is not a node, type error [ERR XPTY0004] XP30.
XML permits more than one unparsed entity declaration with the same name to appear, and says that the first declaration is the one that should be used. This rule should be respected during construction of the data model; the data model instance should not contain more than one unparsed entity with the same name.
Returns the value of a system property
This function is deterministicFO30, focus-independentFO30, and context-dependentFO30. It depends on namespaces.
The value of the $property-name
argument
must be a string containing an EQName. If it is a lexical QName
with a prefix, then it is expanded into an expanded
QName using the namespace declarations in the static context of the
expression. If there is no prefix, the name is
taken as being in no namespace.
The system-property
function returns a string representing the
value of the system property identified by the name. If there is no such system
property, the zero-length string is returned.
Implementations must provide the following system properties, which are all in the XSLT namespace:
xsl:version
, a number giving the version of XSLT implemented by the
processor; for implementations conforming
to the version of XSLT specified by this document, this is the string "3.0"
. The value will always be a
string in the lexical space of the decimal datatype defined in XML Schema (see
[XML Schema Part 2]). This allows the value to be converted to a number
for the purpose of magnitude comparisons.
xsl:vendor
, a string identifying the implementer of the processor
xsl:vendor-url
, a string containing a URL identifying the implementer
of the processor; typically this is the host
page (home page) of the implementer's Web site.
xsl:product-name
, a string containing the name of the implementation,
as defined by the implementer. This should normally remain
constant from one release of the product to the next. It should
also be constant across platforms in cases where the same source code is used to
produce compatible products for multiple execution platforms.
xsl:product-version
, a string identifying the version of the
implementation, as defined by the implementer. This should
normally vary from one release of the product to the next, and at the discretion
of the implementer it may also vary across different execution
platforms.
xsl:is-schema-aware
, returns the string "yes"
in the
case of a processor that claims conformance as a schema-aware XSLT processor, or
"no"
in the case of a basic
XSLT processor.
xsl:supports-serialization
, returns the string "yes"
in
the case of a processor that offers the serialization feature, or "no"
otherwise.
xsl:supports-backwards-compatibility
, returns the string
"yes"
in the case of a processor that offers the XSLT 1.0 compatibility feature, or
"no"
otherwise.
xsl:supports-namespace-axis
, returns the string "yes"
in
the case of a processor that offers the XPath namespace axis even when not in
backwards compatible mode, or "no"
otherwise. Note that a processor
that supports backwards compatible mode must support the namespace axis when in
that mode, so this property is not relevant to that case.
xsl:supports-streaming
, returns the string "yes"
in the
case of a processor that offers the streaming feature (see 27.5 Streaming Feature), or "no"
otherwise.
xsl:supports-dynamic-evaluation
, returns the string
"yes"
in the case of a processor that offers the dynamic
evaluation feature (see 27.6 Dynamic Evaluation Feature), or
"no"
otherwise.
xsl:supports-higher-order-functions
, returns the string
"yes"
in the case of a processor that offers the higher-order functions feature, or
"no"
otherwise.
xsl:xpath-version
, a number giving the version of XPath implemented by the
processor. The value will always be a
string in the lexical space of the decimal datatype defined in XML Schema (see
[XML Schema Part 2]). This allows the value to be converted to a number
for the purpose of magnitude comparisons. Typical values are "3.0"
or "3.1"
.
The value "3.0"
indicates that the processor implements XPath 3.0 plus the extensions
defined in 21 Maps and 22 Processing JSON Data.
xsl:xsd-version
, a number giving the version of XSD (XML Schema) implemented by the
processor. The value will always be a
string in the lexical space of the decimal datatype defined in XML Schema (see
[XML Schema Part 2]). This allows the value to be converted to a number
for the purpose of magnitude comparisons. Typical values are "1.0"
or "1.1"
.
This property is relevant even when the processor is not schema-aware, since the built-in
datatypes
for XSD 1.1 differ from those in XSD 1.0.
Some of these properties relate to the conformance levels and features offered by the processor: these options are described in 27 Conformance.
The actual values returned for the above properties are implementation-defined.
The set of system properties that are supported, in addition to those listed above, is also implementation-defined. Implementations must not define additional system properties in the XSLT namespace.
[ERR XTDE1390] It is a dynamic error if the value supplied as
the $property-name
argument is not a valid
QName, or if there is no namespace declaration in scope for the prefix of the
QName. If the processor is able to detect the error statically (for example, when
the argument is supplied as a string literal), then the processor
may optionally signal this as a static error.
An implementation must not return the value
3.0
as the value of the xsl:version
system property unless it is
conformant to XSLT 3.0.
It is recognized that vendors who are enhancing XSLT 1.0 or
2.0 processors may wish to release interim implementations before all the
mandatory features of this specification are implemented. Since such products are
not
conformant to XSLT 3.0, this specification cannot define their behavior. However,
implementers of such products are encouraged to return a value for the
xsl:version
system property that is intermediate between 1.0 and 3.0,
and to provide the element-available
and
function-available
functions to allow users to test which
features have been fully implemented.
Returns a list of system property names that are suitable for passing to
the system-property
function, as a sequence of QNames.
This function is deterministicFO30, context-independentFO30, and focus-independentFO30.
The function returns a sequence of QNames, being the names of the system properties recognized by the processor, in some implementation-dependent order.
The prefix part of a returned QName is implementation-dependent.
The function is deterministicFO30: that is, the set of available system properties does not vary during the course of a transformation.
The function returns a list of QNames, containing no duplicates.
It is intended that the QNames in this list should be suitable for passing to
system-property
. However, they must first be converted to
the form expected by the system-property
function, which is either
a lexical QName or to an EQName in the form Q{uri}local
. Because the prefix
of the returned QName is unpredictable, the Q{uri}local
is likely
to be more convenient. Conversion of an xs:QName
value to an EQName in
Q{uri}local
format can be achieved using the function:
<xsl:function name="f:QName-to-brace-notation" as="xs:string"> <xsl:param name="qname" as="xs:QName"/> <xsl:sequence select="'Q{' || namespace-uri-from-QName($qname) || '}' || local-name-from-QName($qname)"/> </xsl:function>
When XSLT 3.0 is used with XPath 3.0, it extends the type system and data model of XPath 3.0 with an additional datatype: the map. A map is an additional kind of item. Supporting this additional type are additional XPath language constructs, types, and XSLT instructions, all defined in this section.
Note:
The extensions to XPath 3.0 defined in this section have been incorporated into XPath 3.1. Therefore, when an XSLT 3.0 processor implements the XPath 3.1 Feature, the relevant parts of this section can be ignored.
[Definition: A map consists of a set of entries. Each entry comprises a key which is an arbitrary atomic value, and an arbitrary sequence called the associated value.]
[Definition: Within a map, no
two entries have the same key. Two atomic
values K1
and K2
are the same key for this
purpose if the relation op:same-key(K1, K2, $UCC)
holds.]
To put it another way, subject to
the rule above regarding timezones, the keys are the same if either K1
eq K2
is true under the Unicode codepoint collation, or if both
K1
and K2
are NaN
. It is not necessary that
all the keys should be mutually comparable (for example, they can include a mixture
of
integers and strings).
The function call map:get($map, $key)
can be used to retrieve the value
associated with a given key.
A map can also be viewed as a function from keys to associated values. To achieve this, a map is also a function item. The properties of this function are as follows:
The name of the function is absent.
The arity of the function is 1 (one).
The parameter names comprise a sequence of one QName, conventionally
$key
, though the choice of name has no observable
consequences.
The signature is function($key as xs:anyAtomicValue) as
item()*
(with no annotations).
The implementation is the expression map:get($self,
$key)
The non-local-variable-bindings comprise a single variable,
$self
, whose value is the map itself.
Calling the function has the same effect as calling the get
function: the
expression $map($key)
returns the same result as get($map,
$key)
. For example, if $books-by-isbn
is a map whose keys are
ISBNs and whose associated values are book
elements, then the expression
$books-by-isbn("0470192747")
returns the book
element with
the given ISBN. The fact that a map is a function item allows it to be passed as an
argument to higher-order functions that expect a function item as one of their
arguments.
Like all other values, maps
are immutable. For example, the map:remove
function returns a map
that differs from the supplied map by the omission of one entry, but the supplied
map is
not changed by the operation. Two calls on map:remove
with the same
arguments will return maps that are indistinguishable from each other; there is no
way of
asking whether these are “the same map”.
The syntax of ItemTypeXP30 as defined in XPath is extended as follows:
[69] | ItemType |
::= | KindTest | ("item" "(" ")") | FunctionTest | AtomicOrUnionType |
ParenthesizedItemType |
|
[201] | MapType |
::= | 'map' '(' ( '*' | (AtomicOrUnionTypeXP30 ',' SequenceTypeXP30) ')' |
The following rules express the matching rules for a map item type and a map, and extend the set of rules given in Section 2.5.5.2 Matching an ItemType and an Item XP30:
The ItemType
map(K, V)
matches an item M if (a) M is a
map, and (b) every entry in M has
a key that matches K and an associated value that matches
V. For example, map(xs:integer, element(employee))
matches a map if all the keys in the map are integers, and all the associated
values are employee
elements. Note that a map (like a sequence)
carries no intrinsic type information separate from the types of its entries,
and the type of existing entries in a map does not constrain the type of new
entries that can be added to the map.
Note:
In consequence, map(K, V)
matches an empty
map, whatever the types K and V might be.
The ItemType
map(*)
matches any map regardless of its contents. It is
equivalent to map(xs:anyAtomicType, item()*)
.
A map also acts as a function. This means that maps match certain function item types. Specifically, the following rule extends the list of rules in Section 2.5.5.7 Function Test XP30:
function(*)
matches any map.
function(xs:anyAtomicType) as item()*
matches any map.
Because of the rules for subtyping of function types according to
their signature, it follows that the item type function(A) as item()*
,
where A is an atomic type, also matches any map, regardless of the type of the keys
actually found in the map. For example, a map whose keys are all strings can be
supplied where the required type is function(xs:integer) as item()*
; a
call on the map that treats it as a function with an integer argument will always
succeed, and will always return an empty sequence.
The function signature of the map, treated as a function, is always
function(xs:anyAtomicType) as item()*
, regardless of the actual types
of the keys and values in the map. This means that a function item type with a more
specific return type, such as function(xs:anyAtomicType) as xs:integer
,
does not match a map in the sense required to satisfy the instance of
operator. However, the rules for function coercion mean that any map can be supplied
as a value in a context where such a type is the required type, and a type error will
only occur if an actual call on the map (treated as a function) returns a value that
is not an instance of the required return type.
Note:
So, given a map $M
whose keys are integers and whose results are
strings, such as map{0:"no", 1:"yes"}
, the following relations hold,
among others:
$M instance of map(*)
$M instance of map(xs:integer, xs:string)
$M instance of map(xs:decimal, xs:anyAtomicType)
not($M instance of map(xs:int, xs:string))
not($M instance of map(xs:integer, xs:token))
$M instance of function(*)
$M instance of function(xs:anyAtomicType) as item()*
$M instance of function(xs:integer) as item()*
$M instance of function(xs:int) as item()*
$M instance of function(xs:string) as item()*
not($M instance of function(xs:integer) as xs:string)
The last case might seem surprising; however, function coercion ensures that
$M
can be used successfully anywhere that the required type is
function(xs:integer) as xs:string
.
The rules for judging whether one item type is a subtype of
another, given in Section
2.5.6.2 The judgement subtype-itemtype(Ai, Bi)
XP30, are extended
with some additional rules. The judgement subtype-itemtype(Ai, Bi)
is
true if:
Ai
is map(K, V)
and Bi
is
map(*)
, for any K
and V
.
Ai
is map(Ka, Va)
and Bi
is
map(Kb, Vb)
, where subtype-itemtype(Ka, Kb)
and
subtype(Va, Vb)
.
Ai
is map(*)
(or, because of the transitivity rules,
any other map type) and Bi
is function(*)
.
Ai
is map(*)
, (or, because of the transitivity rules,
any other map type) and Bi
is function(xs:anyAtomicType) as
item()*
.
XSLT 3.0 provides a number of functions that operate on maps, or that are useful in conjunction with maps. These functions are specified in [Functions and Operators 3.1], but they are available with XSLT 3.0 whether or not the processor offers the XPath 3.1 Feature.
Some of the functions defined in this section use a conventional namespace prefix
map
, which is assumed to be bound to the namespace URI
http://www.w3.org/2005/xpath-functions/map
.
Note that there is no operation to atomize a map or convert it to a string.
Determines whether two atomic values can coexist as separate keys within a map.
This function is deterministicFO30, context-independentFO30, and focus-independentFO30.
The internal function op:same-key
(which is not available at the user level) is used to assess whether two atomic
values are considered to be duplicates when used as keys in a map. A map cannot
contain two separate entries whose keys are the same as defined by this function.
The function is also used when matching keys in functions such as map:get
and map:remove
.
The function returns true if and only if one of the following conditions is true:
All of the following conditions are true:
$k1
is an instance of xs:string
, xs:anyURI
, or xs:untypedAtomic
$k2
is an instance of xs:string
, xs:anyURI
, or xs:untypedAtomic
fn:codepoint-equal($k1, $k2)
Note:
Strings are compared without any dependency on collations.
All of the following conditions are true:
$k1
is an instance of xs:decimal
, xs:double
, or xs:float
$k2
is an instance of xs:decimal
, xs:double
, or xs:float
One of the following conditions is true:
Both $k1
and $k2
are NaN
Note:
xs:double('NaN')
is the same key as xs:float('NaN')
Both $k1
and $k2
are positive infinity
Note:
xs:double('INF')
is the same key as xs:float('INF')
Both $k1
and $k2
are negative infinity
Note:
xs:double('-INF')
is the same key as xs:float('-INF')
$k1
and $k2
when converted to decimal numbers with no rounding or loss of precision
are mathematically equal.
Note:
Every instance of xs:double
, xs:float
, and xs:decimal
can be represented
exactly as a decimal number provided enough digits are available both before and after
the decimal point. Unlike the eq
relation, which converts both operands to xs:double
values, possibly losing precision in the process, this
comparison is transitive.
Note:
Positive and negative zero are the same key.
All of the following conditions are true:
$k1
is an instance of xs:date
, xs:time
, xs:dateTime
,
xs:gYear
, xs:gYearMonth
, xs:gMonth
, xs:gMonthDay
, or xs:gDay
$k2
is an instance of xs:date
, xs:time
, xs:dateTime
,
xs:gYear
, xs:gYearMonth
, xs:gMonth
, xs:gMonthDay
, or xs:gDay
One of the following conditions is true:
Both $k1
and $k2
have a timezone
Neither $k1
nor $k2
has a timezone
fn:deep-equal($k1, $k2)
Note:
The use of deep-equal
rather than eq
ensures that comparing values of different
types yields false
rather than an error.
Note:
Unlike the eq
operator, this comparison has no dependency on the implicit timezone, which means
that
the question of whether or not a map contains duplicate keys is not dependent on this
aspect of the dynamic context.
All of the following conditions are true:
$k1
is an instance of xs:boolean
, xs:hexBinary
, xs:base64Binary
,
xs:duration
, xs:QName
, or xs:NOTATION
$k2
is an instance of xs:boolean
, xs:hexBinary
, xs:base64Binary
,
xs:duration
, xs:QName
, or xs:NOTATION
fn:deep-equal($k1, $k2)
Note:
The use of deep-equal
rather than eq
ensures that comparing values of different
types yields false
rather than an error.
The rules for comparing keys in a map are chosen to ensure that the comparison is:
Context-free: there is no dependency on the static or dynamic context
Error-free: any two atomic values can be compared, and the result is either true or false, never an error
Transitive: if A is the same key as B, and B is the same key as C, then A is the same key as C.
As always, any algorithm that delivers the right result is acceptable. For example,
when testing whether an xs:double
value D is the same key as an xs:decimal
value that has N significant digits, it is not
necessary to know all the digits in the decimal expansion of D to establish the result: computing the first N+1
significant digits (or indeed, simply knowing that there are more than N significant digits) is sufficient.
Returns a map that combines the entries from a number of existing maps.
map:merge (
|
$maps |
as map(*)* ,
|
$options |
as map(*) ) as map(*) |
This function is deterministicFO30, context-independentFO30, and focus-independentFO30.
The function map:merge
returns a map that
is formed by combining the contents of the maps supplied in the $maps
argument.
Informally, the supplied maps are combined as follows:
There is one entry in the returned map for each distinct key present in the union of the input maps, where two keys are distinct if they are not the same key.
If there are duplicate keys, that is, if two or more maps contain entries having the
same key, then the way this is handled is
controlled by the second ($options
) argument.
The definitive specification is as follows.
The effect of calling the single-argument function is the same as the effect of
calling the two-argument function with an empty map as the value of $options
.
The $options
argument can be used to control the way in which duplicate keys are handled.
The option parameter conventions apply.
The entries that may appear in the $options
map are as follows:
Key | Value | Meaning |
---|---|---|
duplicates
|
Determines the policy for handling duplicate keys: specifically, the action to be
taken if two maps in the input sequence $maps contain entries with key values
K1 and K2 where K1 and K2 are the same key.
The required type is xs:string . The default value is use-first .
|
|
reject
|
An error is raised [ERR FOJS0003] FO31 if duplicate keys are encountered. | |
use-first
|
If duplicate keys are present, all but the first of a set of duplicates are ignored,
where the ordering is based on the order of maps in the $maps argument.
|
|
use-last
|
If duplicate keys are present, all but the last of a set of duplicates are ignored,
where the ordering is based on the order of maps in the $maps argument.
|
|
combine
|
If duplicate keys are present, the result map includes an entry for the key whose
associated value is the sequence-concatenation of all the values associated with the
key,
retaining order based on the order of maps in the $maps argument.
The key value in the result map that corresponds to such a set of duplicates must
be the same key as each of the duplicates, but it is
otherwise unconstrained: for example if the duplicate keys are xs:byte(1)
and xs:short(1) , the key in the result could legitimately be xs:long(1) .
|
|
unspecified
|
If duplicate keys are present, all but one of a set of duplicates are ignored, and it is implementation-dependent which one is retained. |
The result of the function call map:merge($MAPS, $OPTIONS)
is defined to be consistent with the result of the expression:
let $FOJS0003 := QName("http://www.w3.org/2005/xqt-errors", "FOJS0003"), $duplicates-handler := map { "use-first": function($a, $b) {$a}, "use-last": function($a, $b) {$b}, "combine": function($a, $b) {$a, $b}, "reject": function($a, $b) {fn:error($FOJS0003)}, "unspecified": function($a, $b) {fn:random-number-generator()?permute(($a, $b))[1]} }, $combine-maps := function($A as map(*), $B as map(*), $deduplicator as function(*)) { fn:fold-left(map:keys($B), $A, function($z, $k){ if (map:contains($z, $k)) then map:put($z, $k, $deduplicator($z($k), $B($k))) else map:put($z, $k, $B($k)) }) } return fn:fold-left($MAPS, map{}, $combine-maps(?, ?, $duplicates-handler(($OPTIONS?duplicates, "use-first")[1]))
Note:
By way of explanation, $combine-maps
is a function that combines
two maps by iterating over the keys of the second map, adding each key and its corresponding
value to the first map as it proceeds. The second call of fn:fold-left
in the return
clause then iterates over the maps supplied in the call
to map:merge
, accumulating a single map that absorbs successive maps
in the input sequence by calling $combine-maps
.
This algorithm processes the supplied maps in a defined order, but processes the keys within each map in implementation-dependent order.
The use of fn:random-number-generator
represents one possible conformant
implementation for "duplicates":"unspecified"
, but it is not the only conformant
implementation and is not necessarily a realistic implementation.
An error is raised [ERR FOJS0003] FO31 if the value of
$options
indicates that duplicates are to be rejected, and a duplicate key is encountered.
An error is raised [ERR FOJS0005] FO31 if the value of
$options
includes an entry whose key is defined
in this specification, and whose value is not a permitted value for that key.
If the input is an empty sequence, the result is an empty map.
If the input is a sequence of length one, the result map is indistinguishable from the supplied map.
There is no requirement that the supplied input maps should have the same or compatible
types. The type of a map (for example map(xs:integer, xs:string)
) is
descriptive of the entries it currently contains, but is not a constraint on how the
map
may be combined with other maps.
let $week := map{0:"Sonntag", 1:"Montag", 2:"Dienstag", 3:"Mittwoch", 4:"Donnerstag", 5:"Freitag", 6:"Samstag"}
The expression map:merge(())
returns map{}
. (Returns an empty map).
The expression map:merge((map:entry(0, "no"), map:entry(1, "yes")))
returns map{0:"no", 1:"yes"}
. (Returns a map with two entries).
The expression map:merge(($week, map{7:"Unbekannt"}))
returns map{0:"Sonntag", 1:"Montag", 2:"Dienstag", 3:"Mittwoch", 4:"Donnerstag",
5:"Freitag", 6:"Samstag", 7:"Unbekannt"}
. (The value of the existing map is unchanged; the returned map
contains all the entries from $week
, supplemented with an additional
entry.)
The expression map:merge(($week, map{6:"Sonnabend"}), map{"duplicates":"use-last"})
returns map{0:"Sonntag", 1:"Montag", 2:"Dienstag", 3:"Mittwoch", 4:"Donnerstag",
5:"Freitag", 6:"Sonnabend"}
. (The value of the existing map is unchanged; the returned map
contains all the entries from $week
, with one entry replaced by a
new entry. Both input maps contain an entry with the key 6
; the
one used in the result is the one that comes last in the input
sequence.)
The expression map:merge(($week, map{6:"Sonnabend"}), map{"duplicates":"use-first"})
returns map{0:"Sonntag", 1:"Montag", 2:"Dienstag", 3:"Mittwoch", 4:"Donnerstag",
5:"Freitag", 6:"Samstag"}
. (The value of the existing map is unchanged; the returned map
contains all the entries from $week
, with one entry replaced by a
new entry. Both input maps contain an entry with the key 6
; the
one used in the result is the one that comes first in the input
sequence.)
The expression map:merge(($week, map{6:"Sonnabend"}), map{"duplicates":"combine"})
returns map{0:"Sonntag", 1:"Montag", 2:"Dienstag", 3:"Mittwoch", 4:"Donnerstag",
5:"Freitag", 6:("Samstag", "Sonnabend")}
. (The value of the existing map is unchanged; the returned map
contains all the entries from $week
, with one entry replaced by a
new entry. Both input maps contain an entry with the key 6
; the
entry that appears in the result is the sequence-concatenation of the entries
in the input maps, retaining order.)
Returns the number of entries in the supplied map.
This function is deterministicFO30, context-independentFO30, and focus-independentFO30.
The function map:size
takes any map
as its $map
argument and returns the number of entries that are present
in the map.
The expression map:size(map{})
returns 0
.
The expression map:size(map{"true":1, "false":0})
returns 2
.
Returns a sequence containing all the keys present in a map
This function is deterministicFO30, context-independentFO30, and focus-independentFO30.
The function map:keys
takes any map
as its $map
argument and returns the keys that are present in the map as
a sequence of atomic values, in implementation-dependent order.
The function is non-deterministic with respect to ordering (see Section 1.7.4 Properties of functions FO31). This means that two calls with the same argument are not guaranteed to produce the results in the same order.
The number of items in the result will be the same as the number of entries in the map, and the result sequence will contain no duplicate values.
The expression map:keys(map{1:"yes", 2:"no"})
returns some permutation of (1,2)
. (The result is in implementation-dependent order.)
Tests whether a supplied map contains an entry for a given key
This function is deterministicFO30, context-independentFO30, and focus-independentFO30.
The function map:contains
returns true if the map supplied as $map
contains an entry with the same key as the
supplied value of $key
; otherwise it returns false.
let $week := map{0:"Sonntag", 1:"Montag", 2:"Dienstag", 3:"Mittwoch", 4:"Donnerstag", 5:"Freitag", 6:"Samstag"}
The expression map:contains($week, 2)
returns true()
.
The expression map:contains($week, 9)
returns false()
.
The expression map:contains(map{}, "xyz")
returns false()
.
The expression map:contains(map{"xyz":23}, "xyz")
returns true()
.
The expression map:contains(map{"abc":23, "xyz":()}, "xyz")
returns true()
.
Returns the value associated with a supplied key in a given map.
This function is deterministicFO30, context-independentFO30, and focus-independentFO30.
The function map:get
attempts to find an entry within the map supplied as $map
that has the same key as the supplied
value of $key
. If there is such an entry, it returns the associated value;
otherwise it returns an empty sequence.
A return value of ()
from map:get
could indicate that
the key is present in the map with an associated value of ()
, or it could
indicate that the key is not present in the map. The two cases can be distinguished
by
calling map:contains
.
Invoking the map as a function item has the same effect
as calling get
: that is, when $map
is a map, the expression
$map($K)
is equivalent to map:get($map, $K)
. Similarly, the
expression map:get(map:get(map:get($map, 'employee'), 'name'), 'first')
can
be written as $map('employee')('name')('first')
.
let $week := map{0:"Sonntag", 1:"Montag", 2:"Dienstag", 3:"Mittwoch", 4:"Donnerstag", 5:"Freitag", 6:"Samstag"}
The expression map:get($week, 4)
returns "Donnerstag"
.
The expression map:get($week, 9)
returns ()
. (When the key is not present, the function returns an empty
sequence.)
The expression map:get(map:entry(7,()), 7)
returns ()
. (An empty sequence as the result can also signify that the key is
present and the associated value is an empty sequence.)
Returns a map containing all the contents of the supplied map, but with an additional entry, which replaces any existing entry for the same key.
This function is deterministicFO30, context-independentFO30, and focus-independentFO30.
The function map:put
returns a map that contains all entries from the supplied $map
,
with the exception of any entry whose key is the same key as $key
, together with a new
entry whose key is $key
and whose associated value is $value
.
The effect of the function call map:put($MAP, $KEY, $VALUE)
is equivalent
to the result of the following steps:
let $MAP2 := map:remove($MAP, $KEY)
This returns a map in which all entries with the same key as $KEY
have been removed.
Construct and return a map containing:
All the entries (key/value pairs) in $MAP2
, and
The entry map:entry($KEY, $VALUE)
There is no requirement that the type of $key
and $value
be consistent with the types
of any existing keys and values in the supplied map.
let $week := map{0:"Sonntag", 1:"Montag", 2:"Dienstag", 3:"Mittwoch", 4:"Donnerstag", 5:"Freitag", 6:"Samstag"}
The expression map:put($week, 6, "Sonnabend")
returns map{0:"Sonntag", 1:"Montag", 2:"Dienstag", 3:"Mittwoch", 4:"Donnerstag",
5:"Freitag", 6:"Sonnabend"}
.
The expression map:put($week, -1, "Unbekannt")
returns map{0:"Sonntag", 1:"Montag", 2:"Dienstag", 3:"Mittwoch", 4:"Donnerstag",
5:"Freitag", 6:"Samstag", -1:"Unbekannt"}
.
Returns a map that contains a single entry (a key-value pair).
This function is deterministicFO30, context-independentFO30, and focus-independentFO30.
The function map:entry
returns a map which contains a single
entry. The key of the entry in the new map is
$key
, and its associated value is $value
.
The function map:entry
is intended primarily for use in conjunction with
the function map:merge
. For example, a map containing seven entries may be
constructed like this:
map:merge(( map:entry("Su", "Sunday"), map:entry("Mo", "Monday"), map:entry("Tu", "Tuesday"), map:entry("We", "Wednesday"), map:entry("Th", "Thursday"), map:entry("Fr", "Friday"), map:entry("Sa", "Saturday") ))
Unlike the map expression (map{...}
), this technique can be used to construct
a map with a variable number of entries, for example:
map:merge(for $b in //book return map:entry($b/isbn, $b))
The expression map:entry("M", "Monday")
returns {"M":"Monday"}
.
Returns a map containing all the entries from a supplied map, except those having a specified key.
This function is deterministicFO30, context-independentFO30, and focus-independentFO30.
The function map:remove
returns a map containing all the entries in $map
except for any entry whose key is
the same key as an item in $keys
.
No failure occurs if an item in $keys
does not correspond to any entry in $map
;
that key value is simply ignored.
The effect of the function call map:remove($MAP, $KEY)
can be described more formally as the result of the expression below:
map:merge ( map:for-each ( $MAP, function($k, $v) { if (some $key in $KEY satisfies op:same-key($k, $key)) then () else map:entry($k, $v) } ) )
let $week := map{0:"Sonntag", 1:"Montag", 2:"Dienstag", 3:"Mittwoch", 4:"Donnerstag", 5:"Freitag", 6:"Samstag"}
The expression map:remove($week, 4)
returns map{0:"Sonntag", 1:"Montag", 2:"Dienstag", 3:"Mittwoch", 5:"Freitag",
6:"Samstag"}
.
The expression map:remove($week, 23)
returns map{0:"Sonntag", 1:"Montag", 2:"Dienstag", 3:"Mittwoch", 4:"Donnerstag",
5:"Freitag", 6:"Samstag"}
.
The expression map:remove($week, (0, 6 to 7))
returns map{1:"Montag", 2:"Dienstag", 3:"Mittwoch", 4:"Donnerstag", 5:"Freitag"}
.
The expression map:remove($week, ())
returns >map{0:"Sonntag", 1:"Montag", 2:"Dienstag", 3:"Mittwoch", 4:"Donnerstag", 5:"Freitag",
6:"Samstag"}
.
Applies a supplied function to every entry in a map, returning the concatenation of the results.
This function is deterministicFO30, context-independentFO30, and focus-independentFO30.
The function map:for-each
takes any map as its $map
argument and applies the supplied function
to each entry in the map, in implementation-dependent order; the result is the sequence obtained by
concatenating the results of these function calls.
The function is non-deterministic with respect to ordering (see Section 1.7.4 Properties of functions FO31). This means that two calls with the same arguments are not guaranteed to process the map entries in the same order.
The function supplied as $action
takes two arguments. It is called
supplying the key of the map entry as the first argument, and the associated value
as
the second argument.
The expression map:for-each(map{1:"yes", 2:"no"}, function($k,
$v){$k})
returns some permutation of (1,2)
. (This function call is equivalent to calling map:keys
. The
result is in implementation-dependent order.)
The expression distinct-values(map:for-each(map{1:"yes", 2:"no"}, function($k,
$v){$v}))
returns some permutation of ("yes", "no")
. (This function call returns the distinct values present in the map, in
implementation-dependent order.)
The expression map:merge(map:for-each(map{"a":1, "b":2}, function($k,
$v){map:entry($k, $v+1)}))
returns map{"a":2, "b":3}
. (This function call returns a map with the same keys as the input map,
with the value of each entry increased by one.)
This XQuery example converts the entries in a map to attributes on a newly constructed element node.
let $dimensions := map{'height': 3, 'width': 4, 'depth': 5}; return <box>{ map:for-each($dimensions, function ($k, $v) { attribute {$k} {$v} }) }</box>
The result is the element <box height="3" width="4"
depth="5"/>
.
Searches the supplied input sequence and any contained maps and arrays for a map entry with the supplied key, and returns the corresponding values.
This function is deterministicFO30, context-independentFO30, and focus-independentFO30.
The function map:find
searches the sequence supplied as $input
looking for map entries whose key is the same key
as $key
. The associated value in any such map entry (each being in general a sequence)
is returned as a member of the result array.
The search processes the $input
sequence using the following recursively-defined rules
(any equivalent algorithm may be used provided it delivers
the same result, respecting those rules that constrain the order of the result):
To process a sequence, process each of its items in order.
To process an item that is an array, process each of the array's members in order (each member is, in general, a sequence).
To process an item that is a map, then for each key-value entry (K, V) in the map (in implementation-dependent order) perform both of the following steps, in order:
If K is the same key as $key
,
then add V as a new member to the end of the result array.
Process V (which is, in general, a sequence).
To process an item that is neither a map nor an array, do nothing. (Such items are ignored).
If $input
is an empty sequence, map, or array, or if the requested $key
is not found,
the result will be a zero-length array.
let $responses := [map{0:'no', 1:'yes'}, map{0:'non', 1:'oui'}, map{0:'nein', 1:('ja', 'doch')}]
The expression map:find($responses, 0)
returns ['no', 'non', 'nein']
.
The expression map:find($responses, 1)
returns ['yes', 'oui', ('ja', 'doch')]
.
The expression map:find($responses, 2)
returns []
.
let $inventory := map{"name":"car", "id":"QZ123", "parts": [map{name":"engine", "id":"YW678", "parts":[]}]}
The expression map:find($inventory, "parts")
returns [[map{name":"engine", "id":"YW678", "parts":[]}], []]
.
Given a string value and a collation, generates an internal value called a collation key, with the property that the matching and ordering of collation keys reflects the matching and ordering of strings under the specified collation.
fn:collation-key (
|
$key |
as xs:string ,
|
$collation |
as xs:string ) as xs:base64Binary |
This function is deterministicFO30, context-dependentFO30, and focus-independentFO30. It depends on collations.
Calling the one-argument version of this function is equivalent to calling the two-argument version supplying the default collation as the second argument.
The function returns an implementation-dependent
value with the property that,
for any two strings $K1
and $K2
:
collation-key($K1, $C) eq collation-key($K2, $C)
if and only if
compare($K1, $K2, $C) eq 0
collation-key($K1, $C) lt collation-key($K2, $C)
if and only if
compare($K1, $K2, $C) lt 0
The collation used by this function is determined in the same way as for other functions
accepting a collation URI argument. Collation keys are defined as xs:base64Binary
values
to ensure unambiguous and context-free comparison semantics.
An implementation is free to generate a collation key in any convenient way provided that it always generates the same collation key for two strings that are equal under the collation, and different collation keys for strings that are not equal. This holds only within a single execution scopeFO30; an implementation is under no obligation to generate the same collation keys during a subsequent unrelated query or transformation.
It is possible to define collations that do not have the ability to generate collation keys. Supplying such a collation will cause the function to fail. The ability to generate collation keys is an implementation-defined property of the collation.
An error is raised [ERR FOCH0004] FO31 if the specified collation does not support the generation of collation keys.
The function is provided primarily for use with maps. If a map is required where
codepoint equality is inappropriate for comparing keys, then a common technique is
to
normalize the key so that equality matching becomes feasible. There are many ways
keys can be normalized, for example by use of functions such as
fn:upper-case
, fn:lower-case
,
fn:normalize-space
, or fn:normalize-unicode
, but this
function provides a way of normalizing them according to the rules of a specified
collation. For example, if the collation ignores accents, then the function will
generate the same collation key for two input strings that differ only in their use
of
accents.
The result of the function is defined to be an xs:base64Binary
value. Binary values
are chosen because they have unambiguous and context-free comparison semantics, because
the value space
is unbounded, and because the ordering rules are such that between any two values
in the ordered value space, an
arbitrary number of further values can be interpolated. The choice between xs:base64Binary
and xs:hexBinary
is arbitrary; the only operation that behaves differently between the two binary
data types is conversion to/from a string, and this operation is not one that is normally
required for
effective use of collation keys.
For collations based on the Unicode Collation Algorithm, an algorithm for computing collation keys is provided in [UNICODE TR10]. Implementations are not required to use this algorithm.
This specification does not mandate that collation keys should retain ordering. This is partly because the primary use case is for maps, where only equality comparisons are required, and partly to allow the use of binary data types (which are currently unordered types) for the result. The specification may be revised in a future release to specify that ordering is preserved.
The fact that collation keys are ordered can be exploited in XQuery, whose order by
clause does not allow the collation to be selected dynamically. This restriction can
be circumvented
by rewriting the clause order by $e/@key collation "URI"
as order by fn:collation-key($e/@key, $collation)
,
where $collation
allows the collation to be chosen dynamically.
Note that xs:base64Binary
becomes an ordered type
in XPath 3.1, making binary collation keys possible. In an implementation that adheres
strictly to XPath 3.0,
collation keys can be used only for equality matching, not for ordering operations.
let $C := 'http://www.w3.org/2013/collation/UCA?strength=primary'
The expression map:merge((map{collation-key("A", $C):1}, map{collation-key("a",
$C):2}), map{"duplicates":"use-last"})(collation-key("A", $C))
returns 2
. (Given that the keys of the two entries are equal under the rules of
the chosen collation, only one of the entries can appear in the result; the one
that is chosen is the one from the last map in the input sequence.)
The expression let $M := map{collation-key("A", $C):1, collation-key("B", $C):2}
return $M(collation-key("a", $C))
returns 1
. (The strings "A" and "a" have the same collation key under this
collation.)
As the above examples illustrate, it is important that when the
collation-key
function is used to add entries to a map, then it must
also be used when retrieving entries from the map. This process can be made less
error-prone by encapsulating the map within a function: function($k)
{$M(collation-key($k, $collation)}
.
fn:deep-equal
The deep-equal
FO30 function, when used with XSLT 3.0, is defined to
handle maps in the way that is defined in the [Functions and Operators 3.1] specification of the function.
Specifically, two maps are deep-equal if they have the same number of entries, and
if there
is a one-to-one correspondence in the sense that for every entry E1in the first map, there is
a corresponding entry E2 in the second map, such that the keys of E1 and E2
are equal under the op:same-key
relation (see 21.2.1 op:same-key), and the corresponding values are
equal under the deep-equal
relation, invoked recursively using the collation
supplied as argument to the original deep-equal
call, or its default. Note that collations
are not used for comparing keys.
Two instructions are added to XSLT to facilitate the construction of maps.
<!-- Category: instruction -->
<xsl:map>
<!-- Content: sequence-constructor -->
</xsl:map>
The instruction xsl:map
constructs and returns a new map.
The contained sequence constructor must evaluate to a sequence of
maps: call this $maps
.
The result of the instruction (other than the choice of error code) is then given by the XPath 3.1 expression:
map:merge($maps, map{"duplicates":"reject"})
Note:
Informally: if there are duplicate keys among the sequence of maps, a dynamic error occurs. Otherwise, the resulting map contains the union of the map entries from the supplied sequence of maps.
[ERR XTDE3365] A dynamic error occurs if the set of keys in the maps resulting from evaluating the sequence constructor contains duplicates.
There is no requirement that the supplied input maps should have the same or
compatible types. The type of a map (for example map(xs:integer,
xs:string)
) is descriptive of the entries it currently contains, but is not
a constraint on how the map may be combined with other maps.
[ERR XTTE3375] A type error occurs if the result of evaluating the sequence constructor
is
not an instance of the required type map(*)*
.
Note:
In practice, the effect of this rule is that the sequence
constructor contained in the xsl:map
instruction is severely
constrained: it doesn’t make sense, for example, for it to contain
instructions such as xsl:element
that create new nodes. As with
other type errors, processors are free to signal the error statically if they are
able to determine that the sequence constructor would always fail when
evaluated.
<!-- Category: instruction -->
<xsl:map-entry
key = expression
select? = expression >
<!-- Content: sequence-constructor -->
</xsl:map-entry>
The instruction xsl:map-entry
constructs and returns a singleton
map: that is, a map which contains one
key and one value. Such a map is primarily used as a building block when constructing
maps using the xsl:map
instruction.
The select
attribute and the contained sequence constructor are mutually
exclusive: if a select
attribute is present, then the content
must be empty except optionally for
xsl:fallback
instructions.
[ERR XTSE3280] It is a static error if the
select
attribute of the xsl:map-entry
element
is present unless the element has no children other than
xsl:fallback
elements.
The key of the entry in the new map is the value obtained by evaluating the
expression in the key
attribute, converted to the required type
xs:anyAtomicType
by applying the function conversion rules. If the supplied key (after conversion) is of
type xs:untypedAtomic
, it is cast to xs:string
.
The associated value is the value obtained by evaluating the expression in the
select
attribute, or the contained sequence constructor, with no
conversion. If there is no select
attribute and the sequence constructor
is empty, the associated value is the empty sequence.
The following example binds a variable to a map whose content is statically known:
<xsl:variable name="week" as="map(xs:string, xs:string)"> <xsl:map> <xsl:map-entry key="'Mo'" select="'Monday'"/> <xsl:map-entry key="'Tu'" select="'Tuesday'"/> <xsl:map-entry key="'We'" select="'Wednesday'"/> <xsl:map-entry key="'Th'" select="'Thursday'"/> <xsl:map-entry key="'Fr'" select="'Friday'"/> <xsl:map-entry key="'Sa'" select="'Saturday'"/> <xsl:map-entry key="'Su'" select="'Sunday'"/> </xsl:map> </xsl:variable>
The following example binds a variable to a map acting as an index into a source document:
<xsl:variable name="index" as="map(xs:string, element(employee))"> <xsl:map> <xsl:for-each select="//employee"> <xsl:map-entry key="@empNr" select="."/> </xsl:for-each> </xsl:map> </xsl:variable>
A Map Constructor is a new kind of expression added to the syntax of XPath.
Note:
Map Constructors are defined in XPath 3.1. They are available in XSLT 3.0 whether or not XPath 3.1 is supported. The specification given here is intended to be identical to the specification in XPath 3.1.
The syntax of PrimaryExprXP30 is
extended to permit MapConstructor
as an additional alternative.
[52] | PrimaryExpr |
::= | Literal | VarRef | ParenthesizedExpr | ContextItemExpr | FunctionCall |
FunctionItemExpr |
|
[202] | MapConstructor |
::= | "map" "{" (MapConstructorEntry ("," MapConstructorEntry )*)? "}" |
|
[203] | MapConstructorEntry |
::= | MapKeyExpr ":" MapValueExpr |
|
[204] | MapKeyExpr |
::= | ExprSingleXP30 |
|
[205] | MapValueExpr |
::= | ExprSingleXP30 |
Note:
In some circumstances, it is necessary to include whitespace
before or after the colon to ensure that this grammar is correctly parsed; this
arises for example when the KeyExpr
ends with a name and the
ValueExpr
starts with a name.
The value of the expression is a map whose entries correspond to the key-value pairs
obtained by evaluating the successive KeyExpr
and ValueExpr
expressions.
Each KeyExpr
expression is evaluated and atomized; a type error [ERR XPTY0004] XP30 occurs if the result is not a single atomic value. If the key is of
type xs:untypedAtomic
it is converted to xs:string
. The
associated value is the result of evaluating the corresponding
ValueExpr
. If two or more entries have the same key then
a dynamic error occurs [see ERR XTDE3365].
For example, the following expression constructs a map with seven entries:
map { "Su" : "Sunday", "Mo" : "Monday", "Tu" : "Tuesday", "We" : "Wednesday", "Th" : "Thursday", "Fr" : "Friday", "Sa" : "Saturday" }
Note:
Unlike the map:merge
function, the number of entries in a map
that is constructed using a map expression is known statically.
A new operator is introduced into XPath to allow convenient lookup of entries in a map (or a sequence of maps), knowing the key.
Note:
Map Lookup Expressions are defined in XPath 3.1. They are available in XSLT 3.0 whether or not XPath 3.1 is supported. The specification given here is intended to be identical to the specification in XPath 3.1.
The operator is available in two forms: as a unary (prefix) operator, and as a postfix operator.
[76] UnaryLookup ::= "?" KeySpecifier [54] KeySpecifier ::= NCName |
IntegerLiteral | ParenthesizedExpr | "*"
A UnaryLookup expression returns a sequence of values selected from the map that is the context item. If the context item is not a map or an array, a type error is raised [err:XPTY0004]
The semantics are as follows:
If the KeySpecifier
is an NCName
, the
UnaryLookup
expression ?KS
is equivalent to
.("KS")
. For example, $emp[?name='Jim']
is
shorthand for $emp[.("name")='Jim']
.
If the KeySpecifier
is an IntegerLiteral
, the
UnaryLookup
expression ?N
is equivalent to
.(N)
. This form is only useful for maps whose keys are
numeric. For example, $temp[?7 > 30]
is shorthand for
$temp[.(7) > 30]
.
If the KeySpecifier
is a ParenthesizedExpr
, the
UnaryLookup
expression ?(EXP)
is equivalent to
.(EXP)
. This form allows arbitrary keys, including keys
computed dynamically. For example, $emp[?('Year of Birth') >
1980]
is shorthand for $emp[.("Year of Birth") >
1980]
If the KeySpecifier
is a wildcard ("*") the
UnaryLookup
expression ?*
is equivalent to the
expression for $k in map:keys(.) return .($k)
. That is, it
returns the sequence-concatenation of all the values in the map; since the
order of keys is implementation-dependent, so is the order of these
values.
[53] Lookup ::= "?" KeySpecifier
The semantics of the postfix lookup operator are defined in terms of the unary lookup operator. The left-hand operand must be a map, or a sequence of maps. The KeySpecifier is applied to each of these maps, in order, and the results are sequence-concatenated.
If the KeySpecifier
is an NCName
, the Postfix
Lookup expression E?KS
is equivalent to E!?KS
. For
example, if $emps
is a sequence of maps containing information
about employees, then $emps?name
selects the names of the
employees: it is equivalent to $emps!map:get(., "name")
.
If the KeySpecifier
is an IntegerLiteral
, the
Postfix Lookup expression E?N
is equivalent to
E!?N
. This form is only useful for maps whose keys are
numeric.
For example, if $emps
is a sequence of maps containing
information about employees, and if one of the entries in this map
represents the salary history, as a map whose keys are the relevant year and
whose associated value is the salary, then
$emps[?name='John']?2012
returns the value of John’s salary
in the year 2012.
If the KeySpecifier
is a ParenthesizedExpr
, the
Postfix Lookup expression E?(EXP)
is equivalent to for $m
in E, $k in EXP return $m!?($k)
. This form allows arbitrary keys,
including keys computed dynamically. It also allows multiple keys.
For example, if $emps
is a sequence of maps containing
information about employees, and if one of the entries in this map
represents the salary history, as a map whose keys are the relevant year and
whose associated value is the salary, then $emps[?name='John']?(2012
to 2015)
returns the value of John’s salary in the years 2012
through 2015.
If the KeySpecifier
is a wildcard ("*") the Postfix Lookup
expression E?*
is equivalent to the expression
E!?*
. That is, it returns the sequence-concatenation of all
the values in all the maps; since the order of keys within each map is
implementation-dependent, so is the order of these values.
Maps have many uses, but their introduction to XSLT 3.0 was strongly motivated by streaming use cases. In essence, when a source document is processed in streaming mode, data that is encountered in the course of processing may need to be retained in variables for subsequent use, because the nodes cannot be revisited. This creates a need for a flexible data structure to accommodate such temporary data, and maps were designed to fulfil this need.
The entries in a map are not allowed to contain references to
streamed nodes. This is achieved by ensuring that for all constructs
that supply content to be included in a map (for example the third argument of map:put
, and
the select
attribute of xsl:map-entry
),
the relevant operand is defined to have operand usage navigation. Because maps cannot
contain references to streamed nodes, they are effectively grounded, and can therefore
be used freely in contexts (such as parameters to functions or templates) where only
grounded operands
are permitted.
The xsl:map
instruction, and the XPath MapConstructor
construct, are exceptions to the general rule that during streaming, only one
downward selection (one consuming subexpression) is permitted. They share this
characteristic with xsl:fork
. As with xsl:fork
, a
streaming processor is expected to be able to construct the map during a single pass
of the streamed input document, which may require multiple expressions to be
evaluated in parallel.
In the case of the xsl:map
instruction, this exemption applies only in the
case where the instruction consists exclusively of xsl:map-entry
(and xsl:fallback
) children, and not in more complex cases where the
map entries are constructed dynamically (for example using a control flow implemented
using xsl:choose
, xsl:for-each
, or
xsl:call-template
). Such cases may, of course, be streamable
if they only have a single consuming subexpression.
For example, the following XPath expression is streamable, despite making two downward selections:
let $m := map{'price':xs:decimal(price), 'discount':xs:decimal(discount)} return ($m?price - $m?discount)
Analysis:
Because the return
clause is motionless, the sweep of the let
expression is the sweep of the map
expression (the expression in curly brackets).
The sweep of a map expression is the maximum sweep of its key/value pairs.
For both key/value pairs, the key is motionless and the value is consuming.
The expression carefully atomizes both values, because retaining references to streamed nodes in a map is not permitted.
Therefore the map expression, and hence the expression as a whole, is grounded and consuming.
See also: 19.8.8.17 Streamability of Map Constructors, 19.8.4.23 Streamability of xsl:map, 19.8.4.24 Streamability of xsl:map-entry
This section gives some examples of where maps can be useful.
This example uses maps in conjunction with the xsl:iterate
instruction to find the highest-earning employee in each department, in a single
streaming pass of an input document containing employee records.
<xsl:source-document streamable="yes" href="employees.xml"> <xsl:iterate select="*/employee"> <xsl:param name="highest-earners" as="map(xs:string, element(employee))" select="map{}"/> <xsl:on-completion> <xsl:for-each select="map:keys($highest-earners)"> <department name="{.}"> <xsl:copy-of select="$highest-earners(.)"/> </department> </xsl:for-each> </xsl:on-completion> <xsl:variable name="this" select="copy-of(.)" as="element(employee)"/> <xsl:next-iteration> <xsl:with-param name="highest-earners" select="let $existing := $highest-earners($this/department) return if ($existing/salary gt $this/salary) then $highest-earners else map:put($highest-earners, $this/department, $this)"/> </xsl:next-iteration> </xsl:iterate> </xsl:source-document>
A complex number might be represented as a map with two entries, the keys being
the xs:boolean
value true
for the real part, and the
xs:boolean
value false
for the imaginary part. A
library for manipulation of complex numbers might include functions such as the
following:
<xsl:variable name="REAL" static="yes" as="xs:int" select="0"/> <xsl:variable name="IMAG" static="yes" as="xs:int" select="1"/> <xsl:function name="i:complex" as="map(xs:int, xs:double)"> <xsl:param name="real" as="xs:double"/> <xsl:param name="imaginary" as="xs:double"/> <xsl:sequence select="map{ $REAL : $real, $IMAG : $imaginary }"/> </xsl:function> <xsl:function name="i:real" as="xs:double"> <xsl:param name="complex" as="map(xs:int, xs:double)"/> <xsl:sequence select="$complex($REAL)"/> </xsl:function> <xsl:function name="i:imaginary" as="xs:double"> <xsl:param name="complex" as="map(xs:int, xs:double)"/> <xsl:sequence select="$complex($IMAG)"/> </xsl:function> <xsl:function name="i:add" as="map(xs:int, xs:double)"> <xsl:param name="arg1" as="map(xs:int, xs:double)"/> <xsl:param name="arg2" as="map(xs:int, xs:double)"/> <xsl:sequence select="i:complex(i:real($arg1)+i:real($arg2), i:imaginary($arg1)+i:imaginary($arg2)"/> </xsl:function> <xsl:function name="i:multiply" as="map(xs:boolean, xs:double)"> <xsl:param name="arg1" as="map(xs:boolean, xs:double)"/> <xsl:param name="arg2" as="map(xs:boolean, xs:double)"/> <xsl:sequence select="i:complex( i:real($arg1)*i:real($arg2) - i:imaginary($arg1)*i:imaginary($arg2), i:real($arg1)*i:imaginary($arg2) + i:imaginary($arg1)*i:real($arg2))"/> </xsl:function>
Given a set of book
elements, it is possible to construct an index in
the form of a map allowing the books to be retrieved by ISBN number.
Assume the book elements have the form:
<book> <isbn>0470192747</isbn> <author>Michael H. Kay</author> <publisher>Wiley</publisher> <title>XSLT 2.0 and XPath 2.0 Programmer's Reference</title> </book>
An index may be constructed as follows:
<xsl:variable name="isbn-index" as="map(xs:string, element(book))" select="map:merge(for $b in //book return map{$b/isbn : $b})"/>
This index may then be used to retrieve the book for a given ISBN using either of
the expressions map:get($isbn-index, "0470192747")
or
$isbn-index("0470192747")
.
In this simple form, this replicates the functionality available using
xsl:key
and the key
function. However, it
also provides capabilities not directly available using the
key
function: for example, the index can include
book
elements in multiple source documents. It also allows
processing of all the books using a construct such as <xsl:for-each
select="map:keys($isbn-index)">
As in JavaScript, a map whose keys are strings and whose associated values are function items can be used in a similar way to a class in object-oriented programming languages.
Suppose an application needs to handle customer order information that may arrive in three different formats, with different hierarchic arrangements:
Flat structure:
<customer id="c123">...</customer> <product id="p789">...</product> <order customer="c123" product="p789">...</order>
Orders within customer elements:
<customer id="c123"> <order product="p789">...</order> </customer> <product id="p789">...</product>
Orders within product elements:
<customer id="c123">...</customer> <product id="p789"> <order customer="c123">...</order> </product>
An application can isolate itself from these differences by defining a set of
functions to navigate the relationships between customers, orders, and products:
orders-for-customer
, orders-for-product
,
customer-for-order
, product-for-order
. These
functions can be implemented in different ways for the three different input
formats. For example, with the first format the implementation might be:
<xsl:variable name="flat-input-functions" as="map(xs:string, function(*))*" select="map{ 'orders-for-customer' : function($c as element(customer)) as element(order)* {$c/../order[@customer=$c/@id]}, 'orders-for-product' : function($p as element(product)) as element(order)* {$p/../order[@product=$p/@id]}, 'customer-for-order' : function($o as element(order)) as element(customer) {$o/../customer[@id=$o/@customer]}, 'product-for-order' : function($o as element(order)) as element(product) {$o/../product[@id=$o/@product]} } "/>
Having established which input format is in use, the application can bind the
appropriate implementation of these functions to a variable such as
$input-navigator
, and can then process the input using XPath
expressions such as the following, which selects all products for which there is
no order: //product[empty($input-navigator("orders-for-product")(.))]
JSON is a popular format for exchange of structured data on the web: it is specified in [RFC 7159]. This section describes facilities allowing JSON data to be processed using XSLT.
Note:
RFC7159 is taken as the definitive specification of JSON for the purposes of this document. The RFC explains its relationship with other JSON specifications such as [ECMA-404].
Note:
XPath 3.1 incorporates the functions defined in this
section. It also provides additional JSON capability, in the form of functions
parse-json
, json-doc
, and extensions to the
serialize
FO30 function. These facilities are incorporated in XSLT
3.0 only if the XPath 3.1 feature is supported. They depend on support for
arrays.
This specification defines a mapping from JSON data to XML (specifically, to XDM
instances). A function json-to-xml
is provided to take a JSON
string as input and convert it to the XML representation. Two stylesheet modules are
provided to perform the reverse transformation: one produces JSON in compact linear
form, the other in indented form suitable for display, editing, or printing.
The XML representation is designed to be capable of representing any valid JSON text other than one that uses characters which are not valid in XML. The transformation is lossless: that is, distinct JSON texts convert to distinct XML representations. When converting JSON to XML, options are provided to reject unsupported characters, to replace them with a substitute character, or to leave them in backslash-escaped form.
The following example demonstrates the correspondence of a JSON text and the corresponding XML representation.
Consider the following JSON text:
{ "desc" : "Distances between several cities, in kilometers.", "updated" : "2014-02-04T18:50:45", "uptodate": true, "author" : null, "cities" : { "Brussels": [ {"to": "London", "distance": 322}, {"to": "Paris", "distance": 265}, {"to": "Amsterdam", "distance": 173} ], "London": [ {"to": "Brussels", "distance": 322}, {"to": "Paris", "distance": 344}, {"to": "Amsterdam", "distance": 358} ], "Paris": [ {"to": "Brussels", "distance": 265}, {"to": "London", "distance": 344}, {"to": "Amsterdam", "distance": 431} ], "Amsterdam": [ {"to": "Brussels", "distance": 173}, {"to": "London", "distance": 358}, {"to": "Paris", "distance": 431} ] } }
The XML representation of this text is as follows. Whitespace is included in the
XML representation for purposes of illustration, and is ignored by the stylesheets
that convert XML to JSON, but it will not be present in the output of the
json-to-xml
function.
<map xmlns="http://www.w3.org/2005/xpath-functions"> <string key='desc'>Distances between several cities, in kilometers.</string> <string key='updated'>2014-02-04T18:50:45</string> <boolean key="uptodate">true</boolean> <null key="author"/> <map key='cities'> <array key="Brussels"> <map> <string key="to">London</string> <number key="distance">322</number> </map> <map> <string key="to">Paris</string> <number key="distance">265</number> </map> <map> <string key="to">Amsterdam</string> <number key="distance">173</number> </map> </array> <array key="London"> <map> <string key="to">Brussels</string> <number key="distance">322</number> </map> <map> <string key="to">Paris</string> <number key="distance">344</number> </map> <map> <string key="to">Amsterdam</string> <number key="distance">358</number> </map> </array> <array key="Paris"> <map> <string key="to">Brussels</string> <number key="distance">265</number> </map> <map> <string key="to">London</string> <number key="distance">344</number> </map> <map> <string key="to">Amsterdam</string> <number key="distance">431</number> </map> </array> <array key="Amsterdam"> <map> <string key="to">Brussels</string> <number key="distance">173</number> </map> <map> <string key="to">London</string> <number key="distance">358</number> </map> <map> <string key="to">Paris</string> <number key="distance">431</number> </map> </array> </map> </map>
An XSD 1.0 schema for the XML representation is provided in B.1 Schema for the XML Representation of JSON. It is not necessary to import this schema (using
xsl:import-schema
) unless the stylesheet makes explicit reference
to the components defined in the schema. If the stylesheet does import a schema for
the namespace http://www.w3.org/2005/xpath-functions
, then:
The processor (if it is schema-aware) must recognize an
xsl:import-schema
declaration for this namespace, whether
or not the schema-location
is supplied.
If a schema-location
is provided, then the schema document at that
location must be equivalent to the schema document at
B.1 Schema for the XML Representation of JSON; the effect if it is not is implementation-dependent
The rules governing the mapping from JSON to XML are as follows. In these rules, the
phrase “an element named N” is to be interpreted as meaning “an element node whose
local name is N and whose namespace URI is
http://www.w3.org/2005/xpath-functions
”.
The JSON value null
is represented by an element named
null
, with empty content.
The JSON values true
and false
are represented by an
element named boolean
, with content conforming to the type
xs:boolean
.
A JSON number is represented by an element named number
, with
content conforming to the type xs:double
, with the additional
restriction that the value must not be positive or negative infinity, nor
NaN
.
A JSON string is represented by an element named string
, with
content conforming to the type xs:string
.
A JSON array is represented by an element named array
. The content
is a sequence of child elements representing the members of the array in order,
each such element being the representation of the array member obtained by
applying these rules recursively.
A JSON object is represented by an element named map
. The content
is a sequence of child elements each of which represents one of the name/value
pairs in the object. The representation of the name/value pair N:V
is obtained by taking the element that represents the value V (by
applying these rules recursively) and adding an attribute with name
key
(in no namespace), whose value is N as an
instance of xs:string
.
The attribute escaped="true"
may be specified on a string
element to indicate that the string value contains backslash-escaped characters that
are to be interpreted according to the JSON rules. The attribute
escaped-key="true"
may be specified on any element with a
key
attribute to indicate that the key contains backslash-escaped
characters that are to be interpreted according to the JSON rules. Both attributes
have the default value false
.
The JSON grammar for number
is a subset of
the lexical space of the XSD type xs:double
. The mapping from JSON
number
values to xs:double
values is defined by the
XPath rules for casting from xs:string
to xs:double
. Note
that these rules will never generate an error for out-of-range values; instead very
large or very small values will be converted to +INF
or
-INF
. Since JSON does not impose limits on the range or precision of
numbers, the conversion is not guaranteed to be lossless.
Although the order of entries in a JSON object is generally considered to have no
significance, the function json-to-xml
and the stylesheets that perform
the reverse transformation both retain order.
The XDM representation of a JSON value may either be untyped (all elements annotated
as xs:untyped
, attributes as xs:untypedAtomic
), or it may
be typed. If it is typed, then it must have the type annotations
obtained by validating the untyped representation against the schema given in
B.1 Schema for the XML Representation of JSON. If it is untyped, then it
must be an XDM instance such that validation against this
schema would succeed.
This section describes conventions which in principle can be adopted by the specification
of any function. At the time of writing, the function which invoke these conventions
are
xml-to-json
and json-to-xml
.
As a matter of convention, a number of functions defined in this document take a parameter whose value is a map, defining options controlling the detail of how the function is evaluated. Maps are a new data type introduced in XSLT 3.0.
For example, the function fn:xml-to-json
has an options parameter
allowing specification of whether the output is to be indented. A call might be written:
fn:xml-to-json($input, map{'indent':true()})
[Definition: Functions that take an options parameter adopt common conventions on how the options are used. These are referred to as the option parameter conventions. These rules apply only to functions that explicitly refer to them.]
Where a function adopts the option parameter conventions, the following rules apply:
The value of the relevant argument must be a map. The entries in the map are
referred to as options: the key of the entry is called the option name, and the
associated value is the option value. Option names defined in this specification
are always strings (single xs:string
values). Option values may
be of any type.
The type of the options parameter in the function signature is always
given as map(*)
.
Although option names are described above as strings, the actual key may be
any value that compares equal to the required string (using the eq
operator
with Unicode codepoint collation). For example, instances of xs:untypedAtomic
or xs:anyURI
are equally acceptable.
Note:
This means that the implementation of the function can check for the
presence and value of particular options using the functions map:contains
and/or map:get
.
It is not an error if the options map contains options with names other than those
described in this specification. Implementations may attach an
implementation-defined meaning to such entries,
and may define errors that arise if such entries are present with invalid values.
Implementations must ignore such entries unless they have a specific
implementation-defined meaning.
Implementations that define additional options in this way should
use values of type xs:QName
as the option names, using an appropriate namespace.
All entries in the options map are optional, and supplying an empty map has the same effect as omitting the relevant argument in the function call, assuming this is permitted.
For each named option, the function specification defines a required type for the option value. The value that is actually supplied in the map is converted to this required type using the function conversion rulesXP31. A type error [ERR XPTY0004] XP30 occurs if conversion of the supplied value to the required type is not possible, or if this conversion delivers a coerced function whose invocation fails with a type error. A dynamic error occurs if the supplied value after conversion is not one of the permitted values for the option in question: the error codes for this error are defined in the specification of each function.
Note:
It is the responsibility of each function implementation to invoke this conversion; it does not happen automatically as a consequence of the function calling rules.
In cases where an option is list-valued, by convention the value may be supplied
either as a sequence or as an array. Accepting a sequence is convenient if the
value is generated programmatically using an XPath expression; while accepting an
array
allows the options to be held in an an external file in JSON format, to be read using
a call on the fn:json-doc
function.
In cases where the value of an option is itself a map, the specification of the particular function must indicate whether or not these rules apply recursively to the contents of that map.
Parses a string supplied in the form of a JSON text, returning the results in the form of an XML document node.
fn:json-to-xml (
|
$json-text |
as xs:string ,
|
$options |
as map(*) ) as document-node() |
This function is nondeterministicFO30, context-dependentFO30, and focus-independentFO30. It depends on static base URI.
The effect of the one-argument form of this function is the same as calling the
two-argument form with an empty map as the value of the $options
argument.
The first argument is a JSON-text (see below) in the form of a string. The function parses this string to return an XDM node.
The $options
argument can be used to control the way in which the parsing
takes place. The value of the argument is a map. The options defined in this
specification have keys that are strings. The effect of any map entries whose keys
are
not defined in this specification is implementation-defined; implementation-defined
options should use QNames as keys. Implementations
must ignore any entries in the map whose keys are not defined in
this specification, unless the key has a specific implementation-defined meaning.
The entries that may appear in the $options
map are as follows. The keys
are xs:string
values:
Key | Value | Meaning |
---|---|---|
liberal
|
Determines whether deviations from the syntax of RFC7159 are permitted. The value must be a boolean. | |
false
|
The input must consist of an optional byte order mark (which is ignored) followed by a string
that conforms to the grammar of JSON-text in [RFC 7159].
An error must be raised
(see below) if the input does not conform to the grammar.
|
|
true
|
The input may contain deviations from the grammar of [RFC 7159], which are handled in an implementation-defined way. (Note: some popular extensions include allowing quotes on keys to be omitted, allowing a comma to appear after the last item in an array, allowing leading zeroes in numbers, and allowing control characters such as tab and newline to be present in unescaped form.) Since the extensions accepted are implementation-defined, an error may be raised (see below) if the input does not conform to the grammar. | |
validate
|
If the $options map contains an entry with the key
"validate" , then the value must be an
xs:boolean . The default is true for a schema-aware
processor, false for a non-schema-aware processor. If the value
true is supplied and the processor is not schema-aware, a
dynamic error results [see ERR XTDE3245]. It is not
necessary that the containing stylesheet should import the relevant
schema.
|
|
true
|
Indicates that the resulting XDM instance must be typed; that is, the element
and attribute nodes must carry the type annotations that result from validation
against the schema given at B.1 Schema for the XML Representation of JSON, or against an
implementation-defined schema if the liberal
option has the value yes .
|
|
false
|
Indicates that the XDM instance must be untyped. | |
escape
|
Determines whether special characters are represented in the XDM output
in backslash-escaped form.
The required type is xs:boolean .
|
|
false (default)
|
All characters in the input that are valid
in the version of XML supported by the implementation, whether or not they are represented
in the input by means of an escape sequence, are represented as unescaped characters
in the result. Any
characters or codepoints that are not valid XML characters
(for example, unpaired surrogates) are passed to the fallback function
as described below; in the absence of a fallback function, they are replaced by
the Unicode REPLACEMENT CHARACTER (xFFFD ).
The attributes escaped and escaped-key will not be present in the XDM output.
|
|
true
|
JSON escape sequences are used in the result to represent special characters in the
JSON input, as defined below,
whether or not they were represented using JSON escape sequences in the input.
The characters that are considered "special" for this purpose are:
\t ), or a six-character escape sequence otherwise
(for example \uDEAD ). Characters other than these will not be escaped in the result,
even if they were escaped in the input. In the result:
|
|
fallback
|
Provides a function which is called when an invalid character is encountered. | |
Function with signature function(xs:string) as xs:string |
When an invalid character is encountered this function is called supplying the escaped form of the character as the argument. The function returns a string which is inserted into the result in place of the invalid character. The function also has the option of raising a dynamic error. |
The various structures that can occur in JSON are transformed recursively to XDM values according to the rules given in 22.1 XML Representation of JSON.
The function returns a document node, whose only child is the element node representing the outermost construct in the JSON text.
The function is not deterministicFO30: that is, if the function is called twice with the same arguments, it is implementation-dependent whether the same node is returned on both occasions.
The base URI of the returned document node is taken from the static base URI of the function call.
[ERR XTDE3240] It is a dynamic error if the value of
$input
does not conform to the JSON grammar as defined
by [RFC 7159], allowing implementation-defined extensions
if the liberal
option is set to yes
.
[ERR XTDE3245] It is a dynamic error if the value of
the validate
option is true
and the processor is not
schema-aware.
[ERR XTDE3250] It is a dynamic error if the value of
$input
contains an escaped representation of a character (or
codepoint) that is not a valid character in the version of XML supported by the
implementation, unless the unescape
option is set to false.
[ERR XTDE3260] It is a dynamic error if the value of
$options
includes an entry whose key is liberal
,
validate
, unescape
, or fallback
,
and whose value is not a permitted value for that key.
To read a JSON file, this function can be used in conjunction with the
unparsed-text
FO30 function.
ECMA-404 differs from RFC 4627 in two respects: it does not allow the input to depart from the JSON grammar, but it does allow the top-level construct in the input to be a string, boolean, number, or null, rather than requiring an object or array.
Many JSON implementations allow commas to be used after the last item in an object
or
array, although the specification does not permit it. The option
spec="liberal"
is provided to allow such deviations from the
specification to be accepted. Some JSON implementations also allow constructors such
as
new Date("2000-12-13")
to appear as values: specifying
spec="liberal"
allows such extensions to be accepted, but does not
guarantee it. If such extensions are accepted, the resulting value is
implementation-defined, and will not necessarily conform to the schema at B.1 Schema for the XML Representation of JSON.
The expression json-to-xml('{"x": 1, "y": [3,4,5]}')
returns
<map xmlns="http://www.w3.org/2005/xpath-functions">
<number key="x">1</number>
<array key="y">
<number>3</number>
<number>4</number>
<number>5</number>
</array>
</map>
.
The expression json-to-xml('"abcd"', map{'liberal': false()})
returns <string xmlns="http://www.w3.org/2005/xpath-functions">abcd</string>
.
The expression json-to-xml('{"x": "\\", "y": "\u0025"}')
returns
<map xmlns="http://www.w3.org/2005/xpath-functions">
<string key="x">\</string>
<string key="y">%</string>
</map>
.
The expression json-to-xml('{"x": "\\", "y": "\u0025"}', map{'escape': true()})
returns
<map xmlns="http://www.w3.org/2005/xpath-functions">
<string escaped="true" key="x">\\</string>
<string key="y">%</string>
</map>
. (But see the detailed rules for alternative values of the escaped
attribute
on the second string
element.)
The following example illustrates use of the fallback function to handle characters that are invalid in XML.
let $jsonstr := unparsed-text('http://example.com/endpoint'), $options := map { 'liberal': true(), 'fallback': function($char as xs:string) as xs:string { let $c0chars := map { '\u0000':'[NUL]', '\u0001':'[SOH]', '\u0002':'[STX]', ... '\u001E':'[RS]', '\u001F':'[US]' }, $replacement := $c0chars($char) return if (exists($replacement)) then $replacement else error(xs:QName('err:invalid-char'), 'Error: ' || $char || ' is not a C0 control character.') } } return json-to-xml($jsonstr, $options)
Converts an XML tree, whose format corresponds to the XML representation of JSON defined in this specification, into a string conforming to the JSON grammar.
fn:xml-to-json (
|
$input |
as node()? ,
|
$options |
as map(*) ) as xs:string? |
This function is deterministicFO30, context-independentFO30, and focus-independentFO30.
The effect of the one-argument form of this function is the same as calling the
two-argument form with an empty map as the value of the $options
argument.
The first argument $input
is a node; the subtree rooted at this node will typically be
the XML representation of a JSON document as defined in 22.1 XML Representation of JSON.
If $input
is the empty sequence, the function returns the empty sequence.
The $options
argument can be used to control the way in which the conversion
takes place. The option parameter conventions apply.
The entries that may appear in the $options
map are as follows:
Key | Value | Meaning |
---|---|---|
indent
|
Determines whether additional whitespace should be added to the output to improve
readability.
The required type is xs:boolean .
|
|
false
|
The processor must not insert any insignificant whitespace between JSON tokens. | |
true
|
The processor may insert whitespace between JSON tokens in order to improve readability. The specification imposes no constraints on how this is done. |
The node supplied as $input
must be one of the following: [ERR FOJS0006] FO31
An element node whose name matches the name of a global element declaration in the schema given in B.1 Schema for the XML Representation of JSON and whose type annotation matches the type of that element declaration (indicating that the element has been validated against this schema).
An element node whose name matches the name of a global element declaration in the
schema given in
B.1 Schema for the XML Representation of JSON,
and whose content
after stripping all attributes (at any depth) in namespaces other than http://www.w3.org/2005/xpath-functions
is such that validation against the schema given in B.1 Schema for the XML Representation of JSON would succeed.
Note:
The reason attributes in alien namespaces are stripped is to avoid the need for a
non-schema-aware
processor to take into account the effect of attributes such as xsi:type
and xsi:nil
that would affect the outcome of schema validation.
An element node E having a key
attribute and/or an escaped-key
attribute
provided that E would satisfy one of the above
conditions if the key
and/or escaped-key
attributes were removed.
A document node having exactly one element child and no text node children, where the element child satisfies any of the conditions above.
Furthermore, $input
must satisfy the following constraint
(which cannot be conveniently expressed in the schema). Every element M that is a descendant-or-self of
$input
and has local name map
and namespace URI http://www.w3.org/2005/xpath-functions
must satisfy the following rule: there must not be two distinct children of M (say C1 and C2)
such that the normalized key of C1 is equal to the normalized key of C2. The normalized key
of an element C is as follows:
If C has the attribute value escaped-key="true"
, then the value of the
key
attribute of C, with all JSON escape sequences replaced by the corresponding Unicode characters
according to the JSON escaping rules.
Otherwise (the escaped-key
attribute of C is absent or set to false),
the value of the key
attribute of C.
Nodes in the input tree are handled by applying the following rules, recursively.
In these rules the term
"an element named N" means "an element node whose local name is N and whose namespace URI is
http://www.w3.org/2005/xpath-functions
".
A document node having a single element node child is processed by processing that child.
An element named null
results in the output null
.
An element $E
named boolean
results in the output true
or false
depending on the result of xs:boolean(fn:string($E))
.
An element $E
named number
results in the output of the string
result of xs:string(xs:double(fn:string($E)))
An element named string
results in the output of the string value of the element, enclosed in
quotation marks, with any special characters in the string escaped as described below.
An element named array
results in the output of the children of the array
element,
each processed by applying these rules recursively: the items in the resulting list
are enclosed between square brackets,
and separated by commas.
An element named map
results in the output of a sequence of map entries corresponding to
the children of the map
element, enclosed between curly braces and separated by commas.
Each entry comprises the value of the key
attribute of the child element, enclosed in quotation marks
and escaped as described below, followed by a colon, followed by the result of processing
the child element
by applying these rules recursively.
Comments, processing instructions, and whitespace text node children of map
and array
are ignored.
Strings are escaped as follows:
If the attribute escaped="true"
is present for a string value, or escaped-key="true"
for a key value, then:
any valid JSON escape sequence present in the string is copied unchanged to the output;
any invalid JSON escape sequence results in a dynamic error [ERR FOJS0007] FO31;
any unescaped occurrence of quotation mark, backspace, form-feed, newline, carriage
return, tab, or solidus is replaced by
\"
, \b
, \f
, \n
, \r
, \t
or \/
respectively;
any other codepoint in the range 1-31 or 127-159 is replaced by an escape in the form \uHHHH where HHHH is the upper-case hexadecimal representation of the codepoint value.
Otherwise (that is, in the absence of the attribute escaped="true"
for a string value,
or escaped-key="true"
for a key value):
any occurrence of backslash is replaced by \\
any occurrence of quotation mark, backspace, form-feed, newline, carriage return,
or tab is
replaced by \"
, \b
, \f
, \n
, \r
, or \t
respectively;
any other codepoint in the range 1-31 or 127-159 is replaced by an escape in
the form \uHHHH
where HHHH
is the upper-case hexadecimal representation of the codepoint value.
A dynamic error is raised [ERR FOJS0005] FO31 if the value of
$options
includes an entry whose key is defined in this specification,
and whose value is not a permitted value for that key.
A dynamic error is raised [ERR FOJS0006] FO31 if the value of
$input
is not a document or element node or is not valid according to the schema for the
XML representation of
JSON, or if a map
element has two children whose normalized key values are the same.
A dynamic error is raised [ERR FOJS0007] FO31 if the value of
$input
includes a string labeled with escaped="true"
, or
a key labeled with escaped-key="true"
, where the content of the string or key
contains an invalid JSON escape sequence: specifically, where it contains a backslash
(\
) that is not followed by one
of the characters "
, \
, /
, b
, f
, n
,
r
, t
, or u
, or or where it contains the characters \u
not followed by four hexadecimal digits (that is [0-9A-Fa-f]{4}
).
The rule requiring schema validity has a number of consequences, including the following:
The input cannot contain no-namespace attributes, or attributes in the namespace http://www.w3.org/2005/xpath-functions
,
except where explicitly allowed by the schema. Attributes in other namespaces, however,
are ignored.
Nodes that do not affect schema validity, such as comments, processing instructions,
namespace nodes, and whitespace text node
children of map
and array
, are ignored.
Numeric values are restricted to those that are valid in JSON: the schema disallows positive and negative infinity and NaN.
Duplicate keys within a map are disallowed. Most cases of duplicate keys are prevented by the rules in the schema;
additional cases (where the keys are equal only after expanding JSON escape sequences)
are prevented by the prose rules
of this function. For example, the key values \n
and \u000A
are treated as duplicates even though
the rules in the schema do not treat them as such.
The rule allowing the top-level element to have a key
attribute (which is ignored)
allows any element in the output of the fn:json-to-xml
function
to be processed: for example, it is possible to take a JSON document, convert it to
XML, select
a subtree based on the value of a key
attribute, and then convert this subtree
back to JSON, perhaps after a transformation. The rule means that an element with
the appropriate name will be
accepted if it has been validated against one of the
types mapWithinMapType
, arrayWithinMapType
, stringWithinMapType
,
numberWithinMapType
, booleanWithinMapType
, or nullWithinMapType
.
The input <array xmlns="http://www.w3.org/2005/xpath-functions"><number>1</number><string>is</string><boolean>1</boolean></array>
produces the result [1,"is",true]
.
The input <map xmlns="http://www.w3.org/2005/xpath-functions"><number key="Sunday">1</number><number
key="Monday">2</number></map>
produces the result {"Sunday":1,"Monday":2}
.
Given an XML structure that does not use the XML representation of JSON defined in
22.1 XML Representation of JSON, there are two practical ways to convert it
to JSON: either perform a transformation to the XML representation of JSON and then
call the xml-to-json
function; or transform it to JSON directly
by using custom template rules.
To assist with the second approach, a stylesheet is provided in B.2 Stylesheet for converting XML to JSON. This stylesheet includes a function
j:xml-to-json
which, apart from being in a different namespace, is
functionally very similar to the xml-to-json
function described in
the previous section. (It differs in doing less validation
of the input than the function specification requires, and in the details of how
special characters are escaped.)
The implementation of the function is exposed, using template
rules to perform a recursive descent of the supplied input, and the behavior of the
function can therefore be customized (typically by importing the stylesheet and
adding additional template rules) to handle arbitrary XML input.
The stylesheet is provided under the W3C software license for the convenience of
users. There is no requirement for any conformant XSLT processor to make this
stylesheet available. Processors may implement the
xml-to-json
function by invoking this stylesheet (adapted
to achieve full conformance), but there is no requirement to do so.
<!-- Category: instruction -->
<xsl:message
select? = expression
terminate? = { boolean }
error-code? = { eqname } >
<!-- Content: sequence-constructor -->
</xsl:message>
The xsl:message
instruction sends a message in an implementation-defined way. The
xsl:message
instruction causes the creation of a new document,
which is typically serialized and output to an implementation-defined destination. The
result of the xsl:message
instruction is an empty sequence.
The content of the message may be specified by using either or both of the optional
select
attribute and the sequence constructor that forms the content of the
xsl:message
instruction.
If the xsl:message
instruction contains a sequence constructor, then the sequence
obtained by evaluating this sequence constructor is used to construct the content
of
the new document node, as described in 5.7.1 Constructing Complex Content.
If the xsl:message
instruction has a select
attribute,
then the value of the attribute must be an XPath expression. The
effect of the xsl:message
instruction is then the same as if a
single xsl:copy-of
instruction with this select
attribute were added to the start of the sequence constructor.
If the xsl:message
instruction has no content and no
select
attribute, then an empty message is produced.
The tree produced by the xsl:message
instruction is not technically
a final result tree. The tree has no
URI and processors are not required to make the tree accessible to
applications.
Note:
In many cases, the XML document produced using xsl:message
will
consist of a document node owning a single text node. However, it may contain a
more complex structure.
Note:
An implementation might implement xsl:message
by popping up an
alert box or by writing to a log file. Because the order of execution of
instructions is implementation-defined, the order in which such messages appear is
not predictable.
The terminate
attribute is interpreted as an attribute value template.
If the effective value of the
terminate
attribute is yes
, then the processor
must
signal a dynamic error after
sending the message. This error may be caught in the same
way as any other dynamic error using xsl:catch
. The
default value is no
. Note that because the order of evaluation of
instructions is implementation-dependent, this gives no guarantee that any particular
instruction will or will not be evaluated before processing terminates.
The optional error-code
attribute
(also interpreted as an attribute value template)
may be used to indicate the error code
associated with the message. This may be used irrespective of the value of
terminate
. The
effective value of the
error code attribute is expected to be an EQName. If no error code is specified, or if
the effective value is not a valid EQName, the error code will have local part
XTMM9000
and namespace URI
http://www.w3.org/2005/xqt-errors
. User-defined error codes
should be in a namespace other than
http://www.w3.org/2005/xqt-errors
. When the value of
terminate
is yes
, the error code may be matched in an
xsl:catch
element to catch the error and cause processing to
continue normally.
[ERR XTMM9000] When a transformation is terminated by use of <xsl:message
terminate="yes"/>
, the effect is the same as when a
dynamic error occurs during the transformation. The default error code is XTMM9000
; this may be
overridden using the error-code
attribute of the
xsl:message
instruction.
One convenient way to do localization is to put the localized information (message
text, etc.) in an XML document, which becomes an additional input file to the
stylesheet. For example, suppose
messages for a language
L
are stored in an XML file resources/L.xml
in the
form:
<messages> <message name="problem">A problem was detected.</message> <message name="error">An error was detected.</message> </messages>
Then a stylesheet could use the following approach to localize messages:
<xsl:param name="lang" select="'en'"/> <xsl:variable name="messages" select="document(concat('resources/', $lang, '.xml'))/messages"/> <xsl:template name="localized-message"> <xsl:param name="name"/> <xsl:message select="string($messages/message[@name=$name])"/> </xsl:template> <xsl:template name="problem"> <xsl:call-template name="localized-message"> <xsl:with-param name="name">problem</xsl:with-param> </xsl:call-template> </xsl:template>
Any dynamic error that occurs while
evaluating the select
expression or the contained sequence constructor, and any serialization error that occurs while
processing the result, does not cause the transformation to
fail; at worst, it means that no message is output, or that the only message that
is output is one that relates to the error that occurred.
Note:
An example of such an error is the serialization error that occurs when processing
the instruction <xsl:message select="@code"/>
(on the grounds
that free-standing attributes cannot be serialized). Making such errors
recoverable means that it is implementation-defined whether or not they are
signaled to the user and whether they cause termination of the transformation. If
the processor chooses to recover from the error, the content of any resulting
message is implementation-dependent.
One possible recovery action is to include a description of the error in the generated message text.
The xsl:assert
instruction is used to assert that the value of a
particular expression is true; if the value of the expression is false, and
assertions are enabled, then a dynamic error occurs.
<!-- Category: instruction -->
<xsl:assert
test = expression
select? = expression
error-code? = { eqname } >
<!-- Content: sequence-constructor -->
</xsl:assert>
By default, assertions are disabled.
An implementation must provide an external mechanism to enable or disable assertion checking. This may work either statically or dynamically, and may be at the level of the stylesheet as a whole, or at the level of an individual package, or otherwise. The detail of such mechanisms is implementation-defined.
If assertion checking is enabled, the instruction is evaluated as follows:
The expression in the test
attribute is evaluated. If the
effective boolean value of the result is true
, the assertion
succeeds, and no further action is taken. If the effective boolean value is
false, or if a dynamic error occurs during evaluation of the expression, then
the assertion fails.
If the assertion fails, then the effect of the instruction is governed by the
rules for evaluation of an xsl:message
instruction with the
same select
attribute, error-code
attribute, and
contained sequence constructor, and with the value
terminate="yes"
. However, the default error code if the
error-code
attribute is omitted is XTMM9001
rather
than XTMM9000
.
Note:
To the extent that the behavior of xsl:message
is implementation-defined, this rule does not prevent an
implementation treating xsl:assert
and
xsl:message
differently.
Note:
If evaluation of the test
expression
fails with a dynamic error, the effect is exactly the same as if the
evaluation returns false
, including the fact that the
instruction fails with error code XTMM9001
.
If an assertion fails, then the following sibling
instructions of the xsl:assert
instruction are not
evaluated.
Note:
This means that xsl:assert
can
be used (rather like xsl:if
and
xsl:choose
) to prevent subsequent instructions from
executing if a particular precondition is not true, which might be useful if
the subsequent instructions have side-effects (for example, by calling
extension functions) or if they can fail in uncatchable ways (for example,
non-terminating recursion). It is worth noting that there are limits to this
guarantee. It does not ensure, for example, that when an assertion within a
template fails, the following siblings of the
xsl:call-template
instruction that invokes that template
will not be evaluated; nor does it ensure that if an assertion fails while
processing the first item of a sequence using xsl:for-each
,
then subsequent items in the sequence will not be processed.
[ERR XTMM9001] When a transformation is terminated by use of xsl:assert
, the
effect is the same as when a dynamic error occurs during the
transformation. The default error code is XTMM9001
; this may be
overridden using the error-code
attribute of the
xsl:assert
instruction.
As with any other dynamic error, an error caused by an assertion failing may be
trapped using xsl:try
: see 8.3 Try/Catch.
The result of the xsl:assert
instruction is an empty sequence.
The following example shows a stylesheet function that checks that the value of
its supplied argument is in range. The check is performed only if the static parameter
$DEBUG
is set to true.
<xsl:param name="DEBUG" as="xs:boolean" select="false()" static="yes" required="no"/> <xsl:function name="f:days-elapsed" as="xs:integer"> <xsl:param name="date" as="xs:date"/> <xsl:assert use-when="$DEBUG" test="$date lt current-date()"/> <xsl:sequence select="(current-date() - $since) div xs:dayTimeDuration('PT1D')"/> </xsl:function>
Note:
Implementations should avoid optimizing xsl:assert
instructions
away. As a guideline, if the result of a sequence constructor is required by the
transformation, the implementation should ensure that all
xsl:assert
instructions in that sequence constructor are
evaluated. Conversely, if the result of a sequence constructor is not required by
the transformation, its xsl:assert
instructions should not be
evaluated.
This guidance is not intended to prevent optimizations such as lazy evaluation, where evaluation of a sequence constructor may finish early, as soon as enough information is available to evaluate the containing instruction.
An implementation may provide a user option allowing a processor to treat assertions as being true without explicit checking. This option must not be enabled by default. If such an option is in force, the effect of any assertion not being true is implementation-dependent.
Note:
For example, given the assertion <xsl:assert
test="count(//title)=1"/>
, a processor might generate code for the
expression <xsl:value-of select="//title"/>
that stops searching
for title
elements after finding the first one. In the event that the
source document contains more than one title
, execution of the
stylesheet may fail in arbitrary ways, or it may produce incorrect output.
XSLT allows two kinds of extension, extension instructions and extension functions.
[Definition: An extension instruction is an element within a sequence constructor that is in a namespace (not the XSLT namespace) designated as an extension namespace.]
[Definition: An extension function is a named function introduced to the static or dynamic context by mechanisms outside the scope of this specification.]
This specification does not define any mechanism for creating or binding implementations of extension instructions or extension functions, and it is not required that implementations support any such mechanism. Such mechanisms, if they exist, are implementation-defined. Therefore, an XSLT stylesheet that must be portable between XSLT implementations cannot rely on particular extensions being available. XSLT provides mechanisms that allow an XSLT stylesheet to determine whether the implementation makes particular extensions available, and to specify what happens if those extensions are not available. If an XSLT stylesheet is careful to make use of these mechanisms, it is possible for it to take advantage of extensions and still retain portability.
[ERR XTSE0085] It is a static error to use a reserved namespace
in the name of any extension function or extension instruction,
other than a function or instruction defined in this specification or in a normatively
referenced specification. It is a static error to use a prefix bound
to a reserved namespace in the [xsl:]extension-element-prefixes
attribute.
The set of functions that can be called from a FunctionCallXP30 within an XPath expression may include one or more extension functions. The expanded QName of an extension function always has a non-null namespace URI, which must not be the URI of a reserved namespace.
Note:
The definition of the term extension function is written to exclude
user-written stylesheet functions,
constructor functions for built-in and user-defined types, functions in the fn
, math
,
map
, and array
namespaces,
anonymous XPath inline functions, maps and arrays (see 27.7.1 Arrays),
and partial function applications (including partial applications of extension functions).
It also excludes
functions obtained by invoking XPath-defined functions such as
load-xquery-module
FO31.
The definition allows extension functions to be discovered at evaluation time (typically
using
function-lookup
FO30) rather than necessarily being known statically.
Technically, the definition of extension functions excludes anonymous functions obtained by calling or partially applying other extension functions. Since such functions are by their nature implementation-defined, they may however share some of the characteristics of extension functions.
Determines whether a particular function is or is not available for use. The function
is
particularly useful for calling within an [xsl:]use-when
attribute (see
3.13.1 Conditional Element Inclusion) to test whether a particular extension function is available.
fn:function-available (
|
$function-name |
as xs:string ,
|
$arity |
as xs:integer ) as xs:boolean |
This function is deterministicFO30, context-dependentFO30, and focus-independentFO30. It depends on namespaces, and known function signatures.
A function is said to be available within an XPath expression if it is present in the statically known function signaturesXP30 for that expression (see 5.3.1 Initializing the Static Context). Functions in the static context are uniquely identified by the name of the function (a QName) in combination with its arity.
The value of the $function-name
argument must be a
string containing an EQName. The lexical QName is
expanded into an expanded QName using the
namespace declarations in scope for the expression. If the value is an unprefixed lexical QName, then the standard function namespace is used in
the expanded QName.
The two-argument version of the function-available
function returns
true if and only if there is an available function whose name matches the value of
the
$function-name
argument and whose arity matches the value of the $arity
argument.
The single-argument version of the function-available
function
returns true if and only if there is at least one available function (with some arity)
whose name matches the value of the $function-name
argument.
When the containing expression is evaluated with XPath 1.0 compatibility mode set to
true, the function-available
function returns false in
respect of a function name and arity for which no implementation is available (other
than the fallback error function that raises a dynamic error whenever it is called).
This means that it is possible (as in XSLT 1.0) to use logic such as the following
to
test whether a function is available before calling it:
<summary xsl:version="1.0"> <xsl:choose> <xsl:when test="function-available('my:summary')"> <xsl:value-of select="my:summary()"/> </xsl:when> <xsl:otherwise> <xsl:text>Summary not available</xsl:text> </xsl:otherwise> </xsl:choose> </summary>
[ERR XTDE1400] It is a dynamic error if the argument does not evaluate to a string that is a valid EQName, or if the value is a lexical QName with a prefix for which no namespace declaration is present in the static context. If the processor is able to detect the error statically (for example, when the argument is supplied as a string literal), then the processor may optionally signal this as a static error.
The fact that a function with a given name is available gives no guarantee that any particular call on the function will be successful. For example, it is not possible to determine the types of the arguments expected.
The introduction of the function-lookup
FO30
function in XPath 3.0 reduces the need for function-available
,
since function-lookup
FO30 not only tests whether a function is
available, but also returns a function item that enables it to be dynamically
called.
If a function is present in the static context but with no useful
functionality (for example, if the system has been configured for security reasons
so
that available-environment-variables
FO30 returns no information),
then function-available
when applied to that function should return
false.
It is not necessary that there be a direct equivalence between the
results of function-available
and
function-lookup
FO30 in all cases. For example, there may be
extension functions whose side-effects
are such that for security reasons, dynamic calls to the function are disallowed;
function-lookup
FO30 might then not provide access to the function.
The main use-case for function-available
, by contrast, is for use
in [xsl:]use-when
conditions to test whether static calls on the function
are possible.
A stylesheet that is designed to use XSLT 2.0 facilities when running under an XSLT 2.0 or XSLT 3.0 processor, but to fall back to XSLT 1.0 capabilities when not, might be written using the code:
<out xsl:version="2.0"> <xsl:choose> <xsl:when test="function-available('matches')"> <xsl:value-of select="matches(/doc/title, '[a-z]*')"/> </xsl:when> <xsl:otherwise> <xsl:value-of select="string-length( translate(/doc/title, 'abcdefghijklmnopqrstuvwxyz', '')) = 0"/> </xsl:otherwise> </xsl:choose> </out>
Here an XSLT 2.0 or XSLT 3.0 processor will
always take the xsl:when
branch, while a 1.0 processor will
follow the xsl:otherwise
branch. The single-argument version of
the function-available
function is used here, because that is
the only version available in XSLT 1.0. Under the rules of XSLT 1.0, the call on
the matches
function is not an error, because it is never
evaluated.
A stylesheet that is designed to use facilities in some future XSLT version when
they are available, but to fall back to XSLT 2.0 or XSLT
3.0 capabilities when not, might be written using code such as the
following. This hypothesizes the availability in some future version of a function
pad
which pads a string to a fixed length with spaces:
<xsl:value-of select="pad(/doc/title, 10)" use-when="function-available('pad', 2)"/> <xsl:value-of select="concat(/doc/title, string-join( for $i in 1 to 10 - string-length(/doc/title) return ' ', ''))" use-when="not(function-available('pad', 2))"/>
In this case the two-argument version of function-available
is used, because there is no requirement for this code to run under XSLT 1.0.
If the function name used in a FunctionCallXP30 within an XPath expression identifies an extension function, then to evaluate the FunctionCallXP30, the processor will first evaluate each of the arguments in the FunctionCallXP30. If the processor has information about the datatypes expected by the extension function, then it may perform any necessary type conversions between the XPath datatypes and those defined by the implementation language. If multiple extension functions are available with the same name, the processor may decide which one to invoke based on the number of arguments, the types of the arguments, or any other criteria. The result returned by the implementation is returned as the result of the function call, again after any necessary conversions between the datatypes of the implementation language and those of XPath. The details of such type conversions are outside the scope of this specification.
[ERR XTDE1420] It is a dynamic error if the arguments supplied to a call on an extension function do not satisfy the rules defined for that particular extension function, or if the extension function reports an error, or if the result of the extension function cannot be converted to an XPath value.
Note:
Implementations may also provide mechanisms allowing extension functions to report recoverable dynamic errors, or to execute within an environment that treats some or all of the errors listed above as recoverable.
[ERR XTDE1425] When the containing element is processed with XSLT 1.0 behavior, it is a dynamic error to evaluate an extension function call if no implementation of the extension function is available.
Note:
When XSLT 1.0 behavior is not enabled, this is a static error [ERR XPST0017] XP30.
Note:
There is no prohibition on calling extension functions that have side-effects (for example, an extension function that writes data to a file). However, the order of execution of XSLT instructions is not defined in this specification, so the effects of such functions are unpredictable.
Implementations are not required to perform full validation of values returned by extension functions. It is an error for an extension function to return a string containing characters that are not permitted in XML, but the consequences of this error are implementation-defined. The implementation may raise an error, may convert the string to a string containing valid characters only, or may treat the invalid characters as if they were permitted characters.
Note:
The ability to execute extension functions represents a potential security weakness, since untrusted stylesheets may invoke code that has privileged access to resources on the machine where the processor executes. Implementations may therefore provide mechanisms that restrict the use of extension functions by untrusted stylesheets.
All observations in this section regarding the errors that can occur when invoking extension functions apply equally when invoking extension instructions.
An implementation may allow an extension function to return an
object that does not have any natural representation in the XDM data model,
whether as an atomic value, a node, or a function
item. For example, an extension function sql:connect
might return an object that represents a connection to a relational database; the
resulting connection object might be passed as an argument to calls on other
extension functions such as sql:insert
and
sql:select
.
The way in which such objects are represented in the type system is implementation-defined. They might be
represented by a completely new datatype, or they might be mapped to existing
datatypes such as integer
, string
, or
anyURI
.
Used to control how a stylesheet behaves if a particular schema type is or is not available in the static context.
This function is deterministicFO30, context-dependentFO30, and focus-independentFO30. It depends on namespaces, and schema definitions.
A schema type (that is, a simple type or a complex type) is said to be available within
an XPath expression if it is a type definition that is present in the in-scope schema typesXP30 for that expression
(see 5.3.1 Initializing the Static Context). This includes built-in types, types imported
using xsl:import-schema
, and extension types defined by the
implementation.
The value of the $type-name
argument must be a string
containing an EQName. The EQName is expanded into an expanded QName using the namespace declarations in
scope for the expression. If the value is an
unprefixed lexical QName, then the default namespace is used in the expanded QName.
The function returns true if and only if there is an available type whose name matches
the value of the $type-name
argument.
[ERR XTDE1428] It is a dynamic error if the argument does not evaluate to a string that is a valid EQName, or if the value is a lexical QName with a prefix for which no namespace declaration is present in the static context. If the processor is able to detect the error statically (for example, when the argument is supplied as a string literal), then the processor may optionally signal this as a static error.
The type-available
function is of limited use within an
[xsl:]use-when
expression, because the static context for the expression
does not include any user-defined types.
[Definition: The extension instruction mechanism allows namespaces to be designated as extension namespaces. When a namespace is designated as an extension namespace and an element with a name from that namespace occurs in a sequence constructor, then the element is treated as an instruction rather than as a literal result element.] The namespace determines the semantics of the instruction.
Note:
Since an element that is a child of an xsl:stylesheet
element is
not occurring in a sequence
constructor
, user-defined data elements (see
3.7.3 User-defined Data Elements) are not extension elements as defined
here, and nothing in this section applies to them.
A namespace is designated as an extension namespace by using an
[xsl:]extension-element-prefixes
attribute on an element in the
stylesheet (see 3.4 Standard Attributes). The attribute
must be in the XSLT namespace only if its parent element is
not in the XSLT namespace. The value of the attribute is a
whitespace-separated list of namespace prefixes. The namespace bound to each of
the prefixes is designated as an extension namespace.
The default namespace (as declared by xmlns
) may be designated as an
extension namespace by including #default
in the list of namespace
prefixes.
A reserved namespace cannot be designated as an extension namespace: see [see ERR XTSE0085].
[ERR XTSE1430] It is a static error if there is no
namespace bound to the prefix on the element bearing the
[xsl:]extension-element-prefixes
attribute or, when
#default
is specified, if there is no default namespace.
The designation of a namespace as an extension namespace is effective for the
element bearing the [xsl:]extension-element-prefixes
attribute and
for all descendants of that element within the same stylesheet module.
Determines whether a particular instruction is or is not available for use. The function
is particularly useful for calling within an [xsl:]use-when
attribute (see
3.13.1 Conditional Element Inclusion) to test whether a particular extension instruction is available.
This function is deterministicFO30, context-dependentFO30, and focus-independentFO30. It depends on namespaces.
The value of the $element-name
argument
must be a string containing an EQName. If it is a lexical QName
with a prefix, then it is expanded into an expanded
QName using the namespace declarations in the static context of the
expression. If there is a default namespace in
scope, then it is used to expand an unprefixed lexical
QName.
If the resulting expanded QName is in the XSLT namespace, the function returns true if and only if the local name matches the name of an XSLT element that is defined in this specification and implemented by the XSLT processor.
If the expanded QName has a null namespace
URI, the element-available
function will return false.
If the expanded QName is not in the XSLT namespace, the function returns true if and only if the processor has an implementation available of an extension instruction with the given expanded QName. This applies whether or not the namespace has been designated as an extension namespace.
If the processor does not have an implementation of a particular extension instruction available, and such an extension instruction is evaluated, then the processor must perform fallback for the element as specified in 24.2.3 Fallback. An implementation must not signal an error merely because the stylesheet contains an extension instruction for which no implementation is available.
[ERR XTDE1440] It is a dynamic error if the argument does not evaluate to a string that is a valid EQName, or if the value is a lexical QName with a prefix for which no namespace declaration is present in the static context. If the processor is able to detect the error statically (for example, when the argument is supplied as a string literal), then the processor may optionally signal this as a static error.
For element names in the XSLT namespace:
This function can be useful to distinguish processors that implement XSLT 3.0 from processors that implement other (older or newer) versions of the specification, and to distinguish full implementations from incomplete implementations. (Incomplete implementations, of course, cannot be assumed to behave as described in this specification.)
In earlier versions of this specification,
element-available
was defined to return true only for
elements classified as instructions. The distinction between instructions and
other elements, however, is sometimes rather technical, and in XSLT 3.0 the effect
of the function has therefore been aligned to do what its name might suggest.
If an instruction is recognized but offers no useful
functionality (for example, if the system has been configured for security reasons
so that xsl:evaluate
always raises an error), then
element-available
when applied to that instruction
should return false.
For element names in other namespaces:
The result of the element-available
does not depend on
whether or not the namespace of the supplied instruction name has been designated
as an extension element namespace; it tests whether the instruction would be
available if the namespace were designated as such.
<!-- Category: instruction -->
<xsl:fallback>
<!-- Content: sequence-constructor -->
</xsl:fallback>
The content of an xsl:fallback
element is a sequence constructor, and when
performing fallback, the value returned by the xsl:fallback
element is the result of evaluating this sequence constructor.
When not performing fallback, evaluating an xsl:fallback
element
returns an empty sequence: the content of the xsl:fallback
element is not evaluated.
There are two situations where a processor performs fallback: when an extension instruction that is not available is evaluated, and when an instruction in the XSLT namespace, that is not defined in XSLT 3.0, is evaluated within a region of the stylesheet for which forwards compatible behavior is enabled.
Note:
Fallback processing is not invoked in other situations, for example it is not
invoked when an XPath expression uses unrecognized syntax or contains a call to
an unknown function. To handle such situations dynamically, the stylesheet
should call functions such as system-property
and
function-available
to decide what capabilities are
available.
[ERR XTDE1450] When a processor performs fallback for
an extension instruction
that is not recognized, if the instruction element has one or more
xsl:fallback
children, then the content of each of the
xsl:fallback
children must be
evaluated; it is a dynamic error if it has no
xsl:fallback
children.
Note:
This is different from the situation with unrecognized XSLT elements. As explained in 3.10 Forwards Compatible Processing, an unrecognized XSLT element appearing within a sequence constructor is a static
error unless (a) forwards compatible behavior is enabled,
and (b) the instruction has an xsl:fallback
child.
The output of a transformation includes a principal result and zero or more secondary results.
The way in which these results are delivered to an application is implementation-defined.
Serialization of results is described further in 26 Serialization
<!-- Category: instruction -->
<xsl:result-document
format? = { eqname }
href? = { uri }
validation? = "strict" | "lax" | "preserve" | "strip"
type? = eqname
method? = { "xml" | "html" | "xhtml" | "text" | "json" | "adaptive" | eqname }
allow-duplicate-names? = { boolean }
build-tree? = { boolean }
byte-order-mark? = { boolean }
cdata-section-elements? = { eqnames }
doctype-public? = { string }
doctype-system? = { string }
encoding? = { string }
escape-uri-attributes? = { boolean }
html-version? = { decimal }
include-content-type? = { boolean }
indent? = { boolean }
item-separator? = { string }
json-node-output-method? = { "xml" | "html" | "xhtml" | "text" | eqname }
media-type? = { string }
normalization-form? = { "NFC" | "NFD" | "NFKC" | "NFKD" | "fully-normalized" | "none"
| nmtoken }
omit-xml-declaration? = { boolean }
parameter-document? = { uri }
standalone? = { boolean | "omit" }
suppress-indentation? = { eqnames }
undeclare-prefixes? = { boolean }
use-character-maps? = eqnames
output-version? = { nmtoken } >
<!-- Content: sequence-constructor -->
</xsl:result-document>
The xsl:result-document
instruction is
used to create a secondary result. The content of the
xsl:result-document
element is a sequence constructor,
and the value of the
secondary result (known as the raw result)
is the immediate result of this
sequence constructor.
As with the principal result of the transformation, a secondary result may be delivered to the calling application in three ways (see 2.3.6 Post-processing the Raw Result):
The raw result may be delivered as is.
The raw result may be used to construct a final result tree by invoking the process of sequence normalizationSER30.
The raw result may be serialized to a sequence of octets (which may then, optionally, be saved to a persistent storage location).
The decision whether or not to serialize the raw result depends on the processor and on the way it is invoked. This is implementation-defined, and it is not controlled by anything in the stylesheet.
If the result is not serialized, then the decision whether to
return the raw result or to construct a tree depends on the effective
value of the build-tree
attribute. If the effective value of
the build-tree
attribute is yes
, then
a final result tree is created
by invoking the process of sequence normalizationSER30. The default for the
build-tree
attribute depends on the serialization method. For the
xml
, html
, xhtml
, and text
methods the default value is yes
. For
the json
and adaptive
methods (available only with XPath
3.1) the default value is no
.
The xsl:result-document
instruction
defines a URI that may be used to identify the secondary result.
The instruction may optionally specify the output format to be used for serializing
the result.
Technically, the result of evaluating the xsl:result-document
instruction is an empty sequence. This means it does not contribute anything to the
result of the sequence constructor it is part of.
The effective value of the
format
attribute, if specified, must be an EQName. The value is
expanded using the namespace declarations in scope for the
xsl:result-document
element. The resulting expanded QName
must match the expanded QName of a named output definition in the stylesheet. This identifies the
xsl:output
declaration that will control the serialization of the
final result tree (see 26 Serialization), if the result tree is serialized. If the
format
attribute is omitted, the unnamed output definition is used to control
serialization of the result tree.
[ERR XTDE1460] It is a dynamic error if the effective value of the
format
attribute is not a valid
EQName, or if it does not match the
expanded QName of an output definition in the containing package. If the processor is able to detect
the error statically (for example, when the format
attribute
contains no curly brackets), then the processor may
optionally signal this as a static
error.
Note:
The only way to select the unnamed output
definition is to omit the format
attribute.
The parameter-document
attribute allows serialization
parameters to be supplied in an external document. The external document must contain
an output:serialization-parameters
element with the format described in
Section
3.1 Setting Serialization Parameters by Means of a Data Model Instance
SER30, and the parameters are
interpreted as described in that specification.
If present, the effective value of the URI supplied in the
parameter-document
attribute is dereferenced, after resolution
against the base URI of the xsl:result-document
element if it is a
relative reference.
The parameter document should be read during run-time evaluation of the stylesheet.
If the location of the stylesheet at development time is
different from the deployed location, any relative reference should be resolved
against the deployed location. A serialization error occurs if the result of
dereferencing the URI is ill-formed or invalid; but if no document can be found at
the specified location, the attribute should
be ignored.
A serialization parameter specified in the
parameter-document
takes precedence over a value supplied directly as
an attribute of xsl:result-document
, which in turn takes precedence
over a value supplied in the selected output definition, except that the values of
the cdata-section-elements
and suppress-indentation
attributes are merged in the same way as when multiple xsl:output
declarations are merged.
The attributes method
, allow-duplicate-names
, build-tree
, byte-order-mark
cdata-section-elements
, doctype-public
,
doctype-system
, encoding
,
escape-uri-attributes
, html-version
, indent
, item-separator
,
json-node-output-method
,
media-type
, normalization-form
,
omit-xml-declaration
, standalone
, suppress-indentation
,
undeclare-prefixes
, use-character-maps
, and
output-version
may be used to override attributes defined in the
selected output definition.
With the exception of use-character-maps
, these attributes are all
defined as attribute value
templates, so their values may be set dynamically. For any of these
attributes that is present on the xsl:result-document
instruction,
the effective value of the attribute
overrides or supplements the corresponding value from the output definition. This
works in the same way as when one xsl:output
declaration overrides
another. Some of the attributes have more specific
rules:
In the case of cdata-section-elements
and suppress-indentation
, the
value of the serialization parameter is the union of the expanded names of the
elements named in this instruction and the elements named in the selected
output definition.
In the case of use-character-maps
, the character maps referenced
in this instruction supplement and take precedence over those defined in the
selected output definition.
In the case of doctype-public
and doctype-system
,
setting the effective value of the attribute to a zero-length string has the
effect of overriding any value for these attributes obtained from the output
definition. The corresponding serialization parameter is not set (is
“absent”).
In the case of item-separator
, setting the effective value of the
attribute to the special value "#absent"
has the effect of
overriding any value for this attribute obtained from the output definition.
The corresponding serialization parameter is not set (is “absent”). It is not
possible to set the value of the serialization parameter to the literal
7-character string "#absent"
.
In all other cases, the effective value of an attribute actually present on this instruction takes precedence over the value defined in the selected output definition.
Note:
In the case of the attributes method
,
cdata-section-elements
, suppress-indentation
, and
use-character-maps
, the effective value of the attribute contains a space-separated list of
EQNames. If any of these is a lexical QName with a prefix, the prefix is
expanded using the in-scope namespaces for the
xsl:result-document
element. In the case of
cdata-section-elements
and suppress-indentation
, an
unprefixed element name is expanded using the default namespace. In the case of
the method
attribute, if the method is not one of the system-defined
methods (xml, html, xhtml, text) then the expanded name must have a non-absent
namespace.
Unless the processor implements the XPath 3.1 Feature, the method
values json
and
adaptive
must be rejected as invalid, and the attributes
allow-duplicate-names
and json-node-output-method
must be ignored. The meaning of these output methods and
serialization parameters is defined in [XSLT and XQuery Serialization 3.1].
The output-version
attribute on the xsl:result-document
instruction overrides the version
attribute on
xsl:output
(it has been renamed because version
is
available with a different meaning as a standard attribute: see 3.4 Standard Attributes). In all other cases, attributes correspond if they
have the same name.
There are some serialization parameters that apply to some output methods but not
to
others. For example, the indent
attribute has no effect on the
text
output method. If a value is supplied for an attribute that is
inapplicable to the output method, its value is not passed to the serializer. The
processor may validate the value of such an attribute, but is not
required to do so.
The item-separator
serialization parameter
is used when the raw result is used to construct a result tree
by applying sequence normalization, and it is also used when the result tree is
serialized. For example, if the sequence constructor delivers a sequence of
integers, and the text
serialization method is used, then the result of serialization
will be a string obtained by converting each integer to a string, and separating the
strings using the defined item-separator
.
The href
attribute is optional. The default value is the zero-length
string. The effective value of the
attribute must be a URI
Reference, which may be absolute or relative. If it is relative, then it is resolved against the base output URI. There may be implementation-defined restrictions on
the form of absolute URI that may be used, but the implementation is not
required to enforce any restrictions. Any valid relative URI
reference
must be accepted. Note that the zero-length string is a valid
relative URI reference.
If the implementation provides an API to access secondary results, then it
must allow a secondary result to be identified by means of the
absolutized value of the href
attribute. In addition, if a final result tree is constructed (that is, if the effective value of
build-tree
is yes
), then this value is used as the base
URI of the document node at the root of the final
result tree.
Note:
The base URI of the final result tree is not necessarily the same thing as the URI of its serialized representation on disk, if any. For example, a server (or browser client) might store final result trees only in memory, or in an internal disk cache. As long as the processor satisfies requests for those URIs, it is irrelevant where they are actually written on disk, if at all.
Note:
It will often be the case that one final result tree contains links to another final result tree produced during the same transformation, in the form of a relative URI reference. The mechanism of associating a URI with a final result tree has been chosen to allow the integrity of such links to be preserved when the trees are serialized.
As well as being potentially significant in any API that provides access to final result trees, the base URI of the new document node is relevant if the final result tree, rather than being serialized, is supplied as input to a further transformation.
The optional attributes type
and validation
may be used on
the xsl:result-document
instruction to validate the contents of
a final result tree, and to determine the type
annotation that elements and attributes within the final result tree will carry. The permitted
values and their semantics are described in 25.4.2 Validating Document Nodes. Any such validation is applied to the
document node produced as the result of sequence normalizationSER30.
If sequence normalization does not take place (typically because the raw result
is delivered to the application directly, or because the selected serialization method
does not involve sequence normalization) then the validation
and
type
attributes are ignored.
Note:
Validation applies after inserting item separators as determined by the
item-separator
serialization parameter, and an inappropriate choice
of item-separator
may cause the result to become invalid.
A processor
may allow a final result
tree to be serialized. Serialization is described in 26 Serialization. However, an implementation (for example, a processor running in an environment with no access to
writable filestore) is not required to support the serialization
of final result trees. An
implementation that does not support the serialization of final result trees
may ignore the format
attribute and the
serialization attributes. Such an implementation must provide the
application with some means of access to the (un-serialized) result tree, using its
URI to identify it.
Implementations may provide additional mechanisms, outside the scope of this
specification, for defining the way in which final result trees are processed. Such mechanisms
may make use of the XSLT-defined attributes on the
xsl:result-document
and/or xsl:output
elements,
or they may use additional elements or attributes in an implementation-defined namespace.
The following example takes an XHTML document as input, and breaks it up so that
the text following each <h1> element is included in a separate document. A
new document toc.html
is constructed to act as an index:
<xsl:stylesheet version="3.0" xmlns:xsl="http://www.w3.org/1999/XSL/Transform" xmlns:xhtml="http://www.w3.org/1999/xhtml"> <xsl:output name="toc-format" method="xhtml" indent="yes" doctype-system="http://www.w3.org/TR/xhtml1/DTD/xhtml1-strict.dtd" doctype-public="-//W3C//DTD XHTML 1.0 Strict//EN"/> <xsl:output name="section-format" method="xhtml" indent="no" doctype-system="http://www.w3.org/TR/xhtml1/DTD/xhtml1-transitional.dtd" doctype-public="-//W3C//DTD XHTML 1.0 Transitional//EN"/> <xsl:template match="/"> <xsl:result-document href="toc.html" format="toc-format" validation="strict"> <html xmlns="http://www.w3.org/1999/xhtml"> <head><title>Table of Contents</title></head> <body> <h1>Table of Contents</h1> <xsl:for-each select="/*/xhtml:body/(*[1] | xhtml:h1)"> <p> <a href="section{position()}.html"> <xsl:value-of select="."/> </a> </p> </xsl:for-each> </body> </html> </xsl:result-document> <xsl:for-each-group select="/*/xhtml:body/*" group-starting-with="xhtml:h1"> <xsl:result-document href="section{position()}.html" format="section-format" validation="strip"> <html xmlns="http://www.w3.org/1999/xhtml"> <head><title><xsl:value-of select="."/></title></head> <body> <xsl:copy-of select="current-group()"/> </body> </html> </xsl:result-document> </xsl:for-each-group> </xsl:template> </xsl:stylesheet>
xsl:result-document
There are restrictions on the use of the xsl:result-document
instruction, designed to ensure that the results are fully interoperable even when
processors optimize the sequence in which instructions are evaluated. Informally,
the
restriction is that the xsl:result-document
instruction can only be
used while writing a final result tree, not while writing to a temporary tree or a
sequence. This restriction is defined formally as follows.
[Definition: Each instruction in the stylesheet is evaluated in one of two possible output states: final output state or temporary output state ].
[Definition: The first of the two output states is called final output state. This state applies when instructions are writing to a final result tree.]
[Definition: The second of the two output states is called temporary output state. This state applies when instructions are writing to a temporary tree or any other non-final destination.]
The instructions in the initial named template are evaluated in
final output state. An instruction
is evaluated in the same output state as its
calling instruction, except that xsl:variable
,
xsl:param
, xsl:with-param
,
xsl:function
, xsl:key
, xsl:sort
,
xsl:accumulator-rule
, and
xsl:merge-key
always evaluate the instructions in their
contained sequence constructor in
temporary output state.
[ERR XTDE1480] It is a dynamic error to evaluate the
xsl:result-document
instruction in temporary output state.
[ERR XTDE1490] It is a dynamic error for a transformation to generate two or more final result trees with the same URI.
Note:
Note, this means that it is an error to evaluate more than one
xsl:result-document
instruction that omits the
href
attribute, or to evaluate any
xsl:result-document
instruction that omits the
href
attribute if an initial final result tree is created implicitly.
In addition, an implementation may report this error if it is able to detect that two or more final result trees are generated with different URIs that refer to the same physical resource.
[ERR XTDE1500] It is a dynamic error for a stylesheet to write to an external resource and read from the same resource during a single transformation, if the same absolute URI is used to access the resource in both cases.
In addition, an implementation may report this error if it is able to detect that a transformation writes to a resource and reads from the same resource using different URIs that refer to the same physical resource. Note that if the error is not detected, it is implementation-dependent whether the document that is read from the resource reflects its state before or after the result tree is written.
[Definition: The current output URI is the URI associated with the principal result or secondary result that is currently being written.]
Returns the value of the current output URI.
This function is deterministicFO30, focus-independentFO30, and context-dependentFO30.
On initial invocation of a stylesheet component, the current output uri is set to the base output URI.
During execution of an xsl:result-document
instruction with an href
attribute, the current output URI changes to the absolute URI obtained by resolving
the effective value
of the href
attribute against the base output URI.
The current output URI is cleared (set to absent) while evaluating stylesheet functions, dynamic function calls, evaluation of global variables, stylesheet parameters, and patterns. If the function is called when the current output URI is absent, the function returns the empty sequence.
The current output URI may also be absent in the event that a stylesheet is invoked without supplying a base output URI.
The current output URI is not cleared when evaluating a local variable, even though
xsl:result-document
cannot be used while evaluating a local variable.
The reason for this is to allow the value of current-output-uri
to be set as the value of a
tunnel parameter, so that the original
base output URI is accessible even when writing nested result documents.
It is possible to control the type annotation applied to
individual element and attribute nodes as they are constructed. This is done using
the type
and validation
attributes of the
xsl:element
, xsl:attribute
,
xsl:copy
, xsl:copy-of
,
xsl:document
, and xsl:result-document
instructions, or the xsl:type
and xsl:validation
attributes
of a literal result element.
The same attributes are used on
xsl:source-document
and xsl:merge-source
to control
validation of input documents.
The [xsl:]type
attribute is used to request validation of an element or
attribute against a specific simple or complex type defined in a schema. The
[xsl:]validation
attribute is used to request validation against the
global element or attribute declaration whose name matches the name of the element
or
attribute being validated.
The [xsl:]type
and [xsl:]validation
attributes are mutually
exclusive. Both are optional, but if one is present then the other
must be omitted. If both attributes are omitted, the effect is
the same as specifying the validation
attribute with the value specified
in the [xsl:]default-validation
attribute of
the innermost containing element having such an attribute; if this is not
specified, the effect is the same as specifying validation="strip"
.
The [xsl:]default-validation
attribute defines the
default value of the validation
attribute of all
xsl:element
, xsl:attribute
,
xsl:copy
, xsl:copy-of
,
xsl:document
, and xsl:result-document
instructions, and of the xsl:validation
attribute of all literal result elements
, appearing within its scope. It also determines
the validation applied to the implicit final
result tree created in the absence of an
xsl:result-document
instruction. This default applies within the
containing stylesheet module or
package: it does not extend to included or imported stylesheet
modules or used packages. If the attribute is omitted, the default is
strip
. The permitted values are preserve
and
strip
.
The [xsl:]default-validation
attribute has no
effect on the xsl:source-document
and xsl:merge-source
elements, which perform no validation unless explicitly requested.
[ERR XTSE1505] It is a static error if both the
[xsl:]type
and [xsl:]validation
attributes are
present on the xsl:element
, xsl:attribute
,
xsl:copy
, xsl:copy-of
,
xsl:document
, xsl:result-document
, xsl:source-document
, or
xsl:merge-source
elements, or on a literal result element.
The detailed rules for validation vary depending on the kind of node being validated. The rules for element and attribute nodes are given in 25.4.1 Validating Constructed Elements and Attributes, while those for document nodes are given in 25.4.2 Validating Document Nodes.
[xsl:]validation
AttributeThe [xsl:]validation
attribute defines the validation action to be
taken. It determines not only the type
annotation of the node that is constructed by the relevant
instruction itself, but also the type annotations of all element and attribute
nodes that have the constructed node as an ancestor. Conceptually, the
validation requested for a child element or attribute node is applied before
the validation requested for its parent element. For example, if the
instruction that constructs a child element specifies
validation="strict"
, this will cause the child element to be
checked against an element declaration, but if the instruction that constructs
its parent element specifies validation="strip"
, then the final
effect will be that the child node is annotated as xs:untyped
.
In the paragraphs below, the term contained nodes means the elements and attributes that have the newly constructed node as an ancestor.
The value strip
indicates that the new node and each of the
contained nodes will have the type
annotation
xs:untyped
if it is an element, or
xs:untypedAtomic
if it is an attribute. Any previous type
annotation present on a contained element or attribute node (for example,
a type annotation that is present on an element copied from a source
document) is also replaced by xs:untyped
or
xs:untypedAtomic
as appropriate. The typed value of the
node is changed to be the same as its string value, as an instance of
xs:untypedAtomic
. In the case of elements the
nilled
property is set to false
. The values
of the is-id
and is-idrefs
properties are
unchanged. Schema validation is not invoked.
The value preserve
indicates that nodes that are copied will
retain their type
annotations, but nodes whose content is newly constructed will
be annotated as xs:anyType
in the case of elements, or
xs:untypedAtomic
in the case of attributes. Schema
validation is not invoked. The detailed effect depends on the
instruction:
In the case of xsl:element
and literal result
elements, the new element has a type annotation of xs:anyType
, and the
type annotations of contained nodes are retained unchanged.
The nilled
,
is-id
and is-idrefs
properties on the
new element are set to false
.
In the case of xsl:attribute
, the effect is
exactly the same as specifying validation="strip"
:
that is, the new attribute will have the type annotation
xs:untypedAtomic
.
The is-id
and
is-idrefs
properties on the new attribute are set
to false
.
In the case of xsl:copy-of
, all the nodes that are
copied will retain their type annotations unchanged. The values of their
nilled
, is-id
and
is-idrefs
properties are also
unchanged.
In the case of xsl:copy
, the effect depends on the
kind of node being copied.
Where the node being copied is an attribute, the copied
attribute will retain its type annotation
and the values of its
is-id
and is-idrefs
properties.
Where the node being copied is an element, the copied element
will have a type
annotation of xs:anyType
(because
this instruction does not copy the content of the element, it
would be wrong to assume that the type is unchanged); but any
contained nodes will have their type annotations retained in
the same way as with xsl:element
. The values of the
nilled
, is-id
, and
is-idrefs
properties are handled in the
same way as xsl:element
.
The value strict
indicates that type annotations are established by
performing strict schema validity assessment on the element or attribute
node created by this instruction as follows:
In the case of an element, a top-level element declaration is
identified whose local name and namespace (if any) match the name
of the element, and schema-validity assessment is carried out
according to the rules defined in [XML Schema Part 1]
(section 3.3.4 "Element Declaration Validation Rules",
validation rule "Schema-Validity Assessment
(Element)", clauses 1.1 and 2, using the top-level element
declaration as the “declaration stipulated by the processor”, which
is mentioned in clause 1.1.1.1). The element is considered valid if
the result of the schema validity assessment is a PSVI in which the
relevant element node has a validity
property whose
value is valid
. If there is no matching element
declaration, or if the element is not considered valid, the
transformation fails [see ERR XTTE1510], [see ERR XTTE1512]. In effect this means that the element
being validated must be declared using a
top-level declaration in the schema, and must
conform to its declaration. The process of validation applies
recursively to contained elements and attributes to the extent
required by the schema definition.
Note:
It is not an error if the identified type definition is a simple type, although [XML Schema Part 1] does not define explicitly that this case is permitted.
In the case of an attribute, a top-level attribute declaration is
identified whose local name and namespace (if any) match the name
of the attribute, and schema-validity assessment is carried out
according to the rules defined in [XML Schema Part 1]
(section 3.2.4 "Attribute Declaration Validation
Rules", validation rule "Schema-Validity Assessment
(Attribute)"). The attribute is considered valid if the
result of the schema validity assessment is a PSVI in which the
relevant attribute node has a validity
property whose
value is valid
. If the attribute is not considered
valid, the transformation fails [see ERR XTTE1510].
In effect this means that the attribute being validated
must be declared using a top-level
declaration in the schema, and must conform to
its declaration.
The schema components used to validate an element or attribute may
be located in any way described by [XML Schema Part 1] (see
section 4.3.2, How schema documents are located on the
Web). The components in the schema constructed from the
synthetic schema document (see 3.15 Importing Schema Components) will
always be available for validating constructed nodes; if additional
schema components are needed, they may be
located in other ways, for example implicitly from knowledge of the
namespace in which the elements and attributes appear, or using the
xsi:schemaLocation
attribute of elements within the
tree being validated.
The type annotations on the resulting
nodes, as well as the values of their is-id
,
is-idrefs
, and nilled
properties, are
defined by the rules in Section
3.3 Construction from a PSVI
DM31.
If no validation is performed for a node, which can happen when the
schema specifies lax
or skip
validation
for that node or for a subtree, then the node is annotated as
xs:anyType
in the case of an element, and
xs:untypedAtomic
in the case of an attribute.
The value lax
has the same effect as the value
strict
, except that whereas strict
validation fails if there is no matching top-level element declaration or
if the outcome of validity assessment is a validity
property
of invalid
or notKnown
, lax
validation fails only if the outcome of validity assessment is a
validity
property of invalid
. That is,
lax
validation does not cause a type error when the outcome is
notKnown
.
In practice this means that the element or attribute being validated
must conform to its declaration if a top-level
declaration is available. If no such declaration is available, then the
element or attribute is not validated, but its attributes and children
are validated, again with lax validation. Any nodes whose validation
outcome is a validity
property of notKnown
are
annotated as xs:anyType
in the case of an element, and
xs:untypedAtomic
in the case of an attribute.
The type annotations on the resulting nodes,
as well as the values of their is-id
,
is-idrefs
, and nilled
properties, are defined
by the rules in Section
3.3 Construction from a PSVI
DM31.
Note:
When the parent element lacks a declaration, the XML Schema specification defines the recursive checking of children and attributes as optional. For this specification, this recursive checking is required.
Note:
If an element that is being validated has an xsi:type
attribute, then the value of the xsi:type
attribute will
be taken into account when performing the validation. However, the
presence of an xsi:type
attribute will not of itself
cause an element to be validated: if validation against a named type
is required, as distinct from validation against a top-level element
declaration, then it must be requested using the XSLT
[xsl:]type
attribute on the instruction that invokes
the validation, as described in section 25.4.1.2 Validation using the [xsl:]type Attribute
[ERR XTTE1510] If the validation
attribute of an
xsl:element
, xsl:attribute
,
xsl:copy
, xsl:copy-of
, or
xsl:result-document
instruction, or the
xsl:validation
attribute of a literal result element, has
the effective value strict
, and schema validity assessment
concludes that the validity of the element or attribute is invalid or
unknown, a type error occurs. As
with other type errors, the error may be signaled
statically if it can be detected statically.
[ERR XTTE1512] If the validation
attribute of an
xsl:element
, xsl:attribute
,
xsl:copy
, xsl:copy-of
, or
xsl:result-document
instruction, or the
xsl:validation
attribute of a literal result element, has
the effective value strict
, and there is no matching
top-level declaration in the schema, then a type error occurs. As with other type errors, the error
may be signaled statically if it can be detected
statically.
[ERR XTTE1515] If the validation
attribute of an
xsl:element
, xsl:attribute
,
xsl:copy
, xsl:copy-of
, or
xsl:result-document
instruction, or the
xsl:validation
attribute of a literal result element, has
the effective value lax
, and schema validity assessment
concludes that the element or attribute is invalid, a type error occurs. As with other type
errors, the error may be signaled statically if it can
be detected statically.
Note:
No mechanism is provided to validate an element or attribute against a local declaration in a schema. Such validation can usually be achieved by applying validation to a containing element for which a top-level element declaration exists.
[xsl:]type
AttributeThe [xsl:]type
attribute takes as its value a QName
.
This must be the name of a type definition included in the
in-scope schema
components for the stylesheet. If the QName has no prefix, it is
expanded using the default namespace established using the effective
[xsl:]xpath-default-namespace
attribute if there is one;
otherwise, it is taken as being a name in no namespace.
If the [xsl:]type
attribute is present, then the newly constructed
element or attribute is validated against the type definition identified by
this attribute.
In the case of an element, schema-validity assessment is carried out
according to the rules defined in [XML Schema Part 1] (section
3.3.4 "Element Declaration Validation Rules", validation
rule "Schema-Validity Assessment (Element)", clauses 1.2 and
2), using this type definition as the "processor-stipulated type
definition". The element is considered valid if the result of
the schema validity assessment is a PSVI in which the relevant element
node has a validity
property whose value is
valid
.
In the case of an attribute, the attribute is considered valid if (in the
terminology of XML Schema) the attribute’s normalized value is
locally valid with respect to that type definition according to the rules
for "String Valid" ([XML Schema Part 1], section
3.14.4). (Normalization here refers to the process of normalizing
whitespace according to the rules of the whiteSpace
facet
for the datatype).
If the element or attribute is not considered valid, as defined above, the transformation fails [see ERR XTTE1540].
If an element node is validated against the type
xs:untyped
, the effect is the same as specifying
validation="strip"
: that is, the elements and attributes in the
subtree rooted at the target element are copied with a type annotation of
xs:untyped
or xs:untypedAtomic
respectively.
If an element or attribute node is validated against the type
xs:untypedAtomic
, the effect is the same as specifying
[xsl:]type="xs:string"
except that when validation succeeds,
the returned element or attribute has a type annotation of
xs:untypedAtomic
. Validation fails in the case of an element
with element children.
[ERR XTSE1520] It is a static error if the
value of the type
attribute of an
xsl:element
, xsl:attribute
,
xsl:copy
, xsl:copy-of
,
xsl:document
, or xsl:result-document
instruction, or the xsl:type
attribute of a literal result
element, is not a valid QName
, or if it uses a prefix that
is not defined in an in-scope namespace declaration, or if the QName is
not the name of a type definition included in the in-scope schema
components for the package.
[ERR XTSE1530] It is a static error if the
value of the type
attribute of an
xsl:attribute
instruction refers to a complex type
definition.
[ERR XTTE1535] It is a type error if the value of
the type
attribute of an xsl:copy
or
xsl:copy-of
instruction refers to a complex type
definition and one or more of the items being copied is an attribute
node.
[ERR XTTE1540] It is a type error if an
[xsl:]type
attribute is defined for a constructed element
or attribute, and the outcome of schema validity assessment against that
type is that the validity
property of that element or
attribute information item is other than valid
.
Note:
Like other type errors, this error may be signaled statically if it can be
detected statically. For example, the instruction <xsl:attribute
name="dob" type="xs:date">1999-02-29</xsl:attribute>
may
result in a static error being signaled. If the error is not signaled
statically, it will be signaled when the instruction is evaluated.
As well as checking for validity against the schema, the validity assessment process causes type annotations to be associated with element and attribute nodes. If default values for elements or attributes are defined in the schema, the validation process will where necessary create new nodes containing these default values.
Validation of an element or attribute node only takes into account constraints on the content of the element or attribute. Validation rules affecting the document as a whole are not applied. Specifically, this means:
The validation rule "Validation Root Valid (ID/IDREF)" is not applied. This means that validation will not fail if there are non-unique ID values or dangling IDREF values in the subtree being validated.
The validation rule "Validation Rule: Identity-constraint Satisfied" should be applied.
There is no check that the document contains unparsed entities whose
names match the values of nodes of type xs:ENTITY
or
xs:ENTITIES
. (XSLT 3.0
provides no facility to construct unparsed entities within a tree.)
With these caveats, validating a newly constructed element, using strict or lax validation, is equivalent to the following steps:
The element is serialized to textual XML form, according to the rules defined in [XSLT and XQuery Serialization] using the XML output method, with all parameters defaulted. Note that this process discards any existing type annotations.
The resulting XML document is parsed to create an XML Information Set (see [XML Information Set].)
The Information Set produced in the previous step is validated according to the rules in [XML Schema Part 1]. The result of this step is a Post-Schema Validation Infoset (PSVI). If the validation process is not successful (as defined above), a type error is raised.
The PSVI produced in the previous step is converted back into the XDM data model by the mapping described in [XDM 3.0] (Section 3.3.1 Mapping PSVI Additions to Node Properties DM30). This process creates nodes with simple or complex type annotations based on the types established during schema validation.
The above process must be done in such a way that the base URI property of every node in the resulting XDM tree is the same as the base URI property of the corresponding node in the input tree.
Note:
As an alternative to steps 1 and 2, the XDM tree may be converted to an Infoset directly, using the mapping rules given for each kind of node in [XDM 3.0] (Section 6).
Validating an attribute using strict or lax validation requires a modified version of this procedure. A copy of the attribute is first added to an element node that is created for the purpose, and namespace fixup (see 5.7.3 Namespace Fixup) is performed on this element node. The name of this element is of no consequence, but it must be the same as the name of a synthesized element declaration of the form:
<xs:element name="E"> <xs:complexType> <xs:sequence/> <xs:attribute ref="A"/> </xs:complexType> </xs:element>
where A is the name of the attribute being validated.
This synthetic element is then validated using the procedure given above for validating elements, and if it is found to be valid, a copy of the validated attribute is made, retaining its type annotation, but detaching it from the containing element (and thus, from any namespace nodes).
The XDM data model does not permit an attribute node with no parent to have a
typed value that includes a namespace-qualified name, that is, a value whose
type is derived from xs:QName
or xs:NOTATION
. This
restriction is imposed because these types rely on the namespace nodes of a
containing element to resolve namespace prefixes. Therefore, it is an error to
validate a parentless attribute against such a type. This affects the
instructions xsl:attribute
, xsl:copy
, and
xsl:copy-of
.
[ERR XTTE1545] A type error occurs if a
type
or validation
attribute is defined
(explicitly or implicitly) for an instruction that constructs a new
attribute node, if the effect of this is to cause the attribute value to
be validated against a type that is derived from, or constructed by list
or union from, the primitive types xs:QName
or
xs:NOTATION
.
It is possible to apply validation to a document node. This happens when a new
document node is constructed by one of the XSLT elements xsl:source-document
, xsl:merge-source
, xsl:document
,
xsl:result-document
, xsl:copy
, or
xsl:copy-of
, and this element has a type
attribute, or a validation
attribute with the value
strict
or lax
.
Document-level validation is not applied to the document node that is created
implicitly when a variable-binding element has no select
attribute
and no as
attribute (see 9.4 Creating Implicit Document Nodes). This is
equivalent to using validation="preserve"
on
xsl:document
: nodes within such trees retain their type annotation. Similarly, validation is
not applied to document nodes created using xsl:message
or xsl:assert
.
The values validation="preserve"
and validation="strip"
do not request validation. In the first case, all element and attribute nodes
within the tree rooted at the new document node retain their type annotations. In the second case,
elements within the tree have their type annotation set to
xs:untyped
, while attributes have their type annotation set to
xs:untypedAtomic
.
When validation is requested for a document node (that is, when
validation
is set to strict
or lax
, or
when a type
attribute is present), the following processing takes
place:
[ERR XTTE1550] A type error occurs unless the children of the document node comprise exactly one element node, no text nodes, and zero or more comment and processing instruction nodes, in any order.
The single element node child is validated, using the supplied values of the
validation
and type
attributes, as described in
25.4.1 Validating Constructed Elements and Attributes.
Note:
The type
attribute on xsl:source-document
,
xsl:document
and
xsl:result-document
, and on xsl:copy
and xsl:copy-of
when copying a document node, thus
refers to the required type of the element node that is the only element
child of the document node. It does not refer to the type of the document
node itself.
The validation rule "Validation Root Valid (ID/IDREF)" is applied to the single element node child of the document node. This means that validation will fail if there are non-unique ID values or dangling IDREF values in the document tree.
Identity constraints, as defined in section 3.11 of [XML Schema Part 1], are checked. (This refers to constraints defined
using xs:unique
, xs:key
, and
xs:keyref
.)
There is no check that the tree contains unparsed entities whose names match
the values of nodes of type xs:ENTITY
or
xs:ENTITIES
. This is because there is no facility in XSLT
3.0 to create unparsed entities in a
result tree. It is possible to
add unparsed entity declarations to the result document by referencing a
suitable DOCTYPE during serialization.
All other children of the document node (comments and processing instructions) are copied unchanged.
[ERR XTTE1555] It is a type error if, when validating a document node, document-level constraints (such as ID/IDREF constraints) are not satisfied.
xml:id
attributesThis section provides a non-normative summary of the effect of validation on
attributes named xml:id
. The normative rules can be inferred from rules
given elsewhere in this section.
When an attribute named xml:id
is encountered
in the course of validation:
A validation error occurs if it the attribute is not lexically valid against type
xs:ID
.
The typed value of the attribute is whitespace-normalized.
The attribute is labeled with type annotation xs:ID
.
The attribute acquires the is-id
property.
The previous rule applies whether validation is strict, lax, or by type;
validation will never fail (or be skipped) on the grounds
that no global attribute declaration named xsl:id
is available.
Checking xml:id
attributes for uniqueness happens if and only if
validation is applied at the level of a document node.
A processor
may output a final result
tree as a sequence of octets, although it is not
required to be able to do so (see 27 Conformance).
Stylesheet authors can use xsl:output
declarations to specify how they
wish result trees to be serialized. If a processor serializes a final result tree,
it
must do so as specified by these declarations.
The rules governing the output of the serializer are defined in [XSLT and XQuery Serialization]. The serialization is controlled using a number
of serialization parameters. The values of these serialization parameters may be set
within the stylesheet, using the
xsl:output
, xsl:result-document
, and
xsl:character-map
declarations.
<!-- Category: declaration -->
<xsl:output
name? = eqname
method? = "xml" | "html" | "xhtml" | "text" | "json" | "adaptive" | eqname
allow-duplicate-names? = boolean
build-tree? = boolean
byte-order-mark? = boolean
cdata-section-elements? = eqnames
doctype-public? = string
doctype-system? = string
encoding? = string
escape-uri-attributes? = boolean
html-version? = decimal
include-content-type? = boolean
indent? = boolean
item-separator? = string
json-node-output-method? = "xml" | "html" | "xhtml" | "text" | eqname
media-type? = string
normalization-form? = "NFC" | "NFD" | "NFKC" | "NFKD" | "fully-normalized" | "none"
| nmtoken
omit-xml-declaration? = boolean
parameter-document? = uri
standalone? = boolean | "omit"
suppress-indentation? = eqnames
undeclare-prefixes? = boolean
use-character-maps? = eqnames
version? = nmtoken />
The xsl:output
declaration is optional; if used, it
must always appear as a top-level element within a stylesheet module.
A stylesheet may contain multiple
xsl:output
declarations and may include or import stylesheet modules
that also contain xsl:output
declarations. The name of an
xsl:output
declaration is the value of its name
attribute, if any.
[Definition: All the
xsl:output
declarations within a
package that share the same name
are grouped into a named output definition; those that have no name are
grouped into a single unnamed output definition.]
An output definition is scoped to a package. If this is a library package the output definition applies only
to xsl:result-document
instructions within the same package. If it is
the top-level package, the output
definition applies to xsl:result-document
instructions within the same
package and also to the implicit final result
tree.
A stylesheet always includes an unnamed output
definition; in the absence of an unnamed xsl:output
declaration, the unnamed output definition is equivalent to the one that would be
used
if the stylesheet contained an xsl:output
declaration having no
attributes.
A named output definition is used when its
name matches the format
attribute used in an
xsl:result-document
element. The unnamed output definition is used
when an xsl:result-document
element omits the format
attribute. It is also used when serializing the principal result.
.
All the xsl:output
elements making up an output definition are effectively merged. For
those attributes whose values are namespace-sensitive, the merging is done after
lexical QNames have been converted into
expanded QNames. For the
cdata-section-elements
and suppress-indentation
attributes, the
output definition uses the union of the values from all the constituent
xsl:output
declarations. For the use-character-maps
attribute, the output definition uses the concatenation of the sequences of expanded QNames values from all the constituent
xsl:output
declarations, taking them in order of increasing import precedence, or where several have the
same import precedence, in declaration
order. For other attributes, the output
definition uses the value of that attribute from the
xsl:output
declaration with the highest import precedence.
The parameter-document
attribute allows serialization
parameters to be supplied in an external document. The external document must contain
an
output:serialization-parameters
element with the format described in
Section
3.1 Setting Serialization Parameters by Means of a Data Model Instance
SER30, and the parameters are
interpreted as described in that specification.
If present, the URI supplied in the parameter-document
attribute is dereferenced, after resolution against the base URI of the
xsl:output
element if it is a relative reference.
The parameter document should be read during static analysis of the stylesheet.
A serialization error occurs
if the result of dereferencing the URI is ill-formed or invalid; but if no document
can
be found at the specified location, the attribute should be ignored.
A serialization parameter specified in the
parameter-document
takes precedence over a value supplied directly in
the output declaration, except that the values of the
cdata-section-elements
and suppress-indentation
attributes
are merged in the same way as when multiple xsl:output
declarations are
merged.
[ERR XTSE1560] It is a static error if two
xsl:output
declarations within an output definition specify explicit values
for the same attribute (other than cdata-section-elements
, suppress-indentation
, and
use-character-maps
), with the values of the attributes being not
equal, unless there is another xsl:output
declaration within the
same output definition that has
higher import precedence and that specifies an explicit value for the same
attribute.
The build-tree
attribute controls whether the
raw principal result or secondary result is
converted to a final result tree. The default depends on the value
of the method
attribute: the default is yes
if the
method
attribute specifies xml
, html
,
xhtml
, or text
, or if it is omitted; the default is no
if the method
attribute
specifies json
or adaptive
. A final result tree may be constructed whether or not it is subsequently
serialized.
Note:
The default for build-tree
may differ for user-defined serialization
methods or for serialization methods introduced in future versions of this
specification.
Unless the processor implements the XPath 3.1 Feature, the method
values json
and
adaptive
must be rejected as invalid, and the attributes
allow-duplicate-names
and json-node-output-method
must be ignored. The meaning of these output methods and
serialization parameters is defined in [XSLT and XQuery Serialization 3.1].
If none of the xsl:output
declarations within an output definition specifies a value for a
particular attribute, then the corresponding serialization parameter takes a default
value. The default value depends on the chosen output method.
There are some serialization parameters that apply to some output methods but not
to
others. For example, the indent
attribute has no effect on the
text
output method. If a value is supplied for an attribute that is
inapplicable to the output method, its value is not passed to the serializer. The
processor may validate the value of such an attribute, but is not
required to do so.
An implementation may allow the attributes of the
xsl:output
declaration to be overridden, or the default values to be
changed, using the API that controls the transformation.
The location to which final result trees
are serialized (whether in filestore or elsewhere) is implementation-defined (which in practice
may mean that it is controlled using an implementation-defined
API). However, these locations must satisfy the constraint that when
two final result trees are both created
(implicitly or explicitly) using relative URI references in the href
attribute of the
xsl:result-document
instruction, then these relative URI references may be used to construct references from one
tree to the other, and such references must remain valid when both
result trees are serialized.
The method
attribute on the xsl:output
element identifies
the overall method that is to be used for outputting the final result tree.
[ERR XTSE1570] The value
must (if present) be a valid EQName. If it is a lexical
QName with no a prefix, then it identifies a method specified in
[XSLT and XQuery Serialization] and must be one
of xml
, html
, xhtml
, or
text
. If it is a lexical QName with a
prefix, then the lexical QName is expanded
into an expanded QName as described in
5.1.1 Qualified Names; the expanded QName
identifies the output method; the behavior in this case is not specified by this
document.
The default for the method
attribute depends on the contents of the tree
being serialized, and is chosen as follows. If the document node of the final result tree has an element child, and any
text nodes preceding the first element child of the document node of the result tree
contain only whitespace characters, then:
If the expanded QName of this first
element child has local part html
(in lower case), and namespace URI
http://www.w3.org/1999/xhtml
, then the default output method is
normally xhtml
. However, if the
effective version of the outermost element of the
principal stylesheet
module in the top-level package has the value
1.0
, and if the result tree is generated implicitly
(rather than by an explicit xsl:result-document
instruction),
then the default output method in this situation is xml
.
If the expanded QName of this first
element child has local part html
(in any combination of upper and
lower case) and a null namespace URI, then the default output method is
html
.
In all other cases, the default output method is xml
.
The default output method is used if the selected output definition does not include a method
attribute.
The other attributes on xsl:output
provide parameters for the output
method. The following attributes are allowed:
The value of the encoding
attribute provides the value of the
encoding
parameter to the serialization method. The default value
is implementation-defined, but in the case of the
xml
and xhtml
methods it must be
either UTF-8
or UTF-16
.
The byte-order-mark
attribute defines whether a byte order mark is
written at the start of the file. If the value yes
is specified, a
byte order mark is written; if no
is specified, no byte order mark is
written. The default value depends on the encoding used. If the encoding is
UTF-16
, the default is yes
; for UTF-8
it
is implementation-defined, and for all other encodings it is
no
. The value of the byte order mark indicates whether high order
bytes are written before or after low order bytes; the actual byte order used is
implementation-dependent,
unless it is defined by the selected encoding.
The cdata-section-elements
attribute is a whitespace-separated list
of QNames. The default value is an empty list. After expansion of these names
using the in-scope namespace declarations for the xsl:output
declaration in which they appear, this list of names provides the value of the
cdata-section-elements
parameter to the serialization method. In
the case of an unprefixed name, the default namespace (that is, the namespace
declared using xmlns="uri"
) is used.
Note:
This differs from the rule for most other QNames used in a stylesheet. The
reason is that these names refer to elements in the result document, and
therefore follow the same convention as the name of a literal result element or
the name
attribute of xsl:element
.
The value of the doctype-system
attribute provides the value of the
doctype-system
parameter to the serialization method. If the attribute is absent or has a zero-length
string as its value, then the serialization parameter is not set (is
“absent”).
The value of the doctype-public
attribute provides the value of the
doctype-public
parameter to the serialization method. If the attribute is absent or has a zero-length
string as its value, then the serialization parameter is not set (is
“absent”).
The value of doctype-public
must conform to the rules for a PubidLiteralXML (see [XML 1.0]).
The value of the escape-uri-attributes
attribute provides the value
of the escape-uri-attributes
parameter to the serialization method.
The default value is yes
.
The value of the html-version
attribute provides
the value of the html-version
parameter to the serialization method.
The set of permitted values, and the default value, are implementation-defined. A serialization error will be reported if
the requested version is not supported by the implementation.
Note:
This serialization parameter is new in version 3.0. If it is
absent, the html output method uses the value of the version
parameter in its place. For XHTML serialization, the html-version
parameter indicates the version of XHTML to be used, while the
version
parameter indicates the version of XML.
The value of the include-content-type
attribute provides the value
of the include-content-type
parameter to the serialization method.
The default value is yes
.
The value of the indent
attribute provides the value of the
indent
parameter to the serialization method. The default value is
yes
in the case of the html
and xhtml
output methods, no
in the case of the xml
output method.
The value of the item-separator
attribute provides the value of the
item-separator
parameter to the serialization method. The value of
the serialization parameter can be any string (including a zero-length string), or
absent. To set the parameter to absent, the item-separator
attribute
can either be omitted, or set to the special value
item-separator="#absent"
; it is not possible to set the value of
the serialization parameter to the literal 7-character string "#absent"
.
Note:
The item-separator
attribute has no
effect if the sequence being serialized contains only one item, which will
always be the case if the effective value of build-tree
is
yes
.
The value of the media-type
attribute provides the value of the
media-type
parameter to the serialization method. The default
value is text/xml
in the case of the xml
output method,
text/html
in the case of the html
and
xhtml
output methods, and text/plain
in the case of
the text
output method.
The value of the normalization-form
attribute provides the value of
the normalization-form
parameter to the serialization method. A value
that is an NMTOKEN
other than one of those enumerated for the
normalization-form
attribute specifies an implementation-defined
normalization form; the behavior in this case is not specified by this document.
The default value is none
.
The value of the omit-xml-declaration
attribute provides the value
of the omit-xml-declaration
parameter to the serialization method.
The default value is no
.
The value of the standalone
attribute provides the value of the
standalone
parameter to the serialization method. The default
value is omit
; this means that no standalone
attribute
is to be included in the XML declaration.
The suppress-indentation
attribute is a whitespace-separated list of
QNames. The default value is an empty list. After expansion of these names using
the in-scope namespace declarations for the xsl:output
declaration in which they appear, this list of names provides the value of the
suppress-indentation
parameter to the serialization method. In the
case of an unprefixed name, the default namespace (that is, the namespace declared
using xmlns="uri"
) is used.
Note:
This differs from the rule for most other QNames used in a stylesheet. The
reason is that these names refer to elements in the result document, and
therefore follow the same convention as the name of a literal result element or
the name
attribute of xsl:element
.
The value of the undeclare-prefixes
attribute provides the value of the
undeclare-prefixes
parameter to the serialization method. The default
value is no
.
The use-character-maps
attribute provides a list of named character
maps that are used in conjunction with this output definition. The way this attribute is used is described in
26.1 Character Maps. The default value is an empty list.
The value of the version
attribute provides the value of the
version
parameter to the serialization method. The set of
permitted values, and the default value, are implementation-defined. A serialization error will be reported if
the requested version is not supported by the implementation.
If the processor performs serialization, then it must signal any serialization errors that occur. These have the same effect as dynamic errors: that is, the processor must signal the error and must not finish as if the transformation had been successful.
[Definition: A character map allows a specific character appearing in a text or attribute node in the final result tree to be substituted by a specified string of characters during serialization.] The effect of character maps is defined in [XSLT and XQuery Serialization].
The character map that is supplied as a parameter to the serializer is determined
from the xsl:character-map
elements referenced from the
xsl:output
declaration for the selected output definition.
The xsl:character-map
element is a declaration that may appear as a
child of the xsl:stylesheet
element.
<!-- Category: declaration -->
<xsl:character-map
name = eqname
use-character-maps? = eqnames >
<!-- Content: (xsl:output-character*) -->
</xsl:character-map>
The xsl:character-map
declaration declares a character map with a
name and a set of character mappings. The character mappings are specified by means
of xsl:output-character
elements contained either directly within
the xsl:character-map
element, or in further character maps
referenced in the use-character-maps
attribute.
The required
name
attribute provides a name for the character map. When a character
map is used by an output definition or
another character map, the character map with the highest import precedence is used.
The name of a character map is local to the package in which its declaration appears; it may be referenced only from within the same package.
[ERR XTSE1580] It is a static error if a package contains two or more character maps with the same name and the same import precedence, unless it also contains another character map with the same name and higher import precedence.
The optional use-character-maps
attribute lists the names of further
character maps that are included into this character map.
[ERR XTSE1590] It is a static error if a name in the
use-character-maps
attribute of the xsl:output
or xsl:character-map
elements does not match the
name
attribute of any xsl:character-map
in the
containing package.
[ERR XTSE1600] It is a static error if a character
map references itself, directly or indirectly, via a name in the
use-character-maps
attribute.
It is not an error if the same character map is referenced more than once, directly or indirectly.
An output definition, after recursive
expansion of character maps referenced via its use-character-maps
attribute, may contain several mappings for the same character. In this situation,
the last character mapping takes precedence. To establish the ordering, the following
rules are used:
Within a single xsl:character-map
element, the characters
defined in character maps referenced in the use-character-maps
attribute are considered before the characters defined in the child
xsl:output-character
elements.
The character maps referenced in a single use-character-maps
attribute are considered in the order in which they are listed in that
attribute. The expansion is depth-first: each referenced character map is fully
expanded before the next one is considered.
Two xsl:output-character
elements appearing as children of the
same xsl:character-map
element are considered in document
order.
The xsl:output-character
element is defined as follows:
<xsl:output-character
character = char
string = string />
The character map that is passed as a parameter to the serializer contains a mapping
for the character specified in the character
attribute to the string
specified in the string
attribute.
Character mapping is not applied to characters for which output escaping has been disabled as described in 26.2 Disabling Output Escaping.
If a character is mapped, then it is not subjected to XML or HTML escaping.
Character maps can be useful when producing serialized output in a format that resembles, but is not strictly conformant to, HTML or XML. For example, when the output is a JSP page, there might be a need to generate the output:
<jsp:setProperty name="user" property="id" value='<%= "id" + idValue %>'/>
Although this output is not well-formed XML or HTML, it is valid in Java Server
Pages. This can be achieved by allocating three Unicode characters (which are not
needed for any other purpose) to represent the strings <%
,
%>
, and "
, for example:
<xsl:character-map name="jsp"> <xsl:output-character character="«" string="<%"/> <xsl:output-character character="»" string="%>"/> <xsl:output-character character="§" string='"'/> </xsl:character-map>
When this character map is referenced in the xsl:output
declaration, the required output can be produced by writing the following in the
stylesheet:
<jsp:setProperty name="user" property="id" value='«= §id§ + idValue »'/>
This works on the assumption that when an apostrophe or quotation mark is generated as part of an attribute value by the use of character maps, the serializer will (where possible) use the other choice of delimiter around the attribute value.
The following example illustrates a composite character map constructed in a modular fashion:
<xsl:output name="htmlDoc" use-character-maps="htmlDoc"/> <xsl:character-map name="htmlDoc" use-character-maps="html-chars doc-entities windows-format"/> <xsl:character-map name="html-chars" use-character-maps="latin1 ..."/> <xsl:character-map name="latin1"> <xsl:output-character character=" " string="&nbsp;"/> <xsl:output-character character="¡" string="&iexcl;"/> ... </xsl:character-map> <xsl:character-map name="doc-entities"> <xsl:output-character character="" string="&t-and-c;"/> <xsl:output-character character="" string="&chap1;"/> <xsl:output-character character="" string="&chap2;"/> ... </xsl:character-map> <xsl:character-map name="windows-format"> <!-- newlines as CRLF --> <xsl:output-character character="
" string="
"/> <!-- tabs as three spaces --> <xsl:output-character character="	" string=" "/> <!-- images for special characters --> <xsl:output-character character="" string="<img src='special1.gif' />"/> <xsl:output-character character="" string="<img src='special2.gif' />"/> ... </xsl:character-map>
Note:
When character maps are used, there is no guarantee that the serialized output will be well-formed XML (or HTML). Furthermore, the fact that the result tree was validated against a schema gives no guarantee that the serialized output will still be valid against the same schema. Conversely, it is possible to use character maps to produce schema-valid output from a result tree that would fail validation.
Normally, when using the XML, HTML, or XHTML output method, the serializer will
escape special characters such as &
and <
when
outputting text nodes. This ensures that the output is well-formed. However, it is
sometimes convenient to be able to produce output that is almost, but not quite
well-formed XML; for example, the output may include ill-formed sections which are
intended to be transformed into well-formed XML by a subsequent non-XML-aware
process. For this reason, XSLT defines a mechanism for disabling output escaping.
This feature is deprecated.
This is an optional feature: it is not required that an XSLT processor that implements the serialization option should offer the ability to disable output escaping, and there is no conformance level that requires this feature.
This feature that the serializer (described in [XSLT and XQuery Serialization]) be extended as follows. Conceptually, the final result tree provides an additional
boolean property disable-escaping
associated with every character in a
text node. When this property is set, the normal action of the serializer to escape
special characters such as &
and <
is
suppressed.
An xsl:value-of
or xsl:text
element may have a
disable-output-escaping
attribute; the allowed values are
yes
or no
. The default is no
; if the value
is yes
, then every character in the text node generated by evaluating
the xsl:value-of
or xsl:text
element
should have the disable-escaping
property set.
For example,
<xsl:text disable-output-escaping="yes"><</xsl:text>
should generate the single character <
.
If output escaping is disabled for an xsl:value-of
or
xsl:text
instruction evaluated when temporary output state is in effect, the
request to disable output escaping is ignored.
Similarly, if an xsl:value-of
or
xsl:text
instruction specifies that output escaping is to be
disabled when writing to a final result
tree that is not being serialized, the request to disable output
escaping is ignored.
Note:
Furthermore, a request to disable output escaping has no effect when the newly constructed text node is used to form the value of an attribute, comment, processing instruction, or namespace node. This is because the rules for constructing such nodes (see 5.7.2 Constructing Simple Content) cause the text node to be atomized, and the process of atomizing a text node takes no account of the disable-escaping property.
If output escaping is disabled for text within an element that would normally be
output using a CDATA section, because the element is listed in the
cdata-section-elements
, then the relevant text will not be included
in a CDATA section. In effect, CDATA is treated as an alternative escaping mechanism,
which is disabled by the disable-output-escaping
option.
For example, if <xsl:output cdata-section-elements="title"/>
is
specified, then the following instructions:
<title> <xsl:text disable-output-escaping="yes">This is not <hr/> good coding practice</xsl:text> </title>
should generate the output:
<title><![CDATA[This is not ]]><hr/><![CDATA[ good coding practice]]></title>
The disable-output-escaping
attribute may be used with the
html
output method as well as with the xml
output
method. The text
output method ignores the
disable-output-escaping
attribute, since this method does not perform
any output escaping.
A processor will only be able to disable output escaping if it controls how the final result tree is output. This might not always be the case. For example, the result tree might be used as a source tree for another XSLT transformation instead of being output. It is implementation-defined whether (and under what circumstances) disabling output escaping is supported. If disabling output escaping is not supported, any request to disable output escaping is ignored.
If output escaping is disabled for a character that is not representable in the encoding that the processor is using for output, the request to disable output escaping is ignored in respect of that character.
Since disabling output escaping might not work with all implementations and can result in XML that is not well-formed, it should be used only when there is no alternative.
Note:
When disable-output-escaping is used, there is no guarantee that the serialized output will be well-formed XML (or HTML). Furthermore, the fact that the result tree was validated against a schema gives no guarantee that the serialized output will still be valid against the same schema. Conversely, it is possible to use disable-output-escaping to produce schema-valid output from a result tree that would fail validation.
Note:
The facility to define character maps for use during serialization, as described in 26.1 Character Maps, has been produced as an alternative mechanism that can be used in many situations where disabling of output escaping was previously necessary, without the same difficulties.
A processor that claims conformance with this specification must satisfy the conformance requirements for a basic XSLT processor and for each of the optional features with which it claims conformance.
The following optional features are defined:
The schema-awareness feature, defined in 27.2 Schema-Awareness Conformance Feature
The serialization feature, defined in 27.3 Serialization Feature
The backwards compatibility feature, defined in 27.4 Compatibility Features
The streaming feature, defined in 27.5 Streaming Feature.
The dynamic evaluation feature, defined in 27.6 Dynamic Evaluation Feature.
The higher-order functions feature, defined in 27.8 Higher-Order Functions Feature.
The XPath 3.1 feature, defined in 27.7 XPath 3.1 Feature.
A processor that does not claim conformance with an optional feature must satisfy the requirements for processors that do not implement that feature.
Note:
There is no conformance level or feature defined in this specification that requires implementation of the static typing features described in [XPath 3.0]. An XSLT processor may provide a user option to invoke static typing, but to be conformant with this specification it must allow a stylesheet to be processed with static typing disabled. The interaction of XSLT stylesheets with the static typing feature of XPath 3.0 has not been specified, so the results of using static typing, if available, are implementation-defined.
An XSLT processor takes as its inputs a stylesheet and zero or more XDM trees conforming to the data model defined in [XDM 3.0]. It is not required that the processor supports any particular method of constructing XDM trees, but conformance can only be tested if it provides a mechanism that enables XDM trees representing the stylesheet and primary source document to be constructed and supplied as input to the processor.
The output of the XSLT processor consists of zero or more final result trees. It is not required that the processor supports any particular method of accessing a final result tree, but if it does not support the serialization feature, conformance can only be tested if it provides some alternative mechanism that enables access to the results of the transformation.
Certain facilities in this specification are described as producing implementation-defined results. A claim that asserts conformance with this specification must be accompanied by documentation stating the effect of each implementation-defined feature. For convenience, a non-normative checklist of implementation-defined features is provided at F Checklist of Implementation-Defined Features.
A conforming processor must signal any static error occurring in the stylesheet, or in any XPath expression, except where specified otherwise either for individual error conditions or under the general provisions for forwards compatible behavior (see 3.10 Forwards Compatible Processing). After signaling such an error, the processor may continue for the purpose of signaling additional errors, but must terminate abnormally without performing any transformation.
When a dynamic error occurs during the course
of a transformation, and is not caught using
xsl:catch
,
the processor
must signal it and must eventually terminate
abnormally.
Some errors, notably type errors, may be treated as static errors or dynamic errors at the discretion of the processor.
A conforming processor may impose limits on the processing resources consumed by the processing of a stylesheet.
The mandatory requirements of this specification are taken to include the mandatory requirements of [XPath 3.0], [XDM 3.0], and [Functions and Operators 3.0]. An XSLT 3.0 processor must provide a mode of operation which conforms to the 3.0 versions of those specifications as extended by 21 Maps and 22 Processing JSON Data.
A processor may also provide a mode of operation which conforms to the 3.1 versions of those specifications; in this case it must do so as described in XPath 3.1 Feature.
A processor may also provide a mode of operation which conforms to versions of those specifications later than the 3.1 versions; in such cases the detail of how XSLT 3.0 interacts with new features introduced by such later versions (for example, extensions to the data model) is implementation-defined.
A requirement is mandatory unless the specification includes wording (such as the use of the words should or may) that clearly indicates that it is optional.
Some of the optional features are defined in such a way that if the feature is not provided, the data model is constrained to exclude certain kinds of item. For example:
A processor that does not provide the schema-awareness feature restricts the data model so that it does not contain atomic values of types other than the built-in types, or nodes with non-trivial type annotations.
A processor that does not provide the higher-order functions feature constrains the data model so that it does not contain function items other than maps or arrays.
A processor that does not provide the XPath 3.1 Feature constrains the data model so that it does not contain arrays.
[ERR XTDE1665] A dynamic error may be raised if the input to the processor includes an item that requires availability of an optional feature that the processor does not provide.
Note:
It is not necessarily possible to trigger this error. A processor that does not provide an optional feature might not define or recognize any representation of the items that are disallowed. The error code is provided for use in cases where a processor is able to interoperate with other software that does not have the same constraints — for example, where a package compiled with a non-schema-aware processor is able to invoke functions in a package that was compiled with a schema-aware processor. Even in that case, processors have the option of filtering or converting the input so that it meets the relevant constraints: for example, a non-schema-aware processor when presented with a schema-validated document in the form of a PSVI might simply ignore the properties it does not understand.
The dynamic error is optional: for example a processor might report no error if the offending item is not actually used.
The phrase input to the processor is deliberately wide: it includes (inter alia)
the global context item, items present in the initial match selection, items passed as stylesheet parameters, items returned by functions such as
document
, doc
FO30, and
collection
FO30, items returned by extension functions and extension instructions,
items supplied in function or template parameters or results across package boundaries,
and nodes
reachable from any of the above by axis navigation.
[Definition: A basic XSLT processor is an XSLT processor that implements all the mandatory requirements of this specification with the exception of constructs explicitly associated with an optional feature.] These constructs are listed below.
A conformant processor must either be a conformant schema-aware XSLT processor or a conformant non-schema-aware processor.
[Definition: A
schema-aware XSLT processor is an XSLT processor that implements
the mandatory requirements of this specification connected with the
xsl:import-schema
declaration, the
[xsl:]validation
and [xsl:]type attributes
, and the
ability to handle input documents whose nodes have type annotations other than
xs:untyped
and xs:untypedAtomic
. The mandatory
requirements of this specification are taken to include the mandatory requirements
of XPath 3.0, as described in [XPath 3.0]. A requirement is mandatory unless the specification includes
wording (such as the use of the words should or
may) that clearly indicates that it is optional.]
[Definition: A non-schema-aware processor is a processor that does not claim conformance with the schema-aware conformance feature. Such a processor must handle constructs associated with schema-aware processing as described in this section.]
[ERR XTSE1650] A non-schema-aware
processor
must signal a static
error if a package includes an
xsl:import-schema
declaration.
Note:
A processor that rejects an xsl:import-schema
declaration will
also reject any reference to a user-defined type defined in a schema, or to a
user-defined element or attribute declaration; it will not, however, reject
references to the built-in types listed in 3.14 Built-in Types.
A non-schema-aware
processor is not able to validate input documents, and is not able to
handle input documents containing type annotations other than xs:untyped
or xs:untypedAtomic
. Therefore, such a processor must
treat any [xsl:]validation
attribute
with a value of preserve
or lax
, or a
[xsl:]default-validation
attribute with a value of
preserve
as if the value were strip
.
Note:
The values lax
and preserve
indicate that the validation
to be applied depends on the calling application, so it is appropriate for the
request to be treated differently by different kinds of processor. By contrast,
requesting strict
validation, either through the
[xsl:]validation
attribute or the type
attribute,
indicates that the stylesheet is expecting to deal with typed data, and therefore
cannot be processed without performing the validation.
[ERR XTSE1660] A non-schema-aware
processor
must signal a static
error if a package includes an
[xsl:]type
attribute; or an [xsl:]validation
or
[xsl:]default-validation
attribute with a value other than
strip
, preserve
, or
lax
; or an
xsl:mode
element whose typed
attribute is
equal to yes
or strict
; or an as
attribute whose value is a
SequenceType that can only match
nodes with a type annotation other than xs:untyped
or
xs:untypedAtomic
(for example, as="element(*,
xs:integer)"
).
A non-schema-aware processor constrains the data model as follows, and raises a dynamic error ([see ERR XTDE1665]) if the constraints are not satisfied:
Atomic values must belong to one of the atomic types listed in 3.14 Built-in Types (except as noted below).
An atomic value may also belong to an implementation-defined type that has been added to the context for use with extension functions or extension instructions.
The set of constructor functions available are limited to those that construct values of the above atomic types.
The static context, which defines the full set of type names recognized by an
XSLT processor and also by the XPath processor, includes these atomic types,
plus xs:anyType
, xs:anySimpleType
,
xs:untyped
, and xs:anyAtomicType
.
Element nodes must be annotated with the type annotation
xs:untyped
, and attribute nodes with the type annotation
xs:untypedAtomic
.
[Definition: A processor that
claims conformance with the serialization feature
must support the conversion of a final result tree to a sequence of octets
following the rules defined in 26 Serialization.] It
must respect all the attributes of the
xsl:output
and xsl:character-map
declarations,
and must provide all four output methods, xml
,
xhtml
, html
, and text
. Where the
specification uses words such as must and
required, then it must serialize the result
tree in precisely the way described; in other cases it may use an
alternative, equivalent representation.
A processor may claim conformance with the serialization feature whether or not it
supports the setting disable-output-escaping="yes"
on
xsl:text
, or xsl:value-of
.
A processor that does not claim conformance with the serialization feature
must not signal an error merely because the stylesheet contains xsl:output
or
xsl:character-map
declarations, or serialization attributes on
the xsl:result-document
instruction. Such a processor
may check that these declarations and attributes have valid
values, but is not required to do so. Apart from optional
validation, these declarations should be ignored.
Note:
A processor that does not claim conformance with the serialization feature
may offer alternative serialization capabilities, and these
may make use of the serialization parameters defined on
xsl:output
and/or xsl:result-document
.
If the processor claims conformance with
the serialization feature then it must fully implement the
serialize
FO30 function defined in [Functions and Operators 3.0]
or [Functions and Operators 3.1] as appropriate, and must not
raise error [ERR FODC0010] FO30 as the result of such a call.
If the processor does not claim conformance with
the serialization feature, then it may raise
error [ERR FODC0010] FO30 in respect of some or
all calls on the serialize
FO30 function; it must not
return a result from a call on this function unless the result is conformant with
the specification, given the parameters actually supplied.
A processor that claims conformance with the Serialization Feature must satisfy the mandatory requirements of [XSLT and XQuery Serialization]. It must provide a mode of operation which conforms to the 3.0 version of that specification. It may also provide a mode of operation which conforms to a later version of that specification; in such cases the detail of how XSLT 3.0 interacts with new features introduced by such a version (for example, support for new serialization properties) is implementation-defined.
[Definition: A processor that claims conformance with the XSLT 1.0 compatibility feature must support the processing of stylesheet instructions and XPath expressions with XSLT 1.0 behavior, as defined in 3.9 Backwards Compatible Processing.]
Note that a processor that does not claim conformance with the XSLT 1.0 compatibility feature must raise a dynamic error if an instruction is evaluated whose effective version is 1.0. [see ERR XTDE0160].
Note:
The reason this is a dynamic error rather than a static error is to allow
stylesheets to contain conditional logic, following different paths depending on
whether the XSLT processor implements XSLT 1.0, 2.0, or
3.0. The selection of which path to use can be controlled by using the
system-property
function to test the
xsl:version
system property.
A processor that claims conformance with the XSLT 1.0 compatibility feature must permit the use of the namespace axis in XPath expressions when backwards compatible behavior is enabled. In all other circumstances, support for the namespace axis is optional.
Note:
There are no incompatibilities between 3.0 and 2.0 that would
justify a 2.0-compatibility mode. When a 3.0 processor encounters a stylesheet
that specifies version="2.0"
, evaluation therefore proceeds exactly
as if it specified version="3.0"
. However, a software product may
invoke an XSLT 2.0 processor in preference to an XSLT 3.0 processor when the
stylesheet specifies version="2.0"
, in which case any use of new 3.0
constructs will be rejected.
[Definition: A processor that claims
conformance with the streaming feature
must use streamed processing in cases where (a) streaming is
requested (for example by using the attribute streamable="yes"
on
xsl:mode
, or on
the xsl:source-document
instruction) and
(b) the constructs in question are guaranteed-streamable
according to this specification.]
A processor that does not claim conformance with the streaming feature is not required to use streamed processing and is not required to determine whether any construct is guaranteed streamable. Such a processor must, however, implement the semantics of all constructs in the language provided that enough memory is available to perform the processing without streaming.
A processor that conforms with the feature must
return the value "yes"
in response to the function call
system-property('xsl:supports-streaming')
; a processor that does not
conform with the feature must return the value
"no"
.
Note:
The term streamed processing as used here means the ability to process arbitrarily large input documents without ever-increasing memory requirements.
[Definition: A
processor that claims conformance with the dynamic evaluation feature
must evaluate the xsl:evaluate
function as
described in this specification.]
A processor that does not claim conformance with the dynamic evaluation feature
must report a dynamic error if an xsl:evaluate
instruction is evaluated. It must not report a static error merely
because of the presence of an xsl:evaluate
instruction in the
stylesheet, unless a processor that conforms with the feature would report the same
static error.
A processor that conforms with the feature must return the value
"yes"
in response to the function call
system-property('xsl:supports-dynamic-evaluation')
; a processor that
does not conform with the feature must return the value
"no"
.
A processor that conforms with the feature must return the value
true
in response to the function call
element-available('xsl:evaluate')
; a processor that does not conform
with the feature must return the value false
.
Note:
A processor may allow dynamic evaluation to be enabled and disabled by means of
configuration settings, perhaps for security reasons. In consequence, it may be
impossible to tell during static analysis of the stylesheet whether or not the
feature will be available during execution. A stylesheet author wanting to check
whether the feature is available should therefore make the test using a run-time
call on system-property
, rather than relying on tests in an
[xsl:]use-when
attribute.
[Definition: A processor that claims conformance with the XPath 3.1 feature must implement XPath 3.1 (including [XPath 3.1], [XDM 3.1], [XSLT and XQuery Serialization 3.1], and [Functions and Operators 3.1]).]
Specifically:
All constructs where an expression, pattern, SequenceType, or ItemType
is
expected must accept the XPath 3.1 grammar within those constructs.
All functions defined in [Functions and Operators 3.1] are available.
Note:
Functions labeled as higher-order are available only if the higher-order functions feature is also available.
If both the XPath 3.1 feature and the Higher-Order Functions feature
are available, then the load-xquery-module
FO31
function will be available. However, as prescribed in the specification
of that function, it has the option of returning a dynamic error if no suitable
XQuery processor is available.
The union type xs:numeric
is recognized.
The data model includes maps and arrays.
A processor that does not provide the XPath 3.1 feature constrains the data model by disallowing arrays, and may raise a dynamic error ([see ERR XTDE1665]) if this constraint is not satisfied.
Serialization of final results follows the rules in [XSLT and XQuery Serialization 3.1] (for example, it supports JSON serialization).
The xsl:evaluate
instruction supports dynamic evaluation of
XPath 3.1 expressions.
The result of system-property("xsl:xpath-version")
is
"3.1"
.
A processor that claims conformance with the XPath 3.1 feature may accept or reject constructs defined in any version of XPath (and its associated specifications) later than 3.1.
XPath 3.1 introduces arrays as a new data structure, along with maps, largely in order
to
provide improved support for JSON. An array is an item, and it can be used as a function,
so if
$A
is an array, then $A(3)
selects the third member of the array, counting
from one. The members of an array can be arbitrary values (that is, sequences).
Arrays become available in XSLT 3.0 when the XPath 3.1 Feature is implemented.
There are no specific constructs in XSLT 3.0 to construct or manipulate arrays, but
this
can be achieved using facilities in XPath 3.1. The syntax for SequenceTypes
is extended to allow arrays to be declared: for example array(xs:integer)
represents an array
whose members are (single) integers, while array(map(xs:string, node()*))
represents an array
whose members are maps from strings to sequences of nodes.
Like maps and sequences, arrays are immutable, and have no discernible identity (two arrays with the same members cannot be distinguished).
A number of functions for manipulating arrays are defined in [Functions and Operators 3.1].
[Definition: The higher-order functions feature contains functionality connected with the use of functions as items in the data model, that can be stored in variables and passed to other functions.]
[ERR XTSE3540] A processor that does not provide the
higher-order functions feature raises a static error if any of the following
XPath constructs are found in an expression, pattern,
SequenceType, or ItemType
: a
TypedFunctionTestXP30, a
NamedFunctionRefXP30, an
InlineFunctionExprXP30, or an
ArgumentPlaceholderXP30.
Note:
The effect is to disallow the three constructs used to create function-valued items:
named function references
such as round#1
, inline function expressions such as function($x){$x+1}
, and
partial function application such as starts-with(?, '#')
, along with sequence types
such as function(xs:integer) as xs:string
that serve no useful purpose in the absence of such items.
The item type function(*)
is allowed by these rules, and serves as a generic type for maps and arrays.
Where a processor does not provide the higher-order functions feature, functions whose specification in [Functions and Operators 3.1] labels them with the higher-order property are excluded from the static context of expressions and patterns. An attempt to reference such a function therefore fails in the same way as an attempt to call a non-existent function.
Note:
Examples of functions labeled with this property are filter
FO30, for-each
FO30,
fold-left
FO30, and fold-right
FO30.
A processor that does not provide the higher-order functions feature constrains the data model by disallowing function items other than maps and arrays, and may raise a dynamic error ([see ERR XTDE1665]) if this constraint is not satisfied.
The same rules apply to a dynamic XPath expression processed using xsl:evaluate
.
This appendix contains the schema for the XML representation of JSON described in 22.1 XML Representation of JSON, together with the stylesheets used for converting from this XML representation to strings matching the JSON grammar.
These schema documents and stylesheets are also available as separate resources (links are listed at the top of this document).
The schema is reproduced below:
<?xml version="1.0" encoding="UTF-8"?> <xs:schema xmlns:xs="http://www.w3.org/2001/XMLSchema" elementFormDefault="qualified" targetNamespace="http://www.w3.org/2005/xpath-functions" xmlns:j="http://www.w3.org/2005/xpath-functions"> <!-- * This is a schema for the XML representation of JSON used as the target for the * function fn:json-to-xml() * * The schema is made available under the terms of the W3C software notice and license * at http://www.w3.org/Consortium/Legal/copyright-software-19980720 * --> <xs:element name="map" type="j:mapType"> <xs:unique name="unique-key"> <xs:selector xpath="*"/> <xs:field xpath="@key"/> <xs:field xpath="@escaped-key"/> </xs:unique> </xs:element> <xs:element name="array" type="j:arrayType"/> <xs:element name="string" type="j:stringType"/> <xs:element name="number" type="j:numberType"/> <xs:element name="boolean" type="xs:boolean"/> <xs:element name="null" type="j:nullType"/> <xs:complexType name="nullType"> <xs:sequence/> </xs:complexType> <xs:complexType name="stringType"> <xs:simpleContent> <xs:extension base="xs:string"> <xs:attribute name="escaped" type="xs:boolean" use="optional" default="false"/> </xs:extension> </xs:simpleContent> </xs:complexType> <xs:simpleType name="numberType"> <xs:restriction base="xs:double"> <!-- exclude positive and negative infinity, and NaN --> <xs:minExclusive value="-INF"/> <xs:maxExclusive value="INF"/> </xs:restriction> </xs:simpleType> <xs:complexType name="arrayType"> <xs:choice minOccurs="0" maxOccurs="unbounded"> <xs:element ref="j:map"/> <xs:element ref="j:array"/> <xs:element ref="j:string"/> <xs:element ref="j:number"/> <xs:element ref="j:boolean"/> <xs:element ref="j:null"/> </xs:choice> </xs:complexType> <xs:complexType name="mapType"> <xs:choice minOccurs="0" maxOccurs="unbounded"> <xs:element name="map"> <xs:complexType> <xs:complexContent> <xs:extension base="j:mapType"> <xs:attribute name="key" type="xs:string"/> </xs:extension> </xs:complexContent> </xs:complexType> <xs:unique name="unique-key-2"> <xs:selector xpath="*"/> <xs:field xpath="@key"/> </xs:unique> </xs:element> <xs:element name="array"> <xs:complexType> <xs:complexContent> <xs:extension base="j:arrayType"> <xs:attributeGroup ref="j:key-group"/> </xs:extension> </xs:complexContent> </xs:complexType> </xs:element> <xs:element name="string"> <xs:complexType> <xs:simpleContent> <xs:extension base="j:stringType"> <xs:attributeGroup ref="j:key-group"/> </xs:extension> </xs:simpleContent> </xs:complexType> </xs:element> <xs:element name="number"> <xs:complexType> <xs:simpleContent> <xs:extension base="j:numberType"> <xs:attributeGroup ref="j:key-group"/> </xs:extension> </xs:simpleContent> </xs:complexType> </xs:element> <xs:element name="boolean"> <xs:complexType> <xs:simpleContent> <xs:extension base="xs:boolean"> <xs:attributeGroup ref="j:key-group"/> </xs:extension> </xs:simpleContent> </xs:complexType> </xs:element> <xs:element name="null"> <xs:complexType> <xs:attributeGroup ref="j:key-group"/> </xs:complexType> </xs:element> </xs:choice> </xs:complexType> <xs:attributeGroup name="key-group"> <xs:attribute name="key" type="xs:string" use="required"/> <xs:attribute name="escaped-key" type="xs:boolean" use="optional" default="false"/> </xs:attributeGroup> </xs:schema>
This stylesheet contains the implementation of a function very similar to
xml-to-json
, but implemented in XSLT so that it can be
customized and extended. This stylesheet is provided for the benefit of users and
there are no conformance requirements associated with it; there is no requirement
that processors should make this stylesheet available. The stylesheet is reproduced
below:
<?xml version="1.0" encoding="UTF-8"?> <!-- * This is a stylesheet for converting XML to JSON. * It expects the XML to be in the format produced by the XSLT 3.0 function * fn:json-to-xml(), but is designed to be highly customizable. * * The stylesheet is made available under the terms of the W3C software notice and license * at http://www.w3.org/Consortium/Legal/copyright-software-19980720 * --> <xsl:package name="http://www.w3.org/2013/XSLT/xml-to-json" package-version="1.0" xmlns:xsl="http://www.w3.org/1999/XSL/Transform" xmlns:xs="http://www.w3.org/2001/XMLSchema" xmlns:fn="http://www.w3.org/2005/xpath-functions" xmlns:j="http://www.w3.org/2013/XSLT/xml-to-json" exclude-result-prefixes="xs fn j" default-mode="j:xml-to-json" version="3.0"> <xsl:variable name="quot" visibility="private">"</xsl:variable> <xsl:param name="indent-spaces" select="2"/> <!-- The static parameter STREAMABLE controls whether the stylesheet is declared as streamable --> <xsl:param name="STREAMABLE" static="yes" as="xs:boolean" select="true()"/> <xsl:mode name="indent" _streamable="{$STREAMABLE}" visibility="public"/> <xsl:mode name="no-indent" _streamable="{$STREAMABLE}" visibility="public"/> <xsl:mode name="key-attribute" streamable="false" on-no-match="fail" visibility="public"/> <!-- The static parameter VALIDATE controls whether the input, if untyped, should be validated --> <xsl:param name="VALIDATE" static="yes" as="xs:boolean" select="false()"/> <xsl:import-schema namespace="http://www.w3.org/2005/xpath-functions" use-when="$VALIDATE"/> <!-- Entry point: function to convert a supplied XML node to a JSON string --> <xsl:function name="j:xml-to-json" as="xs:string" visibility="public"> <xsl:param name="input" as="node()"/> <xsl:sequence select="j:xml-to-json($input, map{})"/> </xsl:function> <!-- Entry point: function to convert a supplied XML node to a JSON string, supplying options --> <xsl:function name="j:xml-to-json" as="xs:string" visibility="public"> <xsl:param name="input" as="node()"/> <xsl:param name="options" as="map(*)"/> <xsl:variable name="input" as="node()" use-when="$VALIDATE"> <xsl:copy-of select="$input" validation="strict"/> </xsl:variable> <xsl:choose> <xsl:when test="$options('indent') eq true()"> <xsl:apply-templates select="$input" mode="indent"> <xsl:with-param name="fallback" as="(function(element()) as xs:string)?" select="$options('fallback')" tunnel="yes"/> </xsl:apply-templates> </xsl:when> <xsl:otherwise> <xsl:apply-templates select="$input" mode="no-indent"> <xsl:with-param name="fallback" as="(function(element()) as xs:string)?" select="$options('fallback')" tunnel="yes"/> </xsl:apply-templates> </xsl:otherwise> </xsl:choose> </xsl:function> <!-- A document node is ignored --> <xsl:template match="/" mode="indent no-indent"> <xsl:apply-templates mode="#current"/> </xsl:template> <!-- Template rule for fn:map elements, representing JSON objects --> <xsl:template match="fn:map" mode="indent"> <xsl:value-of> <xsl:variable name="depth" select="count(ancestor::*) + 1"/> <xsl:text>{</xsl:text> <xsl:for-each select="*"> <xsl:if test="position() gt 1"> <xsl:text>, </xsl:text> <xsl:value-of select="j:indent($depth)"/> </xsl:if> <xsl:apply-templates select="snapshot(@key)" mode="key-attribute"/> <xsl:text> : </xsl:text> <xsl:apply-templates select="." mode="#current"/> </xsl:for-each> <xsl:text>}</xsl:text> </xsl:value-of> </xsl:template> <xsl:template match="fn:map" mode="no-indent"> <xsl:value-of> <xsl:text>{</xsl:text> <xsl:for-each select="*"> <xsl:if test="position() gt 1"> <xsl:text>,</xsl:text> </xsl:if> <xsl:apply-templates select="snapshot(@key)" mode="key-attribute"/> <xsl:text>:</xsl:text> <xsl:apply-templates select="." mode="#current"/> </xsl:for-each> <xsl:text>}</xsl:text> </xsl:value-of> </xsl:template> <!-- Template rule for fn:array elements, representing JSON arrays --> <xsl:template match="fn:array" mode="indent"> <xsl:value-of> <xsl:variable name="depth" select="count(ancestor::*) + 1"/> <xsl:text>[</xsl:text> <xsl:for-each select="*"> <xsl:if test="position() gt 1"> <xsl:text>, </xsl:text> <xsl:value-of select="j:indent($depth)"/> </xsl:if> <xsl:apply-templates select="." mode="#current"/> </xsl:for-each> <xsl:text>]</xsl:text> </xsl:value-of> </xsl:template> <xsl:template match="fn:array" mode="no-indent"> <xsl:value-of> <xsl:text>[</xsl:text> <xsl:for-each select="*"> <xsl:if test="position() gt 1"> <xsl:text>,</xsl:text> </xsl:if> <xsl:apply-templates select="." mode="#current"/> </xsl:for-each> <xsl:text>]</xsl:text> </xsl:value-of> </xsl:template> <!-- Template rule for fn:string elements in which special characters are already escaped --> <xsl:template match="fn:string[@escaped='true']" mode="indent no-indent"> <xsl:sequence select="concat($quot, ., $quot)"/> </xsl:template> <!-- Template rule for fn:string elements in which special characters need to be escaped --> <xsl:template match="fn:string[not(@escaped='true')]" mode="indent no-indent"> <xsl:sequence select="concat($quot, j:escape(.), $quot)"/> </xsl:template> <!-- Template rule for fn:boolean elements --> <xsl:template match="fn:boolean" mode="indent no-indent"> <xsl:sequence select="xs:string(xs:boolean(.))"/> </xsl:template> <!-- Template rule for fn:number elements --> <xsl:template match="fn:number" mode="indent no-indent"> <xsl:value-of select="xs:string(xs:double(.))"/> </xsl:template> <!-- Template rule for JSON null elements --> <xsl:template match="fn:null" mode="indent no-indent"> <xsl:text>null</xsl:text> </xsl:template> <!-- Template rule matching a key within a map where special characters in the key are already escaped --> <xsl:template match="fn:*[@key-escaped='true']/@key" mode="key-attribute"> <xsl:value-of select="concat($quot, ., $quot)"/> </xsl:template> <!-- Template rule matching a key within a map where special characters in the key need to be escaped --> <xsl:template match="fn:*[not(@key-escaped='true')]/@key" mode="key-attribute"> <xsl:value-of select="concat($quot, j:escape(.), $quot)"/> </xsl:template> <!-- Template matching "invalid" elements --> <xsl:template match="*" mode="indent no-indent"> <xsl:param name="fallback" as="(function(element()) as xs:string)?" tunnel="yes" required="yes"/> <xsl:choose> <xsl:when test="exists($fallback)"> <xsl:value-of select="$fallback(snapshot(.))"/> </xsl:when> <xsl:otherwise> <xsl:message terminate="yes">>Inc</xsl:message> </xsl:otherwise> </xsl:choose> </xsl:template> <!-- Template rule matching (and discarding) whitespace text nodes in the XML --> <xsl:template match="text()[not(normalize-space())]" mode="indent no-indent"/> <!-- Function to escape special characters --> <xsl:function name="j:escape" as="xs:string" visibility="final"> <xsl:param name="in" as="xs:string"/> <xsl:value-of> <xsl:for-each select="string-to-codepoints($in)"> <xsl:choose> <xsl:when test=". gt 65535"> <xsl:value-of select="concat('\u', j:hex4((. - 65536) idiv 1024 + 55296))"/> <xsl:value-of select="concat('\u', j:hex4((. - 65536) mod 1024 + 56320))"/> </xsl:when> <xsl:when test=". = 34">\"</xsl:when> <xsl:when test=". = 92">\\</xsl:when> <xsl:when test=". = 08">\b</xsl:when> <xsl:when test=". = 09">\t</xsl:when> <xsl:when test=". = 10">\n</xsl:when> <xsl:when test=". = 12">\f</xsl:when> <xsl:when test=". = 13">\r</xsl:when> <xsl:when test=". lt 32 or (. ge 127 and . le 160)"> <xsl:value-of select="concat('\u', j:hex4(.))"/> </xsl:when> <xsl:otherwise> <xsl:value-of select="codepoints-to-string(.)"/> </xsl:otherwise> </xsl:choose> </xsl:for-each> </xsl:value-of> </xsl:function> <!-- Function to convert a UTF16 codepoint into a string of four hex digits --> <xsl:function name="j:hex4" as="xs:string" visibility="final"> <xsl:param name="ch" as="xs:integer"/> <xsl:variable name="hex" select="'0123456789abcdef'"/> <xsl:value-of> <xsl:value-of select="substring($hex, $ch idiv 4096 + 1, 1)"/> <xsl:value-of select="substring($hex, $ch idiv 256 mod 16 + 1, 1)"/> <xsl:value-of select="substring($hex, $ch idiv 16 mod 16 + 1, 1)"/> <xsl:value-of select="substring($hex, $ch mod 16 + 1, 1)"/> </xsl:value-of> </xsl:function> <!-- Function to output whitespace indentation based on the depth of the node supplied as a parameter --> <xsl:function name="j:indent" as="text()" visibility="public"> <xsl:param name="depth" as="xs:integer"/> <xsl:value-of select="'
', string-join((1 to ($depth + 1) * $indent-spaces) ! ' ', '')"/> </xsl:function> </xsl:package>
A component of the context that has no value is said to be absent.
An operand usage of absorption indicates that the construct reads the subtree(s) rooted at a supplied node(s).
An
accumulator defines a series of
values associated with the nodes of the tree. If an accumulator is
applicable to a particular tree, then for each node in the tree, other than
attribute and namespace nodes, there will be two values available, called the
pre-descent and post-descent values. These two values are available via a pair of
functions, accumulator-before
and
accumulator-after
.
The functions
accumulator-before
and
accumulator-after
are referred to as the
accumulator functions.
A stylesheet can use the
xsl:namespace-alias
element to declare that a literal namespace URI is being used
as an alias for a target
namespace URI.
A template rule is applicable to one or more modes.
The modes to which it is applicable are defined by the mode
attribute of the xsl:template
element. If the attribute is
omitted, then the template rule is applicable to the default mode specified in the [xsl:]default-mode
attribute of the innermost containing
element that has such an attribute, which in turn defaults to
the unnamed mode. If the
mode
attribute is present, then its value
must be a non-empty whitespace-separated list of tokens,
each of which defines a mode to which the template rule is
applicable.
The arity of a stylesheet
function is the number of xsl:param
elements in the function
definition.
The term atomization is defined in Section 2.4.2 Atomization XP30. It is a process that takes as input a sequence of items, and returns a sequence of atomic values, in which the nodes are replaced by their typed values as defined in [XDM 3.0]. If the XPath 3.1 Feature is implemented, then arrays (see 27.7.1 Arrays) are atomized by atomizing their members, recursively.
An attribute set is
defined as a set of xsl:attribute-set
declarations in the same
package that share the same expanded QName.
An
attribute set invocation is a pseudo-instruction
corresponding to a single EQName appearing within an
[xsl:]use-attribute-sets
attribute; the effect of the
pseudo-instruction is to cause the referenced attribute set to be evaluated.
In an
attribute that is designated as an attribute value template, such
as an attribute of a literal result
element, an expression can
be used by surrounding the expression with curly brackets ({}
),
following the general rules for value
templates
An element is processed with backwards compatible behavior if its
effective version is less than
3.0
.
The base output URI is a URI to be used as the base URI when resolving a relative URI reference allocated to a final result tree. If the transformation generates more than one final result tree, then typically each one will be allocated a URI relative to this base URI.
A basic XSLT processor is an XSLT processor that implements all the mandatory requirements of this specification with the exception of constructs explicitly associated with an optional feature.
A character map allows a specific character appearing in a text or attribute node in the final result tree to be substituted by a specified string of characters during serialization.
For some construct
kinds, one or more operand roles may be defined to form a choice operand
group. This concept is used where it is known that operands are mutually exclusive (for example the
then
and else
clauses in a conditional
expression).
A circularity is said to exist if a construct such as a global variable, an attribute set, or a key, is defined in terms of itself. For example, if the expression or sequence constructor specifying the value of a global variable X references a global variable Y, then the value for Y must be computed before the value of X. A circularity exists if it is impossible to do this for all global variable definitions.
Climbing: indicates that streamed nodes returned by the construct are reached by navigating the parent, ancestor[-or-self], attribute, and/or namespace axes from the node at the current streaming position.
Facilities in XSLT 3.0 and XPath 3.0 that require strings to be ordered rely on the concept of a named collation. A collation is a set of rules that determine whether two strings are equal, and if not, which of them is to be sorted before the other.
The combined posture of a choice operand group is determined by the postures of the operands in the group (the operand postures), and is the first of the following that applies:
If any of the operand postures is roaming, then the combined posture is roaming.
If all of the operand postures are grounded, then the combined posture is grounded.
If one or more of the operand postures is climbing and the remainder (if any) are grounded, then the combined posture is climbing.
If one or more of the operand postures is striding and the remainder (if any) are grounded, then the combined posture is striding.
If one or more of the operand postures is crawling and each of the remainder (if any) is either striding or grounded, then the combined posture is crawling.
Otherwise (for example, if the group includes both an operand with climbing posture and one with crawling posture), the combined posture is roaming.
The signatures of two components are compatible if they present the same interface to the user of the component. The additional rules depend on the kind of component.
The term component is used to refer to any of the following: a stylesheet function, a named template, a mode, an accumulator, an attribute set, a key, global variable, or a mode.
The ordered collection of merge key values computed for one item in a merge input sequence (one for each merge key component within the merge key specification) is referred to as a composite merge key value.
The term construct refers to the union of the following: a sequence constructor, an instruction, an attribute set, a value template, an expression, or a pattern.
A consuming construct is any construct deemed consuming by the rules in this section (19 Streamability).
A
component declaration results in multiple components, one in the package in
which the declaration appears, and potentially one in each package that uses
the declaring package, directly or indirectly, subject to the visibility of the
component. Each of these multiple components has the same declaring package, but each has a different containing
package. For the original component, the declaring package and the
containing package are the same; for a copy of a component made as a result of
an xsl:use-package
declaration, the declaring package will be
the original package, and the containing package will be the package in which
the xsl:use-package
declaration appears.
The context
item is the item currently being processed. An item (see
[XDM 3.0]) is either an atomic value (such
as an integer, date, or string), a node, or
a function item. It changes whenever instructions such as
xsl:apply-templates
and
xsl:for-each
are used to process a sequence of
items; each item in such a sequence becomes the context item while
that item is being processed.
For every expression, it is possible to establish by static analysis, information about the item type of the context item for evaluation of that expression. This is called the context item type of the expression.
If the context item is a node (as distinct from an atomic value such as an integer), then it is also referred to as the context node. The context node is not an independent variable, it changes whenever the context item changes. When the context item is an atomic value or a function item, there is no context node.
The
context position is the position of the context item
within the sequence of items currently being processed. It changes
whenever the context item changes. When an instruction such as
xsl:apply-templates
or
xsl:for-each
is used to process a sequence of
items, the first item in the sequence is processed with a context
position of 1, the second item with a context position of 2, and so
on.
The context posture. This captures information about how the context item used as input to the construct is positioned relative to the streamed input. The context posture of a construct C is the posture of the expression whose value sets the focus for the evaluation of C.
The context
size is the number of items in the sequence of items
currently being processed. It changes whenever instructions such as
xsl:apply-templates
and
xsl:for-each
are used to process a sequence of
items; during the processing of each one of those items, the context
size is set to the count of the number of items in the sequence (or
equivalently, the position of the last item in the
sequence).
Within a focus-changing construct there are one or more operands that are evaluated with a focus determined by the controlling operand
(or in some cases such as
xsl:on-completion
, with an absent
focus); these are referred to as
controlled operands.
Within a focus-changing construct there is in many cases one operand whose value determines the focus for evaluating other operands; this is referred to as the controlling operand.
Crawling: typically indicates that streamed nodes returned by a construct are reached by navigating the descendant[-or-self] axis.
While
the xsl:matching-substring
instruction is active, a set of
current captured substrings is available, corresponding to the
parenthesized subexpressions of the regular expression.
The current group is the group itself, as a sequence of items
The current grouping key is a single atomic value, or in the case of a composite key, a sequence of atomic values, containing the grouping key of the items in the current group.
The
current merge group is a map. During
evaluation of an xsl:merge
instruction, as each group of
items with equal composite merge
key values is processed, the current merge group is set to a
map whose keys are the names of the various merge sources, and whose
associated values are the items from each merge source having the relevant
composite merge key value.
The current
merge key is a sequence of atomic values. During evaluation of an
xsl:merge
instruction, as each group of items with equal
composite merge key
values is processed, the current merge key is set to the
composite merge key value that these items have in common.
At any point in the processing
of a stylesheet, there is a current mode. When the transformation
is initiated, the current mode is the initial mode, as described in 2.3 Initiating a Transformation. Whenever an xsl:apply-templates
instruction is evaluated, the current mode becomes the mode selected by this
instruction.
The current output URI is the URI associated with the principal result or secondary result that is currently being written.
At any point in
the processing of a stylesheet, there may
be a current template rule. Whenever a template rule is chosen as a result of
evaluating xsl:apply-templates
,
xsl:apply-imports
, or xsl:next-match
, the
template rule becomes the current template rule for the evaluation of the rule’s
sequence constructor.
All the
xsl:decimal-format
declarations in a package that share the same name are grouped into a named
decimal format; those that have no name are grouped into a single
unnamed decimal format.
Top-level elements fall into two categories: declarations, and user-defined data elements. Top-level elements whose names are in the XSLT namespace are declarations. Top-level elements in any other namespace are user-defined data elements (see 3.7.3 User-defined Data Elements)
The declarations within a stylesheet level have a total ordering
known as declaration order. The order of declarations within a
stylesheet level is the same as the document order that would result if each
stylesheet module were inserted textually in place of the
xsl:include
element that references it.
The above constructs (template rules belonging to a
mode declared with streamable="yes"
; and xsl:source-document
,
xsl:attribute-set
, xsl:function
,
xsl:merge-source
, and xsl:accumulator
elements specifying
streamable="yes"
) are said to be
declared-streamable.
The declaring
package of a component is the
package that contains the declaration (or,
in the case of xsl:attribute-set
and
xsl:key
, multiple declarations) of the
component.
In this
specification the term default collation means the collation
that is used by XPath operators such as eq
and
lt
appearing in XPath expressions within the
stylesheet.
If no priority
attribute is specified on an xsl:template
element, a
default priority is computed, based on the syntax of the pattern supplied in the match
attribute.
A string in the form of a lexical QName may occur as the value of an attribute node in a stylesheet module, or within an XPath expression contained in an attribute or text node within a stylesheet module, or as the result of evaluating an XPath expression contained in such a node. The element containing this attribute or text node is referred to as the defining element of the lexical QName.
Some constructs defined in this specification are described as being deprecated. The use of this term implies that stylesheet authors should not use the construct, and that the construct may be removed in a later version of this specification.
An error that is not capable of detection until a source document is being transformed is referred to as a dynamic error.
A
processor that claims conformance with the dynamic evaluation feature
must evaluate the xsl:evaluate
function as
described in this specification.
The result of evaluating a value template is referred to as its effective value.
The effective
version of an element in a stylesheet module or package manifest is the decimal value of the [xsl:]version
attribute
(see 3.4 Standard Attributes) on that element or on the innermost
ancestor element that has such an attribute, excluding the version
attribute on an xsl:output
element.
A stylesheet module whose outermost element is the child of a non-XSLT element in a host document is referred to as an embedded stylesheet module. See 3.12 Embedded Stylesheet Modules.
An EQName is a string representing an expanded QName where the string, after removing leading and trailing whitespace, is in the form defined by the EQNameXP30 production in the XPath specification.
An expanded
QName is a value in the value space of the xs:QName
datatype as defined in the XDM data model (see [XDM 3.0]): that is, a triple containing namespace prefix (optional), namespace URI
(optional), and local name. Two expanded QNames are equal if the namespace URIs
are the same (or both absent) and the local names are the same. The prefix
plays no part in the comparison, but is used only if the expanded QName needs
to be converted back to a string.
An explicit
default for a parameter is indicated by the presence of either a
select
attribute or a non-empty sequence
constructor.
A parameter is
explicitly mandatory if it is a function parameter, or if the
required
attribute is present and has the value
yes
.
Within this specification, the term XPath expression, or simply expression, means a string that matches the production ExprXP30 defined in [XPath 3.0], with the extensions defined in 21 Maps.
An element from the XSLT namespace may have any attribute not from the XSLT namespace, provided that the expanded QName (see [XPath 3.0]) of the attribute has a non-null namespace URI. These attributes are referred to as extension attributes.
An extension function is a named function introduced to the static or dynamic context by mechanisms outside the scope of this specification.
An extension instruction is an element within a sequence constructor that is in a namespace (not the XSLT namespace) designated as an extension namespace.
The extension instruction mechanism allows namespaces to be designated as extension namespaces. When a namespace is designated as an extension namespace and an element with a name from that namespace occurs in a sequence constructor, then the element is treated as an instruction rather than as a literal result element.
The first of the two output states is called final output state. This state applies when instructions are writing to a final result tree.
A final result tree is a result tree that forms part of the output of a transformation: specifically, a tree built by post-processing the items in the principal result or in a secondary result. Once created, the contents of a final result tree are not accessible within the stylesheet itself.
When a sequence constructor is evaluated, the processor keeps track of which items are being processed by means of a set of implicit variables referred to collectively as the focus.
A focus-changing construct is a construct that has one or more operands that are evaluated with a different focus from the parent construct.
The
focus-setting container of a construct C is the
innermost focus-changing construct
F (if one exists) such that C is directly or
indirectly contained in a controlled operand of
F. If there is no such construct
F, then the focus-setting container is the containing
declaration, for example an
xsl:function
or xsl:template
element.
An
element is processed with forwards compatible behavior if its
effective version is greater than
3.0
.
A free-ranging construct is any construct deemed free-ranging by the rules in this section (19 Streamability).
When used in this specification without further qualification, the term function conversion rules means the function conversion rules defined in [XPath 3.0], applied with XPath 1.0 compatibility mode set to false.
An
xsl:param
element may appear as a child of an
xsl:function
element, before any
non-xsl:param
children of that element. Such a parameter
is known as a function parameter. A function parameter is a
local variable with the
additional property that its value can be set when the function is called,
using a function call in an XPath expression.
There are 28
fundamental item types: the 7 node kinds defined in [XDM 3.0] (element, attribute, etc.), the 19 primitive atomic
types defined in [XML Schema Part 2], plus the types
function(*)
and xs:untypedAtomic
. The fundamental
item types are disjoint, and every item is an instance of exactly one of
them.
Many constructs share the same streamability rules. These rules, referred to as the general streamability rules, are defined here.
An item that acts as the global
context item for the transformation. This item acts
as the context item when evaluating
the
select
expression or sequence constructor of a
global variable declaration
within the top-level package, as described in 5.3.3.1 Maintaining Position: the Focus. The global context item may also be available in a named template
when the stylesheet is invoked as described in 2.3.4 Call-Template Invocation
A top-level variable-binding element declares a global variable that is visible everywhere (except within its own declaration, and where it is shadowed by another binding).
Grounded: indicates that the value returned by the construct does not contain nodes from the streamed input document
The xsl:for-each-group
instruction allocates the items in an input sequence into groups of
items (that is, it establishes a collection of sequences) based either on common
values of a grouping key, or on a pattern that
the initial or final item in a group must
match.
If either of the
group-by
or group-adjacent
attributes is present,
then for each item in the population a set
of grouping keys is calculated, as follows: the expression contained
in the group-by
or group-adjacent
attribute is
evaluated; the result is atomized; and any xs:untypedAtomic
values
are cast to xs:string
. If
composite="yes"
is specified, there is a single grouping key
whose value is the resulting sequence; otherwise, there is a set of grouping
keys, consisting of the distinct atomic values present in the result
sequence.
A guaranteed-streamable construct is a construct that is declared to be streamable and that follows the particular rules for that construct to make streaming possible, as defined by the analysis in this specification.
The higher-order functions feature contains functionality connected with the use of functions as items in the data model, that can be stored in variables and passed to other functions.
Whether or not the operand is higher-order. For this purpose an operand O of a construct C is higher-order if the semantics of C potentially require O to be evaluated more than once during a single evaluation of C.
Two components are said to be homonymous if they have the same symbolic identifier.
Types S and T are considered identical for the purpose of
these rules if and only if subtype(S, T)
and subtype(T,
S)
both hold, where the subtype relation is defined in Section
2.5.6.1 The judgement subtype(A, B)
XP30.
The result of evaluating a sequence constructor is the sequence of items formed by concatenating the results of evaluating each of the nodes in the sequence constructor, retaining order. This is referred to as the immediate result of the sequence constructor.
A specific product that performs the functions of an XSLT processor is referred to as an implementation.
In this specification, the term implementation-defined refers to a feature where the implementation is allowed some flexibility, and where the choices made by the implementation must be described in documentation that accompanies any conformance claim.
The term implementation-dependent refers to a feature where the behavior may vary from one implementation to another, and where the vendor is not expected to provide a full specification of the behavior.
If a parameter that is
not explicitly mandatory has no explicit default value, then it has an implicit
default value, which is the empty sequence if there is an
as
attribute, or a zero-length string if not.
If a parameter
has an implicit default value which cannot be converted to
the required type (that is, if it has an as
attribute which does not permit the empty sequence), then the parameter is
implicitly mandatory.
A declaration D in the stylesheet is defined to have lower import precedence than another declaration E if the stylesheet level containing D would be visited before the stylesheet level containing E in a post-order traversal of the import tree (that is, a traversal of the import tree in which a stylesheet level is visited after its children). Two declarations within the same stylesheet level have the same import precedence.
The stylesheet levels making up a stylesheet are treated as forming an
import tree. In the import tree, each stylesheet level has one
child for each xsl:import
declaration that it
contains.
The schema components that may be referenced by name in a package are referred to as the in-scope schema components.
A stylesheet may be evaluated by calling a named stylesheet function, referred to as the initial function.
For each group, the item within the group that is first in population order is known as the initial item of the group.
A stylesheet may be evaluated by supplying a
value to be processed, together with an initial mode. The
value (which can be any sequence of items) is referred to as the initial
match selection. The processing then corresponds to the effect of the
xsl:apply-templates
instruction.
The initial mode is the mode used to select template rules for processing items in the initial match selection when apply-templates invocation is used to initiate a transformation.
A stylesheet may be evaluated by selecting a named template to be evaluated; this is referred to as the initial named template.
The sequence to be sorted is referred to as the initial sequence.
The initial setting of a component of the dynamic context is used
when evaluating global variables
and stylesheet parameters,
when evaluating the use
and match
attributes of
xsl:key
, and when evaluating the initial-value
of
xsl:accumulator
and the select
expressions or
contained sequence constructors of
xsl:accumulator-rule
An operand usage of inspection indicates that the construct accesses properties of a supplied node that are available without reading its subtree.
An instruction is either an XSLT instruction or an extension instruction.
The following constructs are classified as invocation constructs: the
instructions xsl:call-template
,
xsl:apply-templates
, xsl:apply-imports
, and
xsl:next-match
; XPath function calls that bind to stylesheet functions; XPath dynamic
function calls; the functions accumulator-before
and
accumulator-after
; the [xsl:]use-attribute-sets
attribute. These all have the characteristic that they can cause evaluation of
constructs that are not lexically contained within the calling
construct.
A key is defined as a set of
xsl:key
declarations in the same
package that share the same
name.
The expression in the
use
attribute and the sequence constructor within an xsl:key
declaration are referred to collectively as the key specifier. The
key specifier determines the values that may be used to find a node using this
key.
A lexical QName
is a string representing an expanded
QName where the string, after removing leading and trailing
whitespace, is within the lexical space of the xs:QName
datatype
as defined in XML Schema (see [XML Schema Part 2]): that is, a local
name optionally preceded by a namespace prefix and a colon.
Every package within a stylesheet, other than the top-level package, is referred to as a library package.
A namespace URI in the stylesheet tree that is being used to specify a namespace URI in the result tree is called a literal namespace URI.
In a sequence constructor, an element in the stylesheet that does not belong to the XSLT namespace and that is not an extension instruction (see 24.2 Extension Instructions) is classified as a literal result element.
As well as being allowed as a
declaration, the
xsl:variable
element is also allowed in sequence constructors. Such a variable
is known as a local variable.
A map consists of a set of entries. Each entry comprises a key which is an arbitrary atomic value, and an arbitrary sequence called the associated value.
The match type of a pattern is the most specific U-type that is known to match all items that the pattern can match.
A merge
activation is a single evaluation of the sequence constructor contained
within the xsl:merge-action
element, which occurs once for each
distinct composite merge key
value.
A merge input sequence is an arbitrary sequenceDM30 of items which is already sorted according to the merge key specification for the corresponding merge source definition.
A merge key
component specifies one component of a merge key specification; it
corresponds to a single xsl:merge-key
element in the
stylesheet.
A merge
key specification consists of one or more adjacent
xsl:merge-key
elements which together define how the merge input sequences selected by a
merge source definition are
sorted. Each xsl:merge-key
element defines one merge key component.
For each item in a merge input sequence, a value is computed for each merge key component within the merge key specification. The value computed for an item by using the Nth merge key component is referred to as the Nth merge key value of that item.
A merge source definition is the definition of one kind of input to the merge operation. It selects zero or more merge input sequences, and it includes a merge key specification to define how the merge key values are computed for each such merge input sequence.
A mode is a set of template rules;
when the xsl:apply-templates
instruction selects a set of items
for processing, it identifies the rules to be used for processing those items by
nominating a mode, explicitly or implicitly.
All the
xsl:mode
declarations in a package that share the same
name are grouped into a named mode definition; those that have no
name are grouped into a single unnamed mode definition.
A motionless construct is any construct deemed motionless by the rules in this section (19 Streamability).
Templates can be invoked by
name. An xsl:template
element with a name
attribute
defines a named template.
The rules for the individual XSLT instructions that construct a result tree (see 11 Creating Nodes and Sequences) prescribe some of the situations in which namespace nodes are written to the tree. These rules, however, are not sufficient to ensure that the prescribed constraints are always satisfied. The XSLT processor must therefore add additional namespace nodes to satisfy these constraints. This process is referred to as namespace fixup.
An operand usage of navigation indicates that the construct may navigate freely from the supplied node to other nodes in the same tree, in a way that is not constrained by the streamability rules.
The term non-contextual function
call is used to refer to function calls that do not pass the dynamic
context to the called function. This includes all calls on stylesheet functions and all
dynamic function
invocationsXP30, (that is calls to function items as permitted by
XPath 3.0). It excludes calls to some
functions in the namespace
http://www.w3.org/2005/xpath-functions
, in
particular those that explicitly depend on the context, such as the
current-group
and regex-group
functions. It is implementation-defined whether, and under what circumstances,
calls to extension functions are
non-contextual.
A predicate is a non-positional predicate if it satisfies both of the following conditions:
The predicate does not contain a function call or named function reference to any of the following functions, unless that call or reference occurs within a nested predicate:
position
FO30
last
FO30
function-lookup
FO30.
Note:
The exception for nested predicates is there to ensure that patterns
such as match="p[@code = $status[last()]]
are not disqualified.
The expression immediately contained in the predicate is a non-numeric expression. An expression is non-numeric if the intersection of its static type (see 19.1 Determining the Static Type of a Construct) with U{xs:decimal, xs:double, xs:float} is U{}.
A non-schema-aware processor is a processor that does not claim conformance with the schema-aware conformance feature. Such a processor must handle constructs associated with schema-aware processing as described in this section.
In an actual instance of a construct, there will be a number of operands. Each operand is itself a construct; the construct tree can be defined as the transitive relation between constructs and their operands.
For every construct kind, there is a set of zero or more operand roles.
The operand usage. This gives information, in the case where the operand value contains nodes, about how those nodes are used. The operand usage takes one of the values absorption, inspection, transmission, or navigation.
Functions that take an options parameter adopt common conventions on how the options are used. These are referred to as the option parameter conventions. These rules apply only to functions that explicitly refer to them.
There is a total ordering among groups referred to as the order of first appearance. A
group G is defined to precede a group H in order of first
appearance if the initial item of
G precedes the initial item of H in population order. If
two groups G and H have the same initial item (because the
item is in both groups) then G precedes H if the grouping key of G precedes the
grouping key of H in the sequence that results from evaluating the
group-by
expression of this initial item.
All the
xsl:output
declarations within a
package that share the same name
are grouped into a named output definition; those that have no name are
grouped into a single unnamed output definition.
Each instruction in the stylesheet is evaluated in one of two possible output states: final output state or temporary output state
A component in a using package may
override a component in a used package, provided that the
visibility of the component in the
used package is either abstract
or public
. The
overriding declaration is written as a child of the
xsl:override
element, which in turn appears as a child
of xsl:use-package
.
An explicit package is
represented by an xsl:package
element, which will generally be
the outermost element of an XML document. When the
xsl:package
element is not used explicitly, the entire
stylesheet comprises a single implicit package.
The content of the
xsl:package
element is referred to as the package
manifest
The xsl:param
element
declares a parameter, which may be a stylesheet parameter, a template parameter, a function parameter, or an xsl:iterate
parameter. A parameter is a
variable with the additional property that
its value can be set by the caller.
A pattern specifies a set of conditions on an item. An item that satisfies the conditions matches the pattern; an item that does not satisfy the conditions does not match the pattern.
The picture string
is the string supplied as the second argument of the
format-number
FO30 function.
The xsl:number
instruction performs two tasks: firstly, determining a place marker
(this is a sequence of integers, to allow for hierarchic numbering schemes such as
1.12.2
or 3(c)ii
), and secondly, formatting the place
marker for output as a text node in the result sequence.
The sequence of items to be grouped,
which is referred to as the population, is determined by evaluating
the XPath expression contained in the
select
attribute.
The population is treated as a sequence; the order of items in this sequence is referred to as population order
The integer literals and the optional
NamePart
within the version number are referred to as the
portions of the version number.
The posture of the expression. This captures information about the way in which the streamed input document is positioned on return from evaluating the construct. The posture takes one of the values climbing, striding, crawling, roaming, or grounded.
An operand is potentially consuming if at least one of the following conditions applies:
The operand usage is transmission and the operand is not grounded.
A predicate pattern is written as
.
(dot) followed by zero or more predicates in square
brackets, and it matches any item for which each of the predicates evaluates
to true
.
A principal result: this can be any sequence of items (as defined in [XDM 3.0]).
Within a package, one stylesheet module functions as the
principal stylesheet module. The complete package is assembled by
finding the stylesheet modules referenced directly or indirectly from the
principal stylesheet module using xsl:include
and
xsl:import
elements: see 3.11.2 Stylesheet Inclusion and 3.11.3 Stylesheet Import.
The priority of a
template rule is specified by the priority
attribute on the
xsl:template
declaration. If no priority is specified
explicitly for a template rule, its default priority is used, as defined in 6.5 Default Priority for Template Rules.
There is another total ordering among groups referred to as
processing order. If group R precedes group
S in processing order, then in the result sequence returned by the
xsl:for-each-group
instruction the items generated by
processing group R will precede the items generated by processing group
S.
The software responsible for transforming source trees into result trees using an XSLT stylesheet is referred to as the processor. This is sometimes expanded to XSLT processor to avoid any confusion with other processors, for example an XML processor.
The result of invoking the selected component, after any required conversion to the declared result type of the component, is referred to as the raw result.
The process of identifying the component to which a symbolic reference applies (possibly chosen from several homonymous alternatives) is called reference binding.
The context within a stylesheet where an XPath expression appears may specify the required type of the expression. The required type indicates the type of the value that the expression is expected to return.
The XSLT namespace, together with certain other namespaces recognized by an XSLT processor, are classified as reserved namespaces and must be used only as specified in this and related specifications.
The term result tree is used to refer to any tree constructed by instructions in the stylesheet. A result tree is either a final result tree or a temporary tree.
Roaming: indicates that the nodes returned by an expression could be anywhere in the tree, which inevitably means that the construct cannot be evaluated using streaming.
Within a map, no
two entries have the same key. Two atomic
values K1
and K2
are the same key for this
purpose if the relation op:same-key(K1, K2, $UCC)
holds.
A
RelativePathExpr
is a scanning expression
if and only if it is syntactically equivalent to some motionless
pattern.
Type definitions and element and attribute declarations are referred to collectively as schema components.
The schema instance namespace
http://www.w3.org/2001/XMLSchema-instance
is used as defined
in [XML Schema Part 1]
The schema
namespace
http://www.w3.org/2001/XMLSchema
is used as defined in
[XML Schema Part 1]
A
schema-aware XSLT processor is an XSLT processor that implements
the mandatory requirements of this specification connected with the
xsl:import-schema
declaration, the
[xsl:]validation
and [xsl:]type attributes
, and the
ability to handle input documents whose nodes have type annotations other than
xs:untyped
and xs:untypedAtomic
. The mandatory
requirements of this specification are taken to include the mandatory requirements
of XPath 3.0, as described in [XPath 3.0]. A requirement is mandatory unless the specification includes
wording (such as the use of the words should or
may) that clearly indicates that it is optional.
Zero or more secondary results: each secondary result can be any sequence of items (as defined in [XDM 3.0]).
A selection pattern uses a subset of the syntax for path expressions, and is defined to match a node if the corresponding path expression would select the node. Selection patterns may also be formed by combining other patterns using union, intersection, and difference operators.
A sequence constructor is a sequence of zero or more sibling nodes in the stylesheet that can be evaluated to return a sequence of nodes, atomic values, and function items. The way that the resulting sequence is used depends on the containing instruction.
A SequenceType constrains the type and number of items in a sequence. The term is used both to denote the concept, and to refer to the syntactic form in which sequence types are expressed in the XPath grammar: specifically SequenceTypeXP30 in [XPath 3.0], or SequenceTypeXP31 in [XPath 3.1], depending on whether or not the XPath 3.1 Feature is implemented.
A frequent requirement is to output a final result tree as an XML document (or in other formats such as HTML). This process is referred to as serialization.
If a transformation has successfully produced a principal result or secondary result, it is still possible that errors may occur in serializing that result . For example, it may be impossible to serialize the result using the encoding selected by the user. Such an error is referred to as a serialization error.
A processor that claims conformance with the serialization feature must support the conversion of a final result tree to a sequence of octets following the rules defined in 26 Serialization.
A binding shadows another binding if the binding occurs at a point where the other binding is visible, and the bindings have the same name.
A simplified stylesheet, which is a subtree rooted at a literal result element, as described in 3.8 Simplified Stylesheet Modules. This is first converted to a standard stylesheet module by wrapping it in an xsl:stylesheet element using the transformation described in 3.8 Simplified Stylesheet Modules.
A singleton focus based on an item J has the context item (and therefore the context node, if J is a node) set to J, and the context position and context size both set to 1 (one).
A snapshot of a node N
is a deep copy of N, as produced by the xsl:copy-of
instruction with copy-namespaces
set to yes
,
copy-accumulators
set to yes
, and
validation
set to preserve
, with the additional property
that for every ancestor of N, the copy also has a corresponding ancestor
whose name, node-kind, and base URI are the same as the corresponding ancestor of
N, and that has copies of the attributes, namespaces and accumulator values of the
corresponding ancestor of N. But the ancestor has a type annotation of
xs:anyType
, has the properties nilled
,
is-id
, and is-idref
set to false, and has no children
other than the child that is a copy of N or one of its
ancestors.
Within a sort key specification, each
xsl:sort
element defines one sort key
component.
A sort key
specification is a sequence of one or more adjacent
xsl:sort
elements which together define rules for sorting the
items in an input sequence to form a sorted sequence.
For each item in the initial sequence, a value is computed for each sort key component within the sort key specification. The value computed for an item by using the Nth sort key component is referred to as the Nth sort key value of that item.
The sequence after sorting
as defined by the xsl:sort
elements is referred to as the
sorted sequence.
The term source tree
means any tree provided as input to the transformation. This includes the document
containing the global context item if any, documents containing
nodes present in the initial match selection,
documents containing nodes supplied as the values of stylesheet parameters, documents
obtained from the results of functions such as document
,
doc
FO30, and collection
FO30, documents read using the xsl:source-document
instruction, and documents returned by extension functions or
extension instructions. In the context of a particular XSLT instruction, the term
source tree means any tree provided as input to that instruction;
this may be a source tree of the transformation as a whole, or it may be a
temporary tree produced during the
course of the transformation.
A sort
key specification is said to be stable if its first
xsl:sort
element has no stable
attribute, or has
a stable
attribute whose effective
value is yes
.
There are a number of
standard attributes that may appear on any XSLT element: specifically
default-collation
, default-mode
,
default-validation
,
exclude-result-prefixes
, expand-text
, extension-element-prefixes
,
use-when
, version
, and
xpath-default-namespace
.
The standard error namespace
http://www.w3.org/2005/xqt-errors
is used for error codes
defined in this specification and related specifications. It is also used
for the names of certain predefined variables accessible within the scope
of an xsl:catch
element.
The standard function
namespace
http://www.w3.org/2005/xpath-functions
is used for functions
in the function library defined in [Functions and Operators 3.0] and
for standard functions defined in this specification.
A
standard stylesheet module, which is a subtree rooted at an
xsl:stylesheet
or xsl:transform
element.
An error that can be detected by examining a stylesheet before execution starts (that is, before the source document and values of stylesheet parameters are available) is referred to as a static error.
A static expression is an XPath expression whose value must be computed during static analysis of the stylesheet.
A static variable declared using an xsl:param
element
is referred to as a static parameter.
The static type of a construct is such that all values produced by evaluating the construct will conform to that type. The static type of a construct is a U-type.
A top-level
variable-binding element
having the attribute static="yes"
declares a static
variable: that is, a global variable whose value is
known during static analysis of the stylesheet.
Stylesheet functions belong to one of a number of streamability categories: the choice of category characterizes the way in which the function handles streamed input.
A streamable
mode is a mode that is declared in
an xsl:mode
declaration with the attribute
streamable="yes"
.
A streamed document is a source tree that is processed using streaming, that is, without constructing a complete tree of nodes in memory.
A streamed node is a node in a streamed document.
The term streaming refers to a manner of processing in which XML documents (such as source and result documents) are not represented by a complete tree of nodes occupying memory proportional to document size, but instead are processed “on the fly” as a sequence of events, similar in concept to the stream of events notified by an XML parser to represent markup in lexical XML.
A processor that claims
conformance with the streaming feature
must use streamed processing in cases where (a) streaming is
requested (for example by using the attribute streamable="yes"
on
xsl:mode
, or on
the xsl:source-document
instruction) and
(b) the constructs in question are guaranteed-streamable
according to this specification.
The first parameter of a declared-streamable stylesheet function is referred to as a streaming parameter.
Striding: indicates that the result of a construct contains a sequence of streamed nodes, in document order, that are peers in the sense that none of them is an ancestor or descendant of any other.
The term string value is defined in Section 5.13 string-value Accessor DM30. Every node has a string value. For example, the string value of an element is the concatenation of the string values of all its descendant text nodes.
A stylesheet consists of one or more packages: specifically, one top-level package and zero or more library packages.
An
xsl:function
declaration declares the name, parameters, and
implementation of a stylesheet function that can be called from any
XPath expression within the stylesheet
(subject to visibility
rules).
A stylesheet
level is a collection of stylesheet modules connected using xsl:include
declarations: specifically, two stylesheet modules A and
B are part of the same stylesheet level if one of them includes
the other by means of an xsl:include
declaration, or if there
is a third stylesheet module C that is in the same stylesheet level
as both A and B.
A package consists of one or more stylesheet modules, each one forming all or part of an XML document.
A top-level
xsl:param
element declares a stylesheet
parameter. A stylesheet parameter is a global variable with the additional
property that its value can be supplied by the caller when a transformation is
initiated.
The value of the variable is
computed using the expression given in the
select
attribute or the contained sequence constructor, as described in
9.3 Values of Variables and Parameters. This value is referred to as the
supplied value of the variable.
Every construct has a sweep, which is a measure of the extent to which the current position in the input stream moves during the evaluation of the expression. The sweep is one of: motionless, consuming, or free-ranging .
The symbolic identifier of a component is a composite name used to identify the component uniquely within a package. The symbolic identifier comprises the kind of component (stylesheet function, named template, accumulator, attribute set, global variable, key, or mode), the expanded QName of the component (namespace URI plus local name), and in the case of stylesheet functions, the arity.
The declaration of a component includes
constructs that can be interpreted as references to other components by means of their symbolic identifiers. These
constructs are generically referred to as symbolic references.
Examples of constructs that give rise to symbolic references are the
name
attribute of xsl:call-template
; the
[xsl:]use-attribute-sets
attribute of
xsl:copy
, xsl:element
, and literal result elements; the
explicit or implicit
mode
attribute of xsl:apply-templates
; XPath
variable references referring to global variables; XPath static function calls (including partial function
applications) referring to stylesheet functions; and
named function references (example: my:f#1
) referring to
stylesheet functions.
An instruction J is in a tail position within a sequence constructor SC if it satisfies one of the following conditions:
J is the last instruction in SC, ignoring any
xsl:fallback
instructions.
J is in a tail position
within the sequence constructor that forms the body of an
xsl:if
instruction that is itself in a tail position within SC.
J is in a tail position
within the sequence constructor that forms the body of an
xsl:when
or xsl:otherwise
branch of an
xsl:choose
instruction that is itself in a tail position within SC.
J is in a tail position
within the sequence constructor that forms the body of an
xsl:try
instruction that is itself in a tail position within SC (that
is, it is immediately followed by an xsl:catch
element,
ignoring any xsl:fallback
elements).
J is in a tail position
within the sequence constructor that forms the body of an
xsl:catch
element within an xsl:try
instruction that is itself in a tail
position within SC.
The string that results
from evaluating the expression in the xpath
attribute is referred to
as the target expression.
The namespace URI that is to be used in the result tree as a substitute for a literal namespace URI is called the target namespace URI.
An xsl:template
declaration defines a template, which contains a sequence constructor;
this sequence constructor is evaluated to determine
the result of the template. A template can serve either as a template rule, invoked by matching items against a pattern, or as a named
template, invoked explicitly by name. It is also possible for the
same template to serve in both capacities.
An
xsl:param
element may appear as a child of an
xsl:template
element, before any
non-xsl:param
children of that element. Such a parameter
is known as a template parameter. A template parameter is a
local variable with the
additional property that its value can be set when the template is called,
using any of the instructions xsl:call-template
,
xsl:apply-templates
, xsl:apply-imports
,
or xsl:next-match
.
A stylesheet contains a set of template rules (see 6 Template Rules). A template rule has three parts: a pattern that is matched against selected items (often but not necessarily nodes), a (possibly empty) set of template parameters, and a sequence constructor that is evaluated to produce a sequence of items.
The second of the two output states is called temporary output state. This state applies when instructions are writing to a temporary tree or any other non-final destination.
The term temporary tree means any tree that is neither a source tree nor a final result tree.
In a text node
that is designated as a text value template, expressions can be used by surrounding each
expression with curly brackets ({}
).
An element occurring as a child of an
xsl:package
,
xsl:stylesheet
,
xsl:transform
, or xsl:override
element is called a top-level element.
For a given transformation, one package functions as the top-level package. The
complete stylesheet is assembled by finding
the packages referenced directly or indirectly from the top-level package using
xsl:use-package
declarations: see 3.5.2 Dependencies between Packages.
An operand usage of transmission indicates that the construct will (potentially) return a supplied node as part of its result to the calling construct (that is, to its parent in the construct tree).
A traversal of a tree is a sequence of traversal events.
a traversal event (shortened to event in this section) is a pair comprising a phase (start or end) and a node.
The term tree is used (as in [XDM 3.0]) to refer to the aggregate consisting of a parentless node together with all its descendant nodes, plus all their attributes and namespaces.
A parameter passed to a template may be defined as a tunnel parameter. Tunnel parameters have the property that they are automatically passed on by the called template to any further templates that it calls, and so on recursively.
The term type
annotation is used in this specification to refer to the value returned
by the dm:type-name
accessor of a node: see Section
5.14 type-name Accessor
DM30.
Certain errors are classified as type errors. A type error occurs when the value supplied as input to an operation is of the wrong type for that operation, for example when an integer is supplied to an operation that expects a node.
The type-adjusted posture and sweep of a construct C, with respect to a type T, are the posture and sweep established by applying the general streamability rules to a construct D whose single operand is the construct C, where the operand usage of C in D is the type-determined usage based on the required type T.
The
type-determined usage of an operand is as
follows: if the required type (ignoring occurrence indicator) is
function(*)
or a subtype thereof, then inspection; if the required type (ignoring occurrence indicator) is an atomic or union type, then absorption; otherwise navigation.
The term typed
value is defined in Section
5.15 typed-value Accessor
DM30.
Every node, other than an element whose type
annotation identifies it as having element-only content, has a
typed value. For example, the
typed value of an attribute of
type xs:IDREFS
is a sequence of zero or more
xs:IDREF
values.
A U-type is a set of fundamental item types.
The unnamed mode is the default mode used when no
mode
attribute is specified on an
xsl:apply-templates
instruction or
xsl:template
declaration, unless a different default mode
has been specified using the [xsl:]default-mode
attribute of a containing
element.
Within this specification, the
term URI Reference, unless otherwise stated, refers to a string in
the lexical space of the xs:anyURI
datatype as defined in [XML Schema Part 2].
If a package Q contains an
xsl:use-package
element that references package
P, then package Q is said to use package
P. In this relationship package Q is referred to as
the using package, package P as the used
package.
In addition to
declarations, the
xsl:stylesheet
element may contain among its children any
element not from the XSLT namespace,
provided that the expanded QName of
the element has a non-null namespace URI. Such elements are referred to as
user-defined data elements.
An item is vacuous if
it is one of the following: a zero-length text node; a document node with no children;
an atomic value which,
on casting to xs:string
, produces a zero-length string; or (when XPath 3.1 is supported) an array
which on flattening using the array:flatten
FO31 function produces either an empty sequence
or a sequence consisting entirely of vacuous items.
A variable is a binding between a name and a value. The value of a variable is any sequence (of nodes, atomic values, and/or function items), as defined in [XDM 3.0].
Collectively, attribute value templates and text value templates are referred to as value templates.
The xsl:variable
element
declares a variable, which may be a global variable or a local
variable.
The two
elements xsl:variable
and xsl:param
are referred to
as variable-binding elements
The visibility of a
component is one of:
private
, public
, abstract
,
final
, or hidden
.
A whitespace text node is a text node whose content consists entirely of whitespace characters (that is, #x09, #x0A, #x0D, or #x20).
The XML
namespace, defined in [Namespaces in XML] as
http://www.w3.org/XML/1998/namespace
, is used for
attributes such as xml:lang
, xml:space
, and
xml:id
.
The term
XPath 1.0 compatibility mode is defined in Section
2.1.1 Static Context
XP30. This is a setting in the static
context of an XPath expression; it has two values, true
and
false
. When the value is set to true, the semantics of
function calls and certain other operations are adjusted to give a greater
degree of backwards compatibility between XPath
3.0 and XPath 1.0.
A processor that claims conformance with the XPath 3.1 feature must implement XPath 3.1 (including [XPath 3.1], [XDM 3.1], [XSLT and XQuery Serialization 3.1], and [Functions and Operators 3.1]).
An element in the stylesheet is processed with XSLT 1.0 behavior if its effective version is equal to 1.0.
A processor that claims conformance with the XSLT 1.0 compatibility feature must support the processing of stylesheet instructions and XPath expressions with XSLT 1.0 behavior, as defined in 3.9 Backwards Compatible Processing.
An element is processed with XSLT 2.0 behavior if its effective version is equal to 2.0.
An XSLT element is an element in the XSLT namespace whose syntax and semantics are defined in this specification.
An XSLT
instruction is an XSLT element
whose syntax summary in this specification contains the annotation <!--
category: instruction -->
.
The XSLT namespace
has the URI http://www.w3.org/1999/XSL/Transform
. It is used to
identify elements, attributes, and other names that have a special meaning defined
in this specification.
The syntax of each XSLT element is summarized below, together with the context in the stylesheet where the element may appear. Some elements (specifically, instructions) are allowed as a child of any element that is allowed to contain a sequence constructor. These elements are:
Model:
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This appendix provides a summary of error conditions that a processor may signal. This list includes all error codes defined in this specification, but this is not an exhaustive list of all errors that can occur. Implementations must signal errors using these error codes, and applications can test for these codes; however, when more than one rule in the specification is violated, different processors will not necessarily signal the same error code. Implementations are not required to signal errors using the descriptive text used here.
Note:
The appendix is non-normative because the same information is given normatively elsewhere.
Static errors
It is a static error if an XSLT-defined element is used in a context where it is not permitted, if a required attribute is omitted, or if the content of the element does not correspond to the content that is allowed for the element.
It is a static error if an attribute (other than an attribute written using curly brackets in a position where an attribute value template is permitted) contains a value that is not one of the permitted values for that attribute.
It is a static error to use a
reserved namespace in the
name of a named template, a
mode, an attribute set, a key, a
decimal-format, a variable or parameter, a stylesheet
function, a named output
definition, an accumulator, or a character map; except that the name
xsl:initial-template
is permitted as a template
name.
It is a static error to use a reserved namespace
in the name of any extension function or extension instruction,
other than a function or instruction defined in this specification or in a normatively
referenced specification. It is a static error to use a prefix bound
to a reserved namespace in the [xsl:]extension-element-prefixes
attribute.
It is a static error for an element from the XSLT namespace to have an attribute whose namespace is either null (that is, an attribute with an unprefixed name) or the XSLT namespace, other than attributes defined for the element in this document.
The value of the version
attribute must be a number:
specifically, it must be a valid instance of the type
xs:decimal
as defined in [XML Schema Part 2].
An xsl:stylesheet
, xsl:transform
,
or xsl:package
element must not have any
text node children.
It is a static error if the value
of an [xsl:]default-collation
attribute, after resolving
against the base URI, contains no URI that the implementation recognizes as
a collation URI.
It is a static error if an
xsl:stylesheet
, xsl:transform
,
or xsl:package
element has a child element whose name
has a null namespace URI.
A literal result element
that is used as the outermost element of a simplified stylesheet module
must have an xsl:version
attribute.
It is a static error if the
processor is not able to retrieve the resource identified by the URI
reference [ in the href
attribute of
xsl:include
or xsl:import
] , or if the resource that is retrieved does not contain a
stylesheet module.
An xsl:include
element must be a
top-level element.
It is a static error if a stylesheet module directly or indirectly includes itself.
An xsl:import
element must be a top-level element.
It is a static error if a stylesheet module directly or indirectly imports itself.
It is a static error if an
xsl:import-schema
element that contains an
xs:schema
element has a schema-location
attribute,
or if it has a namespace
attribute that conflicts with the target
namespace of the contained schema.
It is a static error if the synthetic schema document does not satisfy the constraints described in [XML Schema Part 1] (section 5.1, Errors in Schema Construction and Structure). This includes, without loss of generality, conflicts such as multiple definitions of the same name.
Within an XSLT element that is
required to be empty, any content other than comments or
processing instructions, including any whitespace text node preserved using the
xml:space="preserve"
attribute, is a static error.
It is a static error if there is a
stylesheet module in a
package that specifies
input-type-annotations="strip"
and another stylesheet module that specifies
input-type-annotations="preserve"
, or if a stylesheet module specifies the value
strip
or preserve
and the same value is not
specified on the xsl:package
element of the containing
package.
It is a static error if within any package the same NameTestXP30 appears in both an
xsl:strip-space
and an xsl:preserve-space
declaration if both have the same import
precedence. Two NameTests are considered the same if they match
the same set of names (which can be determined by comparing them after
expanding namespace prefixes to URIs).
In the case of a prefixed lexical QName used as the value (or as part of the value) of an attribute in the stylesheet, or appearing within an XPath expression in the stylesheet, it is a static error if the defining element has no namespace node whose name matches the prefix of the lexical QName.
Where an attribute is defined to contain a pattern, it is a static error if the pattern does not match the production Pattern30.
It is a static error if an unescaped left curly bracket appears in a fixed part of a value template without a matching right curly bracket.
It is a static error if an unescaped right curly bracket occurs in a fixed part of a value template.
An xsl:template
element must have either a
match
attribute or a name
attribute, or both. An
xsl:template
element that has no match
attribute must have no mode
attribute and no
priority
attribute. An
xsl:template
element that has no name
attribute must have no visibility
attribute.
The value of the priority
attribute [ of the
xsl:template
element]
must conform to the rules for the
xs:decimal
type defined in [XML Schema Part 2].
Negative values are permitted.
It is a static error if for any
named or unnamed mode, a package explicitly specifies two conflicting
values for the same attribute in different xsl:mode
declarations having the same import
precedence, unless there is another definition of the same
attribute with higher import precedence. The attributes in question are the
attributes other than name
on the xsl:mode
element.
It is a static error if the list of
modes [in the mode
attribute of
xsl:template
] is empty, if the same token is included more than once in the
list, if the list contains an invalid token, or if the token
#all
appears together with any other value.
It is a static error if the values of
the name
attribute of two sibling
xsl:param
elements represent the same expanded QName.
It is a static error if a variable-binding element has a
select
attribute and has non-empty content.
It is a static error if a package contains more than one non-hidden binding of a global variable with the same name and same import precedence, unless it also contains another binding with the same name and higher import precedence.
It is a static error if a package contains an
xsl:call-template
instruction whose name
attribute does not match the name
attribute of any named template
visible in the containing package (this
includes any template defined in this package, as well as templates accepted
from used packages whose visibility in this package is not
hidden
). For more details of the process of binding the
called template, see 3.5.3.5 Binding References to Components.
It is a static error if a package contains more than one non-hidden template with the same name and the same import precedence, unless it also contains a template with the same name and higher import precedence.
It is a static error
if two or more sibling xsl:with-param
elements have
name
attributes that represent the same expanded QName.
In the case of xsl:call-template
, it is a static error to pass a non-tunnel
parameter named x to a template that does not have a non-tunnel
template
parameter named x, unless the xsl:call-template
instruction is processed with
XSLT 1.0
behavior.
It is a static error if a
package contains both (a) a
named template named T that is not overridden by another
named template of higher import precedence and that has an explicitly mandatory non-tunnel parameter named
P, and (b) an xsl:call-template
instruction whose name
attribute equals T and
that has no non-tunnel xsl:with-param
child element
whose name
attribute equals P. (All names are
compared as QNames.)
It is a static error if the value
of the use-attribute-sets
attribute of an
xsl:copy
, xsl:element
, or
xsl:attribute-set
element, or the
xsl:use-attribute-sets
attribute of a literal result element, is not
a whitespace-separated sequence of EQNames, or if it contains an
EQName that does not match the name
attribute of any
xsl:attribute-set
declaration in the containing package.
If an xsl:attribute
set element specifies
streamable="yes"
then every attribute set referenced in its
use-attribute-sets
attribute (if present) must also specify
streamable="yes"
.
It is a static error if a stylesheet function has a name that is in no namespace.
It is a static error if an xsl:param
child of
an xsl:function
element has either a select
attribute or non-empty content.
It is a static error for a package to
contain two or more xsl:function
declarations with the same expanded QName, the same arity, and the same import
precedence, unless there is another xsl:function
declaration with the same
expanded QName and arity, and
a higher import precedence.
It is a static error if an attribute on a literal result element is in the XSLT namespace, unless it is one of the attributes explicitly defined in this specification.
It is a static error if a
namespace prefix is used within the
[xsl:]exclude-result-prefixes
attribute and there is
no namespace binding in scope for that prefix.
It is a static error if the
value #default
is used within the
[xsl:]exclude-result-prefixes
attribute and the parent
element of the [xsl:]exclude-result-prefixes
attribute
has no default namespace.
It is a static error if within a package there is more than one such declaration
[more than one xsl:namespace-alias
declaration] with the same literal namespace URI and the
same import precedence and
different values for the target
namespace URI, unless there is also an
xsl:namespace-alias
declaration with the same literal namespace URI and a
higher import precedence.
It is a static error if a value
other than #default
is specified for either the
stylesheet-prefix
or the result-prefix
attributes of the xsl:namespace-alias
element when there is
no in-scope binding for that namespace prefix.
It is a static error if the
select
attribute of the xsl:attribute
element
is present unless the element has empty content.
It is a static error if the
select
attribute of the xsl:value-of
element is present when the content of the element is non-empty.
It is a static error if the
select
attribute of the
xsl:processing-instruction
element is present unless the
element has empty content.
It is a static error if the
select
attribute of the xsl:namespace
element
is present when the element has content other than one or more
xsl:fallback
instructions, or if the select
attribute is absent when the element has empty content.
It is a static error if the
select
attribute of the xsl:comment
element is
present unless the element has empty content.
It is a static error if the
value
attribute of xsl:number
is present unless
the select
, level
, count
, and
from
attributes are all absent.
It is a static error if an
xsl:sort
element with a select
attribute has
non-empty content.
It is a static error if an
xsl:sort
element other than the first in a sequence of
sibling xsl:sort
elements has a stable
attribute.
It is a static error if an
xsl:perform-sort
instruction with a select
attribute has any content other than xsl:sort
and
xsl:fallback
instructions.
It is a static error if the
current-group
function is used within a pattern.
It is a static error if the
current-grouping-key
function is used within a pattern.
These four attributes [the group-by
,
group-adjacent
, group-starting-with
, and
group-ending-with
attributes of
xsl:for-each-group
] are mutually exclusive: it is a static error if none of these four attributes is present or if
more than one of them is present.
It is a static error to specify the
collation
attribute or the
composite
attribute if neither the
group-by
attribute nor group-adjacent
attribute is
specified.
It is a static error if the
xsl:analyze-string
instruction contains neither an
xsl:matching-substring
nor an
xsl:non-matching-substring
element.
It is a static error if an
xsl:key
declaration has a use
attribute and
has non-empty content, or if it has empty content and no use
attribute.
It is a static error if the
xsl:key
declaration has a collation
attribute whose value (after resolving against the base URI) is not a URI
recognized by the implementation as referring to a collation.
It is a static error if there are
several xsl:key
declarations in the same package with the
same key name and different effective collations. Two collations are the
same if their URIs are equal under the rules for comparing
xs:anyURI
values, or if the implementation can determine
that they are different URIs referring to the same collation.
It is a static error if there are
several xsl:key
declarations in a package with the same key name and
different effective values for the composite
attribute.
It is a static error if a named or
unnamed decimal format contains two
conflicting values for the same attribute in different
xsl:decimal-format
declarations having the same import precedence, unless there is
another definition of the same attribute with higher import precedence.
It is a static error if the character
specified in the zero-digit
attribute is not a digit or is a digit
that does not have the numeric value zero.
It is a static error if, for any named or unnamed decimal format, the variables representing characters used in a picture string do not each have distinct values. These variables are decimal-separator-sign, grouping-sign, percent-sign, per-mille-sign, digit-zero-sign, digit-sign, and pattern-separator-sign.
It is a static error if there is no
namespace bound to the prefix on the element bearing the
[xsl:]extension-element-prefixes
attribute or, when
#default
is specified, if there is no default namespace.
It is a static error if both the
[xsl:]type
and [xsl:]validation
attributes are
present on the xsl:element
, xsl:attribute
,
xsl:copy
, xsl:copy-of
,
xsl:document
, xsl:result-document
, xsl:source-document
, or
xsl:merge-source
elements, or on a literal result element.
It is a static error if the
value of the type
attribute of an
xsl:element
, xsl:attribute
,
xsl:copy
, xsl:copy-of
,
xsl:document
, or xsl:result-document
instruction, or the xsl:type
attribute of a literal result
element, is not a valid QName
, or if it uses a prefix that
is not defined in an in-scope namespace declaration, or if the QName is
not the name of a type definition included in the in-scope schema
components for the package.
It is a static error if the
value of the type
attribute of an
xsl:attribute
instruction refers to a complex type
definition
It is a static error if two
xsl:output
declarations within an output definition specify explicit values
for the same attribute (other than cdata-section-elements
, suppress-indentation
, and
use-character-maps
), with the values of the attributes being not
equal, unless there is another xsl:output
declaration within the
same output definition that has
higher import precedence and that specifies an explicit value for the same
attribute.
The value [of the method
attribute on
xsl:output
]
must (if present) be a valid EQName. If it is a lexical
QName with no a prefix, then it identifies a method specified in
[XSLT and XQuery Serialization] and must be one
of xml
, html
, xhtml
, or
text
.
It is a static error if a package contains two or more character maps with the same name and the same import precedence, unless it also contains another character map with the same name and higher import precedence.
It is a static error if a name in the
use-character-maps
attribute of the xsl:output
or xsl:character-map
elements does not match the
name
attribute of any xsl:character-map
in the
containing package.
It is a static error if a character
map references itself, directly or indirectly, via a name in the
use-character-maps
attribute.
A non-schema-aware
processor
must signal a static
error if a package includes an
xsl:import-schema
declaration.
A non-schema-aware
processor
must signal a static
error if a package includes an
[xsl:]type
attribute; or an [xsl:]validation
or
[xsl:]default-validation
attribute with a value other than
strip
, preserve
, or
lax
; or an
xsl:mode
element whose typed
attribute is
equal to yes
or strict
; or an as
attribute whose value is a
SequenceType that can only match
nodes with a type annotation other than xs:untyped
or
xs:untypedAtomic
(for example, as="element(*,
xs:integer)"
).
It is a static error if the number of
xsl:merge-key
children of a
xsl:merge-source
element is not equal to the number of
xsl:merge-key
children of another
xsl:merge-source
child of the same
xsl:merge
instruction.
It is a static error if no package matching the package
name and version specified in an xsl:use-package
declaration can be located.
It is a static error if a package is dependent on
itself, where package A is defined as being dependent on package
B if A contains an xsl:use-package
declaration that references B, or if A contains an
xsl:use-package
declaration that references a package
C that is itself dependent on B.
It is a static error if an xsl:use-package
declaration appears in a stylesheet module that is not in the
same stylesheet level as the principal stylesheet module
of the package.
It is a static error if the
explicit exposed visibility of a component is inconsistent with its
declared visibility, as defined in the above table. (This error occurs
only when the component declaration has an explicit
visibility
attribute, and the component is also listed
explicitly by name in an xsl:expose
declaration.)
It is a static error if a token
in the names
attribute of xsl:expose
, other
than a wildcard, matches no component in the containing package.
It is a static error if the
component
attribute of xsl:expose
specifies *
(meaning all component kinds) and the names
attribute is not a wildcard.
It is a static error if the
effect of an xsl:expose
declaration would be to make a component
abstract
, unless the component is already abstract
in the absence of the xsl:expose
declaration.
It is a static error if a token
in the names
attribute of xsl:accept
, other
than a wildcard, matches no component in the used package.
It is a static error if the
component
attribute of xsl:accept
specifies *
(meaning all component kinds) and the names
attribute is not a wildcard.
It is a static error if the
visibility assigned to a component by an xsl:accept
element is incompatible with the visibility of the corresponding
component in the used package, as defined by the above table, unless the
token that matches the component name is a wildcard, in which case the
xsl:accept
element is treated as not matching that
component.
It is a static error if the
xsl:use-package
elements in a package manifest cause two or more
homonymous components to be
accepted with a visibility other than hidden
.
It is a static error if
a token in the names
attribute of xsl:accept
,
other than a wildcard, matches the symbolic name of a component declared
within an xsl:override
child of the same
xsl:use-package
element.
It is a static error if a
component declaration appearing as a child of
xsl:override
is homonymous with any other declaration in the using package,
regardless of import
precedence, including any other overriding declaration in
the package manifest of the using package.
It is a static error if a
component declaration appearing as a child of
xsl:override
does not match (is not homonymous with) some component in the
used package.
It is a static error if the
component referenced by an xsl:override
declaration has
visibility other than
public
or abstract
It is a static error if the signature of an overriding component is not compatible with the signature of the component that it is overriding.
It is a static error to use the
component reference xsl:original
when the overridden
component has visibility="abstract"
.
It is a static error if a
top-level package (as
distinct from a library
package) contains
components whose visibility is abstract
.
It is a static error,
when the effective value of the declared-modes
attribute of
an xsl:package
element is yes
, if the
package contains an explicit reference to an undeclared mode, or if
it implicitly uses the unnamed mode and the unnamed mode is undeclared.
It is a static error if more than
one xsl:global-context-item
declaration appears within a
stylesheet module, or if several modules within a
single package contain inconsistent
xsl:global-context-item
declarations
It is a static error if the as
attribute is
present [on the xsl:context-item
element] when use="absent"
is specified.
It is a static error if the as
attribute is
present [on the xsl:global-context-item
element] when use="absent"
is specified.
It is a static error if a template
rule applicable to a mode that is defined with typed="strict"
uses a match pattern that contains a RelativePathExprP
whose
first StepExprP
is an AxisStepP
whose
ForwardStepP
uses an axis whose principal node kind is
Element
and whose NodeTest
is an
EQName
that does not correspond to the name of any global
element declaration in the in-scope schema components.
It is a static error if an
xsl:break
or xsl:next-iteration
element
appears other than in a tail position
within the sequence
constructor forming the body of an xsl:iterate
instruction.
It is a static error if the
select
attribute of xsl:break
or
xsl:on-completion
is present and the instruction has
children.
It is a static error if the
name
attribute of an xsl:with-param
child of
an xsl:next-iteration
element does not match the
name
attribute of an xsl:param
child of the
innermost containing
xsl:iterate
instruction.
It is a static error if the
select
attribute of the xsl:try
element is
present and the element has children other than xsl:catch
and
xsl:fallback
elements.
It is a static error if the
select
attribute of the xsl:catch
element is
present unless the element has empty content.
It is a static error if the
select
attribute of xsl:sequence
is present
and the instruction has children other than xsl:fallback
.
It is a static error if two sibling
xsl:merge-source
elements have the same name.
If the for-each-item
is present then the
for-each-source
, use-accumulators
, and streamable
attributes
must both be absent. If the use-accumulators
attribute is present
then the for-each-source
attribute must be present. If the
for-each-source
attribute is present then the
for-each-item
attribute must be absent.
It is a static error if an
xsl:merge-key
element with a select
attribute
has non-empty content.
It is a static error if the
select
attribute of the xsl:map-entry
element
is present unless the element has no children other than
xsl:fallback
elements.
It is a static error if the list of
accumulator names [in the use-accumulators
attribute] contains an invalid token, contains the same
token more than once, or contains the token #all
along with any
other value; or if any token (other than
#all
) is not the name of a declared-streamable accumulator visible in the containing
package.
It is a static error for a package to contain two or more non-hidden accumulators with the same expanded QName and the same import precedence, unless there is another accumulator with the same expanded QName, and a higher import precedence.
It is a static error if a package contains a construct that is declared to be streamable but which is not guaranteed-streamable, unless the user has indicated that the processor is to handle this situation by processing the stylesheet without streaming or by making use of processor extensions to the streamability rules where available.
In the case of a template rule (that is, an
xsl:template
element having a match
attribute) appearing as a child of xsl:override
, it is a
static error if the list of
modes in the mode
attribute contains #all
or
#unnamed
, or if it contains #default
and the
default mode is the unnamed mode, or if the
mode
attribute is omitted when the default mode is the
unnamed mode.
It is a static error if a
variable declared with static="yes"
is inconsistent with
another static variable of the same name that is declared earlier in
stylesheet tree order and that has lower import precedence.
It is a static error if an
xsl:apply-imports
element appears in a template rule declared within an
xsl:override
element. (To invoke the template rule
that is being overridden, xsl:next-match
should
therefore be used.)
It is a static error if the
current-merge-group
function is used within a pattern.
It is a static error if the
current-merge-key
function is used within a pattern.
It is a static error if a parameter to xsl:iterate
is
implicitly mandatory.
A processor that does not provide the
higher-order functions feature raises a static error if any of the following
XPath constructs are found in an expression, pattern,
SequenceType, or ItemType
: a
TypedFunctionTestXP30, a
NamedFunctionRefXP30, an
InlineFunctionExprXP30, or an
ArgumentPlaceholderXP30
Type errors
It is a type error if the result of evaluating the sequence constructor cannot be converted to the required type.
It is a type error if an
xsl:apply-templates
instruction with no select
attribute is evaluated when the context
item is not a node.
It is a type error if the supplied value of a variable cannot be converted to the required type.
It is a type error if the conversion of the supplied value of a parameter to its required type fails.
If the as
attribute [of
xsl:function
] is specified, then the result evaluated by the sequence constructor (see
5.7 Sequence Constructors) is converted to the required
type, using the function
conversion rules. It is a type
error if this conversion fails.
It is a type error to use the
xsl:copy
instruction with no select
attribute when the context item is absent.
It is a type error to use the
xsl:copy
or xsl:copy-of
instruction to
copy a node that has namespace-sensitive content if the
copy-namespaces
attribute has the value no
and
its explicit or implicit validation
attribute has the value
preserve
. It is also a type error if either of these
instructions (with validation="preserve"
) is used to copy an
attribute having namespace-sensitive content, unless the parent element is
also copied. A node has namespace-sensitive content if its typed value
contains an item of type xs:QName
or xs:NOTATION
or a type derived therefrom. The reason this is an error is because the
validity of the content depends on the namespace context being
preserved.
It is a type error if the
xsl:number
instruction is evaluated, with no
value
or select
attribute, when the context item is not a node.
It is a type error if the result of
evaluating the select
attribute of the xsl:number
instruction is anything other than a single node.
If any sort key value, after
atomization and any type
conversion required by the data-type
attribute, is a sequence containing more than one item, then the effect
depends on whether the xsl:sort
element is processed with XSLT 1.0
behavior. With XSLT 1.0 behavior, the effective
sort key value is the first item in the sequence. In other cases, this is a
type error.
It is a type error if the result of
evaluating the group-adjacent
expression is an empty sequence or a
sequence containing more than one item, unless
composite="yes"
is specified.
If the validation
attribute of an
xsl:element
, xsl:attribute
,
xsl:copy
, xsl:copy-of
, or
xsl:result-document
instruction, or the
xsl:validation
attribute of a literal result element, has
the effective value strict
, and schema validity assessment
concludes that the validity of the element or attribute is invalid or
unknown, a type error occurs. As
with other type errors, the error may be signaled
statically if it can be detected statically.
If the validation
attribute of an
xsl:element
, xsl:attribute
,
xsl:copy
, xsl:copy-of
, or
xsl:result-document
instruction, or the
xsl:validation
attribute of a literal result element, has
the effective value strict
, and there is no matching
top-level declaration in the schema, then a type error occurs. As with other type errors, the error
may be signaled statically if it can be detected
statically.
If the validation
attribute of an
xsl:element
, xsl:attribute
,
xsl:copy
, xsl:copy-of
, or
xsl:result-document
instruction, or the
xsl:validation
attribute of a literal result element, has
the effective value lax
, and schema validity assessment
concludes that the element or attribute is invalid, a type error occurs. As with other type
errors, the error may be signaled statically if it can
be detected statically.
It is a type error if the value of
the type
attribute of an xsl:copy
or
xsl:copy-of
instruction refers to a complex type
definition and one or more of the items being copied is an attribute
node.
It is a type error if an
[xsl:]type
attribute is defined for a constructed element
or attribute, and the outcome of schema validity assessment against that
type is that the validity
property of that element or
attribute information item is other than valid
.
A type error occurs if a
type
or validation
attribute is defined
(explicitly or implicitly) for an instruction that constructs a new
attribute node, if the effect of this is to cause the attribute value to
be validated against a type that is derived from, or constructed by list
or union from, the primitive types xs:QName
or
xs:NOTATION
.
A type error occurs [when a document node is validated] unless the children of the document node comprise exactly one element node, no text nodes, and zero or more comment and processing instruction nodes, in any order.
It is a type error if, when validating a document node, document-level constraints (such as ID/IDREF constraints) are not satisfied.
It is a type error if some item selected
by a particular merge key in one input sequence is not comparable using the
XPath le
operator with some item selected by the corresponding
sort key in another input sequence.
It is a type error if the
xsl:context-item
child of xsl:template
specifies that a context item is required and none is supplied by the
caller, that is, if the context item is absent at the point where
xsl:call-template
is evaluated.
It is a type error if an
xsl:apply-templates
instruction in a particular
mode
selects an element or attribute whose type is
xs:untyped
or xs:untypedAtomic
when the
typed
attribute of that mode specifies the value
yes
, strict
, or lax
.
It is a type error if an
xsl:apply-templates
instruction in a particular
mode
selects an element or attribute whose type is anything
other than xs:untyped
or xs:untypedAtomic
when the
typed
attribute of that mode specifies the value
no
.
It is a type error if the
result of evaluating the expression in the with-params
attribute of the xsl:evaluate
instruction is
anything other than a single map of type
map(xs:QName, item()*)
.
It is a type error if the
result of evaluating the namespace-context
attribute of the xsl:evaluate
instruction is
anything other than a single node.
It is a type error if the result of
evaluating the select
expression [of the
xsl:copy
element] is a sequence of more
than one item.
If the result of evaluating the context-item
expression
[of an xsl:evaluate
instruction] is a sequence containing more than one
item, then a type error is signaled.
A type error occurs if the result of evaluating the sequence constructor
[within an xsl:map
instruction] is
not an instance of the required type map(*)*
.
Dynamic errors
It is a dynamic error if the effective value of an attribute written using curly brackets, in a position where an attribute value template is permitted, is a value that is not one of the permitted values for that attribute. If the processor is able to detect the error statically (for example, when any XPath expressions within the curly brackets can be evaluated statically), then the processor may optionally signal this as a static error.
It is a dynamic error if the invocation of
the stylesheet specifies a template
name that does not match the expanded
QName of a named template defined in the stylesheet, whose
visibility is public
or final
.
It is a dynamic error if the invocation of the stylesheet specifies a function name and
arity that does not match the expanded
QName and arity of a named stylesheet function defined in the stylesheet, whose visibility is
public
or final
.
It is a dynamic error if the invocation of the stylesheet specifies an initial mode when no initial match selection is supplied (either explicitly, or defaulted to the global context item).
It is a dynamic error if the invocation of the stylesheet specifies an initial mode and the specified mode is not eligible as an initial mode (as defined above).
It is a dynamic error if a stylesheet declares a visible stylesheet parameter that is explicitly or implicitly mandatory, and no value for this parameter is supplied when the stylesheet is primed. A stylesheet parameter is visible if it is not masked by another global variable or parameter with the same name and higher import precedence. If the parameter is a static parameter then the value must be supplied prior to the static analysis phase.
It is a dynamic error if an element has an effective version of V (with V < 3.0) when the implementation does not support backwards compatible behavior for XSLT version V.
Where the result of evaluating an XPath expression (or an attribute value template) is required to be a lexical QName, or if it is permitted to be a lexical QName and the actual value takes the form of a lexical QName, then unless otherwise specified it is a dynamic error if the value has a prefix and the defining element has no namespace node whose name matches that prefix. This error may be signaled as a static error if the value of the expression can be determined statically.
It is a dynamic error if the sequence used to construct the content of an element node contains a namespace node or attribute node that is preceded in the sequence by a node that is neither a namespace node nor an attribute node.
It is a dynamic error if the sequence used to construct the content of a document node contains a namespace node or attribute node.
It is a dynamic error if the sequence contains two or more namespace nodes having the same name but different string values (that is, namespace nodes that map the same prefix to different namespace URIs).
It is a dynamic error if the sequence contains a namespace node with no name and the element node being constructed has a null namespace URI (that is, it is an error to define a default namespace when the element is in no namespace).
It is a dynamic error if the result sequence contains a function item.
It is a dynamic error if the
conflict resolution algorithm for template rules leaves more than
one matching template rule when the
declaration of the relevant mode has an on-multiple-match
attribute with the value fail
.
It is a dynamic error if
xsl:apply-templates
, xsl:apply-imports
or xsl:next-match
is used to process a node using a mode
whose declaration specifies on-no-match="fail"
when there is no
template rule in the stylesheet
whose match pattern matches that node.
It is a dynamic error if
xsl:apply-imports
or xsl:next-match
is
evaluated when the current template
rule is absent.
In general, a circularity in a stylesheet is a dynamic error.
It is a dynamic error if a template that has an explicitly mandatory or implicitly mandatory parameter is invoked without supplying a value for that parameter.
It is a dynamic error if the effective value of the
name
attribute [of the
xsl:element
instruction] is not a
lexical QName.
In the case of an xsl:element
instruction with no
namespace
attribute, it is a dynamic
error if the effective
value of the name
attribute is a lexical QName whose prefix is not
declared in an in-scope namespace declaration for the
xsl:element
instruction.
It is a dynamic error if the effective value of the
namespace
attribute [of the
xsl:element
instruction] is not in the
lexical space of the xs:anyURI
datatype or if it is the string
http://www.w3.org/2000/xmlns/
.
It is a dynamic error if the effective value of the name
attribute [of an xsl:attribute
instruction] is not a lexical
QName.
In the case of an xsl:attribute
instruction with no
namespace
attribute, it is a dynamic
error if the effective
value of the name
attribute is the string
xmlns
.
In the case of an xsl:attribute
instruction with no
namespace
attribute, it is a dynamic
error if the effective
value of the name
attribute is a lexical QName whose prefix is not declared
in an in-scope namespace declaration for the xsl:attribute
instruction.
It is a dynamic error if the effective value of the
namespace
attribute [of the
xsl:attribute
instruction] is not in the
lexical space of the xs:anyURI
datatype or if it is the string
http://www.w3.org/2000/xmlns/
.
It is a dynamic error if the effective value of the name
attribute [of the xsl:processing-instruction
instruction] is not both an NCNameNames and a PITargetXML.
It is a dynamic error if the string value of
the new namespace node is not valid in the lexical space of the datatype
xs:anyURI
, or if it is the string
http://www.w3.org/2000/xmlns/
.
It is a dynamic error if the effective value of the name
attribute [of the xsl:namespace
instruction] is neither a zero-length string nor an NCNameNames, or if it is xmlns
.
It is a dynamic error if the
xsl:namespace
instruction generates a namespace node whose
name is xml
and whose string value is not
http://www.w3.org/XML/1998/namespace
, or a namespace node whose
string value is http://www.w3.org/XML/1998/namespace
and whose
name is not xml
.
It is a dynamic error if evaluating the
select
attribute or the contained sequence constructor of an xsl:namespace
instruction results in a zero-length string.
It is a dynamic error if any undiscarded item
in the atomized sequence supplied as the value of the value
attribute of xsl:number
cannot be converted to an integer, or
if the resulting integer is less than 0 (zero).
It is a dynamic error if, for any sort key component, the set of
sort key values evaluated for
all the items in the initial
sequence, after any type conversion requested, contains a pair
of ordinary values for which the result of the XPath lt
operator is an error. If the processor is
able to detect the error statically, it may optionally
signal it as a static
error.
It is a dynamic error if the
collation
attribute of xsl:sort
(after
resolving against the base URI) is not a URI that is recognized by the
implementation as referring to a collation.
It is a dynamic error if the
current-group
function is used when the current group is
absent
, or when it is invoked in the course of evaluating a
pattern. The error may be reported statically if it
can be detected statically.
It is a dynamic error if the
current-grouping-key
function is used when the current
grouping key is absent, or when it is invoked in the course of evaluating a pattern.
The error may be reported statically if it can be detected
statically.
It is a dynamic error if the collation URI
specified to xsl:for-each-group
(after resolving against the
base URI) is a collation that is not recognized by the implementation. (For
notes, [see ERR XTDE1035].)
It is a dynamic error if the effective value of the regex
attribute [of the xsl:analyze-string
instruction] does not conform to the
required syntax for regular expressions, as specified in
[Functions and Operators 3.0]. If the regular expression is known
statically (for example, if the attribute does not contain any expressions enclosed in curly brackets) then
the processor may signal the error as a static error.
It is a dynamic error if the effective value of the flags
attribute [of the xsl:analyze-string
instruction] has a value other than the values defined in
[Functions and Operators 3.0]. If the value of the attribute is known
statically (for example, if the attribute does not contain any expressions enclosed in curly brackets) then
the processor may signal the error as a static error.
When a URI reference [supplied to the document
function] contains a fragment identifier, it is a dynamic error if the media type is not one that is recognized by the
processor, or if the fragment identifier does not conform to the rules for
fragment identifiers for that media type, or if the fragment identifier selects
something other than a sequence of nodes (for example, if it selects a range of
characters within a text node).
When a URI reference [supplied to the document
function] is a relative reference, it is a dynamic error if no base URI is available to
resolve the relative reference. This can arise for example when the URI is
contained in a node that has no base URI (for example a parentless text node), or
when the second argument to the function is a node that has no base URI, or when
the base URI from the static context is undefined.
It is a dynamic error if the value
[of the first argument to the key
function] is not a valid QName, or if there is no namespace
declaration in scope for the prefix of the QName, or if the name obtained by
expanding the QName is not the same as the expanded name of any
xsl:key
declaration in the containing package. If the
processor is able to detect the error statically (for example, when the argument
is supplied as a string literal), then the processor may
optionally signal this as a static
error.
It is a dynamic
error to call the key
function with
two arguments if there is no context
node, or if the root of the tree containing the context node is not a
document node; or to call the function with three arguments if the root of the
tree containing the node supplied in the third argument is not a document
node.
If the current
function is evaluated within an expression
that is evaluated when the context item is absent, a
dynamic error occurs.
It is a dynamic error if $node
,
or the context item if the second argument is omitted,
is a node in a tree whose root is not a document node.
It is a dynamic error if $node
,
or the context item if the second argument is omitted,
is a node in a tree whose root is not a document node.
It is a dynamic error if the value supplied as
the $property-name
argument [to the
system-property
function] is not a valid
QName, or if there is no namespace declaration in scope for the prefix of the
QName. If the processor is able to detect the error statically (for example, when
the argument is supplied as a string literal), then the processor
may optionally signal this as a static error.
It is a dynamic error if the argument
[passed to the function-available
function] does not evaluate to a string that is a valid EQName, or if the value is a lexical QName with a prefix for which no
namespace declaration is present in the static context. If the processor is able
to detect the error statically (for example, when the argument is supplied as a
string literal), then the processor may optionally signal this
as a static error.
It is a dynamic error if the arguments supplied to a call on an extension function do not satisfy the rules defined for that particular extension function, or if the extension function reports an error, or if the result of the extension function cannot be converted to an XPath value.
When the containing element is processed with XSLT 1.0 behavior, it is a dynamic error to evaluate an extension function call if no implementation of the extension function is available.
It is a dynamic error if the argument
[passed to the type-available
function] does not evaluate to a string that is a valid EQName, or if the value is a lexical QName with a prefix for which no
namespace declaration is present in the static context. If the processor is able
to detect the error statically (for example, when the argument is supplied as a
string literal), then the processor may optionally signal this
as a static error.
It is a dynamic error if the argument
[passed to the element-available
function] does not evaluate to a string that is a valid EQName, or if the value is a lexical QName with a prefix for which no
namespace declaration is present in the static context. If the processor is able
to detect the error statically (for example, when the argument is supplied as a
string literal), then the processor may optionally signal this
as a static error.
When a processor performs fallback for
an extension instruction
that is not recognized, if the instruction element has one or more
xsl:fallback
children, then the content of each of the
xsl:fallback
children must be
evaluated; it is a dynamic error if it has no
xsl:fallback
children.
It is a dynamic error if the effective value of the
format
attribute [of an
xsl:result-document
element] is not a valid
EQName, or if it does not match the
expanded QName of an output definition in the containing package. If the processor is able to detect
the error statically (for example, when the format
attribute
contains no curly brackets), then the processor may
optionally signal this as a static
error.
It is a dynamic error to evaluate the
xsl:result-document
instruction in temporary output state.
It is a dynamic error for a transformation to generate two or more final result trees with the same URI.
It is a dynamic error for a stylesheet to write to an external resource and read from the same resource during a single transformation, if the same absolute URI is used to access the resource in both cases.
A dynamic error may be raised if the input to the processor includes an item that requires availability of an optional feature that the processor does not provide.
It is a dynamic
error if there are two xsl:merge-key
elements
that occupy corresponding positions among the xsl:merge-key
children of two different xsl:merge-source
elements and that
have differing effective values for
any of the attributes lang
, order
,
collation
, case-order
, or data-type
.
Values are considered to differ if the attribute is present on one element and
not on the other, or if it is present on both elements with effective values that are not equal to
each other. In the case of the collation
attribute, the values are
compared as absolute URIs after resolving against the base URI. The error
may be reported statically if it is detected
statically.
It is a dynamic error if any input
sequence to an xsl:merge
instruction contains two items that
are not correctly sorted according to the merge key values defined on the
xsl:merge-key
children of the corresponding
xsl:merge-source
element, when compared using the collation
rules defined by the attributes of the corresponding
xsl:merge-key
children of the xsl:merge
instruction, unless the attribute sort-before-merge
is present
with the value yes
.
It is a dynamic error if an invocation of an abstract component is evaluated.
It is a static error if an xsl:function
element with no
xsl:param
children has a streamability
attribute with any value other than unclassified
.
It is a dynamic error if the target expression
[of an xsl:evaluate
instruction] is
not a valid expression (that is, if a static error occurs when analyzing the string
according to the rules of the XPath specification).
It is a dynamic error if an
xsl:evaluate
instruction is evaluated when use of
xsl:evaluate
has been statically or dynamically
disabled.
It is a dynamic error if the value of
$input
does not conform to the JSON grammar as defined
by [RFC 7159], allowing implementation-defined extensions
if the liberal
option is set to yes
.
It is a dynamic error if the value of
the validate
option is true
and the processor is not
schema-aware.
It is a dynamic error if the value of
$input
contains an escaped representation of a character (or
codepoint) that is not a valid character in the version of XML supported by the
implementation, unless the unescape
option is set to false.
It is a dynamic error if the value of
$options
includes an entry whose key is liberal
,
validate
, unescape
, or fallback
,
and whose value is not a permitted value for that key.
It is a dynamic error if the value of the first
argument to the accumulator-before
or
accumulator-after
function is not a valid
EQName, or if there is no namespace declaration in scope
for the prefix of the QName, or if the name obtained by expanding the QName is not
the same as the expanded name of any xsl:accumulator
declaration
appearing in the package in which the function
call appears. If the processor is able to detect the error statically (for
example, when the argument is supplied as a string literal), then the processor
may optionally signal this as a static error.
It is a dynamic error to call the
accumulator-before
or
accumulator-after
function when there is no context item.
It is a type error to call the
accumulator-before
or
accumulator-after
function when the context item is not a node, or when it is an attribute or namespace
node.
It is a dynamic error to call the
accumulator-before
or
accumulator-after
function when the context
item is a node in a tree to which the selected accumulator is not
applicable (including the case where it is not applicable
because the document is streamed and the accumulator is not
declared with streamable="yes"
). Implementations
may raise this error but are not required to do so,
if they are capable of streaming documents without imposing this restriction.
A dynamic error occurs if the set of
keys in the maps resulting from evaluating the sequence constructor
[within an xsl:map
instruction]
contains duplicates.
It is an error if there is a cyclic set of dependencies among accumulators such that the (pre- or post-descent) value of an accumulator depends directly or indirectly on itself. A processor may report this as a static error if it can be detected statically. Alternatively a processor may report this as a dynamic error. As a further option, a processor may fail catastrophically when this error occurs.
It is a dynamic error if the
current-merge-group
function is used when the current
merge group is absent. The error
may be reported statically if it can be detected
statically.
It is a dynamic error if the
$source
argument of the current-merge-group
function does not match the name
attribute of any
xsl:merge-source
element for the current merge operation. The
error may be reported statically if it can be detected
statically.
It is a dynamic error if the
current-merge-key
function is used when the current
merge key is absent, or when it is invoked
in the course of evaluating a pattern. The error may be
reported statically if it can be detected statically.
It is a dynamic error if an xsl:try
instruction is unable to recover the state of a final result tree because
recovery has been disabled by use of the attribute
rollback-output="no"
.
When a transformation is terminated by use of <xsl:message
terminate="yes"/>
, the effect is the same as when a
dynamic error occurs during the transformation. The default error code is XTMM9000
; this may be
overridden using the error-code
attribute of the
xsl:message
instruction.
When a transformation is terminated by use of xsl:assert
, the
effect is the same as when a dynamic error occurs during the
transformation. The default error code is XTMM9001
; this may be
overridden using the error-code
attribute of the
xsl:assert
instruction.
This appendix provides a summary of XSLT language features whose effect is explicitly implementation-defined. The conformance rules (see 27 Conformance) require vendors to provide documentation that explains how these choices have been exercised.
The implementation-defined features are grouped into categories for convenience.
This category covers interfaces for initiating a transformation, setting its parameters, initializing the static and dynamic context, and collecting the results. In general terms, it is implementation defined how input is passed to the processor and how it returns its output. This includes the interpretation of URIs used to refer to stylesheet packages and modules, source documents and collections, collations, and result documents.
More specifically:
If the initialization of any global variables or parameter depends on the context item, a dynamic error can occur if the context item is absent. It is implementation-defined whether this error occurs during priming of the stylesheet or subsequently when the variable is referenced; and it is implementation-defined whether the error occurs at all if the variable or parameter is never referenced. (See 2.3.2 Priming a Stylesheet)
The way in which an XSLT processor is invoked, and the way in which values are supplied for the source document, starting node, stylesheet parameters, and base output URI, are implementation-defined. (See 2.3.2 Priming a Stylesheet)
The way in which a base output URI is established is implementation-defined (See 2.3.6.2 Serializing the Result)
It is implementation-defined how a package is located given its name and version, and which version of a package is chosen if several are available. (See 3.5.2 Dependencies between Packages)
In the absence of an
[xsl:]default-collation
attribute, the default collation
may be set by the calling application in an implementation-defined way. (See 3.7.1 The default-collation Attribute)
It is implementation-defined what forms of
URI reference are acceptable in the href
attribute of the
xsl:include
and xsl:import
elements, for
example, the URI schemes that may be used, the forms of fragment identifier that
may be used, and the media types that are supported. The way in which the URI
reference is used to locate a representation of a stylesheet module, and the way in which
the stylesheet module is constructed from that representation, are also
implementation-defined. (See 3.11.1 Locating Stylesheet Modules)
The statically known documentsXP30, statically known collectionsXP30, and the statically known default collection typeXP30 are implementation-defined. (See 5.3.1 Initializing the Static Context)
Implementations may provide user options that
relax the requirement for the doc
FO30 and
collection
FO30 functions (and therefore, by implication, the
document
function) to return stable results. The manner in
which such user options are provided, if at all, is implementation-defined. (See
5.3.3 Initializing the Dynamic Context)
Streamed processing may be initiated by invoking the transformation with an initial mode declared as streamable, while supplying the initial match selection (in an implementation-defined way) as a streamed document. (See 6.6.4 Streamable Templates)
The mechanism by which the caller supplies a value for a stylesheet parameter is implementation-defined. (See 9.5 Global Variables and Parameters)
The detail of any external mechanism allowing a processor to enable or disable checking of assertions is implementation-defined. (See 23.2 Assertions)
The way in which the results of the transformation are delivered to an application is implementation-defined. (See 25 Transformation Results)
It is implementation-defined how the URI appearing in the href
attribute of xsl:result-document
affects the way in which the result
tree is delivered to the application. There may be restrictions on
the form of this URI. (See 25.1 Creating Secondary Results)
If serialization is supported, then the location to which a final result tree is serialized is implementation-defined, subject to the constraint that relative URI references used to reference one tree from another remain valid. (See 26 Serialization)
This category covers extensions and extensibility: mechanisms for providing vendor or user extensions to the language without sacrificing interoperability.
In general terms, it is implementation-defined:
whether and under what circumstances the implementation recognizes any extension functions, extension instructions, extension attributes, user-defined data elements, additional types, additional serialization methods or serialization parameters, or additional collations, and if so, what effect they have.
whether, how, and under what circumstances the implementation allows users to define extension functions, extension instructions, extension attributes, user-defined data elements, additional types, additional serialization methods or serialization parameters, or additional collations. If it does allow users to do so, it must follow the rules given elsewhere in this specification.
what information is available to such extensions (for example, whether they have access to the static and dynamic context.)
where such extensions are allowed, the extent to which the processor enforces their correct behavior (for example, checking that strings returned by extension functions contain only valid XML characters)
More specifically:
The mechanisms for creating new extension instructions and extension functions are implementation-defined. It is not required that implementations provide any such mechanism. (See 2.9 Extensibility)
The set of namespaces that are specially recognized by the implementation (for example, for user-defined data elements, and extension attributes) is implementation-defined. (See 3.7.3 User-defined Data Elements)
The effect of user-defined data elements whose name is in a namespace recognized by the implementation is implementation-defined. (See 3.7.3 User-defined Data Elements)
An implementation may define mechanisms, above
and beyond xsl:import-schema
, that allow schema components such as type definitions to
be made available within a stylesheet. (See 3.14 Built-in Types)
The set of extension functions
available in the static context for the target expression of
xsl:evaluate
is implementation-defined. (See 10.4.1 Static context for the target expression)
If the data-type
attribute of
the xsl:sort
element has a value other than text
or
number
, the effect is implementation-defined. (See 13.1.2 Comparing Sort Key Values)
The posture and sweep of extension functions (and references to extension functions) and extension instructions are implementation-defined. (See 19.8.4.2 Streamability of extension instructions)
Additional streamability categories for stylesheet functions may be defined by an implementation. (See 19.8.5 Classifying Stylesheet Functions)
The effect of an extension function returning a string containing characters that are not permitted in XML is implementation-defined. (See 24.1.2 Calling Extension Functions)
The way in which external objects are represented in the type system is implementation-defined. (See 24.1.3 External Objects)
This specification, and the specifications that it refers to, include facilities for adapting the output of a transformation to meet local expectations: examples include the formatting of numbers and dates, and the choice of collations for sorted output. The general principles are:
The specification does not mandate any particular localizations that processors must offer: for example, a conformant processor might choose to provide output in Japanese only.
The specification provides fallback mechanisms so that if a particular localization is requested and is not available, processing does not fail.
More specifically:
The combinations of languages and numbering
sequences recognized by the xsl:number
instruction, beyond those
defined as mandatory in this specification, are implementation-defined. There may be
implementation-defined upper bounds on the numbers that can be formatted using any
particular numbering sequence. There may be constraints on the
values of the ordinal
attribute recognized for any given
language. (See 12.4 Number to String Conversion Attributes)
The facilities for defining collations and allocating URIs to identify them are largely implementation-defined. (See 13.1.3 Sorting Using Collations)
The algorithm used by
xsl:sort
to locate a collation, given the values of the
lang
and case-order
attributes, is
implementation-defined. (See 13.1.3 Sorting Using Collations)
If none of the
collation
, lang
, or case-order
attributes is present (on xsl:sort
), the collation is chosen in
an implementation-defined way. (See 13.1.3 Sorting Using Collations)
When using the family of URIs that invoke the Unicode Collation Algorithm, the effect of supplying a query keyword or value not defined in this specification is implementation-defined. The defaults for query keywords are also implementation-defined unless otherwise stated. (See 13.4 The Unicode Collation Algorithm)
As well as the optional conformance features identified in 27 Conformance, some specific features of the specification are defined to be optional.
It is implementation-defined whether an XSLT 3.0 processor supports backwards compatible behavior for any XSLT version earlier than XSLT 3.0. (See 3.9 Backwards Compatible Processing)
If an xml:id
attribute that has
not been subjected to attribute value normalization is copied from a source tree
to a result tree, it is implementation-defined whether attribute value
normalization will be applied during the copy process. (See 11.9.1 Shallow Copy)
It is implementation-defined whether, and under what circumstances, disabling output escaping is supported. (See 26.2 Disabling Output Escaping)
When this specification refers normatively to other specifications, it generally gives implementations freedom to decide (within constraints) which version of the referenced specification should be used. Specifically:
It is implementation-defined which versions and editions of XML and XML Namespaces (1.0 and/or 1.1) are supported. (See 4.1 XML Versions)
It is implementation-defined which versions of
XML, HTML, and XHTML are supported in the version
attribute of the
xsl:output
declaration. (See 26 Serialization)
It is implementation-defined whether (and if so how) an XSLT 3.0 processor is able to work with versions of XPath later than XPath 3.1. (See 27 Conformance)
It is implementation-defined whether (and if so how) an XSLT 3.0 processor is able to work with versions of [XSLT and XQuery Serialization] later than 3.1. (See 27.3 Serialization Feature)
To accommodate variations in the way that the XSLT language is deployed, and the constraints of different processing environments, defaults for some options are implementation-defined. In addition, limits on the sizes of ranges of values permitted are in general implementation-defined:
Limits on the value space of primitive datatypes, where not fixed by [XML Schema Part 2], are implementation-defined. (See 4.7 Limits)
The default value of the
encoding
attribute of the xsl:output
element is
implementation-defined. Where the encoding is UTF-8, the default for the
byte-order-mark
attribute is
implementation-defined. (See 26 Serialization)
Some aspects of error handling are implementation-defined:
It is implementation-defined whether type errors are signaled statically. (See 2.14 Error Handling)
If the effective version of any element in the stylesheet is not 1.0 or 2.0 but is less than 3.0, the recommended action is to report a static error; however, processors may recognize such values and process the element in an implementation-defined way. (See 3.9 Backwards Compatible Processing)
The default values for the
warning-on-no-match
and warning-on-multiple-match
attributes of xsl:mode
are implementation-defined. (See 6.6.1 Declaring Modes)
The form of any warnings output when there is no matching template rule, or when there are multiple matching template rules, is implementation-defined. (See 6.6.1 Declaring Modes)
The destination and formatting of messages
written using the xsl:message
instruction are implementation-defined. (See 23.1 Messages)
The functions available for use within an XSLT stylesheet can be classified based firstly, on where the function is defined, and secondly, on where it can be used. Specifically, the set of functions available is slightly different for :
Regular XPath expressions within the stylesheet, for example those appearing in
select
or test
attributes, or between braces in a text value template (R)
XPath expressions evaluated dynamically using xsl:evaluate
(D)
The categories are listed in the following table:
Category | Defined where? | Available where? | Notes |
---|---|---|---|
User-defined functions | Defined using xsl:function declarations in the stylesheet
|
R, D | Functions are private by default; private functions can be referenced only
within the package where they are declared (and not in xsl:evaluate
expressions).
|
Constructor functions for built-in types | Section 17 Constructor functions FO30 | R, S, D | These functions are all in the namespace conventionally associated with the
prefix xs . The semantics of a constructor function are identical
to the semantics of a cast expression.
|
Constructor functions for user-defined types | Section 17 Constructor functions FO30 | R, D (if schema-aware="yes" )
|
This category includes a function for every named user-defined simple type in an imported schema; the function allows the conversion of strings and certain other values to instances of the user-defined type. |
Functions defined in XPath 3.0 | [Functions and Operators 3.0] | R, S, D | Includes functions in the namespaces conventionally
referred to be the prefixes fn and math .
|
Additional functions defined in XPath 3.1 (where supported) | [Functions and Operators 3.1] | R, S, D. | This category has an overlap with the set of XSLT-defined-functions. Where a function
is defined both in this document and in XPath 3.1, the function is available in an
XSLT 3.0
stylesheet whether or not the processor supports XPath 3.1. This category includes
functions
in namespaces conventionally referred to by the prefixes fn , map ,
and array .
|
Functions defined in XSLT 3.0 | This specification | R, S (see note), D | See G.2 List of XSLT-defined functions. There is an overlap with
the set of functions defined in XPath 3.1. The functions available in static expressions
are:
element-available , function-available ,
type-available , available-system-properties ,
and system-property .
|
Extension functions | Implementation-defined: see 24.1 Extension Functions. | R, S, D | Availability is implementation-defined |
This appendix acts as an index of functions defined in this specification, to augment the set of functions defined in [Functions and Operators 3.0].
accumulator-after
accumulator-before
available-system-properties
collation-key
copy-of
current
current-group
current-grouping-key
current-merge-group
current-merge-key
current-output-uri
document
element-available
function-available
json-to-xml
key
map:contains
map:entry
map:find
map:for-each
map:get
map:keys
map:merge
map:put
map:remove
map:size
regex-group
snapshot
stream-available
system-property
type-available
unparsed-entity-public-id
unparsed-entity-uri
xml-to-json
For convenience, schemas are provided for validation of XSLT 3.0 stylesheets
using the XSD 1.1 and Relax NG schema languages. These are non-normative. Neither
will detect
every static error that might arise in an XSLT 3.0 stylesheet (for example, there
is no attempt
to check the syntax of XPath expressions); in addition, these schemas may reject some
stylesheets
that are valid, for example because they rely on xsl:use-when
to eliminate sections of code
that would otherwise be invalid.
The following XSD 1.1 schema describes the structure of an XSLT stylesheet module. It does not define all the constraints that apply to a stylesheet (for example, it does not attempt to define a datatype that precisely represents attributes containing XPath expressions). However, every valid stylesheet module conforms to this schema, unless it contains elements that invoke forwards compatible behavior.
A copy of this schema is available at schema-for-xslt30.xsd
Note:
The schema as written uses a lax wildcard to permit literal result elements to appear
in a sequence constructor. This assumes that the schema used for validation will not
contain any global element declaration that matches the element name of a literal
result element. The content model for an element such as invoice
appearing within a stylesheet is not the same as the content model for the same
element appearing within a source document (it is likely to contain XSLT instructions
rather than other elements from the target vocabulary): therefore, including such
declarations in the schema used for validating a stylesheet is inappropriate.
The reason that lax validation rather than skip validation is used is so that XSLT instructions appearing as children of the literal result element will themselves be validated, using the appropriate global element declaration.
Note:
The schema uses XSD 1.1 assertions to represent some of the non-grammatical
constraints appearing in the specification, for example the rule that some elements
can have either a select
attribute or a contained sequence constructor,
but not both. At this stage, no attempt has been made to represent every such
constraint, even where it is not difficult to express the rule. There will always
be
some constraints that cannot be expressed at all, for example those that require
access to multiple stylesheet modules, those that require access to the in-scope
schema components, and those that involve parsing a non-regular grammar, such as the
grammar for patterns.
Apart from assertions, the only other significant use of XSD 1.1 features is that
the
elements xsl:param
and xsl:variable
are in two
substitution groups: one containing all instructions, and one containing all
declarations. If the schema needs to be converted to an XSD 1.0 schema, removing all
assertions is straightforward; the other change needed is to remove
xsl:param
and xsl:variable
from the substitution
group for declarations, and instead permit them explicitly as children of
xsl:transform
.
<?xml version="1.0" encoding="UTF-8"?> <!--* <!DOCTYPE xs:schema PUBLIC "-//W3C//DTD XMLSCHEMA 200105//EN" "http://www.w3.org/2001/XMLSchema.dtd" [ <!ENTITY % schemaAttrs " xmlns:xs CDATA #IMPLIED xmlns:xsl CDATA #IMPLIED xmlns:xsd CDATA #IMPLIED" > <!ENTITY % p "xs:"> <!ENTITY % s ":xs"> ]> *--> <?xml-stylesheet href="http://www.w3.org/2008/09/xsd.xsl" type="text/xsl"?> <xs:schema xmlns:xs="http://www.w3.org/2001/XMLSchema" xmlns:xsl="http://www.w3.org/1999/XSL/Transform" xmlns:vc="http://www.w3.org/2007/XMLSchema-versioning" targetNamespace="http://www.w3.org/1999/XSL/Transform" elementFormDefault="qualified" vc:minVersion="1.1"> <!-- ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ --> <xs:annotation> <xs:documentation> <p> This is an XSD 1.1 schema for XSLT 3.0 stylesheets. It defines all the elements that appear in the XSLT namespace; it also provides hooks that allow the inclusion of user-defined literal result elements, extension instructions, and top-level data elements. </p> <p> This schema is available for use under the conditions of the W3C Software License published at http://www.w3.org/Consortium/Legal/copyright-software-19980720 </p> <p> The schema is organized as follows: </p> <ul> <li> PART A: definitions of complex types and model groups used as the basis for element definitions </li> <li> PART B: definitions of individual XSLT elements </li> <li> PART C: definitions for literal result elements </li> <li> PART D: definitions of simple types used in attribute definitions </li> </ul> <p> The schema has a number of limitations: </p> <ul> <li> The XSLT specification allows additional elements and attributes to be present where forwards compatibility is invoked. This schema does not. </li> <li> The XSLT specification allows arbitrary content in a part of the stylesheet that is excluded by virtue of a use-when attribute. This schema does not. </li> <li> The handling of literal result elements in this schema is imperfect; although various options are allowed, none matches the specification exactly. For example, the content of a literal result element uses lax validation, which permits child elements in the XSLT namespace that have no declaration in this schema. </li> <li> The schema makes no attempt to check XPath expressions for syntactic or semantic correctness, nor to check that component references are resolved (for example that a template named in xsl:call-template has a declaration). Doing this in general requires cross-document validation, which is beyond the scope of XSD. </li> <li> The schema imports the schema for XSD 1.0 schema documents. In stylesheets that contain an inline XSD 1.1 schema, this import should be replaced with one for the schema for XSD 1.1 schema documents. </li> </ul> </xs:documentation> </xs:annotation> <!-- ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ --> <!-- The declaration of xml:space and xml:lang may need to be commented out because of problems processing the schema using various tools --> <xs:import namespace="http://www.w3.org/XML/1998/namespace"/> <!--schemaLocation="http://www.w3.org/2001/xml.xsd"--> <!-- An XSLT stylesheet may contain an in-line schema within an xsl:import-schema element, so the Schema for schemas needs to be imported. We use the XSD 1.1 version. --> <xs:import namespace="http://www.w3.org/2001/XMLSchema" schemaLocation="http://www.w3.org/TR/xmlschema11-1/XMLSchema.xsd"/> <!-- ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ --> <xs:annotation> <xs:documentation> <p> PART A: definitions of complex types and model groups used as the basis for element definitions </p> </xs:documentation> </xs:annotation> <!-- ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ --> <xs:complexType name="generic-element-type" mixed="true"> <xs:annotation> <xs:documentation> <p> This complex type provides a generic supertype for all XSLT elements; it contains the definitions of the standard attributes that may appear on any element. </p> </xs:documentation> </xs:annotation> <xs:attribute name="default-collation" type="xsl:uri-list"/> <xs:attribute name="default-mode" type="xsl:default-mode-type"/> <xs:attribute name="default-validation" type="xsl:validation-strip-or-preserve" default="strip"/> <xs:attribute name="exclude-result-prefixes" type="xsl:prefix-list-or-all"/> <xs:attribute name="expand-text" type="xsl:yes-or-no"/> <xs:attribute name="extension-element-prefixes" type="xsl:prefix-list"/> <xs:attribute name="use-when" type="xsl:expression"/> <xs:attribute name="xpath-default-namespace" type="xs:anyURI"/> <xs:attribute name="_default-collation" type="xs:string"/> <xs:attribute name="_default-mode" type="xs:string"/> <xs:attribute name="_default-validation" type="xs:string"/> <xs:attribute name="_exclude-result-prefixes" type="xs:string"/> <xs:attribute name="_expand-text" type="xs:string"/> <xs:attribute name="_extension-element-prefixes" type="xs:string"/> <xs:attribute name="_use-when" type="xs:string"/> <xs:attribute name="_xpath-default-namespace" type="xs:string"/> <xs:anyAttribute namespace="##other" processContents="lax"/> </xs:complexType> <xs:complexType name="versioned-element-type" mixed="true"> <xs:annotation> <xs:documentation> <p> This complex type provides a generic supertype for all XSLT elements with the exception of xsl:output; it contains the definitions of the version attribute that may appear on any element. </p> <p> The xsl:output does not use this definition because, although it has a version attribute, the syntax and semantics of this attribute are unrelated to the standard version attribute allowed on other elements. </p> </xs:documentation> </xs:annotation> <xs:complexContent> <xs:extension base="xsl:generic-element-type"> <xs:attribute name="version" type="xs:decimal" use="optional"/> <xs:attribute name="_version" type="xs:string"/> </xs:extension> </xs:complexContent> </xs:complexType> <xs:complexType name="element-only-versioned-element-type" mixed="false"> <xs:complexContent> <xs:restriction base="xsl:versioned-element-type"> <xs:anyAttribute namespace="##other" processContents="lax"/> </xs:restriction> </xs:complexContent> </xs:complexType> <xs:complexType name="sequence-constructor"> <xs:annotation> <xs:documentation> <p> This complex type provides a generic supertype for all XSLT elements that allow a sequence constructor as their content. </p> </xs:documentation> </xs:annotation> <xs:complexContent mixed="true"> <xs:extension base="xsl:versioned-element-type"> <xs:group ref="xsl:sequence-constructor-group" minOccurs="0" maxOccurs="unbounded"/> </xs:extension> </xs:complexContent> </xs:complexType> <xs:complexType name="sequence-constructor-and-select"> <xs:annotation> <xs:documentation> <p> This complex type allows a sequence constructor and a select attribute. </p> </xs:documentation> </xs:annotation> <xs:complexContent mixed="true"> <xs:extension base="xsl:sequence-constructor"> <xs:attribute name="select" type="xsl:expression"/> <xs:attribute name="_select" type="xs:string"/> </xs:extension> </xs:complexContent> </xs:complexType> <xs:complexType name="sequence-constructor-or-select"> <xs:annotation> <xs:documentation> <p> This complex type allows a sequence constructor or a select attribute, but not both. </p> </xs:documentation> </xs:annotation> <xs:complexContent mixed="true"> <xs:restriction base="xsl:sequence-constructor-and-select"> <xs:group ref="xsl:sequence-constructor-group" minOccurs="0" maxOccurs="unbounded"/> <xs:anyAttribute namespace="##other" processContents="lax"/> <xs:assert test="not(exists(@select | @_select) and (exists(* except xsl:fallback) or exists(text()[normalize-space()])))"/> </xs:restriction> </xs:complexContent> </xs:complexType> <xs:group name="sequence-constructor-group"> <xs:annotation> <xs:documentation> <p> This complex type provides a generic supertype for all XSLT elements that allow a sequence constructor as their content. </p> </xs:documentation> </xs:annotation> <xs:choice> <xs:element ref="xsl:instruction"/> <xs:group ref="xsl:result-elements"/> </xs:choice> </xs:group> <xs:element name="declaration" type="xsl:generic-element-type" abstract="true"/> <xs:element name="instruction" type="xsl:versioned-element-type" abstract="true"/> <!-- ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ --> <xs:annotation> <xs:documentation> <p> PART B: definitions of individual XSLT elements Elements are listed in alphabetical order. </p> </xs:documentation> </xs:annotation> <!-- ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ --> <xs:element name="accept"> <xs:annotation> <xs:documentation> <p> This element appears as a child of xsl:use-package and defines any variations that the containing package wishes to make to the visibility of components made available from a library package. For example, it may indicate that some of the public components in the library package are not to be made available to the containing package. </p> </xs:documentation> </xs:annotation> <xs:complexType> <xs:complexContent> <xs:extension base="xsl:element-only-versioned-element-type"> <xs:attribute name="component" type="xsl:component-kind-type"/> <xs:attribute name="names" type="xsl:EQNames"/> <xs:attribute name="visibility" type="xsl:visibility-type"/> <xs:attribute name="_component" type="xs:string"/> <xs:attribute name="_names" type="xs:string"/> <xs:attribute name="_visibility" type="xs:string"/> <xs:assert test="exists(@component | @_component)"/> <xs:assert test="exists(@names | @_names)"/> <xs:assert test="exists(@visibility | @_visibility)"/> </xs:extension> </xs:complexContent> </xs:complexType> </xs:element> <xs:element name="accumulator" substitutionGroup="xsl:declaration"> <xs:complexType> <xs:complexContent> <xs:extension base="xsl:element-only-versioned-element-type"> <xs:sequence> <xs:element ref="xsl:accumulator-rule" minOccurs="1" maxOccurs="unbounded"/> </xs:sequence> <xs:attribute name="name" type="xsl:EQName"/> <xs:attribute name="initial-value" type="xsl:expression"/> <xs:attribute name="as" type="xsl:sequence-type"/> <xs:attribute name="streamable" type="xsl:yes-or-no"/> <xs:attribute name="_name" type="xs:string"/> <xs:attribute name="_initial-value" type="xs:string"/> <xs:attribute name="_as" type="xs:string"/> <xs:attribute name="_streamable" type="xs:string"/> </xs:extension> </xs:complexContent> </xs:complexType> </xs:element> <xs:element name="accumulator-rule"> <xs:complexType> <xs:complexContent mixed="true"> <xs:extension base="xsl:sequence-constructor-or-select"> <xs:sequence/> <xs:attribute name="match" type="xsl:pattern"/> <xs:attribute name="phase"> <xs:simpleType> <xs:restriction base="xs:token"> <xs:enumeration value="start"/> <xs:enumeration value="end"/> </xs:restriction> </xs:simpleType> </xs:attribute> <xs:attribute name="_match" type="xs:string"/> <xs:attribute name="_phase" type="xs:string"/> <xs:assert test="exists(@match | @_match)"/> </xs:extension> </xs:complexContent> </xs:complexType> </xs:element> <xs:element name="analyze-string" substitutionGroup="xsl:instruction"> <xs:complexType> <xs:complexContent> <xs:extension base="xsl:element-only-versioned-element-type"> <xs:sequence> <xs:element ref="xsl:matching-substring" minOccurs="0"/> <xs:element ref="xsl:non-matching-substring" minOccurs="0"/> <xs:element ref="xsl:fallback" minOccurs="0" maxOccurs="unbounded"/> </xs:sequence> <xs:attribute name="select" type="xsl:expression"/> <xs:attribute name="regex" type="xsl:avt"/> <xs:attribute name="flags" type="xsl:avt" default=""/> <xs:attribute name="_select" type="xs:string"/> <xs:attribute name="_regex" type="xs:string"/> <xs:attribute name="_flags" type="xs:string"/> <xs:assert test="exists(@select | @_select)"/> <xs:assert test="exists(@regex | @_regex)"/> </xs:extension> </xs:complexContent> </xs:complexType> </xs:element> <xs:element name="apply-imports" substitutionGroup="xsl:instruction"> <xs:complexType> <xs:complexContent> <xs:extension base="xsl:element-only-versioned-element-type"> <xs:sequence> <xs:element ref="xsl:with-param" minOccurs="0" maxOccurs="unbounded"/> </xs:sequence> </xs:extension> </xs:complexContent> </xs:complexType> </xs:element> <xs:element name="apply-templates" substitutionGroup="xsl:instruction"> <xs:complexType> <xs:complexContent> <xs:extension base="xsl:element-only-versioned-element-type"> <xs:choice minOccurs="0" maxOccurs="unbounded"> <xs:element ref="xsl:sort"/> <xs:element ref="xsl:with-param"/> </xs:choice> <xs:attribute name="select" type="xsl:expression" default="child::node()"/> <xs:attribute name="mode" type="xsl:mode"/> <xs:attribute name="_select" type="xs:string"/> <xs:attribute name="_mode" type="xs:string"/> <xs:assert test="every $e in subsequence(xsl:sort, 2) satisfies empty($e/(@stable | @_stable))"> <xs:annotation> <xs:documentation> <p> It is a static error if an xsl:sort element other than the first in a sequence of sibling xsl:sort elements has a stable attribute. </p> </xs:documentation> </xs:annotation> </xs:assert> </xs:extension> </xs:complexContent> </xs:complexType> </xs:element> <xs:element name="assert" substitutionGroup="xsl:instruction"> <xs:complexType> <xs:complexContent mixed="true"> <xs:extension base="xsl:sequence-constructor"> <xs:attribute name="test" type="xsl:expression"/> <xs:attribute name="select" type="xsl:expression"/> <xs:attribute name="error-code" type="xsl:avt"/> <xs:attribute name="_test" type="xs:string"/> <xs:attribute name="_select" type="xs:string"/> <xs:attribute name="_error-code" type="xs:string"/> <xs:assert test="exists(@test | @_test)"/> </xs:extension> </xs:complexContent> </xs:complexType> </xs:element> <xs:element name="attribute" substitutionGroup="xsl:instruction"> <xs:complexType> <xs:complexContent mixed="true"> <xs:extension base="xsl:sequence-constructor-or-select"> <xs:attribute name="name" type="xsl:avt"/> <xs:attribute name="namespace" type="xsl:avt"/> <xs:attribute name="separator" type="xsl:avt"/> <xs:attribute name="type" type="xsl:EQName"/> <xs:attribute name="validation" type="xsl:validation-type"/> <xs:attribute name="_name" type="xs:string"/> <xs:attribute name="_namespace" type="xs:string"/> <xs:attribute name="_separator" type="xs:string"/> <xs:attribute name="_type" type="xs:string"/> <xs:attribute name="_validation" type="xs:string"/> <xs:assert test="not(exists(@type | @_type) and exists(@validation | @_validation))"> <xs:annotation> <xs:documentation> <p> The type and validation attributes are mutually exclusive (if one is present, the other must be absent). </p> </xs:documentation> </xs:annotation> </xs:assert> <xs:assert test="exists(@name | @_name)"/> </xs:extension> </xs:complexContent> </xs:complexType> </xs:element> <xs:element name="attribute-set" substitutionGroup="xsl:declaration"> <xs:complexType> <xs:complexContent> <xs:extension base="xsl:element-only-versioned-element-type"> <xs:sequence minOccurs="0" maxOccurs="unbounded"> <xs:element ref="xsl:attribute"/> </xs:sequence> <xs:attribute name="name" type="xsl:EQName"/> <xs:attribute name="streamable" type="xsl:yes-or-no"/> <xs:attribute name="use-attribute-sets" type="xsl:EQNames" default=""/> <xs:attribute name="visibility" type="xsl:visibility-type"/> <xs:attribute name="_name" type="xs:string"/> <xs:attribute name="_streamable" type="xs:string"/> <xs:attribute name="_use-attribute-sets" type="xs:string"/> <xs:attribute name="_visibility" type="xs:string"/> <xs:assert test="exists(@name | @_name)"/> </xs:extension> </xs:complexContent> </xs:complexType> </xs:element> <xs:element name="break" substitutionGroup="xsl:instruction" type="xsl:sequence-constructor-or-select"/> <xs:element name="call-template" substitutionGroup="xsl:instruction"> <xs:complexType> <xs:complexContent> <xs:extension base="xsl:element-only-versioned-element-type"> <xs:sequence> <xs:element ref="xsl:with-param" minOccurs="0" maxOccurs="unbounded"/> </xs:sequence> <xs:attribute name="name" type="xsl:EQName"/> <xs:attribute name="_name" type="xs:string"/> <xs:assert test="exists(@name | @_name)"/> </xs:extension> </xs:complexContent> </xs:complexType> </xs:element> <xs:element name="catch"> <xs:complexType> <xs:complexContent mixed="true"> <xs:extension base="xsl:sequence-constructor-or-select"> <xs:attribute name="errors" type="xs:token" use="optional"/> <xs:attribute name="_errors" type="xs:string"/> </xs:extension> </xs:complexContent> </xs:complexType> </xs:element> <xs:element name="character-map" substitutionGroup="xsl:declaration"> <xs:complexType> <xs:complexContent> <xs:extension base="xsl:element-only-versioned-element-type"> <xs:sequence> <xs:element ref="xsl:output-character" minOccurs="0" maxOccurs="unbounded"/> </xs:sequence> <xs:attribute name="name" type="xsl:EQName"/> <xs:attribute name="use-character-maps" type="xsl:EQNames" default=""/> <xs:attribute name="_name" type="xs:string"/> <xs:attribute name="_use-character-maps" type="xs:string"/> <xs:assert test="exists(@name | @_name)"/> </xs:extension> </xs:complexContent> </xs:complexType> </xs:element> <xs:element name="choose" substitutionGroup="xsl:instruction"> <xs:complexType> <xs:complexContent> <xs:extension base="xsl:element-only-versioned-element-type"> <xs:sequence> <xs:element ref="xsl:when" maxOccurs="unbounded"/> <xs:element ref="xsl:otherwise" minOccurs="0"/> </xs:sequence> </xs:extension> </xs:complexContent> </xs:complexType> </xs:element> <xs:element name="comment" substitutionGroup="xsl:instruction" type="xsl:sequence-constructor-or-select"/> <xs:element name="context-item"> <xs:complexType> <xs:complexContent> <xs:extension base="xsl:element-only-versioned-element-type"> <xs:attribute name="as" type="xsl:item-type"/> <xs:attribute name="use"> <xs:simpleType> <xs:restriction base="xs:token"> <xs:enumeration value="required"/> <xs:enumeration value="optional"/> <xs:enumeration value="absent"/> </xs:restriction> </xs:simpleType> </xs:attribute> <xs:attribute name="_as" type="xs:string"/> <xs:attribute name="_use" type="xs:string"/> </xs:extension> </xs:complexContent> </xs:complexType> </xs:element> <xs:element name="copy" substitutionGroup="xsl:instruction"> <xs:complexType> <xs:complexContent mixed="true"> <xs:extension base="xsl:sequence-constructor"> <xs:attribute name="select" type="xsl:expression"/> <xs:attribute name="copy-namespaces" type="xsl:yes-or-no" default="yes"/> <xs:attribute name="inherit-namespaces" type="xsl:yes-or-no" default="yes"/> <xs:attribute name="use-attribute-sets" type="xsl:EQNames" default=""/> <xs:attribute name="type" type="xsl:EQName"/> <xs:attribute name="validation" type="xsl:validation-type"/> <xs:attribute name="_select" type="xs:string"/> <xs:attribute name="_copy-namespaces" type="xs:string"/> <xs:attribute name="_inherit-namespaces" type="xs:string"/> <xs:attribute name="_use-attribute-sets" type="xs:string"/> <xs:attribute name="_type" type="xs:string"/> <xs:attribute name="_validation" type="xs:string"/> <xs:assert test="not(exists(@type | @_type) and exists(@validation | @_validation))"> <xs:annotation> <xs:documentation> <p> The type and validation attributes are mutually exclusive (if one is present, the other must be absent). </p> </xs:documentation> </xs:annotation> </xs:assert> </xs:extension> </xs:complexContent> </xs:complexType> </xs:element> <xs:element name="copy-of" substitutionGroup="xsl:instruction"> <xs:complexType> <xs:complexContent mixed="true"> <xs:extension base="xsl:versioned-element-type"> <xs:attribute name="select" type="xsl:expression"/> <xs:attribute name="copy-accumulators" type="xsl:yes-or-no" default="no"/> <xs:attribute name="copy-namespaces" type="xsl:yes-or-no" default="yes"/> <xs:attribute name="type" type="xsl:EQName"/> <xs:attribute name="validation" type="xsl:validation-type"/> <xs:attribute name="_select" type="xs:string"/> <xs:attribute name="_copy-accumulators" type="xs:string"/> <xs:attribute name="_copy-namespaces" type="xs:string"/> <xs:attribute name="_type" type="xs:string"/> <xs:attribute name="_validation" type="xs:string"/> <xs:assert test="not(exists(@type | @_type) and exists(@validation | @_validation))"> <xs:annotation> <xs:documentation> <p> The type and validation attributes are mutually exclusive (if one is present, the other must be absent). </p> </xs:documentation> </xs:annotation> </xs:assert> <xs:assert test="exists(@select | @_select)"/> </xs:extension> </xs:complexContent> </xs:complexType> </xs:element> <xs:element name="document" substitutionGroup="xsl:instruction"> <xs:complexType> <xs:complexContent mixed="true"> <xs:extension base="xsl:sequence-constructor"> <xs:attribute name="type" type="xsl:EQName"/> <xs:attribute name="validation" type="xsl:validation-type"/> <xs:attribute name="_type" type="xs:string"/> <xs:attribute name="_validation" type="xs:string"/> <xs:assert test="not(exists(@type | @_type) and exists(@validation | @_validation))"> <xs:annotation> <xs:documentation> <p> The type and validation attributes are mutually exclusive (if one is present, the other must be absent). </p> </xs:documentation> </xs:annotation> </xs:assert> </xs:extension> </xs:complexContent> </xs:complexType> </xs:element> <xs:element name="decimal-format" substitutionGroup="xsl:declaration"> <xs:complexType> <xs:complexContent> <xs:extension base="xsl:element-only-versioned-element-type"> <xs:attribute name="name" type="xsl:EQName"/> <xs:attribute name="decimal-separator" type="xsl:char" default="."/> <xs:attribute name="grouping-separator" type="xsl:char" default=","/> <xs:attribute name="infinity" type="xs:string" default="Infinity"/> <xs:attribute name="minus-sign" type="xsl:char" default="-"/> <xs:attribute name="exponent-separator" type="xsl:char" default="e"/> <xs:attribute name="NaN" type="xs:string" default="NaN"/> <xs:attribute name="percent" type="xsl:char" default="%"/> <xs:attribute name="per-mille" type="xsl:char" default="~"/> <xs:attribute name="zero-digit" type="xsl:zero-digit" default="0"/> <xs:attribute name="digit" type="xsl:char" default="#"/> <xs:attribute name="pattern-separator" type="xsl:char" default=";"/> <xs:attribute name="_name" type="xs:string"/> <xs:attribute name="_decimal-separator" type="xs:string"/> <xs:attribute name="_grouping-separator" type="xs:string"/> <xs:attribute name="_infinity" type="xs:string"/> <xs:attribute name="_minus-sign" type="xs:string"/> <xs:attribute name="_exponent-separator" type="xs:string"/> <xs:attribute name="_NaN" type="xs:string"/> <xs:attribute name="_percent" type="xs:string"/> <xs:attribute name="_per-mille" type="xs:string"/> <xs:attribute name="_zero-digit" type="xs:string"/> <xs:attribute name="_digit" type="xs:string"/> <xs:attribute name="_pattern-separator" type="xs:string"/> </xs:extension> </xs:complexContent> </xs:complexType> </xs:element> <xs:element name="element" substitutionGroup="xsl:instruction"> <xs:complexType mixed="true"> <xs:complexContent> <xs:extension base="xsl:sequence-constructor"> <xs:attribute name="name" type="xsl:avt"/> <xs:attribute name="namespace" type="xsl:avt"/> <xs:attribute name="inherit-namespaces" type="xsl:yes-or-no" default="yes"/> <xs:attribute name="use-attribute-sets" type="xsl:EQNames" default=""/> <xs:attribute name="type" type="xsl:EQName"/> <xs:attribute name="validation" type="xsl:validation-type"/> <xs:attribute name="_name" type="xs:string"/> <xs:attribute name="_namespace" type="xs:string"/> <xs:attribute name="_inherit-namespaces" type="xs:string"/> <xs:attribute name="_use-attribute-sets" type="xs:string"/> <xs:attribute name="_type" type="xs:string"/> <xs:attribute name="_validation" type="xs:string"/> <xs:assert test="exists(@name | @_name)"/> <xs:assert test="not(exists(@type | @_type) and exists(@validation | @_validation))"> <xs:annotation> <xs:documentation> <p> The type and validation attributes are mutually exclusive (if one is present, the other must be absent). </p> </xs:documentation> </xs:annotation> </xs:assert> </xs:extension> </xs:complexContent> </xs:complexType> </xs:element> <xs:element name="evaluate" substitutionGroup="xsl:instruction"> <xs:complexType> <xs:complexContent mixed="true"> <xs:extension base="xsl:element-only-versioned-element-type"> <xs:choice minOccurs="0" maxOccurs="unbounded"> <xs:element ref="xsl:with-param"/> <xs:element ref="xsl:fallback"/> </xs:choice> <xs:attribute name="xpath" type="xsl:expression"/> <xs:attribute name="as" type="xsl:sequence-type"/> <xs:attribute name="base-uri" type="xsl:avt"/> <xs:attribute name="context-item" type="xsl:expression"/> <xs:attribute name="namespace-context" type="xsl:expression"/> <xs:attribute name="schema-aware" type="xsl:avt"/> <xs:attribute name="with-params" type="xsl:expression"/> <xs:attribute name="_xpath" type="xs:string"/> <xs:attribute name="_as" type="xs:string"/> <xs:attribute name="_base-uri" type="xs:string"/> <xs:attribute name="_context-item" type="xs:string"/> <xs:attribute name="_namespace-context" type="xs:string"/> <xs:attribute name="_schema-aware" type="xs:string"/> <xs:attribute name="_with-params" type="xs:string"/> <xs:assert test="exists(@xpath | @_xpath)"/> </xs:extension> </xs:complexContent> </xs:complexType> </xs:element> <xs:element name="expose"> <xs:annotation> <xs:documentation> <p> This element appears as a child of xsl:use-package and defines the visibility of components that are made available (or not) by this package to other using packages. </p> </xs:documentation> </xs:annotation> <xs:complexType> <xs:complexContent> <xs:extension base="xsl:element-only-versioned-element-type"> <xs:attribute name="component" type="xsl:component-kind-type"/> <xs:attribute name="names" type="xsl:EQNames"/> <xs:attribute name="visibility" type="xsl:visibility-not-hidden-type"/> <xs:attribute name="_component" type="xs:string"/> <xs:attribute name="_names" type="xs:string"/> <xs:attribute name="_visibility" type="xs:string"/> </xs:extension> </xs:complexContent> </xs:complexType> </xs:element> <xs:element name="fallback" substitutionGroup="xsl:instruction" type="xsl:sequence-constructor"/> <xs:element name="for-each" substitutionGroup="xsl:instruction"> <xs:complexType> <xs:complexContent mixed="true"> <xs:extension base="xsl:versioned-element-type"> <xs:sequence> <xs:element ref="xsl:sort" minOccurs="0" maxOccurs="unbounded"/> <xs:group ref="xsl:sequence-constructor-group" minOccurs="0" maxOccurs="unbounded"/> </xs:sequence> <xs:attribute name="select" type="xsl:expression"/> <xs:attribute name="_select" type="xs:string"/> <xs:assert test="every $e in subsequence(xsl:sort, 2) satisfies empty($e/(@stable | @_stable))"> <xs:annotation> <xs:documentation> <p> It is a static error if an xsl:sort element other than the first in a sequence of sibling xsl:sort elements has a stable attribute. </p> </xs:documentation> </xs:annotation> </xs:assert> <xs:assert test="exists(@select | @_select)"/> </xs:extension> </xs:complexContent> </xs:complexType> </xs:element> <xs:element name="for-each-group" substitutionGroup="xsl:instruction"> <xs:complexType> <xs:complexContent mixed="true"> <xs:extension base="xsl:versioned-element-type"> <xs:sequence> <xs:element ref="xsl:sort" minOccurs="0" maxOccurs="unbounded"/> <xs:group ref="xsl:sequence-constructor-group" minOccurs="0" maxOccurs="unbounded"/> </xs:sequence> <xs:attribute name="select" type="xsl:expression"/> <xs:attribute name="group-by" type="xsl:expression"/> <xs:attribute name="group-adjacent" type="xsl:expression"/> <xs:attribute name="group-starting-with" type="xsl:pattern"/> <xs:attribute name="group-ending-with" type="xsl:pattern"/> <xs:attribute name="composite" type="xsl:yes-or-no"/> <xs:attribute name="collation" type="xsl:avt"/> <xs:attribute name="_select" type="xs:string"/> <xs:attribute name="_group-by" type="xs:string"/> <xs:attribute name="_group-adjacent" type="xs:string"/> <xs:attribute name="_group-starting-with" type="xs:string"/> <xs:attribute name="_group-ending-with" type="xs:string"/> <xs:attribute name="_composite" type="xs:string"/> <xs:attribute name="_collation" type="xs:string"/> <xs:assert test="exists(@select | @_select)"/> <xs:assert test="every $e in subsequence(xsl:sort, 2) satisfies empty($e/(@stable | @_stable))"> <xs:annotation> <xs:documentation> <p> It is a static error if an xsl:sort element other than the first in a sequence of sibling xsl:sort elements has a stable attribute. </p> </xs:documentation> </xs:annotation> </xs:assert> <xs:assert test="count(((@group-by|@_group-by)[1], (@group-adjacent|@_group-adjacent)[1], (@group-starting-with|@_group-starting-with)[1], (@group-ending-with|@_group-ending-with)[1])) = 1"> <xs:annotation> <xs:documentation> <p> These four attributes are mutually exclusive: it is a static error if none of these four attributes is present or if more than one of them is present. </p> </xs:documentation> </xs:annotation> </xs:assert> <xs:assert test="if (exists(@collation|@_collation) or exists(@composite|@_composite)) then (exists(@group-by|@_group-by) or exists(@group-adjacent|@_group-adjacent)) else true()"> <xs:annotation> <xs:documentation> <p> It is an error to specify the collation attribute or the composite attribute if neither the group-by attribute nor group-adjacent attribute is specified. </p> </xs:documentation> </xs:annotation> </xs:assert> </xs:extension> </xs:complexContent> </xs:complexType> </xs:element> <xs:element name="fork" substitutionGroup="xsl:instruction"> <xs:complexType> <xs:complexContent mixed="true"> <xs:extension base="xsl:versioned-element-type"> <xs:sequence> <xs:element ref="xsl:fallback" minOccurs="0" maxOccurs="unbounded"/> <xs:choice> <xs:sequence minOccurs="0" maxOccurs="unbounded"> <xs:element ref="xsl:sequence"/> <xs:element ref="xsl:fallback" minOccurs="0" maxOccurs="unbounded"/> </xs:sequence> <xs:sequence> <xs:element ref="xsl:for-each-group"/> <xs:element ref="xsl:fallback" minOccurs="0" maxOccurs="unbounded"/> </xs:sequence> </xs:choice> </xs:sequence> </xs:extension> </xs:complexContent> </xs:complexType> </xs:element> <xs:element name="function" substitutionGroup="xsl:declaration"> <xs:complexType> <xs:complexContent mixed="true"> <xs:extension base="xsl:versioned-element-type"> <xs:sequence> <xs:element ref="xsl:param" minOccurs="0" maxOccurs="unbounded"/> <xs:group ref="xsl:sequence-constructor-group" minOccurs="0" maxOccurs="unbounded"/> </xs:sequence> <xs:attribute name="name" type="xsl:EQName-in-namespace"/> <xs:attribute name="override" type="xsl:yes-or-no" default="yes"/> <xs:attribute name="as" type="xsl:sequence-type" default="item()*"/> <xs:attribute name="visibility" type="xsl:visibility-type"/> <xs:attribute name="streamability" type="xsl:streamability-type"/> <xs:attribute name="override-extension-function" type="xsl:yes-or-no"/> <xs:attribute name="new-each-time" type="xsl:yes-or-no-or-maybe"/> <xs:attribute name="cache" type="xsl:yes-or-no"/> <xs:attribute name="_name" type="xs:string"/> <xs:attribute name="_override" type="xs:string"/> <xs:attribute name="_as" type="xs:string"/> <xs:attribute name="_visibility" type="xs:string"/> <xs:attribute name="_streamability" type="xs:string"/> <xs:attribute name="_override-extension-function" type="xs:string"/> <xs:attribute name="_identity-sensitive" type="xs:string"/> <xs:attribute name="_cache" type="xs:string"/> <xs:assert test="exists(@name | @_name)"/> <xs:assert test="every $e in xsl:param satisfies (empty($e/(@select | @_select)) and empty($e/child::node()))"> <xs:annotation> <xs:documentation> <p> A parameter for a function must have no default value. </p> </xs:documentation> </xs:annotation> </xs:assert> <xs:assert test="every $e in xsl:param satisfies empty($e/(@visibility | @_visibility))"> <xs:annotation> <xs:documentation> <p> A parameter for a function must have no visibility attribute. </p> </xs:documentation> </xs:annotation> </xs:assert> <xs:assert test="every $e in xsl:param satisfies empty($e/(@required | @_required))"> <xs:annotation> <xs:documentation> <p> A parameter for a function must have no required attribute. </p> </xs:documentation> </xs:annotation> </xs:assert> </xs:extension> </xs:complexContent> </xs:complexType> </xs:element> <xs:element name="global-context-item" substitutionGroup="xsl:declaration"> <xs:complexType> <xs:complexContent> <xs:extension base="xsl:element-only-versioned-element-type"> <xs:attribute name="as" type="xsl:item-type"/> <xs:attribute name="use"> <xs:simpleType> <xs:restriction base="xs:token"> <xs:enumeration value="required"/> <xs:enumeration value="optional"/> <xs:enumeration value="absent"/> </xs:restriction> </xs:simpleType> </xs:attribute> <xs:attribute name="_as" type="xs:string"/> <xs:attribute name="_use" type="xs:string"/> </xs:extension> </xs:complexContent> </xs:complexType> </xs:element> <xs:element name="if" substitutionGroup="xsl:instruction"> <xs:complexType> <xs:complexContent mixed="true"> <xs:extension base="xsl:sequence-constructor"> <xs:attribute name="test" type="xsl:expression"/> <xs:attribute name="_test" type="xs:string"/> <xs:assert test="exists(@test | @_test)"/> </xs:extension> </xs:complexContent> </xs:complexType> </xs:element> <xs:element name="import" substitutionGroup="xsl:declaration"> <xs:complexType> <xs:complexContent> <xs:extension base="xsl:element-only-versioned-element-type"> <xs:attribute name="href" type="xs:anyURI"/> <xs:attribute name="_href" type="xs:string"/> <xs:assert test="exists(@href | @_href)"/> </xs:extension> </xs:complexContent> </xs:complexType> </xs:element> <xs:element name="import-schema" substitutionGroup="xsl:declaration"> <xs:complexType> <xs:complexContent> <xs:extension base="xsl:element-only-versioned-element-type"> <xs:sequence> <xs:element ref="xs:schema" minOccurs="0" maxOccurs="1"/> </xs:sequence> <xs:attribute name="namespace" type="xs:anyURI"/> <xs:attribute name="schema-location" type="xs:anyURI"/> <xs:attribute name="_namespace" type="xs:string"/> <xs:attribute name="_schema-location" type="xs:string"/> <xs:assert test="not(exists(@schema-location | @_schema-location) and exists(xs:schema))"> <xs:annotation> <xs:documentation> <p> XTSE0215: It is a static error if an xsl:import-schema element that contains an xs:schema element has a schema-location attribute </p> </xs:documentation> </xs:annotation> </xs:assert> </xs:extension> </xs:complexContent> </xs:complexType> </xs:element> <xs:element name="include" substitutionGroup="xsl:declaration"> <xs:complexType> <xs:complexContent> <xs:extension base="xsl:element-only-versioned-element-type"> <xs:attribute name="href" type="xs:anyURI"/> <xs:attribute name="_href" type="xs:string"/> <xs:assert test="exists(@href | @_href)"/> </xs:extension> </xs:complexContent> </xs:complexType> </xs:element> <xs:element name="iterate" substitutionGroup="xsl:instruction"> <xs:complexType> <xs:complexContent mixed="true"> <xs:extension base="xsl:versioned-element-type"> <xs:sequence> <xs:element ref="xsl:param" minOccurs="0" maxOccurs="unbounded"/> <xs:element ref="xsl:on-completion" minOccurs="0" maxOccurs="1"/> <xs:group ref="xsl:sequence-constructor-group" minOccurs="0" maxOccurs="unbounded"/> </xs:sequence> <xs:attribute name="select" type="xsl:expression"/> <xs:attribute name="_select" type="xs:string"/> <xs:assert test="exists(@select | @_select)"/> </xs:extension> </xs:complexContent> </xs:complexType> </xs:element> <xs:element name="key" substitutionGroup="xsl:declaration"> <xs:complexType> <xs:complexContent mixed="true"> <xs:extension base="xsl:sequence-constructor"> <xs:attribute name="name" type="xsl:EQName"/> <xs:attribute name="match" type="xsl:pattern"/> <xs:attribute name="use" type="xsl:expression"/> <xs:attribute name="composite" type="xsl:yes-or-no"/> <xs:attribute name="collation" type="xs:anyURI"/> <xs:attribute name="_name" type="xs:string"/> <xs:attribute name="_match" type="xs:string"/> <xs:attribute name="_use" type="xs:string"/> <xs:attribute name="_composite" type="xs:string"/> <xs:attribute name="_collation" type="xs:string"/> <xs:assert test="exists(@name | @_name)"/> <xs:assert test="exists(@match | @_match)"/> </xs:extension> </xs:complexContent> </xs:complexType> </xs:element> <xs:element name="map" type="xsl:sequence-constructor" substitutionGroup="xsl:instruction"/> <xs:element name="map-entry" substitutionGroup="xsl:instruction"> <xs:complexType> <xs:complexContent mixed="true"> <xs:extension base="xsl:sequence-constructor-and-select"> <xs:attribute name="key" type="xsl:expression"/> <xs:attribute name="_key" type="xs:string"/> <xs:assert test="exists(@key | @_key)"/> </xs:extension> </xs:complexContent> </xs:complexType> </xs:element> <xs:element name="matching-substring" type="xsl:sequence-constructor"/> <xs:element name="merge" substitutionGroup="xsl:instruction"> <xs:complexType> <xs:complexContent> <xs:extension base="xsl:element-only-versioned-element-type"> <xs:sequence> <xs:element ref="xsl:merge-source" minOccurs="1" maxOccurs="unbounded"/> <xs:element ref="xsl:merge-action" minOccurs="1" maxOccurs="1"/> <xs:element ref="xsl:fallback" minOccurs="0" maxOccurs="unbounded"/> </xs:sequence> </xs:extension> </xs:complexContent> </xs:complexType> </xs:element> <xs:element name="merge-action" type="xsl:sequence-constructor"/> <xs:element name="merge-key" substitutionGroup="xsl:instruction"> <xs:complexType> <xs:complexContent mixed="true"> <xs:extension base="xsl:versioned-element-type"> <xs:sequence> <xs:group ref="xsl:sequence-constructor-group" minOccurs="0" maxOccurs="unbounded"/> </xs:sequence> <xs:attribute name="select" type="xsl:expression"/> <xs:attribute name="lang" type="xsl:avt"/> <xs:attribute name="order" type="xsl:avt"/> <xs:attribute name="collation" type="xs:anyURI"/> <xs:attribute name="case-order" type="xsl:avt"/> <xs:attribute name="data-type" type="xsl:avt"/> <xs:attribute name="_select" type="xs:string"/> <xs:attribute name="_lang" type="xs:string"/> <xs:attribute name="_order" type="xs:string"/> <xs:attribute name="_collation" type="xs:string"/> <xs:attribute name="_case-order" type="xs:string"/> <xs:attribute name="_data-type" type="xs:string"/> </xs:extension> </xs:complexContent> </xs:complexType> </xs:element> <xs:element name="merge-source"> <xs:complexType> <xs:complexContent> <xs:extension base="xsl:element-only-versioned-element-type"> <xs:sequence> <xs:element ref="xsl:merge-key" minOccurs="1" maxOccurs="unbounded"/> </xs:sequence> <xs:attribute name="name" type="xs:NCName"/> <xs:attribute name="for-each-item" type="xsl:expression"/> <xs:attribute name="for-each-source" type="xsl:expression"/> <xs:attribute name="select" type="xsl:expression"/> <xs:attribute name="streamable" type="xsl:yes-or-no"/> <xs:attribute name="use-accumulators" type="xsl:accumulator-names"/> <xs:attribute name="sort-before-merge" type="xsl:yes-or-no"/> <xs:attribute name="type" type="xsl:EQName"/> <xs:attribute name="validation" type="xsl:validation-type"/> <xs:attribute name="_name" type="xs:string"/> <xs:attribute name="_for-each-item" type="xs:string"/> <xs:attribute name="_for-each-source" type="xs:string"/> <xs:attribute name="_select" type="xs:string"/> <xs:attribute name="_streamable" type="xs:string"/> <xs:attribute name="_use-accumulators" type="xs:string"/> <xs:attribute name="_sort-before-merge" type="xs:string"/> <xs:attribute name="_type" type="xs:string"/> <xs:attribute name="_validation" type="xs:string"/> <xs:assert test="exists(@select | @_select)"/> </xs:extension> </xs:complexContent> </xs:complexType> </xs:element> <xs:element name="message" substitutionGroup="xsl:instruction"> <xs:complexType> <xs:complexContent mixed="true"> <xs:extension base="xsl:sequence-constructor"> <xs:attribute name="select" type="xsl:expression"/> <xs:attribute name="terminate" type="xsl:avt" default="no"/> <xs:attribute name="error-code" type="xsl:avt"/> <xs:attribute name="_select" type="xs:string"/> <xs:attribute name="_terminate" type="xs:string"/> <xs:attribute name="_error-code" type="xs:string"/> </xs:extension> </xs:complexContent> </xs:complexType> </xs:element> <xs:element name="mode" substitutionGroup="xsl:declaration"> <xs:complexType> <xs:complexContent mixed="false"> <xs:extension base="xsl:element-only-versioned-element-type"> <xs:attribute name="name" type="xsl:EQName"/> <xs:attribute name="streamable" type="xsl:yes-or-no" default="no"/> <xs:attribute name="use-accumulators" type="xsl:accumulator-names"/> <xs:attribute name="on-no-match" type="xsl:on-no-match-type" default="shallow-skip"/> <xs:attribute name="on-multiple-match" type="xsl:on-multiple-match-type" default="use-last"/> <xs:attribute name="warning-on-no-match" type="xsl:yes-or-no"/> <xs:attribute name="warning-on-multiple-match" type="xsl:yes-or-no"/> <xs:attribute name="typed" type="xsl:typed-type"/> <xs:attribute name="visibility"> <xs:simpleType> <xs:restriction base="xsl:visibility-type"> <xs:enumeration value="public"/> <xs:enumeration value="private"/> <xs:enumeration value="final"/> </xs:restriction> </xs:simpleType> </xs:attribute> <xs:attribute name="_name" type="xs:string"/> <xs:attribute name="_streamable" type="xs:string"/> <xs:attribute name="_on-no-match" type="xs:string"/> <xs:attribute name="_on-multiple-match" type="xs:string"/> <xs:attribute name="_warning-on-no-match" type="xs:string"/> <xs:attribute name="_warning-on-multiple-match" type="xs:string"/> <xs:attribute name="_typed" type="xs:string"/> <xs:attribute name="_visibility" type="xs:string"/> </xs:extension> </xs:complexContent> </xs:complexType> </xs:element> <xs:element name="namespace" substitutionGroup="xsl:instruction"> <xs:complexType> <xs:complexContent mixed="true"> <xs:extension base="xsl:sequence-constructor-or-select"> <xs:attribute name="name" type="xsl:avt"/> <xs:attribute name="_name" type="xs:string"/> <xs:assert test="exists(@name | @_name)"/> </xs:extension> </xs:complexContent> </xs:complexType> </xs:element> <xs:element name="namespace-alias" substitutionGroup="xsl:declaration"> <xs:complexType> <xs:complexContent> <xs:extension base="xsl:element-only-versioned-element-type"> <xs:attribute name="stylesheet-prefix" type="xsl:prefix-or-default"/> <xs:attribute name="result-prefix" type="xsl:prefix-or-default"/> <xs:attribute name="_stylesheet-prefix" type="xs:string"/> <xs:attribute name="_result-prefix" type="xs:string"/> <xs:assert test="exists(@stylesheet-prefix | @_stylesheet-prefix)"/> <xs:assert test="exists(@result-prefix | @_result-prefix)"/> <xs:assert test="every $prefix in (@stylesheet-prefix, @result-prefix) /normalize-space(.)[. ne '#default'] satisfies $prefix = in-scope-prefixes(.)"/> </xs:extension> </xs:complexContent> </xs:complexType> </xs:element> <xs:element name="next-iteration" substitutionGroup="xsl:instruction"> <xs:complexType> <xs:complexContent mixed="true"> <xs:extension base="xsl:element-only-versioned-element-type"> <xs:sequence> <xs:element ref="xsl:with-param" minOccurs="0" maxOccurs="unbounded"/> </xs:sequence> </xs:extension> </xs:complexContent> </xs:complexType> </xs:element> <xs:element name="next-match" substitutionGroup="xsl:instruction"> <xs:complexType> <xs:complexContent> <xs:extension base="xsl:element-only-versioned-element-type"> <xs:choice minOccurs="0" maxOccurs="unbounded"> <xs:element ref="xsl:with-param"/> <xs:element ref="xsl:fallback"/> </xs:choice> </xs:extension> </xs:complexContent> </xs:complexType> </xs:element> <xs:element name="non-matching-substring" type="xsl:sequence-constructor"/> <xs:element name="number" substitutionGroup="xsl:instruction"> <xs:complexType> <xs:complexContent mixed="true"> <xs:extension base="xsl:versioned-element-type"> <xs:attribute name="value" type="xsl:expression"/> <xs:attribute name="select" type="xsl:expression"/> <xs:attribute name="level" type="xsl:level" default="single"/> <xs:attribute name="count" type="xsl:pattern"/> <xs:attribute name="from" type="xsl:pattern"/> <xs:attribute name="format" type="xsl:avt" default="1"/> <xs:attribute name="lang" type="xsl:avt"/> <xs:attribute name="letter-value" type="xsl:avt"/> <xs:attribute name="ordinal" type="xsl:avt"/> <xs:attribute name="start-at" type="xsl:avt"/> <xs:attribute name="grouping-separator" type="xsl:avt"/> <xs:attribute name="grouping-size" type="xsl:avt"/> <xs:attribute name="_value" type="xs:string"/> <xs:attribute name="_select" type="xs:string"/> <xs:attribute name="_level" type="xs:string"/> <xs:attribute name="_count" type="xs:string"/> <xs:attribute name="_from" type="xs:string"/> <xs:attribute name="_format" type="xs:string"/> <xs:attribute name="_lang" type="xs:string"/> <xs:attribute name="_letter-value" type="xs:string"/> <xs:attribute name="_ordinal" type="xs:string"/> <xs:attribute name="_start-at" type="xs:string"/> <xs:attribute name="_grouping-separator" type="xs:string"/> <xs:attribute name="_grouping-size" type="xs:string"/> <xs:assert test="if (exists(@value | @_value)) then empty((@select | @_select, @count | @_count, @from | @_from)) and (exists(@_level) or normalize-space(@level)='single') else true()"> <xs:annotation> <xs:documentation> <p> It is a static error if the value attribute of xsl:number is present unless the select, level, count, and from attributes are all absent. </p> </xs:documentation> </xs:annotation> </xs:assert> </xs:extension> </xs:complexContent> </xs:complexType> </xs:element> <xs:element name="on-completion" type="xsl:sequence-constructor-or-select"/> <xs:element name="on-empty" substitutionGroup="xsl:instruction" type="xsl:sequence-constructor-or-select"/> <xs:element name="on-non-empty" substitutionGroup="xsl:instruction" type="xsl:sequence-constructor-or-select"/> <xs:element name="otherwise" type="xsl:sequence-constructor"/> <xs:element name="output" substitutionGroup="xsl:declaration"> <xs:complexType> <xs:complexContent mixed="true"> <xs:extension base="xsl:generic-element-type"> <xs:attribute name="name" type="xsl:EQName"/> <xs:attribute name="method" type="xsl:method"/> <xs:attribute name="allow-duplicate-names" type="xsl:yes-or-no"/> <xs:attribute name="build-tree" type="xsl:yes-or-no"/> <xs:attribute name="byte-order-mark" type="xsl:yes-or-no"/> <xs:attribute name="cdata-section-elements" type="xsl:EQNames"/> <xs:attribute name="doctype-public" type="xs:string"/> <xs:attribute name="doctype-system" type="xs:string"/> <xs:attribute name="encoding" type="xs:string"/> <xs:attribute name="escape-uri-attributes" type="xsl:yes-or-no"/> <xs:attribute name="html-version" type="xs:decimal"/> <xs:attribute name="include-content-type" type="xsl:yes-or-no"/> <xs:attribute name="indent" type="xsl:yes-or-no"/> <xs:attribute name="item-separator" type="xs:string"/> <xs:attribute name="json-node-output-method" type="xsl:method"/> <xs:attribute name="media-type" type="xs:string"/> <xs:attribute name="normalization-form" type="xs:NMTOKEN"/> <xs:attribute name="omit-xml-declaration" type="xsl:yes-or-no"/> <xs:attribute name="parameter-document" type="xs:anyURI"/> <xs:attribute name="standalone" type="xsl:yes-or-no-or-omit"/> <xs:attribute name="suppress-indentation" type="xsl:EQNames"/> <xs:attribute name="undeclare-prefixes" type="xsl:yes-or-no"/> <xs:attribute name="use-character-maps" type="xsl:EQNames"/> <xs:attribute name="version" type="xs:NMTOKEN"/> <xs:attribute name="_name" type="xs:string"/> <xs:attribute name="_method" type="xs:string"/> <xs:attribute name="_byte-order-mark" type="xs:string"/> <xs:attribute name="_cdata-section-elements" type="xs:string"/> <xs:attribute name="_doctype-public" type="xs:string"/> <xs:attribute name="_doctype-system" type="xs:string"/> <xs:attribute name="_encoding" type="xs:string"/> <xs:attribute name="_escape-uri-attributes" type="xs:string"/> <xs:attribute name="_html-version" type="xs:string"/> <xs:attribute name="_include-content-type" type="xs:string"/> <xs:attribute name="_indent" type="xs:string"/> <xs:attribute name="_item-separator" type="xs:string"/> <xs:attribute name="_media-type" type="xs:string"/> <xs:attribute name="_normalization-form" type="xs:string"/> <xs:attribute name="_omit-xml-declaration" type="xs:string"/> <xs:attribute name="_parameter-document" type="xs:string"/> <xs:attribute name="_standalone" type="xs:string"/> <xs:attribute name="_suppress-indentation" type="xs:string"/> <xs:attribute name="_undeclare-prefixes" type="xs:string"/> <xs:attribute name="_use-character-maps" type="xs:string"/> <xs:attribute name="_version" type="xs:string"/> </xs:extension> </xs:complexContent> </xs:complexType> </xs:element> <xs:element name="output-character"> <xs:complexType> <xs:complexContent> <xs:extension base="xsl:element-only-versioned-element-type"> <xs:attribute name="character" type="xsl:char"/> <xs:attribute name="string" type="xs:string"/> <xs:attribute name="_character" type="xs:string"/> <xs:attribute name="_string" type="xs:string"/> <xs:assert test="exists(@character | @_character)"/> <xs:assert test="exists(@string | @_string)"/> </xs:extension> </xs:complexContent> </xs:complexType> </xs:element> <xs:element name="override"> <xs:annotation> <xs:documentation> <p> This element appears as a child of xsl:use-package and defines any overriding definitions of components that the containing package wishes to make to the components made available from a library package. </p> </xs:documentation> </xs:annotation> <xs:complexType> <xs:complexContent> <xs:extension base="xsl:element-only-versioned-element-type"> <xs:choice minOccurs="0" maxOccurs="unbounded"> <xs:element ref="xsl:template"/> <xs:element ref="xsl:function"/> <xs:element ref="xsl:variable"/> <xs:element ref="xsl:param"/> <xs:element ref="xsl:attribute-set"/> </xs:choice> </xs:extension> </xs:complexContent> </xs:complexType> </xs:element> <xs:element name="package"> <xs:complexType> <xs:complexContent> <xs:extension base="xsl:element-only-versioned-element-type"> <xs:sequence> <xs:choice minOccurs="0" maxOccurs="unbounded"> <xs:element ref="xsl:expose"/> <xs:element ref="xsl:declaration"/> <xs:any namespace="##other" processContents="lax"/> </xs:choice> </xs:sequence> <xs:attribute name="declared-modes" type="xsl:yes-or-no"/> <xs:attribute name="id" type="xs:ID"/> <xs:attribute name="name" type="xs:anyURI"/> <xs:attribute name="package-version" type="xs:string"/> <xs:attribute name="input-type-annotations" type="xsl:input-type-annotations-type"/> <xs:attribute name="_declared-modes" type="xs:string"/> <xs:attribute name="_id" type="xs:string"/> <xs:attribute name="_name" type="xs:string"/> <xs:attribute name="_package-version" type="xs:string"/> <xs:attribute name="_input-type-annotations" type="xs:string"/> </xs:extension> </xs:complexContent> </xs:complexType> </xs:element> <xs:element name="param" substitutionGroup="xsl:declaration"> <xs:annotation> <xs:documentation> <p> Declaration of the xsl:param element, used both defining function parameters, template parameters, parameters to xsl:iterate, and global stylesheet parameters. </p> </xs:documentation> </xs:annotation> <xs:complexType> <xs:complexContent mixed="true"> <xs:extension base="xsl:sequence-constructor-or-select"> <xs:attribute name="name" type="xsl:EQName"/> <xs:attribute name="as" type="xsl:sequence-type"/> <xs:attribute name="required" type="xsl:yes-or-no"/> <xs:attribute name="tunnel" type="xsl:yes-or-no"/> <xs:attribute name="static" type="xsl:yes-or-no"/> <xs:attribute name="_name" type="xs:string"/> <xs:attribute name="_as" type="xs:string"/> <xs:attribute name="_required" type="xs:string"/> <xs:attribute name="_tunnel" type="xs:string"/> <xs:attribute name="_static" type="xs:string"/> <xs:assert test="exists(@name | @_name)"/> <xs:assert test="if (normalize-space(@static) = ('yes', 'true', '1')) then empty((*,text())) else true()"> <xs:annotation> <xs:documentation> <p> When the attribute static="yes" is specified, the xsl:param element must have empty content. </p> </xs:documentation> </xs:annotation> </xs:assert> </xs:extension> </xs:complexContent> </xs:complexType> </xs:element> <xs:element name="perform-sort" substitutionGroup="xsl:instruction"> <xs:complexType> <xs:complexContent mixed="true"> <xs:extension base="xsl:versioned-element-type"> <xs:sequence> <xs:element ref="xsl:sort" minOccurs="1" maxOccurs="unbounded"/> <xs:group ref="xsl:sequence-constructor-group" minOccurs="0" maxOccurs="unbounded"/> </xs:sequence> <xs:attribute name="select" type="xsl:expression"/> <xs:assert test="every $e in subsequence(xsl:sort, 2) satisfies empty($e/(@stable | @_stable))"> <xs:annotation> <xs:documentation> <p> It is a static error if an xsl:sort element other than the first in a sequence of sibling xsl:sort elements has a stable attribute. </p> </xs:documentation> </xs:annotation> </xs:assert> </xs:extension> </xs:complexContent> </xs:complexType> </xs:element> <xs:element name="preserve-space" substitutionGroup="xsl:declaration"> <xs:complexType> <xs:complexContent> <xs:extension base="xsl:element-only-versioned-element-type"> <xs:attribute name="elements" type="xsl:nametests"/> <xs:attribute name="_elements" type="xs:string"/> <xs:assert test="exists(@elements | @_elements)"/> </xs:extension> </xs:complexContent> </xs:complexType> </xs:element> <xs:element name="processing-instruction" substitutionGroup="xsl:instruction"> <xs:complexType> <xs:complexContent mixed="true"> <xs:extension base="xsl:sequence-constructor-or-select"> <xs:attribute name="name" type="xsl:avt"/> <xs:attribute name="_name" type="xs:string"/> <xs:assert test="exists(@name | @_name)"/> </xs:extension> </xs:complexContent> </xs:complexType> </xs:element> <xs:element name="result-document" substitutionGroup="xsl:instruction"> <xs:complexType> <xs:complexContent mixed="true"> <xs:extension base="xsl:sequence-constructor"> <xs:attribute name="format" type="xsl:avt"/> <xs:attribute name="href" type="xsl:avt"/> <xs:attribute name="type" type="xsl:EQName"/> <xs:attribute name="validation" type="xsl:validation-type"/> <xs:attribute name="method" type="xsl:avt"/> <xs:attribute name="allow-duplicate-names" type="xsl:avt"/> <xs:attribute name="build-tree" type="xsl:avt"/> <xs:attribute name="byte-order-mark" type="xsl:avt"/> <xs:attribute name="cdata-section-elements" type="xsl:avt"/> <xs:attribute name="doctype-public" type="xsl:avt"/> <xs:attribute name="doctype-system" type="xsl:avt"/> <xs:attribute name="encoding" type="xsl:avt"/> <xs:attribute name="escape-uri-attributes" type="xsl:avt"/> <xs:attribute name="html-version" type="xsl:avt"/> <xs:attribute name="include-content-type" type="xsl:avt"/> <xs:attribute name="indent" type="xsl:avt"/> <xs:attribute name="item-separator" type="xsl:avt"/> <xs:attribute name="json-node-output-method" type="xsl:avt"/> <xs:attribute name="media-type" type="xsl:avt"/> <xs:attribute name="normalization-form" type="xsl:avt"/> <xs:attribute name="omit-xml-declaration" type="xsl:avt"/> <xs:attribute name="parameter-document" type="xsl:avt"/> <xs:attribute name="standalone" type="xsl:avt"/> <xs:attribute name="suppress-indentation" type="xsl:avt"/> <xs:attribute name="undeclare-prefixes" type="xsl:avt"/> <xs:attribute name="use-character-maps" type="xsl:EQNames"/> <xs:attribute name="output-version" type="xsl:avt"/> <xs:attribute name="_format" type="xs:string"/> <xs:attribute name="_href" type="xs:string"/> <xs:attribute name="_type" type="xs:string"/> <xs:attribute name="_validation" type="xs:string"/> <xs:attribute name="_method" type="xs:string"/> <xs:attribute name="_byte-order-mark" type="xs:string"/> <xs:attribute name="_cdata-section-elements" type="xs:string"/> <xs:attribute name="_doctype-public" type="xs:string"/> <xs:attribute name="_doctype-system" type="xs:string"/> <xs:attribute name="_encoding" type="xs:string"/> <xs:attribute name="_escape-uri-attributes" type="xs:string"/> <xs:attribute name="_html-version" type="xs:string"/> <xs:attribute name="_include-content-type" type="xs:string"/> <xs:attribute name="_indent" type="xs:string"/> <xs:attribute name="_item-separator" type="xs:string"/> <xs:attribute name="_media-type" type="xs:string"/> <xs:attribute name="_normalization-form" type="xs:string"/> <xs:attribute name="_omit-xml-declaration" type="xs:string"/> <xs:attribute name="_parameter-document" type="xs:string"/> <xs:attribute name="_standalone" type="xs:string"/> <xs:attribute name="_suppress-indentation" type="xs:string"/> <xs:attribute name="_undeclare-prefixes" type="xs:string"/> <xs:attribute name="_use-character-maps" type="xs:string"/> <xs:attribute name="_output-version" type="xs:string"/> <xs:assert test="not(exists(@type | @_type) and exists(@validation | @_validation))"> <xs:annotation> <xs:documentation> <p> The type and validation attributes are mutually exclusive (if one is present, the other must be absent). </p> </xs:documentation> </xs:annotation> </xs:assert> </xs:extension> </xs:complexContent> </xs:complexType> </xs:element> <xs:element name="sequence" substitutionGroup="xsl:instruction" type="xsl:sequence-constructor-or-select"/> <xs:element name="sort"> <xs:complexType> <xs:complexContent mixed="true"> <xs:extension base="xsl:sequence-constructor-or-select"> <xs:attribute name="lang" type="xsl:avt"/> <xs:attribute name="data-type" type="xsl:avt" default="text"/> <xs:attribute name="order" type="xsl:avt" default="ascending"/> <xs:attribute name="case-order" type="xsl:avt"/> <xs:attribute name="collation" type="xsl:avt"/> <xs:attribute name="stable" type="xsl:avt"/> <xs:attribute name="_lang" type="xs:string"/> <xs:attribute name="_data-type" type="xs:string"/> <xs:attribute name="_order" type="xs:string"/> <xs:attribute name="_case-order" type="xs:string"/> <xs:attribute name="_collation" type="xs:string"/> <xs:attribute name="_stable" type="xs:string"/> </xs:extension> </xs:complexContent> </xs:complexType> </xs:element> <xs:element name="source-document" substitutionGroup="xsl:instruction"> <xs:complexType> <xs:complexContent> <xs:extension base="xsl:sequence-constructor"> <xs:attribute name="href" type="xsl:avt"/> <xs:attribute name="streamable" type="xsl:yes-or-no" default="no"/> <xs:attribute name="use-accumulators" type="xsl:accumulator-names"/> <xs:attribute name="type" type="xsl:EQName"/> <xs:attribute name="validation" type="xsl:validation-type"/> <xs:attribute name="_href" type="xs:string"/> <xs:attribute name="_streamable" type="xs:string"/> <xs:attribute name="_use-accumulators" type="xs:string"/> <xs:attribute name="_type" type="xs:string"/> <xs:attribute name="_validation" type="xs:string"/> <xs:assert test="exists(@href | @_href)"/> <xs:assert test="not(exists(@type | @_type) and exists(@validation | @_validation))"> <xs:annotation> <xs:documentation> <p> The type and validation attributes are mutually exclusive (if one is present, the other must be absent). </p> </xs:documentation> </xs:annotation> </xs:assert> </xs:extension> </xs:complexContent> </xs:complexType> </xs:element> <xs:element name="strip-space" substitutionGroup="xsl:declaration"> <xs:complexType> <xs:complexContent> <xs:extension base="xsl:element-only-versioned-element-type"> <xs:attribute name="elements" type="xsl:nametests"/> <xs:attribute name="_elements" type="xs:string"/> <xs:assert test="exists(@elements | @_elements)"/> </xs:extension> </xs:complexContent> </xs:complexType> </xs:element> <xs:element name="stylesheet" substitutionGroup="xsl:transform"/> <xs:element name="template" substitutionGroup="xsl:declaration"> <xs:complexType> <xs:complexContent mixed="true"> <xs:extension base="xsl:versioned-element-type"> <xs:sequence> <xs:element ref="xsl:context-item" minOccurs="0" maxOccurs="1"/> <xs:element ref="xsl:param" minOccurs="0" maxOccurs="unbounded"/> <xs:group ref="xsl:sequence-constructor-group" minOccurs="0" maxOccurs="unbounded"/> </xs:sequence> <xs:attribute name="match" type="xsl:pattern"/> <xs:attribute name="priority" type="xs:decimal"/> <xs:attribute name="mode" type="xsl:modes"/> <xs:attribute name="name" type="xsl:EQName"/> <xs:attribute name="as" type="xsl:sequence-type" default="item()*"/> <xs:attribute name="visibility" type="xsl:visibility-type"/> <xs:attribute name="_match" type="xs:string"/> <xs:attribute name="_priority" type="xs:string"/> <xs:attribute name="_mode" type="xs:string"/> <xs:attribute name="_name" type="xs:string"/> <xs:attribute name="_as" type="xs:string"/> <xs:attribute name="_visibility" type="xs:string"/> <xs:assert test="exists(@match | @_match) or exists(@name | @_name)"> <xs:annotation> <xs:documentation> <p> An xsl:template element must have either a match attribute or a name attribute, or both. </p> </xs:documentation> </xs:annotation> </xs:assert> <xs:assert test="if (empty(@match | @_match)) then (empty(@mode | @_mode) and empty(@priority | @_priority)) else true()"> <xs:annotation> <xs:documentation> <p> An xsl:template element that has no match attribute must have no mode attribute and no priority attribute. </p> </xs:documentation> </xs:annotation> </xs:assert> <xs:assert test="not(exists(@visibility | @_visibility) and empty(@name | @_name))"> <xs:annotation> <xs:documentation> <p> An xsl:template element that has no name attribute must have no visibility attribute </p> </xs:documentation> </xs:annotation> </xs:assert> <xs:assert test="if (normalize-space(@visibility) = 'abstract') then empty(* except (xsl:context-item, xsl:param)) else true()"> <xs:annotation> <xs:documentation> <p> If the visibility attribute is present with the value abstract then (a) the sequence constructor defining the template body must be empty: that is, the only permitted children are xsl:context-item and xsl:param </p> </xs:documentation> </xs:annotation> </xs:assert> <xs:assert test="not(normalize-space(@visibility) = 'abstract' and exists(@match))"> <xs:annotation> <xs:documentation> <p> If the visibility attribute is present with the value abstract then there must be no match attribute. </p> </xs:documentation> </xs:annotation> </xs:assert> <xs:assert test="every $e in xsl:param satisfies empty($e/(@visibility | @_visibility))"> <xs:annotation> <xs:documentation> <p> A parameter for a template must have no visibility attribute. </p> </xs:documentation> </xs:annotation> </xs:assert> </xs:extension> </xs:complexContent> </xs:complexType> </xs:element> <xs:complexType name="text-element-base-type"> <xs:simpleContent> <xs:restriction base="xsl:versioned-element-type"> <xs:simpleType> <xs:restriction base="xs:string"/> </xs:simpleType> <xs:anyAttribute namespace="##other" processContents="lax"/> </xs:restriction> </xs:simpleContent> </xs:complexType> <xs:complexType name="text-element-type"> <xs:simpleContent> <xs:extension base="xsl:text-element-base-type"> <xs:attribute name="disable-output-escaping" type="xsl:yes-or-no" default="no"/> <xs:attribute name="_disable-output-escaping" type="xs:string"/> </xs:extension> </xs:simpleContent> </xs:complexType> <xs:element name="text" substitutionGroup="xsl:instruction" type="xsl:text-element-type"/> <xs:complexType name="transform-element-base-type"> <xs:complexContent> <xs:restriction base="xsl:element-only-versioned-element-type"> <xs:attribute name="version" type="xs:decimal" use="optional"/> <xs:attribute name="_version" type="xs:string"> <xs:annotation> <xs:documentation> <p> The version attribute indicates the version of XSLT that the stylesheet module requires. The attribute is required, unless the xsl:stylesheet element is a child of an xsl:package element, in which case it is optional: the default is then taken from the parent xsl:package element. </p> </xs:documentation> </xs:annotation> </xs:attribute> <xs:anyAttribute namespace="##other" processContents="lax"/> </xs:restriction> </xs:complexContent> </xs:complexType> <xs:element name="transform"> <xs:complexType> <xs:complexContent> <xs:extension base="xsl:transform-element-base-type"> <xs:sequence> <xs:choice minOccurs="0" maxOccurs="unbounded"> <xs:element ref="xsl:declaration"/> <xs:any namespace="##other" processContents="lax"/> <!-- weaker than XSLT 1.0 --> </xs:choice> </xs:sequence> <xs:attribute name="id" type="xs:ID"/> <xs:attribute name="input-type-annotations" type="xsl:input-type-annotations-type" default="unspecified"/> <xs:attribute name="_id" type="xs:string"/> <xs:attribute name="_input-type-annotations" type="xs:string"/> <!--* The 'static' attribute may be used on 'param' and 'variable' * only when they are top-level elements. *--> <xs:assert test="every $v in (.//xsl:param, .//xsl:variable)[exists(@static | @_static)] satisfies $v[parent::xsl:stylesheet or parent::xsl:transform or parent::xsl:override]"> <xs:annotation> <xs:documentation> <p> The static attribute must not be present on an xsl:variable or xsl:param element unless it is a top-level element. </p> </xs:documentation> </xs:annotation> </xs:assert> <xs:assert test="every $prefix in (@exclude-result-prefixes[not(. = '#all')], @extension-element-prefixes) satisfies ((if ($prefix = '#default') then '' else $prefix) = in-scope-prefixes(.))"> <xs:annotation> <xs:documentation> <p> XTSE0808: It is a static error if a namespace prefix is used within the [xsl:]exclude-result-prefixes attribute and there is no namespace binding in scope for that prefix. </p> <p> XTSE0809: It is a static error if the value #default is used within the [xsl:]exclude-result-prefixes attribute and the parent element of the [xsl:]exclude-result-prefixes attribute has no default namespace. </p> </xs:documentation> </xs:annotation> </xs:assert> </xs:extension> </xs:complexContent> </xs:complexType> </xs:element> <xs:element name="try" substitutionGroup="xsl:instruction"> <xs:complexType> <xs:complexContent mixed="true"> <xs:extension base="xsl:versioned-element-type"> <xs:sequence> <xs:group ref="xsl:sequence-constructor-group" minOccurs="0" maxOccurs="unbounded"/> <xs:element ref="xsl:catch" minOccurs="1" maxOccurs="1"/> <xs:choice minOccurs="0" maxOccurs="unbounded"> <xs:element ref="xsl:catch"/> <xs:element ref="xsl:fallback"/> </xs:choice> </xs:sequence> <xs:attribute name="rollback-output" type="xsl:yes-or-no" default="yes"/> <xs:attribute name="select" type="xsl:expression" use="optional"/> <xs:attribute name="_rollback-output" type="xs:string"/> <xs:attribute name="_select" type="xs:string"/> </xs:extension> </xs:complexContent> </xs:complexType> </xs:element> <xs:element name="use-package" substitutionGroup="xsl:declaration"> <xs:annotation> <xs:documentation> <p> This element appears as a child of xsl:package and defines a dependency of the containing package on another package, identified by URI in the name attribute. The package-version attribute indicates which version of the library package is required, or may indicate a range of versions. </p> </xs:documentation> </xs:annotation> <xs:complexType> <xs:complexContent mixed="false"> <xs:extension base="xsl:element-only-versioned-element-type"> <xs:choice minOccurs="0" maxOccurs="unbounded"> <xs:element ref="xsl:accept"/> <xs:element ref="xsl:override"/> </xs:choice> <xs:attribute name="name" type="xs:anyURI"/> <xs:attribute name="package-version" type="xs:string"/> <xs:attribute name="_name" type="xs:string"/> <xs:attribute name="_package-version" type="xs:string"/> </xs:extension> </xs:complexContent> </xs:complexType> </xs:element> <xs:element name="value-of" substitutionGroup="xsl:instruction"> <xs:complexType> <xs:complexContent mixed="true"> <xs:extension base="xsl:sequence-constructor-or-select"> <xs:attribute name="separator" type="xsl:avt"/> <xs:attribute name="disable-output-escaping" type="xsl:yes-or-no" default="no"/> <xs:attribute name="_separator" type="xs:string"/> <xs:attribute name="_disable-output-escaping" type="xs:string"/> </xs:extension> </xs:complexContent> </xs:complexType> </xs:element> <xs:element name="variable" substitutionGroup="xsl:declaration xsl:instruction"> <xs:annotation> <xs:documentation> <p> Declaration of the xsl:variable element, used both for local and global variable bindings. </p> <p> This definition takes advantage of the ability in XSD 1.1 for an element to belong to more than one substitution group. A global variable is a declaration, while a local variable can appear as an instruction in a sequence constructor. </p> </xs:documentation> </xs:annotation> <xs:complexType> <xs:complexContent mixed="true"> <xs:extension base="xsl:sequence-constructor-or-select"> <xs:attribute name="name" type="xsl:EQName"/> <xs:attribute name="as" type="xsl:sequence-type"/> <xs:attribute name="visibility" type="xsl:visibility-type"/> <xs:attribute name="static" type="xsl:yes-or-no"/> <xs:attribute name="_name" type="xs:string"/> <xs:attribute name="_as" type="xs:string"/> <xs:attribute name="_visibility" type="xs:string"/> <xs:attribute name="_static" type="xs:string"/> <xs:assert test="exists(@name | @_name)"/> <xs:assert test="if (normalize-space(@static) = ('yes', 'true', '1')) then (exists(@_visibility) or normalize-space(@visibility) = ('', 'private', 'final')) else true()"> <xs:annotation> <xs:documentation> <p> When the static attribute is present with the value yes, the visibility attribute must not have a value other than private or final. </p> </xs:documentation> </xs:annotation> </xs:assert> <xs:assert test="if (normalize-space(@static) = ('yes', 'true', '1')) then (empty((*, text())) and exists(@select | @_select)) else true()"> <xs:annotation> <xs:documentation> <p> When the attribute static="yes" is specified, the xsl:variable element must have empty content, and the select attribute must be present to define the value of the variable. </p> </xs:documentation> </xs:annotation> </xs:assert> </xs:extension> </xs:complexContent> </xs:complexType> </xs:element> <xs:element name="when"> <xs:complexType> <xs:complexContent mixed="true"> <xs:extension base="xsl:sequence-constructor"> <xs:attribute name="test" type="xsl:expression"/> <xs:attribute name="_test" type="xs:string"/> <xs:assert test="exists(@test | @_test)"/> </xs:extension> </xs:complexContent> </xs:complexType> </xs:element> <xs:element name="where-populated" substitutionGroup="xsl:instruction" type="xsl:sequence-constructor"/> <xs:element name="with-param"> <xs:complexType> <xs:complexContent mixed="true"> <xs:extension base="xsl:sequence-constructor-or-select"> <xs:attribute name="name" type="xsl:EQName"/> <xs:attribute name="as" type="xsl:sequence-type"/> <xs:attribute name="tunnel" type="xsl:yes-or-no"/> <xs:attribute name="_name" type="xs:string"/> <xs:attribute name="_as" type="xs:string"/> <xs:attribute name="_tunnel" type="xs:string"/> <xs:assert test="exists(@name | @_name)"/> </xs:extension> </xs:complexContent> </xs:complexType> </xs:element> <!-- ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ --> <xs:annotation> <xs:documentation> <p> PART C: definition of literal result elements There are three ways to define the literal result elements permissible in a stylesheet. (a) do nothing. This allows any element to be used as a literal result element, provided it is not in the XSLT namespace (b) declare all permitted literal result elements as members of the xsl:literal-result-element substitution group (c) redefine the model group xsl:result-elements to accommodate all permitted literal result elements. Literal result elements are allowed to take certain attributes in the XSLT namespace. These are defined in the attribute group literal-result-element-attributes, which can be included in the definition of any literal result element. </p> </xs:documentation> </xs:annotation> <!-- ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ --> <xs:element name="literal-result-element" abstract="true" type="xs:anyType"/> <xs:attributeGroup name="literal-result-element-attributes"> <xs:attribute name="default-collation" form="qualified" type="xsl:uri-list"/> <xs:attribute name="default-mode" type="xsl:default-mode-type"/> <xs:attribute name="default-validation" type="xsl:validation-strip-or-preserve" default="strip"/> <xs:attribute name="expand-text" type="xsl:yes-or-no"/> <xs:attribute name="extension-element-prefixes" form="qualified" type="xsl:prefixes"/> <xs:attribute name="exclude-result-prefixes" form="qualified" type="xsl:prefixes"/> <xs:attribute name="xpath-default-namespace" form="qualified" type="xs:anyURI"/> <xs:attribute name="inherit-namespaces" form="qualified" type="xsl:yes-or-no" default="yes"/> <xs:attribute name="use-attribute-sets" form="qualified" type="xsl:EQNames" default=""/> <xs:attribute name="use-when" form="qualified" type="xsl:expression"/> <xs:attribute name="version" form="qualified" type="xs:decimal"/> <xs:attribute name="type" form="qualified" type="xsl:EQName"/> <xs:attribute name="validation" form="qualified" type="xsl:validation-type"/> </xs:attributeGroup> <xs:group name="result-elements"> <xs:choice> <xs:element ref="xsl:literal-result-element"/> <xs:any namespace="##other" processContents="lax"/> <xs:any namespace="##local" processContents="lax"/> </xs:choice> </xs:group> <!-- ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ --> <xs:annotation> <xs:documentation> <p> PART D: definitions of simple types used in stylesheet attributes </p> </xs:documentation> </xs:annotation> <!-- ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ --> <xs:simpleType name="accumulator-names"> <xs:annotation> <xs:documentation> <p> The use-accumulators attribute of xsl:source-document, xsl:merge-source, or xsl:global-context-item: either a list, each member being a QName; or the value #all </p> </xs:documentation> </xs:annotation> <xs:union> <xs:simpleType> <xs:list itemType="xsl:EQName"/> </xs:simpleType> <xs:simpleType> <xs:restriction base="xs:token"> <xs:enumeration value="#all"/> </xs:restriction> </xs:simpleType> </xs:union> </xs:simpleType> <xs:simpleType name="avt"> <xs:annotation> <xs:documentation> <p> This type is used for all attributes that allow an attribute value template. The general rules for the syntax of attribute value templates, and the specific rules for each such attribute, are described in the XSLT 2.1 Recommendation. </p> </xs:documentation> </xs:annotation> <xs:restriction base="xs:string"/> </xs:simpleType> <xs:simpleType name="char"> <xs:annotation> <xs:documentation> <p> A string containing exactly one character. </p> </xs:documentation> </xs:annotation> <xs:restriction base="xs:string"> <xs:length value="1"/> </xs:restriction> </xs:simpleType> <xs:simpleType name="component-kind-type"> <xs:annotation> <xs:documentation> <p> Describes a kind of component within a package. </p> </xs:documentation> </xs:annotation> <xs:restriction base="xs:token"> <xs:enumeration value="template"/> <xs:enumeration value="function"/> <xs:enumeration value="variable"/> <xs:enumeration value="attribute-set"/> <xs:enumeration value="mode"/> <xs:enumeration value="*"/> </xs:restriction> </xs:simpleType> <xs:simpleType name="default-mode-type"> <xs:annotation> <xs:documentation> <p> The default-mode attribute of xsl:stylesheet, xsl:transform, xsl:package (or any other xsl:* element): either a QName or #unnamed. </p> </xs:documentation> </xs:annotation> <xs:union memberTypes="xsl:EQName"> <xs:simpleType> <xs:restriction base="xs:token"> <xs:enumeration value="#unnamed"/> </xs:restriction> </xs:simpleType> </xs:union> </xs:simpleType> <xs:simpleType name="expression"> <xs:annotation> <xs:documentation> <p> An XPath 2.0 expression. </p> </xs:documentation> </xs:annotation> <xs:restriction base="xs:token"> <xs:pattern value=".+"/> </xs:restriction> </xs:simpleType> <xs:simpleType name="item-type"> <xs:annotation> <xs:documentation> <p> An XPath 2.1 ItemType </p> </xs:documentation> </xs:annotation> <xs:restriction base="xs:token"> <xs:pattern value=".+"/> </xs:restriction> </xs:simpleType> <xs:simpleType name="input-type-annotations-type"> <xs:annotation> <xs:documentation> <p> Describes how type annotations in source documents are handled. </p> </xs:documentation> </xs:annotation> <xs:restriction base="xs:token"> <xs:enumeration value="preserve"/> <xs:enumeration value="strip"/> <xs:enumeration value="unspecified"/> </xs:restriction> </xs:simpleType> <xs:simpleType name="level"> <xs:annotation> <xs:documentation> <p> The level attribute of xsl:number: one of single, multiple, or any. </p> </xs:documentation> </xs:annotation> <xs:restriction base="xs:token"> <xs:enumeration value="single"/> <xs:enumeration value="multiple"/> <xs:enumeration value="any"/> </xs:restriction> </xs:simpleType> <xs:simpleType name="mode"> <xs:annotation> <xs:documentation> <p> The mode attribute of xsl:apply-templates: either a QName, or #current, or #unnamed, or #default. </p> </xs:documentation> </xs:annotation> <xs:union memberTypes="xsl:EQName"> <xs:simpleType> <xs:restriction base="xs:token"> <xs:enumeration value="#default"/> <xs:enumeration value="#unnamed"/> <xs:enumeration value="#current"/> </xs:restriction> </xs:simpleType> </xs:union> </xs:simpleType> <xs:simpleType name="modes"> <xs:annotation> <xs:documentation> <p> The mode attribute of xsl:template: either a list, each member being either a QName or #default or #unnamed; or the value #all </p> </xs:documentation> </xs:annotation> <xs:union> <xs:simpleType> <xs:restriction> <xs:simpleType> <xs:list> <xs:simpleType> <xs:union memberTypes="xsl:EQName"> <xs:simpleType> <xs:restriction base="xs:token"> <xs:enumeration value="#default"/> <xs:enumeration value="#unnamed"/> </xs:restriction> </xs:simpleType> </xs:union> </xs:simpleType> </xs:list> </xs:simpleType> <xs:assertion test="count($value) = count(distinct-values($value))"> <xs:annotation> <xs:documentation> <p> XTSE0550: It is a static error if the same token is included more than once in the list. </p> </xs:documentation> </xs:annotation> </xs:assertion> </xs:restriction> </xs:simpleType> <xs:simpleType> <xs:restriction base="xs:token"> <xs:enumeration value="#all"/> </xs:restriction> </xs:simpleType> </xs:union> </xs:simpleType> <xs:simpleType name="nametests"> <xs:annotation> <xs:documentation> <p> A list of NameTests, as defined in the XPath 2.0 Recommendation. Each NameTest is either a QName, or "*", or "prefix:*", or "*:localname" </p> </xs:documentation> </xs:annotation> <xs:list> <xs:simpleType> <xs:union memberTypes="xsl:EQName"> <xs:simpleType> <xs:restriction base="xs:token"> <xs:enumeration value="*"/> </xs:restriction> </xs:simpleType> <xs:simpleType> <xs:restriction base="xs:token"> <xs:pattern value="\i\c*:\*"/> <xs:pattern value="\*:\i\c*"/> </xs:restriction> </xs:simpleType> </xs:union> </xs:simpleType> </xs:list> </xs:simpleType> <xs:simpleType name="on-multiple-match-type"> <xs:annotation> <xs:documentation> <p> Describes the action to be taken when there are several template rules to match an item in a given mode. </p> </xs:documentation> </xs:annotation> <xs:restriction base="xs:token"> <xs:enumeration value="use-last"/> <xs:enumeration value="fail"/> </xs:restriction> </xs:simpleType> <xs:simpleType name="on-no-match-type"> <xs:annotation> <xs:documentation> <p> Describes the action to be taken when there is no template rule to match an item in a given mode. </p> </xs:documentation> </xs:annotation> <xs:restriction base="xs:token"> <xs:enumeration value="deep-copy"/> <xs:enumeration value="shallow-copy"/> <xs:enumeration value="deep-skip"/> <xs:enumeration value="shallow-skip"/> <xs:enumeration value="text-only-copy"/> <xs:enumeration value="fail"/> </xs:restriction> </xs:simpleType> <xs:simpleType name="prefixes"> <xs:list itemType="xs:NCName"/> </xs:simpleType> <xs:simpleType name="prefix-list-or-all"> <xs:union memberTypes="xsl:prefix-list"> <xs:simpleType> <xs:restriction base="xs:token"> <xs:enumeration value="#all"/> </xs:restriction> </xs:simpleType> </xs:union> </xs:simpleType> <xs:simpleType name="prefix-list"> <xs:list itemType="xsl:prefix-or-default"/> </xs:simpleType> <xs:simpleType name="method"> <xs:annotation> <xs:documentation> <p> The method attribute of xsl:output: Either one of the recognized names "xml", "xhtml", "html", "text", or a QName that must include a prefix. </p> </xs:documentation> </xs:annotation> <xs:union> <xs:simpleType> <xs:restriction base="xs:token"> <xs:enumeration value="xml"/> <xs:enumeration value="xhtml"/> <xs:enumeration value="html"/> <xs:enumeration value="text"/> </xs:restriction> </xs:simpleType> <xs:simpleType> <xs:restriction base="xsl:EQName"> <xs:pattern value="\c*:\c*"/> </xs:restriction> </xs:simpleType> </xs:union> </xs:simpleType> <xs:simpleType name="pattern"> <xs:annotation> <xs:documentation> <p> A match pattern as defined in the XSLT 2.1 Recommendation. The syntax for patterns is a restricted form of the syntax for XPath 2.0 expressions. Change since XSLT 2.0: Patterns may now match any item (not only nodes) </p> </xs:documentation> </xs:annotation> <xs:restriction base="xsl:expression"/> </xs:simpleType> <xs:simpleType name="prefix-or-default"> <xs:annotation> <xs:documentation> <p> Either a namespace prefix, or #default. Used in the xsl:namespace-alias element. </p> </xs:documentation> </xs:annotation> <xs:union memberTypes="xs:NCName"> <xs:simpleType> <xs:restriction base="xs:token"> <xs:enumeration value="#default"/> </xs:restriction> </xs:simpleType> </xs:union> </xs:simpleType> <xs:simpleType name="EQNames"> <xs:annotation> <xs:documentation> <p> A list of QNames. Used in the [xsl:]use-attribute-sets attribute of various elements, and in the cdata-section-elements attribute of xsl:output </p> </xs:documentation> </xs:annotation> <xs:list itemType="xsl:EQName"/> </xs:simpleType> <xs:simpleType name="EQName"> <xs:annotation> <xs:documentation> <p> An extended QName. This schema does not use the built-in type xs:QName, but rather defines its own QName type. This may be either a local name, or a prefixed QName, or a name written using the extended QName notation Q{uri}local </p> <p> Although xs:QName would define the correct validation on these attributes, a schema processor would expand unprefixed QNames incorrectly when constructing the PSVI, because (as defined in XML Schema errata) an unprefixed xs:QName is assumed to be in the default namespace, which is not the correct assumption for XSLT. The datatype is therefore defined as a union of NCName and QName, so that an unprefixed name will be validated as an NCName and will therefore not be treated as having the semantics of an unprefixed xs:QName. </p> </xs:documentation> </xs:annotation> <xs:union memberTypes="xs:NCName xs:QName"> <xs:simpleType> <xs:restriction base="xs:token"> <xs:pattern value="Q\{[^{}]*\}[\i-[:]][\c-[:]]*"/> </xs:restriction> </xs:simpleType> </xs:union> </xs:simpleType> <xs:simpleType name="EQName-in-namespace"> <xs:annotation> <xs:documentation> <p> A subtype of EQNames that excludes no-namespace names </p> </xs:documentation> </xs:annotation> <xs:restriction base="xsl:EQName"> <xs:pattern value="Q\{.+\}.+|\i\c*:.+"/> </xs:restriction> </xs:simpleType> <xs:simpleType name="sequence-type"> <xs:annotation> <xs:documentation> <p> The description of a datatype, conforming to the SequenceType production defined in the XPath 2.0 Recommendation </p> </xs:documentation> </xs:annotation> <xs:restriction base="xs:token"> <xs:pattern value=".+"/> </xs:restriction> </xs:simpleType> <xs:simpleType name="streamability-type"> <xs:annotation> <xs:documentation> <p> Describes the category to which a function belongs, with regards to its streaming behavior. </p> </xs:documentation> </xs:annotation> <xs:union memberTypes="xsl:EQName-in-namespace"> <xs:simpleType> <xs:restriction base="xs:token"> <xs:enumeration value="unclassified"/> <xs:enumeration value="absorbing"/> <xs:enumeration value="inspection"/> <xs:enumeration value="filter"/> <xs:enumeration value="shallow-descent"/> <xs:enumeration value="deep-descent"/> <xs:enumeration value="ascent"/> </xs:restriction> </xs:simpleType> </xs:union> </xs:simpleType> <xs:simpleType name="typed-type"> <xs:annotation> <xs:documentation> <p> Describes whether a mode is designed to match typed or untyped nodes. </p> </xs:documentation> </xs:annotation> <xs:restriction base="xs:token"> <xs:enumeration value="yes"/> <xs:enumeration value="no"/> <xs:enumeration value="true"/> <xs:enumeration value="false"/> <xs:enumeration value="1"/> <xs:enumeration value="0"/> <xs:enumeration value="strict"/> <xs:enumeration value="lax"/> <xs:enumeration value="unspecified"/> </xs:restriction> </xs:simpleType> <xs:simpleType name="uri-list"> <xs:list itemType="xs:anyURI"/> </xs:simpleType> <xs:simpleType name="validation-strip-or-preserve"> <xs:annotation> <xs:documentation> <p> Describes different ways of type-annotating an element or attribute. </p> </xs:documentation> </xs:annotation> <xs:restriction base="xsl:validation-type"> <xs:enumeration value="preserve"/> <xs:enumeration value="strip"/> </xs:restriction> </xs:simpleType> <xs:simpleType name="validation-type"> <xs:annotation> <xs:documentation> <p> Describes different ways of type-annotating an element or attribute. </p> </xs:documentation> </xs:annotation> <xs:restriction base="xs:token"> <xs:enumeration value="strict"/> <xs:enumeration value="lax"/> <xs:enumeration value="preserve"/> <xs:enumeration value="strip"/> </xs:restriction> </xs:simpleType> <xs:simpleType name="visibility-type"> <xs:annotation> <xs:documentation> <p> Describes the visibility of a component within a package. </p> </xs:documentation> </xs:annotation> <xs:restriction base="xs:token"> <xs:enumeration value="public"/> <xs:enumeration value="private"/> <xs:enumeration value="final"/> <xs:enumeration value="abstract"/> <xs:enumeration value="hidden"/> </xs:restriction> </xs:simpleType> <xs:simpleType name="visibility-not-hidden-type"> <xs:annotation> <xs:documentation> <p> Describes the visibility of a component within a package. </p> </xs:documentation> </xs:annotation> <xs:restriction base="xsl:visibility-type"> <xs:enumeration value="public"/> <xs:enumeration value="private"/> <xs:enumeration value="final"/> <xs:enumeration value="abstract"/> </xs:restriction> </xs:simpleType> <xs:simpleType name="yes-or-no"> <xs:annotation> <xs:documentation> <p> One of the values "yes" or "no": the values "true" or "false", or "1" or "0" are accepted as synonyms. </p> </xs:documentation> </xs:annotation> <xs:restriction base="xs:token"> <xs:enumeration value="yes"/> <xs:enumeration value="no"/> <xs:enumeration value="true"/> <xs:enumeration value="false"/> <xs:enumeration value="1"/> <xs:enumeration value="0"/> </xs:restriction> </xs:simpleType> <xs:simpleType name="yes-or-no-or-maybe"> <xs:annotation> <xs:documentation> <p> One of the values "yes" or "no" or "omit". The values "true" or "false", or "1" or "0" are accepted as synonyms of "yes" and "no" respectively. </p> </xs:documentation> </xs:annotation> <xs:restriction base="xs:token"> <xs:enumeration value="yes"/> <xs:enumeration value="no"/> <xs:enumeration value="true"/> <xs:enumeration value="false"/> <xs:enumeration value="1"/> <xs:enumeration value="0"/> <xs:enumeration value="maybe"/> </xs:restriction> </xs:simpleType> <xs:simpleType name="yes-or-no-or-omit"> <xs:annotation> <xs:documentation> <p> One of the values "yes" or "no" or "omit". The values "true" or "false", or "1" or "0" are accepted as synonyms of "yes" and "no" respectively. </p> </xs:documentation> </xs:annotation> <xs:restriction base="xs:token"> <xs:enumeration value="yes"/> <xs:enumeration value="no"/> <xs:enumeration value="true"/> <xs:enumeration value="false"/> <xs:enumeration value="1"/> <xs:enumeration value="0"/> <xs:enumeration value="omit"/> </xs:restriction> </xs:simpleType> <xs:simpleType name="zero-digit"> <xs:annotation> <xs:documentation> <p> A digit that has the numerical value zero. </p> </xs:documentation> </xs:annotation> <xs:restriction base="xsl:char"> <xs:pattern value="\p{Nd}"/> <xs:assertion test="matches(string-join(codepoints-to-string( for $i in 0 to 9 return string-to-codepoints($value) + $i), ''), '\p{Nd}{10}')"/> </xs:restriction> </xs:simpleType> </xs:schema>
The following Relax-NG schema may be used to validate XSLT 3.0 stylesheet modules. Similar caveats apply as for the XSD 1.1 version.
A copy of this schema is available at schema-for-xslt30.rnc
# XSLT 3.0 Relax NG Schema # # Copyright (c) 2010-2016, Mohamed ZERGAOUI (Innovimax) # # All rights reserved. # # Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: # Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. # Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. # Neither the name of the Mohamed ZERGAOUI or Innovimax nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. # # THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS # FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES # (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, # STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. # namespace local = "" default namespace xsl = "http://www.w3.org/1999/XSL/Transform" namespace xs = "http://www.w3.org/2001/XMLSchema" start = stylesheet.element | transform.element | package.element | literal-result-element-as-stylesheet sequence-constructor.model = (instruction.category | literal-result-element | text)* literal-result-element-as-stylesheet = element * - xsl:* { attribute xsl:version { decimal.datatype }, literal-result-element-no-version.atts, sequence-constructor.model } literal-result-element = element * - xsl:* { literal-result-element.atts, sequence-constructor.model } literal-result-element.atts = literal-result-element-no-version.atts, attribute xsl:version { text }? # These attributes may also appear on a literal result element, but in this case, to distinguish them from user-defined attributes, # the names of the attributes are in the XSLT namespace. They are thus typically written as # xsl:default-collation, # xsl:default-mode, # xsl:default-validation, # xsl:exclude-result-prefixes, # xsl:expand-text, # xsl:extension-element-prefixes, # xsl:use-when, # xsl:version, # or xsl:xpath-default-namespace. literal-result-element-no-version.atts = attribute * - xsl:* { avt.datatype }* & attribute xsl:default-collation { uris.datatype }? & attribute xsl:default-mode { eqname.datatype | '#unnamed' }? & attribute xsl:default-validation { "preserve" | "strip" }? & attribute xsl:exclude-result-prefixes { exclude.prefixes.datatype }? # or prefixes.datatype ? & attribute xsl:expand-text { boolean.datatype }? & attribute xsl:extension-element-prefixes { extension.prefixes.datatype }? # or prefixes.datatype ? & attribute xsl:inherit-namespaces { boolean.datatype }? & attribute xsl:on-empty { expression.datatype }? & attribute xsl:use-attribute-sets { eqnames.datatype }? & attribute xsl:use-when { expression.datatype }? & attribute xsl:xpath-default-namespace { xsd:anyURI }? & (attribute xsl:type { eqname.datatype } | attribute xsl:validation { "strict" | "lax" | "preserve" | "strip" })? top-level-extension = element * - (xsl:* | local:*) { anyElement } anyElement = grammar { start = any any = (attribute * { text } | text | element * { any })* } extension.atts = attribute * - (xsl:* | local:*) { text }* declarations.model = (declaration.category | top-level-extension)* # [Definition: There are a number of standard attributes that may appear on any XSLT element: specifically # default-collation, # default-mode, # default-validation, # exclude-result-prefixes, # expand-text, # extension-element-prefixes, # use-when, # version, # and xpath-default-namespace.] global.atts = attribute default-collation { uris.datatype }?, attribute _default-collation { avt.datatype }?, attribute default-mode { eqname.datatype | '#unnamed' }?, attribute _default-mode { avt.datatype }?, attribute default-validation { "preserve" | "strip" }?, attribute _default-validation { avt.datatype }?, attribute exclude-result-prefixes { exclude.prefixes.datatype }?, attribute _exclude-result-prefixes { avt.datatype }?, # or prefixes.datatype ? attribute expand-text { boolean.datatype }?, attribute _expand-text { avt.datatype }?, attribute extension-element-prefixes { extension.prefixes.datatype }?, attribute _extension-element-prefixes { avt.datatype }?, # or prefixes.datatype ? attribute use-when { expression.datatype }?, attribute _use-when { avt.datatype }?, attribute version { decimal.datatype }?, attribute _version { avt.datatype }?, attribute xpath-default-namespace { uri.datatype }?, attribute _xpath-default-namespace { avt.datatype }? global.atts.except.version = attribute default-collation { uris.datatype }?, attribute _default-collation { avt.datatype }?, attribute exclude-result-prefixes { exclude.prefixes.datatype }?, attribute _exclude-result-prefixes { avt.datatype }?, # or prefixes.datatype ? attribute expand-text { boolean.datatype }?, attribute _expand-text { avt.datatype }?, attribute extension-element-prefixes { extension.prefixes.datatype }?, attribute _extension-element-prefixes { avt.datatype }?, # or prefixes.datatype ? attribute use-when { expression.datatype }?, attribute _use-when { avt.datatype }?, attribute xpath-default-namespace { uri.datatype }?, attribute _xpath-default-namespace { avt.datatype }? qname.datatype = xsd:QName # Extract from XPath 3.0 #[94] EQName ::= QName | URIQualifiedName #[104] QName ::= [http://www.w3.org/TR/REC-xml-names/#NT-QName]Names #[105] NCName ::= [http://www.w3.org/TR/REC-xml-names/#NT-NCName]Names #[99] URIQualifiedName ::= BracedURILiteral NCName #[100] BracedURILiteral ::= "Q" "{" [^{}]* "}" uri.qualified.name = xsd:token { pattern = "Q\{[^\{\}]*\}[\i-[:]][\c-[:]]*" } qname.strict = xsd:token { pattern = "[\i-[:]][\c-[:]]:[\i-[:]][\c-[:]]" } eqname.datatype = xsd:QName | uri.qualified.name | qname.strict qnames.datatype = list { qname.datatype* } eqnames.datatype = list { eqname.datatype* } ncname.datatype = xsd:NCName prefix.datatype = xsd:NCName boolean.datatype = "yes" | "no" | "true" | "false" | "0" | "1" expression.datatype = text char.datatype = xsd:string { length = "1" } string.datatype = text id.datatype = xsd:NCName tokens.datatype = list { token* } prefixes.datatype = list { token* } extension.prefixes.datatype = list { xsd:NCName* } exclude.prefixes.datatype = list { "#all" | (xsd:NCName | "#default")* } token.datatype = token language.datatype = xsd:language nmtoken.datatype = xsd:NMTOKEN decimal.datatype = xsd:decimal integer.datatype = xsd:integer uri.datatype = xsd:anyURI uris.datatype = list { xsd:anyURI* } pattern.datatype = text qname-but-not-ncname.datatype = xsd:QName { pattern = ".*:.*" } xs_schema.element = element xs:schema { anyElement* } item-type.datatype = text sequence-type.datatype = text declaration.category = use-package.element | include.element | import.element | import-schema.element | strip-space.element | preserve-space.element | decimal-format.element | template.element | mode.element | global-context-item.element | variable.element | param.element | attribute-set.element | function.element | namespace-alias.element | accumulator.element | key.element | output.element | character-map.element instruction.category = apply-templates.element | apply-imports.element | next-match.element | for-each.element | iterate.element | next-iteration.element | break.element | if.element | choose.element | try.element | variable.element | call-template.element | evaluate.element | element.element | attribute.element | text.element | value-of.element | document.element | processing-instruction.element | namespace.element | comment.element | copy.element | copy-of.element | sequence.element | where-populated.element | on-empty.element | on-non-empty.element | number.element | perform-sort.element | for-each-group.element | merge.element | fork.element | analyze-string.element | source-document.element | map.element | map-entry.element | message.element | assert.element | fallback.element | result-document.element package.element = element package { extension.atts, attribute id { id.datatype }?, attribute _id { avt.datatype }?, attribute name { uri.datatype }?, attribute _name { avt.datatype }?, attribute package-version { string.datatype }?, attribute _package-version { avt.datatype }?, attribute version { decimal.datatype }?, attribute _version { avt.datatype }?, attribute input-type-annotations { "preserve" | "strip" | "unspecified" }?, attribute _input-type-annotations { avt.datatype }?, attribute declared-modes { boolean.datatype }?, attribute _declared-modes { avt.datatype }?, attribute default-mode { eqname.datatype | "#unnamed" }?, attribute _default-mode { avt.datatype }?, attribute default-validation { "preserve" | "strip" }?, attribute _default-validation { avt.datatype }?, attribute default-collation { uris.datatype }?, attribute _default-collation { avt.datatype }?, attribute extension-element-prefixes { prefixes.datatype }?, attribute _extension-element-prefixes { avt.datatype }?, attribute exclude-result-prefixes { prefixes.datatype }?, attribute _exclude-result-prefixes { avt.datatype }?, attribute expand-text { boolean.datatype }?, attribute _expand-text { avt.datatype }?, attribute use-when { expression.datatype }?, attribute _use-when { avt.datatype }?, attribute xpath-default-namespace { uri.datatype }?, attribute _xpath-default-namespace { avt.datatype }?, ((expose.element | declarations.model)*) } use-package.element = element use-package { extension.atts, global.atts, attribute name { uri.datatype }?, attribute _name { avt.datatype }?, attribute package-version { string.datatype }?, attribute _package-version { avt.datatype }?, (accept.element | override.element)* } expose.element = element expose { extension.atts, global.atts, attribute component { "template" | "function" | "attribute-set" | "variable" | "mode" | "*" }?, attribute _component { avt.datatype }?, attribute names { tokens.datatype }?, attribute _names { avt.datatype }?, attribute visibility { "public" | "private" | "final" | "abstract" }?, attribute _visibility { avt.datatype }?, empty } accept.element = element accept { extension.atts, global.atts, (attribute component { "template" | "function" | "attribute-set" | "variable" | "mode" | "*" } | attribute _component { avt.datatype })+, (attribute names { tokens.datatype } | attribute _names { avt.datatype })+, (attribute visibility { "public" | "private" | "final" | "abstract" | "hidden" } | attribute _visibility { avt.datatype })+, empty } override.element = element override { extension.atts, global.atts, (template.element | function.element | variable.element | param.element | attribute-set.element)* } stylesheet.element = element stylesheet { extension.atts, attribute id { id.datatype }?, attribute _id { avt.datatype }?, attribute version { decimal.datatype }?, attribute _version { avt.datatype }?, attribute default-mode { eqname.datatype | "#unnamed" }?, attribute _default-mode { avt.datatype }?, attribute default-validation { "preserve" | "strip" }?, attribute _default-validation { avt.datatype }?, attribute input-type-annotations { "preserve" | "strip" | "unspecified" }?, attribute _input-type-annotations { avt.datatype }?, attribute default-collation { uris.datatype }?, attribute _default-collation { avt.datatype }?, attribute extension-element-prefixes { prefixes.datatype }?, attribute _extension-element-prefixes { avt.datatype }?, attribute exclude-result-prefixes { prefixes.datatype }?, attribute _exclude-result-prefixes { avt.datatype }?, attribute expand-text { boolean.datatype }?, attribute _expand-text { avt.datatype }?, attribute use-when { expression.datatype }?, attribute _use-when { avt.datatype }?, attribute xpath-default-namespace { uri.datatype }?, attribute _xpath-default-namespace { avt.datatype }?, (declarations.model) } transform.element = element transform { extension.atts, attribute id { id.datatype }?, attribute _id { avt.datatype }?, attribute version { decimal.datatype }?, attribute _version { avt.datatype }?, attribute default-mode { eqname.datatype | "#unnamed" }?, attribute _default-mode { avt.datatype }?, attribute default-validation { "preserve" | "strip" }?, attribute _default-validation { avt.datatype }?, attribute input-type-annotations { "preserve" | "strip" | "unspecified" }?, attribute _input-type-annotations { avt.datatype }?, attribute default-collation { uris.datatype }?, attribute _default-collation { avt.datatype }?, attribute extension-element-prefixes { prefixes.datatype }?, attribute _extension-element-prefixes { avt.datatype }?, attribute exclude-result-prefixes { prefixes.datatype }?, attribute _exclude-result-prefixes { avt.datatype }?, attribute expand-text { boolean.datatype }?, attribute _expand-text { avt.datatype }?, attribute use-when { expression.datatype }?, attribute _use-when { avt.datatype }?, attribute xpath-default-namespace { uri.datatype }?, attribute _xpath-default-namespace { avt.datatype }?, (declarations.model) } include.element = element include { extension.atts, global.atts, attribute href { uri.datatype }?, attribute _href { avt.datatype }?, empty } import.element = element import { extension.atts, global.atts, (attribute href { uri.datatype } | attribute _href { avt.datatype })+, empty } import-schema.element = element import-schema { extension.atts, global.atts, attribute namespace { uri.datatype }?, attribute _namespace { avt.datatype }?, attribute schema-location { uri.datatype }?, attribute _schema-location { avt.datatype }?, xs_schema.element? } strip-space.element = element strip-space { extension.atts, global.atts, (attribute elements { tokens.datatype } | attribute _elements { avt.datatype })+, empty } preserve-space.element = element preserve-space { extension.atts, global.atts, (attribute elements { tokens.datatype } | attribute _elements { avt.datatype })+, empty } decimal-format.element = element decimal-format { extension.atts, global.atts, attribute name { eqname.datatype }?, attribute _name { avt.datatype }?, attribute decimal-separator { char.datatype }?, attribute _decimal-separator { avt.datatype }?, attribute grouping-separator { char.datatype }?, attribute _grouping-separator { avt.datatype }?, attribute infinity { string.datatype }?, attribute _infinity { avt.datatype }?, attribute minus-sign { char.datatype }?, attribute _minus-sign { avt.datatype }?, attribute exponent-separator { char.datatype }?, attribute _exponent-separator { avt.datatype }?, attribute NaN { string.datatype }?, attribute _NaN { avt.datatype }?, attribute percent { char.datatype }?, attribute _percent { avt.datatype }?, attribute per-mille { char.datatype }?, attribute _per-mille { avt.datatype }?, attribute zero-digit { char.datatype }?, attribute _zero-digit { avt.datatype }?, attribute digit { char.datatype }?, attribute _digit { avt.datatype }?, attribute pattern-separator { char.datatype }?, attribute _pattern-separator { avt.datatype }?, empty } template.element = element template { extension.atts, global.atts, (attribute match { pattern.datatype } | attribute _match { avt.datatype } | attribute name { eqname.datatype } | attribute _name { avt.datatype })+, attribute priority { decimal.datatype }?, attribute _priority { avt.datatype }?, attribute mode { list { '#all' | ('#default' | '#unnamed' | eqname.datatype)* } }?, attribute _mode { avt.datatype }?, attribute as { sequence-type.datatype }?, attribute _as { avt.datatype }?, attribute visibility { "public" | "private" | "final" | "abstract" }?, attribute _visibility { avt.datatype }?, (context-item.element?, param.element*, sequence-constructor.model) } apply-templates.element = element apply-templates { extension.atts, global.atts, attribute select { expression.datatype }?, attribute _select { avt.datatype }?, attribute mode { (eqname.datatype | '#unnamed' | '#default' | '#current') }?, attribute _mode { avt.datatype }?, (sort.element | with-param.element)* } mode.element = element mode { extension.atts, global.atts, attribute name { eqname.datatype }?, attribute _name { avt.datatype }?, attribute streamable { boolean.datatype }?, attribute _streamable { avt.datatype }?, attribute on-no-match { "deep-copy" | "shallow-copy" | "deep-skip" | "shallow-skip" | "text-only-copy" | "fail" }?, attribute _on-no-match { avt.datatype }?, attribute on-multiple-match { "use-last" | "fail" }?, attribute _on-multiple-match { avt.datatype }?, attribute warning-on-no-match { boolean.datatype }?, attribute _warning-on-no-match { avt.datatype }?, attribute warning-on-multiple-match { boolean.datatype }?, attribute _warning-on-multiple-match { avt.datatype }?, attribute typed { boolean.datatype | "strict" | "lax" | "unspecified" }?, attribute _typed { avt.datatype }?, attribute visibility { "public" | "private" | "final" }?, attribute _visibility { avt.datatype }?, attribute use-accumulators { tokens.datatype }?, attribute _use-accumulators { avt.datatype }?, empty } context-item.element = element context-item { extension.atts, global.atts, attribute as { item-type.datatype }?, attribute _as { avt.datatype }?, attribute use { "required" | "optional" | "absent" }?, attribute _use { avt.datatype }?, empty } global-context-item.element = element global-context-item { extension.atts, global.atts, attribute as { item-type.datatype }?, attribute _as { avt.datatype }?, attribute use { "required" | "optional" | "absent" }?, attribute _use { avt.datatype }?, empty } apply-imports.element = element apply-imports { extension.atts, global.atts, with-param.element* } next-match.element = element next-match { extension.atts, global.atts, (with-param.element | fallback.element)* } for-each.element = element for-each { extension.atts, global.atts, (attribute select { expression.datatype } | attribute _select { avt.datatype })+, (sort.element*, sequence-constructor.model) } iterate.element = element iterate { extension.atts, global.atts, (attribute select { expression.datatype } | attribute _select { avt.datatype })+, (param.element*, on-completion.element?, sequence-constructor.model) } next-iteration.element = element next-iteration { extension.atts, global.atts, (with-param.element*) } break.element = element break { extension.atts, global.atts, (attribute select { expression.datatype } | attribute _select { avt.datatype })?, sequence-constructor.model } on-completion.element = element on-completion { extension.atts, global.atts, attribute select { expression.datatype }?, attribute _select { avt.datatype }?, sequence-constructor.model } if.element = element if { extension.atts, global.atts, (attribute test { expression.datatype } | attribute _test { avt.datatype })+, sequence-constructor.model } choose.element = element choose { extension.atts, global.atts, (when.element+, otherwise.element?) } when.element = element when { extension.atts, global.atts, (attribute test { expression.datatype } | attribute _test { avt.datatype })+, sequence-constructor.model } otherwise.element = element otherwise { extension.atts, global.atts, sequence-constructor.model } try.element = element try { extension.atts, global.atts, attribute select { expression.datatype }?, attribute _select { avt.datatype }?, attribute rollback-output { boolean.datatype }?, attribute _rollback-output { avt.datatype }?, (sequence-constructor.model, catch.element, (catch.element | fallback.element)*) } catch.element = element catch { extension.atts, global.atts, attribute errors { tokens.datatype }?, attribute _errors { avt.datatype }?, attribute select { expression.datatype }?, attribute _select { avt.datatype }?, sequence-constructor.model } variable.element = element variable { extension.atts, global.atts, (attribute name { eqname.datatype } | attribute _name { avt.datatype })+, attribute select { expression.datatype }?, attribute _select { avt.datatype }?, attribute as { sequence-type.datatype }?, attribute _as { avt.datatype }?, attribute static { boolean.datatype }?, attribute _static { avt.datatype }?, attribute visibility { "public" | "private" | "final" | "abstract" }?, attribute _visibility { avt.datatype }?, sequence-constructor.model } param.element = element param { extension.atts, global.atts, (attribute name { eqname.datatype } | attribute _name { avt.datatype })+, attribute select { expression.datatype }?, attribute _select { avt.datatype }?, attribute as { sequence-type.datatype }?, attribute _as { avt.datatype }?, attribute required { boolean.datatype }?, attribute _required { avt.datatype }?, attribute tunnel { boolean.datatype }?, attribute _tunnel { avt.datatype }?, attribute static { boolean.datatype }?, attribute _static { avt.datatype }?, sequence-constructor.model } with-param.element = element with-param { extension.atts, global.atts, (attribute name { eqname.datatype } | attribute _name { avt.datatype })+, attribute select { expression.datatype }?, attribute _select { avt.datatype }?, attribute as { sequence-type.datatype }?, attribute _as { avt.datatype }?, attribute tunnel { boolean.datatype }?, attribute _tunnel { avt.datatype }?, sequence-constructor.model } call-template.element = element call-template { extension.atts, global.atts, (attribute name { eqname.datatype } | attribute _name { avt.datatype })+, with-param.element* } attribute-set.element = element attribute-set { extension.atts, global.atts, (attribute name { eqname.datatype } | attribute _name { avt.datatype })+, attribute use-attribute-sets { eqnames.datatype }?, attribute _use-attribute-sets { avt.datatype }?, attribute visibility { "public" | "private" | "final" | "abstract" }?, attribute _visibility { avt.datatype }?, attribute streamable { boolean.datatype }?, attribute _streamable { avt.datatype }?, attribute.element* } function.element = element function { extension.atts, global.atts, (attribute name { eqname.datatype } | attribute _name { avt.datatype })+, attribute as { sequence-type.datatype }?, attribute _as { avt.datatype }?, attribute visibility { "public" | "private" | "final" | "abstract" }?, attribute _visibility { avt.datatype }?, attribute streamability { "unclassified" | "absorbing" | "inspection" | "filter" | "shallow-descent" | "deep-descent" | "ascent" | eqname.datatype }?, attribute _streamability { avt.datatype }?, attribute override-extension-function { boolean.datatype }?, attribute _override-extension-function { avt.datatype }?, attribute override { boolean.datatype }?, attribute _override { avt.datatype }?, attribute new-each-time { "yes" | "true" | "1" | "no" | "false" | "0" | "maybe" }?, attribute _new-each-time { avt.datatype }?, attribute cache { boolean.datatype }?, attribute _cache { avt.datatype }?, (param.element*, sequence-constructor.model) } evaluate.element = element evaluate { extension.atts, global.atts, (attribute xpath { expression.datatype } | attribute _xpath { avt.datatype })+, attribute as { sequence-type.datatype }?, attribute _as { avt.datatype }?, attribute base-uri { uri.datatype | avt.datatype }?, attribute _base-uri { avt.datatype }?, attribute with-params { expression.datatype }?, attribute _with-params { avt.datatype }?, attribute context-item { expression.datatype }?, attribute _context-item { avt.datatype }?, attribute namespace-context { expression.datatype }?, attribute _namespace-context { avt.datatype }?, attribute schema-aware { boolean.datatype | avt.datatype }?, attribute _schema-aware { avt.datatype }?, (with-param.element | fallback.element)* } namespace-alias.element = element namespace-alias { extension.atts, global.atts, (attribute stylesheet-prefix { prefix.datatype | "#default" } | attribute _stylesheet-prefix { avt.datatype })+, (attribute result-prefix { prefix.datatype | "#default" } | attribute _result-prefix { avt.datatype })+, empty } element.element = element element { extension.atts, global.atts, (attribute name { qname.datatype | avt.datatype } | attribute _name { avt.datatype })+, attribute namespace { uri.datatype | avt.datatype }?, attribute _namespace { avt.datatype }?, attribute inherit-namespaces { boolean.datatype }?, attribute _inherit-namespaces { avt.datatype }?, attribute use-attribute-sets { eqnames.datatype }?, attribute _use-attribute-sets { avt.datatype }?, ((attribute type { eqname.datatype }?, attribute _type { avt.datatype }?) | (attribute validation { "strict" | "lax" | "preserve" | "strip" }?, attribute _validation { avt.datatype }? )), # type and validation are mutually exclusive sequence-constructor.model } attribute.element = element attribute { extension.atts, global.atts, (attribute name { qname.datatype | avt.datatype } | attribute _name { avt.datatype })+, attribute namespace { uri.datatype | avt.datatype }?, attribute _namespace { avt.datatype }?, attribute select { expression.datatype }?, attribute _select { avt.datatype }?, attribute separator { string.datatype | avt.datatype }?, attribute _separator { avt.datatype }?, ((attribute type { eqname.datatype }?, attribute _type { avt.datatype }?) | (attribute validation { "strict" | "lax" | "preserve" | "strip" }?, attribute _validation { avt.datatype }? )), # type and validation are mutually exclusive sequence-constructor.model } text.element = element text { extension.atts, global.atts, attribute disable-output-escaping { boolean.datatype }?, attribute _disable-output-escaping { avt.datatype }?, text } value-of.element = element value-of { extension.atts, global.atts, attribute select { expression.datatype }?, attribute _select { avt.datatype }?, attribute separator { string.datatype | avt.datatype }?, attribute _separator { avt.datatype }?, attribute disable-output-escaping { boolean.datatype }?, attribute _disable-output-escaping { avt.datatype }?, sequence-constructor.model } document.element = element document { extension.atts, global.atts, ((attribute type { eqname.datatype }?, attribute _type { avt.datatype }?) | (attribute validation { "strict" | "lax" | "preserve" | "strip" }?, attribute _validation { avt.datatype }? )), # type and validation are mutually exclusive sequence-constructor.model } processing-instruction.element = element processing-instruction { extension.atts, global.atts, (attribute name { ncname.datatype | avt.datatype } | attribute _name { avt.datatype })+, attribute select { expression.datatype }?, attribute _select { avt.datatype }?, sequence-constructor.model } namespace.element = element namespace { extension.atts, global.atts, (attribute name { ncname.datatype | avt.datatype } | attribute _name { avt.datatype })+, attribute select { expression.datatype }?, attribute _select { avt.datatype }?, sequence-constructor.model } comment.element = element comment { extension.atts, global.atts, attribute select { expression.datatype }?, attribute _select { avt.datatype }?, sequence-constructor.model } copy.element = element copy { extension.atts, global.atts, attribute select { expression.datatype }?, attribute _select { avt.datatype }?, attribute copy-namespaces { boolean.datatype }?, attribute _copy-namespaces { avt.datatype }?, attribute inherit-namespaces { boolean.datatype }?, attribute _inherit-namespaces { avt.datatype }?, attribute use-attribute-sets { eqnames.datatype }?, attribute _use-attribute-sets { avt.datatype }?, ((attribute type { eqname.datatype }?, attribute _type { avt.datatype }?) | (attribute validation { "strict" | "lax" | "preserve" | "strip" }?, attribute _validation { avt.datatype }? )), # type and validation are mutually exclusive sequence-constructor.model } copy-of.element = element copy-of { extension.atts, global.atts, (attribute select { expression.datatype } | attribute _select { avt.datatype })+, attribute copy-accumulators { boolean.datatype }?, attribute _copy-accumulators { avt.datatype }?, attribute copy-namespaces { boolean.datatype }?, attribute _copy-namespaces { avt.datatype }?, ((attribute type { eqname.datatype }?, attribute _type { avt.datatype }?) | (attribute validation { "strict" | "lax" | "preserve" | "strip" }?, attribute _validation { avt.datatype }? )), # type and validation are mutually exclusive empty } sequence.element = element sequence { extension.atts, global.atts, attribute select { expression.datatype }?, attribute _select { avt.datatype }?, sequence-constructor.model } where-populated.element = element where-populated { extension.atts, global.atts, sequence-constructor.model } on-empty.element = element on-empty { extension.atts, global.atts, attribute select { expression.datatype }?, attribute _select { avt.datatype }?, sequence-constructor.model } on-non-empty.element = element on-non-empty { extension.atts, global.atts, attribute select { expression.datatype }?, attribute _select { avt.datatype }?, sequence-constructor.model } number.element = element number { extension.atts, global.atts, attribute value { expression.datatype }?, attribute _value { avt.datatype }?, attribute select { expression.datatype }?, attribute _select { avt.datatype }?, attribute level { "single" | "multiple" | "any" }?, attribute _level { avt.datatype }?, attribute count { pattern.datatype }?, attribute _count { avt.datatype }?, attribute from { pattern.datatype }?, attribute _from { avt.datatype }?, attribute format { string.datatype | avt.datatype }?, attribute _format { avt.datatype }?, attribute lang { language.datatype | avt.datatype }?, attribute _lang { avt.datatype }?, attribute letter-value { "alphabetic" | "traditional" | avt.datatype }?, attribute _letter-value { avt.datatype }?, attribute ordinal { string.datatype | avt.datatype }?, attribute _ordinal { avt.datatype }?, attribute start-at { integer.datatype | avt.datatype }?, attribute _start-at { avt.datatype }?, attribute grouping-separator { char.datatype | avt.datatype }?, attribute _grouping-separator { avt.datatype }?, attribute grouping-size { integer.datatype | avt.datatype }?, attribute _grouping-size { avt.datatype }?, empty } sort.element = element sort { extension.atts, global.atts, attribute select { expression.datatype }?, attribute _select { avt.datatype }?, attribute lang { language.datatype | avt.datatype }?, attribute _lang { avt.datatype }?, attribute order { "ascending" | "descending" | avt.datatype }?, attribute _order { avt.datatype }?, attribute collation { uri.datatype | avt.datatype }?, attribute _collation { avt.datatype }?, attribute stable { boolean.datatype | avt.datatype }?, attribute _stable { avt.datatype }?, attribute case-order { "upper-first" | "lower-first" | avt.datatype }?, attribute _case-order { avt.datatype }?, attribute data-type { "text" | "number" | eqname.datatype | avt.datatype }?, attribute _data-type { avt.datatype }?, sequence-constructor.model } perform-sort.element = element perform-sort { extension.atts, global.atts, attribute select { expression.datatype }?, attribute _select { avt.datatype }?, (sort.element+, sequence-constructor.model) } for-each-group.element = element for-each-group { extension.atts, global.atts, (attribute select { expression.datatype } | attribute _select { avt.datatype })+, ((attribute group-by { expression.datatype }?, attribute _group-by { avt.datatype }?) | (attribute group-adjacent { expression.datatype }?, attribute _group-adjacent { avt.datatype }?) | (attribute group-starting-with { pattern.datatype }?, attribute _group-starting-with { avt.datatype }?) | (attribute group-ending-with { pattern.datatype }?, attribute _group-ending-with { avt.datatype }?)), attribute composite { boolean.datatype }?, attribute _composite { avt.datatype }?, attribute collation { uri.datatype | avt.datatype }?, attribute _collation { avt.datatype }?, (sort.element*, sequence-constructor.model) } merge.element = element merge { extension.atts, global.atts, (merge-source.element+, merge-action.element, fallback.element*) } merge-source.element = element merge-source { extension.atts, global.atts, attribute name { ncname.datatype }?, attribute _name { avt.datatype }?, attribute for-each-item { expression.datatype }?, attribute _for-each-item { avt.datatype }?, attribute for-each-stream { expression.datatype }?, attribute _for-each-stream { avt.datatype }?, (attribute select { expression.datatype } | attribute _select { avt.datatype })+, attribute streamable { boolean.datatype }?, attribute _streamable { avt.datatype }?, attribute use-accumulators { tokens.datatype }?, attribute _use-accumulators { avt.datatype }?, attribute sort-before-merge { boolean.datatype }?, attribute _sort-before-merge { avt.datatype }?, attribute validation { "strict" | "lax" | "preserve" | "strip" }?, attribute _validation { avt.datatype }?, attribute type { eqname.datatype }?, attribute _type { avt.datatype }?, attribute for-each-source { expression.datatype }?, attribute _for-each-source { avt.datatype }?, merge-key.element+ } merge-key.element = element merge-key { extension.atts, global.atts, attribute select { expression.datatype }?, attribute _select { avt.datatype }?, attribute lang { language.datatype | avt.datatype }?, attribute _lang { avt.datatype }?, attribute order { "ascending" | "descending" | avt.datatype }?, attribute _order { avt.datatype }?, attribute collation { uri.datatype | avt.datatype }?, attribute _collation { avt.datatype }?, attribute case-order { "upper-first" | "lower-first" | avt.datatype }?, attribute _case-order { avt.datatype }?, attribute data-type { "text" | "number" | eqname.datatype | avt.datatype }?, attribute _data-type { avt.datatype }?, sequence-constructor.model } merge-action.element = element merge-action { extension.atts, global.atts, sequence-constructor.model } fork.element = element fork { extension.atts, global.atts, (fallback.element*, ((sequence.element, fallback.element*)* | (for-each-group.element, fallback.element*))) } analyze-string.element = element analyze-string { extension.atts, global.atts, (attribute select { expression.datatype } | attribute _select { avt.datatype })+, (attribute regex { string.datatype | avt.datatype } | attribute _regex { avt.datatype })+, attribute flags { string.datatype | avt.datatype }?, attribute _flags { avt.datatype }?, (matching-substring.element?, non-matching-substring.element?, fallback.element*) } matching-substring.element = element matching-substring { extension.atts, global.atts, sequence-constructor.model } non-matching-substring.element = element non-matching-substring { extension.atts, global.atts, sequence-constructor.model } source-document.element = element source-document { extension.atts, global.atts, (attribute href { uri.datatype | avt.datatype } | attribute _href { avt.datatype })+, attribute use-accumulators { tokens.datatype }?, attribute _use-accumulators { avt.datatype }?, ((attribute type { eqname.datatype }?, attribute _type { avt.datatype }?) | (attribute validation { "strict" | "lax" | "preserve" | "strip" }?, attribute _validation { avt.datatype }? )), # type and validation are mutually exclusive attribute streamable { boolean.datatype }?, attribute _streamable { avt.datatype }?, sequence-constructor.model } accumulator.element = element accumulator { extension.atts, global.atts, (attribute name { eqname.datatype } | attribute _name { avt.datatype }), (attribute initial-value { expression.datatype } | attribute _initial-value { avt.datatype }), attribute as { sequence-type.datatype }?, attribute _as { avt.datatype }?, attribute streamable { boolean.datatype }?, attribute _streamable { avt.datatype }?, accumulator-rule.element+ } accumulator-rule.element = element accumulator-rule { extension.atts, global.atts, (attribute match { pattern.datatype } | attribute _match { avt.datatype })+, attribute phase { "start" | "end" }?, attribute _phase { avt.datatype }?, attribute select { expression.datatype }?, attribute _select { avt.datatype }?, sequence-constructor.model } key.element = element key { extension.atts, global.atts, (attribute name { eqname.datatype } | attribute _name { avt.datatype })+, (attribute match { pattern.datatype } | attribute _match { avt.datatype })+, attribute use { expression.datatype }?, attribute _use { avt.datatype }?, attribute composite { boolean.datatype }?, attribute _composite { avt.datatype }?, attribute collation { uri.datatype }?, attribute _collation { avt.datatype }?, sequence-constructor.model } map.element = element map { extension.atts, global.atts, sequence-constructor.model } map-entry.element = element map-entry { extension.atts, global.atts, (attribute key { expression.datatype } | attribute _key { avt.datatype }), attribute select { expression.datatype }?, attribute _select { avt.datatype }?, sequence-constructor.model } message.element = element message { extension.atts, global.atts, attribute select { expression.datatype }?, attribute _select { avt.datatype }?, attribute terminate { boolean.datatype | avt.datatype }?, attribute _terminate { avt.datatype }?, attribute error-code { eqname.datatype | avt.datatype }?, attribute _error-code { avt.datatype }?, sequence-constructor.model } assert.element = element assert { extension.atts, global.atts, (attribute test { expression.datatype } | attribute _test { avt.datatype })+, attribute select { expression.datatype }?, attribute _select { avt.datatype }?, attribute error-code { eqname.datatype | avt.datatype }?, attribute _error-code { avt.datatype }?, sequence-constructor.model } fallback.element = element fallback { extension.atts, global.atts, sequence-constructor.model } result-document.element = element result-document { extension.atts, global.atts, attribute format { eqname.datatype | avt.datatype }?, attribute _format { avt.datatype }?, attribute href { uri.datatype | avt.datatype }?, attribute _href { avt.datatype }?, ((attribute type { eqname.datatype }?, attribute _type { avt.datatype }?) | (attribute validation { "strict" | "lax" | "preserve" | "strip" }?, attribute _validation { avt.datatype }? )), # type and validation are mutually exclusive attribute method { "xml" | "html" | "xhtml" | "text" | "json" | "adaptive" | eqname.datatype | avt.datatype }?, attribute _method { avt.datatype }?, attribute allow-duplicate-names { boolean.datatype | avt.datatype }?, attribute _allow-duplicate-names { avt.datatype }?, attribute build-tree { boolean.datatype | avt.datatype }?, attribute _build-tree { avt.datatype }?, attribute byte-order-mark { boolean.datatype | avt.datatype }?, attribute _byte-order-mark { avt.datatype }?, attribute cdata-section-elements { eqnames.datatype | avt.datatype }?, attribute _cdata-section-elements { avt.datatype }?, attribute doctype-public { string.datatype | avt.datatype }?, attribute _doctype-public { avt.datatype }?, attribute doctype-system { string.datatype | avt.datatype }?, attribute _doctype-system { avt.datatype }?, attribute encoding { string.datatype | avt.datatype }?, attribute _encoding { avt.datatype }?, attribute escape-uri-attributes { boolean.datatype | avt.datatype }?, attribute _escape-uri-attributes { avt.datatype }?, attribute html-version { decimal.datatype | avt.datatype }?, attribute _html-version { avt.datatype }?, attribute include-content-type { boolean.datatype | avt.datatype }?, attribute _include-content-type { avt.datatype }?, attribute indent { boolean.datatype | avt.datatype }?, attribute _indent { avt.datatype }?, attribute item-separator { string.datatype | avt.datatype }?, attribute _item-separator { avt.datatype }?, attribute json-node-output-method { "xml" | "html" | "xhtml" | "text" | eqname.datatype | avt.datatype }?, attribute _json-node-output-method { avt.datatype }?, attribute media-type { string.datatype | avt.datatype }?, attribute _media-type { avt.datatype }?, attribute normalization-form { "NFC" | "NFD" | "NFKC" | "NFKD" | "fully-normalized" | "none" | nmtoken.datatype | avt.datatype }?, attribute _normalization-form { avt.datatype }?, attribute omit-xml-declaration { boolean.datatype | avt.datatype }?, attribute _omit-xml-declaration { avt.datatype }?, attribute parameter-document { uri.datatype | avt.datatype }?, attribute _parameter-document { avt.datatype }?, attribute standalone { boolean.datatype | "omit" | avt.datatype }?, attribute _standalone { avt.datatype }?, attribute suppress-indentation { eqnames.datatype | avt.datatype }?, attribute _suppress-indentation { avt.datatype }?, attribute undeclare-prefixes { boolean.datatype | avt.datatype }?, attribute _undeclare-prefixes { avt.datatype }?, attribute use-character-maps { eqnames.datatype }?, attribute _use-character-maps { avt.datatype }?, attribute output-version { nmtoken.datatype | avt.datatype }?, attribute _output-version { avt.datatype }?, sequence-constructor.model } output.element = element output { extension.atts, global.atts.except.version, attribute name { eqname.datatype }?, attribute _name { avt.datatype }?, attribute method { "xml" | "html" | "xhtml" | "text" | "json" | "adaptive" | eqname.datatype }?, attribute _method { avt.datatype }?, attribute allow-duplicate-names { boolean.datatype }?, attribute _allow-duplicate-names { avt.datatype }?, attribute build-tree { boolean.datatype }?, attribute _build-tree { avt.datatype }?, attribute byte-order-mark { boolean.datatype }?, attribute _byte-order-mark { avt.datatype }?, attribute cdata-section-elements { eqnames.datatype }?, attribute _cdata-section-elements { avt.datatype }?, attribute doctype-public { string.datatype }?, attribute _doctype-public { avt.datatype }?, attribute doctype-system { string.datatype }?, attribute _doctype-system { avt.datatype }?, attribute encoding { string.datatype }?, attribute _encoding { avt.datatype }?, attribute escape-uri-attributes { boolean.datatype }?, attribute _escape-uri-attributes { avt.datatype }?, attribute html-version { decimal.datatype }?, attribute _html-version { avt.datatype }?, attribute include-content-type { boolean.datatype }?, attribute _include-content-type { avt.datatype }?, attribute indent { boolean.datatype }?, attribute _indent { avt.datatype }?, attribute item-separator { string.datatype }?, attribute _item-separator { avt.datatype }?, attribute json-node-output-method { "xml" | "html" | "xhtml" | "text" | eqname.datatype }?, attribute _json-node-output-method { avt.datatype }?, attribute media-type { string.datatype }?, attribute _media-type { avt.datatype }?, attribute normalization-form { "NFC" | "NFD" | "NFKC" | "NFKD" | "fully-normalized" | "none" | nmtoken.datatype }?, attribute _normalization-form { avt.datatype }?, attribute omit-xml-declaration { boolean.datatype }?, attribute _omit-xml-declaration { avt.datatype }?, attribute parameter-document { uri.datatype }?, attribute _parameter-document { avt.datatype }?, attribute standalone { boolean.datatype | "omit" }?, attribute _standalone { avt.datatype }?, attribute suppress-indentation { eqnames.datatype }?, attribute _suppress-indentation { avt.datatype }?, attribute undeclare-prefixes { boolean.datatype }?, attribute _undeclare-prefixes { avt.datatype }?, attribute use-character-maps { eqnames.datatype }?, attribute _use-character-maps { avt.datatype }?, attribute version { nmtoken.datatype }?, attribute _version { avt.datatype }?, empty } character-map.element = element character-map { extension.atts, global.atts, (attribute name { eqname.datatype } | attribute _name { avt.datatype })+, attribute use-character-maps { eqnames.datatype }?, attribute _use-character-maps { avt.datatype }?, (output-character.element*) } output-character.element = element output-character { extension.atts, global.atts, (attribute character { char.datatype } | attribute _character { avt.datatype })+, (attribute string { string.datatype } | attribute _string { avt.datatype })+, empty } avt.datatype = xsd:string # { # pattern = # """([^\{\}]|\{\{|\}\}|\{([^"'\{\}]|"[^"]*"|'[^']*')+\})*""" # this regexp will not work in all the case. # }
This specification was developed and approved for publication by the W3C XSLT Working Group (WG).
The chair of the XSLT WG is Sharon Adler. The active membership of the XSLT WG during the final stages of the preparation of this specification included:
Sharon Adler (Chair)
Anders Berglund
Carine Bournez (W3C team)
Abel Braaksma
Charles Foster
Florent Georges
Michael Kay (Editor)
Jirka Kosek
Luis Ibhiabor
Michael Sperberg-McQueen
Norm Walsh
Mohamed Zergaoui
The Working Group wishes to acknowledge the contribution of those who have participated in the work at earlier stages, as well as the pioneering work of the developers of STX (see [STX]) which formed an important intellectual input to the design of XSLT 3.0 and demonstrated the feasibility of creating a streaming transformation language based on the core XSLT concept of recursive descent of the source tree using rule-based templates.
The Working Group also wishes to thank external reviewers who have provided feedback during the development of the specification.
A stylesheet may now consist of multiple packages. The language specification for packages has been designed with a view to allowing packages to be compiled independently of each other. The specification provides control over the interface offered by a package to other packages; in particular it allows functions, variables, named templates and other components to be declared as public, private, final, or abstract.
A new xsl:mode
declaration is added.
A mode may be declared to be streamable, and rules are given that constrain what the template rules in a streamable mode can do.
An xsl:mode
declaration may define the action to be
taken when there is no matching template rule, and the action to be taken
when there are multiple matching template rules.
An xsl:mode
declaration may indicate that the template
rules in a given mode are designed to process typed (schema-validated)
nodes only, or untyped nodes only. It may also indicate that element
names appearing in match patterns for the mode are only to match elements
in the source document that have been validated against the corresponding
element declarations in the schema.
A default mode can be declared for a stylesheet module, making it easier to reuse existing stylesheet modules to construct a composite stylesheet.
Several new instructions are introduced with the aim of making it easier to write streamable transformations, although all of these instructions can also be used without streaming:
The xsl:source-document
instruction is provided to
read and process an input document using streaming.
The xsl:iterate
instruction allows iterative processing
of a sequence, with the ability for the processing of one item to depend
on the results of processing of previous items, and with the ability to
terminate the iteration before all the items in the sequence have been
processed.
The xsl:merge
instruction allows several input sequences
to be merged into a single output sequence, based on the value of a merge
key.
The xsl:fork
instruction allows multiple results to be
computed during a single pass of a streamed input document.
The xsl:sequence
instruction can now contain a sequence
constructor as an alternative to using the select
attribute.
This is primarily for use cases involving xsl:fork
.
New instructions
xsl:where-populated
, xsl:on-empty
,
and xsl:on-non-empty
are introduced to allow elements to
be generated only when relevant content exists (or does not exist),
without requiring the input to be processed more than once.
Other changes introduced to facilitate the writing of streamable transformations include:
The new top-level declaration
xsl:accumulator
is introduced. An accumulator
represents information about a node in a document that can be computed
during a streamed pass over the document, starting at the start and
ending at that node.
New functions copy-of
and
snapshot
are provided, to enable streaming
applications to operate in windowing mode, where the input document is
divided into a sequence of small subtrees processed one at a time.
Some further new instructions are provided, unrelated to streaming:
The xsl:try
instruction allows recovery from dynamic
errors.
A new xsl:evaluate
instruction is provided, to allow
evaluation of XPath expressions constructed dynamically from strings, or
read from a source document.
The xsl:assert
instruction allows
arbitrary assertions about the state of variables or the input document,
improving testability and robustness.
Static global variables and parameters can be declared. These act as compile-time
constants. The values of static variables can be used in initializing other static
variables, or in [xsl:]use-when
attributes, or in shadow attributes.
Shadow attributes allow any attribute of an XSLT instruction or declaration to
be parameterized by reference to static variables and parameters.
Text nodes within a sequence constructor may now contain
text value templates (XPath
expressions enclosed in curly brackets), if this is enabled by setting
expand-text="yes">
on an enclosing element. This reduces the
verbosity of code written to generate boilerplate text with variable inserts.
The syntax of patterns has been
generalized. Patterns may now match any item (not only nodes). In consequence,
xsl:apply-templates
can now process sequences of atomic
values as well as nodes, and xsl:for-each-group
with the
group-starting-with
and group-ending-with
options
can also process atomic sequences. As a further consequence, the items in the initial match selection supplied when initiating a
transformation are no longer required to be nodes.
A new datatype, called a map, has been introduced, together with supporting functions, operators, and type syntax. Maps allow more complex data structures to be created than is possible using atomic values and nodes alone. This has particular applications to streamed processing: since a streamed application can visit each node of its primary input document only once, it often needs more advanced data structures to retain what it has already seen in the document.
Miscellaneous changes to existing instructions and declarations include:
The regular expression supplied to the
xsl:analyze-string
instruction is now permitted to be
one that matches a zero-length string.
The xsl:copy
instruction now has a select
attribute, which is convenient when it is used inside a function where
there is no context item.
Composite keys are supported in
xsl:for-each-group
.
Two new attributes have been added to xsl:function
to
provide increased scope for optimization: new-each-time
and
cache
. The first indicates whether the identity of nodes
created by the function is significant to the application; the second
indicates whether the function is to cache its results (memoization).
The override
attribute of
xsl:function
is renamed
override-extension-function
, retaining the old name as a
deprecated synonym.
The rule requiring xsl:import
declarations to precede all other declarations in a stylesheet module has
been removed.
Composite keys are supported in
xsl:key
.
A new attribute on xsl:message
allows
specification of an error code.
The rules for handling conflicts between
xsl:strip-space
and
xsl:preserve-space
have changed. A conflict that can
be detected statically is now signaled as a static error; a run-time
conflict between two declarations having the same precedence and priority
is now resolved by taking whichever comes last in declaration order.
An xsl:template
declaration may
contain an xsl:context-item
element to declare the
required type of the context item when the template is called.
An empty xsl:value-of
instruction with
no select
attribute is now permitted; its effect is to
construct a zero-length text node.
The xsl:variable
and
xsl:param
elements may now specify
static="yes"
, denoting that the variable is available
statically (informally, “at compile time”). Static variables and
parameters make the [xsl:]use-when
mechanism more useful,
especially in conjunction with xsl:assert
.
New functions are available to import and export data in JSON format.
A basic XSLT Processor now recognizes all the built-in types defined in XML Schema.
A basic XSLT Processor will
now accept the attribute validation="lax"
and interpret it in the
same way as a schema-aware processor when there is no schema component
available to perform the validation.
Some functions, including generate-id
FO30,
format-date
FO30, format-dateTime
FO30,
format-number
FO30, format-time
FO30,
and unparsed-text
FO30 have been moved from this
specification to the Functions and Operators specification, to make them
available in other host languages.
The rule that effectively prevented references to external
documents in [xsl:]use-when
expressions has been removed.
A default value is defined for the named template to be used
when initiating a transformation (specifically,
xsl:initial-template
).
Serialization to HTML5 and XHTML5 is supported. To this end,
a new serialization parameter html-version
is provided in
xsl:output
and xsl:result-document
.
Other new serialization parameters include:
item-separator
, json-node-output-method
, parameter-document
,
suppress-indentation
.
The concept of recoverable dynamic errors has been dropped. Of the remaining
recoverable dynamic errors, some are no longer errors, and others are now
situations where the behavior of the processor is implementation-dependent. The adjective non-recoverable in
describing other dynamic errors becomes redundant and has therefore been
dropped (the term was in any case misleading since the introduction of a
try/catch mechanism). Error codes of the form XTREnnnn
have been
renumbered XTDEnnnn
.
Dynamic errors occurring during pattern evaluation are always masked (they cause the pattern to report a non-match.)
A family of collation URIs is defined for selecting collations based on the Unicode Collation Algorithm.
The effect of specifying the type xs:untyped
or
xs:untypedAtomic
when validating by type is now defined.
The set of constructs that set temporary output state has been reduced, and no longer includes
instructions that create nodes, such as xsl:attribute
and
xsl:value-of
. However, xsl:merge-key
has
been added to the list.
The possibilities for invocation of a stylesheet have been expanded; they now include the ability to directly execute a stylesheet function; to supply parameters to the initial template; and to return the results of the invoked template or function as a raw value, without construction of a result tree.
A number of changes affecting XSLT 3.0 have been made in other related specifications. Some of the more significant changes are as follows:
A number of new functions have been defined whose aim is to facilitate
streaming. These include unparsed-text-lines
FO30,
innermost
FO30, outermost
FO30.
XPath 3.0 supports a subset of the let
expression from XQuery.
XPath 3.0 supports function items as first-class values (functions can, for example, be bound to variables and passed as parameters to other functions.)
XPath 3.0 supports a new syntax for writing expanded names using the namespace
URI and local part only, avoiding the need to create a static context that
binds namespace prefixes. This is intended to be particularly useful when XPath
expressions are software-generated. Complementing this, a new function
path
FO30 is available to generate a
(namespace-context-independent) path to any node that can subsequently be
evaluated using the xsl:evaluate
instruction, or
otherwise.
This section contains a list of changes that were made between the first Candidate Recommendation in November 2015 and the second Candidate Recommendation in February 2017. Design changes affecting the syntax or semantics of the XSLT language are marked (**). Minor changes to edge cases, and cases where rules have been supplied that were previously missing, are marked (*). Other changes may be considered editorial: these include corrections to examples, addition of non-normative notes, removal of ambiguities and inconsistencies, and textual clarifications. Changes that are purely typographical are not listed.
Bug29234: If explicit packages are used, then the initial mode used when a stylesheet is invoked (like an initial template or initial function) must now be declared as public. (**)
Bug29256: Clarified that it is an error for the top-level package to contain abstract components, whether or not the components are referenced. (*)
Bug29340: Streamability rules for XPath expressions now include the XPath 3.1 production number as well as the XPath 3.0 production number.
Bug29342: The streamability rules for XPath 3.1 arrow expressions did not cover dynamic function calls.
Bug29351: An error code has been allocated for the type error that occurs when
xsl:evaluate/@with-params
is not a map, or is a map of the wrong type. (*)
Bug29392: Defined how support for the serialize
FO30 function
relates to the optional serialization feature. (*)
Bug29425: The syntax summary now marks the xsl:result-document
attributes
method
and json-node-output-method
as attribute value templates, bringing it into
line with the prose.
Bug29431: The rules for returning the principal and secondary results of a transformation,
and in particular the interaction of build-tree
and item-separator
, have
been clarified. (*)
Bug29436: The list of instructions in 5.7 that return the results of a contained sequence constructor without alteration has been corrected and made non-normative.
Bug29441: The term extension function has been more carefully defined.
Bug29442: Part of the text on evaluating sequence constructors has been rewritten to improve clarity.
Bug29445: The summary of the rules for selecting a separator in 5.7.2 Constructing Simple Content has been made more complete.
Bug29449: The section on streamability of dynamic function calls now provides non-normative advice on the use of this construct in conjunction with maps and arrays.
Bug29453: An xsl:use-package
declaration may appear in an
included stylesheet module but not in an imported stylesheet module. (**)
Bug29455: Added to the list of items that are considered empty (now vacuous)
by the xsl:on-empty
and xsl:on-non-empty
instructions, for example to include
zero-length strings, and arrays consisting entirely of vacuous items. (**)
Bug29459: Clarified the rules for streamability of arrow expressions. (*)
Bug29460: The introduction to the concept of packages now mentions that an implementation might allow packages to be written in other languages (for example, XQuery).
Bug29461: Clarified how the concept of “static base URI” should be interpreted in situations where the source stylesheet is not available at execution time. (*)
Bug29468: Modified the rules for the default visibility of overriding components. (*)
Bug29473: Removed a misleading suggestion that the default visibility
of overriding components is always private
; this is not the case for
xsl:param
.
Bug29474: There was an incorrect suggestion that xsl:original
could be
used to refer to a declaration overridden using the traditional mechanism of import
precedence.
This has been removed.
Bug29478: In response to usability feedback, xsl:expose
and xsl:accept
now allow the value component="*"
to mean “all kinds of component”. (**)
Bug29480: Defined that the focus for evaluating attribute sets referenced by xsl:copy
is the same as the focus for evaluating the contained sequence constructor (*)
Bug29482: The Working Group decided not to change the streamability rules to make a particular
use case involving xsl:copy
guaranteed-streamable, but instead to add
a note explaining how to rewrite this use case in a streamable way.
Bug29492: Simplified the rules for streamability of attribute sets. Attribute sets can no longer be consuming. (*)
Bug29502: The streamability rules for xsl:fork
were incomplete for the
case where the instruction has an xsl:for-each-group
child. (*)
Bug29507: Clarified that a striding expression such as (/a/b, $doc/a/b)
can deliver
a mix of streamed and unstreamed nodes and that the result is not necessarily in document
order.
Bug29544: Clarified that whitespace stripping does not
apply to the trees returned by functions such as parse-xml
FO30 and
parse-xml-fragment
FO30. (*)
Bug29558: When the namespace used for the XML representation of JSON was
changed to http://www.w3.org/2005/xpath-functions
, one reference to the
old namespace was not updated.
Bug29574: By default a public component in a used package now becomes private
in the using package. This also affects the treatment of abstract components; as part
of this
change, the keyword visibility="absent"
is dropped. (**)
Bug29588: In the xml-to-json
function, map keys are now
compared after normalizing escape sequences to determine whether duplicates exist.
(*)
Bug29602: Changes made to the xml-to-json
in the XPath 3.1 project
have been retrofitted to this document. The changes include the detailed rules for
escaping special
characters, and the adoption of uniform conventions for type-checking and conversion
of parameter options. (**)
Bug29604: Corrected a throwaway remark in the text of an example concerning how to compute multiple aggregate values in a single pass of the input.
Bug29660: The function map:remove
can now remove multiple entries
from a map in a single call. (**)
Bug29665: The xml-to-json
now escapes a solidus (/
becomes \/
),
which is useful when the resulting JSON is embedded in HTML. (**)
Bug29666: Added a note to clarify how the concept of stylesheet levels relates to packages.
Bug29667: Added a note to confirm that it is not intrinsically an error to have two xsl:use-package
declarations that reference the same package.
Bug29669: Introductory material describing the XSLT processing model has been rewritten for clarity.
Bug29675: The rules for determining the context item static type in a global variable
declaration take account of the declared type in the xsl:global-context-item
declaration if available. (*)
Bug29686: Clarified the rules for compatibility of types when overriding functions. (*)
Bug29690: The requirement that a streaming processor should always use streaming if requested is relaxed if for example (a) the input is supplied as a tree in memory, or (b) the processor is able to determine that the input document is too small for streaming to give any benefit.
Bug29692: Clarified how stripping of type annotations and whitespace text nodes works when the rules vary by package. (*)
Bug29696: The global context item is not streamable. (**)
Bug29697: Clarified where calls on current-merge-group
and current-merge-key
can be used when xsl:merge
instructions are nested. (*)
Bug29698: Corrected several mentions of the streamable
attribute of
xsl:merge
; the attribute actually appears on xsl:merge-source
.
Bug29699: Clarified that for the purpose of error XTSE3085
,
only xsl:template
elements with a match
attribute are relevant. (*)
Bug29709: Some xsl:merge
examples used obsolete syntax from an earlier
working draft.
Bug29710: Used more precise terminology in some of the rules defining the streamability of stylesheet functions.
Bug29712: Streamable stylesheet functions declared with streamability absorbing, shallow-descent, or deep-descent now allow the function body to be motionless (previously it had to be consuming). (*)
Bug29716: Defined additional situations where the current template rule is cleared. (*)
Bug29723: The map:merge
function takes a second argument to control
how duplicate keys are handled. (**)
Bug29732: The rules for streamable stylesheet functions have been refined. In most cases the argument must now be a single node rather than a sequence of nodes, and constraints on the variable reference have been rewritten as constraints on the function signature. (**)
Bug29733: An example for an absorbing stylesheet function was correct, but the explanation for why it was correct was misleading.
Bug29738: The vague term “streamable stylesheet” is no longer used.
Bug29743: A new function map:find
is provided to allow recursive searching of nested maps. (**)
Bug29747: The xsl:stream
instruction has been generalized to handle both
streamed and unstreamed processing, and it has accordingly been renamed xsl:source-document
,
and has a streamable
attribute. (**)
Bug29752: Improved an example where accumulators are used to compute a word count, to give a more realistic real-world result.
Bug29763: Added rules concerning the effect of xsl:expose
and xsl:accept
on xsl:param
declarations (which are always public). (*)
Bug29768: The operand usages for the map:for-each
and map:merge
functions have been corrected (affecting the streamability of these functions in the
unusual case where the functions are
called with references to streamed nodes). (*)
Bug29790: The sample stylesheet for the xml-to-json
function has been changed to
avoid using a reserved namespace.
Bug29793: Added a note confirming that the input-type-annotations
attribute has
no effect on an xsl:source-document
instruction when the type
or validation
attributes are present.
Bug29796: A note has been added pointing out that keys only allow searching within a tree that is rooted at a document node.
Bug29802: Clarified the text describing the function of the global context item.
Bug29803: Having been dropped from xsl:global-context-item
, the ability to
control which accumulators are used on the initial match selection has been moved
to xsl:mode
. (**)
Bug29804: The for-each-stream
attribute of xsl:merge-source
has
been generalized to handle both streamed and unstreamed processing, and it has accordingly
been renamed for-each-source
;
streaming of the merge input is controlled using the streamable
attribute. (**)
Bug29805: The use-accumulators
attribute of xsl:source-document
now applies
whether or not the instruction is declared streamable. (**)
Bug29811: Clarified what error code should be used for a particular error involving static variables. (*)
Bug29813: A section has been added explaining how to handle dynamic errors that occur during the evaluation of accumulators. (*)
Bug29814: Clarified that XPath comments can appear (only) in attributes of type expression, pattern, item-type, or sequence-type. (*)
Bug29819: Dropped the use of the term “core functions” in favour of more precise wording.
Bug29827: Clarified the rules defining which modes are eligible to be used as the initial mode when a stylesheet is first invoked. (*)
Bug29853: The result of the collation-key
function is now always xs:base64Binary
,
making the comparison semantics unambiguous and context-independent. (**)
Bug29865: A new parameter maxVariable
is added to UCA collation URIs, to define which
groups of characters (such as whitespace and punctuation) are ignored, or treated
as less significant, when
comparing strings. In addition, interoperable defaults are defined for most of the
collation parameters. (**)
Bug29860, Bug29861, Bug29862, Bug29865: Fixed errors in the
schema for XSLT 3.0 stylesheets resulting from changes logged elsewhere, notable the
renaming of xsl:stream
to xsl:source-document
.
Bug29866: Changed the definition of type EQName
in the
schema for XSLT 3.0 stylesheets to be more restrictive.
Bug29880: Implementations may impose limits on the values used in a package version number, and minimum values for those limits have been defined. (*)
Bug29887: Changed an assertion against xsl:for-each-group
in the
schema for XSLT 3.0 stylesheets to be allow for the possibility of shadow attributes.
(*)
Bug29889: Added an introductory section concerning streaming of non-XML data.
Bug29917: The xml-to-json
function now allows the top-level element of the input to have
a key
attribute (which is ignored), so that it can successfully process any subtree of
the output of
json-to-xml
. (*)
Bug29919: A use-when
attribute on xsl:package
works the same way as
on xsl:stylesheet
and xsl:transform
. (*)
Bug29920: The rules for shadow attributes have been rewritten to avoid using the undefined term target attribute.
Bug29927: Clarified that facilities for disabling xsl:evaluate
are
implementation-defined.
Bug29933: In line with other serialization parameters, the detail of what undeclare-prefixes
does is now delegated to the serialization specification.
Bug29960: Processors are now allowed to provide a mode of operation in which there is no requirement to report static errors in code that is never executed. (*)
Bug29975: Added a non-normative summary of the rules affecting validation of xml:id
attributes.
Bug29978: Rules relating the the permitted children of xsl:stylesheet
apply
also to xsl:package
. (*)
Bug29980: Editorial improvements to the definition of error XTSE0760. (*)
Bug29981: Relaxed the rule requiring the tunnel parameters on an overriding template to be identical to those on the overridden template. (**)
Bug29982: Expanded the note explaining the rationale and use cases for tunnel parameters.
Bug29983: The justification and explanation for the streamability of scanning expression
such as //section/head
has been rewritten for clarity; and the term itself is now defined in terms
of the rules for motionless patterns since the two concepts are very closely aligned. (*)
Bug29988: Clarified that in the xs:QName
values returned by
available-system-properties
, the prefix part of the QName is implementation-dependent.
Bug30002: Rectified the omission of xsl:function/@cache
in the schema for XSLT 3.0.
Bug30032: Refined the static typing rules for axis steps to take account of the axis as well as the node test. (*)
Bug30033: Refined the rules for streamability of the current
function. (*)
Bug30034: Corrected a note concerning the streamability of xsl:choose
to match
the normative rules.
Bug30036: document-node(E)
sequence type tests cause streaming difficulties for
treat as
expressions just as they do for instance of
expressions. (*)
Bug30049: Supplied missing rules regarding the dynamic context for evaluation of XPath expressions
(both static expressions and expressions evaluated using xsl:evaluate
), especially as regards
the named functions available in the dynamic context for function-lookup
FO30. (*)
Bug30056: Corrected the expected output of an example of streamed grouping.
A non-normative Relax NG schema for XSLT 3.0 has been added to H Schemas for XSLT 3.0 Stylesheets.
This section contains a list of changes that have been made. Trivial typographic errors and changes to non-normative front and back matter are not listed.
Bug30060: An example purporting to show streamable use of xsl:iterate
was
not in fact guaranteed-streamable, and has been corrected by injecting a call of the
copy-of
function.
Bug30064: Added a Note to explain why certain path expressions (such as .//section/head
)
are not guaranteed-streamable.
This section contains a list of changes that have been made. Trivial typographic errors and changes to non-normative front and back matter are not listed.
Bug30089: A non-normative note in 2.3.6.1 wrongly stated that serializing an array would raise an error. The serialization specification is clear that this is not the case.
Bug30090: A non-normative note in 3.2 referred to the "four standard serialization methods". With the 3.1 version of the serialization specification, there are now six standard methods.
Bug30091: A non-normative note in 3.5.4 advised users to solve a particular problem by using
the
instruction <xsl:apply-templates/>
. Better advice would be to use
<xsl:apply-templates select="."/>
Bug30093: An example in 5.5.1 Examples of Patterns (carried over unchanged from the XSLT 2.0 specification) gave incorrect
semantics for the pattern //para
.
Bug30094: In 9.1 Variables the term local variable
is used. The definition of this
term appears in 9.8 Local Variables and Parameters. But rather than linking to the definition, the former section gave an
incomplete explanation of its meaning.
Bug30095: In 9.9 Scope of Variables, the scope of global variables was described without making clear that the discussion was in the context of a single package; a note has been added explaining that the rules for cross-package visibility are defined elsewhere.
Bug30099: In the proforma for the start-at
attribute of xsl:number
(appearing
in both section 12 and Appendix D), the type of the attribute was given as integer
although the normative description
of the syntax and semantics of the attribute makes clear that a whitespace-separated
sequence of integers is permitted.
(For technical reasons this change is not color-highlighted.)
Bug30100: A non-normative note in section 27.4 referred to version "3.0", in a context that made no sense unless this is read as version "2.0".
Bug30109: A non-normative note has been added to explain that as a consequence of the general
rules for constructing simple content, the disable-output-escaping
attribute has
no effect when writing attributes, comments or processing instructions.
This section lists all known incompatibilities with XSLT 2.0, that is, situations
where a stylesheet that is error-free
according to the XSLT 2.0 specification and where all elements have an effective version
of 2.0
or less, will produce different results depending on whether it is
run under an XSLT 2.0 processor or an XSLT 3.0 processor.
XSLT 2.0 gave implementations freedom what to do when a node selected by
xsl:apply-templates
matched more than one template rule. XSLT 3.0 is more prescriptive in this situation. The
behavior prescribed in XSLT 3.0 (selecting the template rule that is last in
declaration order) is compatible with the action of some
XSLT 2.0 processors but not necessarily others.
It is now a static error if the same NameTest
appears in both an
xsl:strip-space
and an xsl:preserve-space
declaration with the same precedence and priority. Previously this was a dynamic
error, and processors were allowed to recover from the error.
The current group and current grouping key are now absent rather than empty when not in use, which means that attempting to refer to them in this state gives a dynamic error.
As a consequence of functions such as
format-date
FO30 moving from this specification to [Functions and Operators 3.0], error codes associated with these functions have
changed.
The concept of recoverable dynamic errors has been dropped. Of
the remaining recoverable dynamic errors, some are no longer errors, and others
are now situations where the behavior of the processor is implementation-dependent. Error codes of the form
XTREnnnn
have been renumbered XTDEnnnn
.
In previous versions of the specification, the
element-available
function when applied to names in the
XSLT namespace was defined to return false
in the case of XSLT
elements other than instructions. (Actual practice in implementations was not
always consistent with this rule). In XSLT 3.0 the rules have been changed so that
it returns true
for the names of such elements, bringing the
specification of the function into line with the intuitive meaning of its name.
(This is not strictly speaking an incompatibility, as conforming XSLT 2.0 stylesheets will continue to function correctly without error. It can be considered as migration advice, a warning that care is needed when introducing new XSLT 3.0 features.)
When a function or template has a parameter with a declared
type of item()
, it should not assume (as it could in XSLT 2.0) that
when the supplied item is not a node, it must be an atomic value, and vice versa.
In XSLT 3.0 there is a third option: it might be a function. Functions and
templates that fail to cater for this possibility may fail with a type error if
the caller supplies a function as the relevant parameter value.
XSLT 1.0 and 2.0 required the
grouping-size
attribute of xsl:number
to be a
number (a term which in other contexts was defined to mean any decimal value),
but no interpretation was provided for non-integer values. XSLT 3.0 requires the
value to be an integer.
In XPath 3.0, the rules for matching node tests of the form
element(*, U)
or attribute(*, U)
have changed in the
case where U
is a union type. Specifically, an element or attribute
whose type annotation is a member type of U
will now match such a
node test, whereas in XPath 2.0 it did not. Since the semantics of XSLT pattern
matching are based on the XPath rules for matching node tests, this change affects
which template rules are chosen to match a node when the match patterns use one of
these forms.
The handling of XSLT version numbers that do not
correspond to any published specification has changed. An example is
version="1.1"
(which is sometimes encountered because it was used
in examples in a popular book). XSLT 2.0 requires processors to treat all values
less than 2.0 as if 1.0 were specified. XSLT 3.0 recommends that processors reject
such a value as a static error.
XSLT 3.0 disallows the use of certain reserved namespaces
in extension functions and extension instructions, and in the [xsl:]extension-element-prefixes
attribute.
Note:
For example, it becomes an error to write extension-element-prefixes="xs"
where
the prefix xs
is bound to the XML Schema namespace. Such an attribute is occasionally seen
where exclude-result-prefixes
was probably intended.