Copyright © 2001 W3C® (MIT, INRIA, Keio), All Rights Reserved. W3C liability, trademark, document use, and software licensing rules apply.
This specification defines the syntax and semantics of XSLT, which is a language for transforming XML documents into other XML documents.
XSLT is designed for use as part of XSL, which is a stylesheet language for XML. In addition to XSLT, XSL includes an XML vocabulary for specifying formatting. XSL specifies the styling of an XML document by using XSLT to describe how the document is transformed into another XML document that uses the formatting vocabulary.
XSLT is also designed to be used independently of XSL. However, XSLT is not intended as a completely general-purpose XML transformation language. Rather it is designed primarily for the kinds of transformations that are needed when XSLT is used as part of XSL.
This document is a W3C Working Draft for review by W3C members and other interested parties.
NOTICE:
As of 24 August 2001 no further work on this draft is expected. The work on XSLT 2.0 identified a number of issues with the approaches being pursued in this document; solutions to the requirements of XSLT 1.1 will be considered in the development of XSLT 2.0 [XSLT20REQ]. Other than this paragraph, the document is unchanged from the previous version.It is inappropriate to use W3C Working Drafts as reference material or to cite them as other than "work in progress".
This document is based on the XSLT 1.0 Recommendation [XSLT10]. The changes made in this document are intended to meet the requirements for XSLT 1.1 described in [XSLT11REQ] and to incorporate fixes for errors that have been detected in XSLT 1.0.
Comments on this specification may be sent to [email protected]; archives of the comments are available. Public discussion of XSL, including XSL Transformations, takes place on the XSL-List mailing list.
The English version of this specification is the only normative version. However, for translations of this document, see http://www.w3.org/Style/XSL/translations.html.
A list of current W3C Recommendations and other technical documents can be found at http://www.w3.org/TR/.
This specification has been produced as part of the W3C Style activity.
1 Introduction
2 Stylesheet Structure
2.1 XSLT Namespace
2.2 Stylesheet Element
2.3 Literal Result Element as Stylesheet
2.4 Qualified Names
2.5 Forwards-Compatible Processing
2.6 Combining Stylesheets
2.6.1 Stylesheet Inclusion
2.6.2 Stylesheet Import
2.7 Embedding Stylesheets
3 Data Model
3.1 Root Node Children
3.2 Base URI
3.3 Unparsed Entities
3.4 Whitespace Stripping
3.5 Namespace Fixup
4 Expressions
5 Template Rules
5.1 Processing Model
5.2 Patterns
5.3 Defining Template Rules
5.4 Applying Template Rules
5.5 Conflict Resolution for Template Rules
5.6 Overriding Template Rules
5.7 Modes
5.8 Built-in Template Rules
6 Named Templates
7 Creating the Result Tree
7.1 Creating Elements and Attributes
7.1.1 Literal Result Elements
7.1.2 Creating Elements with xsl:element
7.1.3 Creating Attributes with xsl:attribute
7.1.4 Named Attribute Sets
7.2 Creating Text
7.3 Creating Processing Instructions
7.4 Creating Comments
7.5 Copying
7.6 Computing Generated Text
7.6.1 Generating Text with xsl:value-of
7.6.2 Attribute Value Templates
7.7 Numbering
7.7.1 Number to String Conversion Attributes
8 Repetition
9 Conditional Processing
9.1 Conditional Processing with xsl:if
9.2 Conditional Processing with xsl:choose
10 Sorting
11 Variables and Parameters
11.1 Result Tree Fragments
11.2 Values of Variables and Parameters
11.3 Using Values of Variables and Parameters with
xsl:copy-of
11.4 Top-level Variables and Parameters
11.5 Variables and Parameters within Templates
11.6 Passing Parameters to Templates
12 Additional Functions
12.1 Multiple Source Documents
12.2 Keys
12.3 Number Formatting
12.4 Miscellaneous Additional Functions
13 Messages
14 Extensions
14.1 Using Extension Elements
14.2 Using Extension Functions
14.3 External Objects
14.4 Defining Extension Functions
15 Fallback
16 Output
16.1 XML Output Method
16.2 HTML Output Method
16.3 Text Output Method
16.4 Disabling Output Escaping
16.5 Multiple Output Documents
17 Conformance
18 Notation
A References
A.1 Normative References
A.2 Other References
B Element Syntax Summary
C DOM-Based Language Bindings
C.1 DOM Issues
C.1.1 Passing an XPath node-set to an Extension Function
C.1.2 Returning a NodeList or Node from an Extension Function
C.2 IDL/DOM2 Language Binding
C.3 ECMAScript/DOM2 Language Binding
C.4 Java/DOM2 Language Binding
C.4.1 Identifying the Java Method
C.4.2 Argument Conversions
C.4.3 Return Value Conversions
C.4.4 Accessing XSLT Context Information
D DTD Fragment for XSLT Stylesheets (Non-Normative)
E Examples (Non-Normative)
E.1 Document Example
E.2 Data Example
F Acknowledgements (Non-Normative)
G Changes from XSLT 1.0 (Non-Normative)
This specification defines the syntax and semantics of the XSLT language. A transformation in the XSLT language is expressed as a well-formed XML document [XML] conforming to the Namespaces in XML Recommendation [XML Names], which may include both elements that are defined by XSLT and elements that are not defined by XSLT. [Definition: XSLT-defined elements are distinguished by belonging to a specific XML namespace (see 2.1 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.
A transformation expressed in XSLT describes rules for transforming a source tree into a result tree. The transformation is achieved by associating patterns with templates. A pattern is matched against elements in the source tree. A template is instantiated to create part of the result tree. The result tree is separate from the source tree. The structure of the result tree can be completely different from the structure of the source tree. In constructing the result tree, elements from the source tree can be filtered and reordered, and arbitrary structure can be added.
A transformation expressed in XSLT is called a stylesheet. This is because, in the case when XSLT is transforming into the XSL formatting vocabulary, the transformation functions as a stylesheet.
This document does not specify how an XSLT stylesheet is associated with an XML document. It is recommended that XSL processors support the mechanism described in [XML Stylesheet]. When this or any other mechanism yields a sequence of more than one XSLT stylesheet to be applied simultaneously to a XML document, then the effect should be the same as applying a single stylesheet that imports each member of the sequence in order (see 2.6.2 Stylesheet Import).
A stylesheet contains a set of template rules. A template rule has two parts: a pattern which is matched against nodes in the source tree and a template which can be instantiated to form part of the result tree. This allows a stylesheet to be applicable to a wide class of documents that have similar source tree structures.
A template is instantiated for a particular source element to create part of the result tree. A template can contain elements that specify literal result element structure. A template can also contain elements from the XSLT namespace that are instructions for creating result tree fragments. When a template is instantiated, each instruction is executed and replaced by the result tree fragment that it creates. Instructions can select and process descendant source elements. Processing a descendant element creates a result tree fragment by finding the applicable template rule and instantiating its template. Note that elements are only processed when they have been selected by the execution of an instruction. The result tree is constructed by finding the template rule for the root node and instantiating its template.
In the process of finding the applicable template rule, more than one template rule may have a pattern that matches a given element. However, only one template rule will be applied. The method for deciding which template rule to apply is described in 5.5 Conflict Resolution for Template Rules.
A single template by itself has considerable power: it can create structures of arbitrary complexity; it can pull string values out of arbitrary locations in the source tree; it can generate structures that are repeated according to the occurrence of elements in the source tree. For simple transformations where the structure of the result tree is independent of the structure of the source tree, a stylesheet can often consist of only a single template, which functions as a template for the complete result tree. Transformations on XML documents that represent data are often of this kind (see E.2 Data Example). XSLT allows a simplified syntax for such stylesheets (see 2.3 Literal Result Element as Stylesheet).
When a template is instantiated, it is always instantiated with respect to a [Definition: current node] and a [Definition: current node list]. The current node is always a member of the current node list. Many operations in XSLT are relative to the current node. Only a few instructions change the current node list or the current node (see 5 Template Rules and 8 Repetition); during the instantiation of one of these instructions, the current node list changes to a new list of nodes and each member of this new list becomes the current node in turn; after the instantiation of the instruction is complete, the current node and current node list revert to what they were before the instruction was instantiated.
XSLT makes use of the expression language defined by [XPath] for selecting elements for processing, for conditional processing and for generating text.
XSLT provides two "hooks" for extending the language, one hook for extending the set of instruction elements used in templates and one hook for extending the set of functions used in XPath expressions. These hooks are both based on XML namespaces. See 14 Extensions. This version of XSLT defines a mechanism for providing implementations of extension functions (see 14.4 Defining Extension Functions), but does not define a mechanism for providing implementations of extension elements.
Note:
The XSL WG intends to define such a mechanism for extension elements in a future version of this specification or in a separate specification.
The element syntax summary notation used to describe the syntax of XSLT-defined elements is described in 18 Notation.
The MIME media types text/xml
and
application/xml
[RFC2376] should be used
for XSLT stylesheets. It is possible that a media type will be
registered specifically for XSLT stylesheets; if and when it is, that
media type may also be used.
The XSLT namespace has the URI http://www.w3.org/1999/XSL/Transform
.
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 2.2 Stylesheet Element and 2.3 Literal Result Element as Stylesheet).
XSLT processors must use the XML namespaces mechanism [XML Names] 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 B Element Syntax Summary. Vendors 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 element mechanism specified in 14.1 Using Extension Elements.
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.
An element from the XSLT namespace may have any attribute not from the XSLT namespace, provided that the expanded-name of the attribute has a non-null namespace URI. The presence of such attributes must not change the behavior of XSLT elements and functions defined in this document. Thus, an XSLT processor is always free to ignore such attributes, and must ignore such attributes without giving an error if it does not recognize the namespace URI. Such attributes can provide, for example, unique identifiers, optimization hints, or documentation.
It is an error for an element from the XSLT namespace to have attributes with expanded-names that have null namespace URIs (i.e. attributes with unprefixed names) other than attributes defined for the element in this document.
Note:
The conventions used for the names of XSLT elements, attributes and functions are that names are all lower-case, use hyphens to separate words, and use abbreviations only if they already appear in the syntax of a related language such as XML or HTML.
A stylesheet is represented by an xsl:stylesheet
element in an XML document. xsl:transform
is allowed as
a synonym for xsl:stylesheet
.
An xsl:stylesheet
element must have a
version
attribute, indicating the version of XSLT that
the stylesheet requires. For this version of XSLT, the value should
be 1.1
. When the value is not equal to
1.0
or 1.1
,
forwards-compatible processing mode is enabled (see 2.5 Forwards-Compatible Processing).
The xsl:stylesheet
element may contain the following types
of elements:
xsl:import
xsl:include
xsl:strip-space
xsl:preserve-space
xsl:output
xsl:key
xsl:decimal-format
xsl:namespace-alias
xsl:attribute-set
xsl:variable
xsl:param
xsl:template
xsl:script
[Definition: An element occurring as
a child of an xsl:stylesheet
element is called a
top-level element.]
This example shows the structure of a stylesheet. Ellipses
(...
) indicate where attribute values or content have
been omitted. Although this example shows one of each type of allowed
element, stylesheets may contain zero or more of each of these
elements.
<xsl:stylesheet version="1.1" xmlns:xsl="http://www.w3.org/1999/XSL/Transform"> <xsl:import href="..."/> <xsl:include href="..."/> <xsl:strip-space elements="..."/> <xsl:preserve-space elements="..."/> <xsl:output method="..."/> <xsl:key name="..." match="..." use="..."/> <xsl:decimal-format name="..."/> <xsl:namespace-alias stylesheet-prefix="..." result-prefix="..."/> <xsl:attribute-set name="..."> ... </xsl:attribute-set> <xsl:variable name="...">...</xsl:variable> <xsl:param name="...">...</xsl:param> <xsl:script implements-prefix="..." language="..."> ... </xsl:script> <xsl:template match="..."> ... </xsl:template> <xsl:template name="..."> ... </xsl:template> </xsl:stylesheet>
The order in which the children of the xsl:stylesheet
element occur is not significant except for xsl:import
elements and for error recovery. Users are free to order the elements
as they prefer, and stylesheet creation tools need not provide control
over the order in which the elements occur.
In addition, the xsl:stylesheet
element may contain
any element not from the XSLT namespace, provided that the
expanded-name of the element has a non-null namespace URI. The presence of
such top-level elements must not change the behavior of XSLT elements
and functions defined in this document; for example, it would not be
permitted for such a top-level element to specify that
xsl:apply-templates
was to use different rules to resolve
conflicts. Thus, an XSLT processor is always free to ignore such
top-level elements, and must ignore a top-level element without giving
an error if it does not recognize the namespace URI. Such elements can
provide, for example,
information used by extension elements or extension functions (see 14 Extensions),
information about what to do with the result tree,
information about how to obtain the source tree,
metadata about the stylesheet,
structured documentation for the stylesheet.
A simplified syntax is allowed for stylesheets that consist of only
a single template for the root node. The stylesheet may consist of
just a literal result element (see 7.1.1 Literal Result Elements). Such a stylesheet is equivalent to a
stylesheet with an xsl:stylesheet
element containing a
template rule containing the literal result element; the template rule
has a match pattern of /
. For example
<html xsl:version="1.1" xmlns:xsl="http://www.w3.org/1999/XSL/Transform" xmlns="http://www.w3.org/TR/xhtml1"> <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="1.1" xmlns:xsl="http://www.w3.org/1999/XSL/Transform" xmlns="http://www.w3.org/TR/xhtml1"> <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>
A literal result element that is the document element of a
stylesheet must have an xsl:version
attribute, which
indicates the version of XSLT that the stylesheet requires. For this
version of XSLT, the value should be 1.1
; the
value must be a Number. Other
literal result elements may also have an xsl:version
attribute. When the xsl:version
attribute is not equal to
1.0
or 1.1
,
forwards-compatible processing mode is enabled (see 2.5 Forwards-Compatible Processing).
The allowed content of a literal result element when used as a stylesheet is no different from when it occurs within a stylesheet. Thus, a literal result element used as a stylesheet cannot contain top-level elements.
In some situations, the only way that a system can recognize that an XML document needs to be processed by an XSLT processor as an XSLT stylesheet is by examining the XML document itself. Using the simplified syntax makes this harder.
Note:
For example, another XML language (AXL) might also use an
axl:version
on the document element to indicate that an
XML document was an AXL document that required processing by an AXL
processor; if a document had both an axl:version
attribute and an xsl:version
attribute, it would be
unclear whether the document should be processed by an XSLT processor
or an AXL processor.
Therefore, the simplified syntax should not be used for XSLT
stylesheets that may be used in such a situation. This situation can,
for example, arise when an XSLT stylesheet is transmitted as a message
with a MIME media type of text/xml
or
application/xml
to a recipient that will use the MIME
media type to determine how the message is processed.
The name of an internal XSLT object, specifically a named template (see 6 Named Templates), a mode (see 5.7 Modes), an attribute set (see 7.1.4 Named Attribute Sets), a key (see 12.2 Keys), a decimal-format (see 12.3 Number Formatting), a variable or a parameter (see 11 Variables and Parameters) is specified as a QName. If it has a prefix, then the prefix is expanded into a URI reference using the namespace declarations in effect on the attribute in which the name occurs. The expanded-name 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 is not used for unprefixed names.
An element enables forwards-compatible mode for itself, its
attributes, its descendants and their attributes if either it is an
xsl:stylesheet
element whose version
attribute is not equal to 1.0
or
1.1
, or it is a literal result element that has
an xsl:version
attribute whose value is not equal to
1.0
or
1.1
. A literal result element
that has an xsl:version
attribute whose value is equal to
1.0
or 1.1
disables forwards-compatible mode for itself, its attributes, its
descendants and their attributes.
If an element is processed in forwards-compatible mode, then:
if it is a top-level element and XSLT 1.1 does not allow such elements as top-level elements, then the element must be ignored along with its content;
if it is an element in a template and XSLT 1.1 does not allow such elements to occur in templates, then if the element is not instantiated, an error must not be signaled, and if the element is instantiated, the XSLT must perform fallback for the element as specified in 15 Fallback;
if the element has an attribute that XSLT 1.1 does not allow the element to have or if the element has an optional attribute with a value that the XSLT 1.1 does not allow the attribute to have, then the attribute must be ignored.
Thus, any XSLT 1.1 processor must be able to 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:choose> <xsl:when test="system-property('xsl:version') >= 17.0"> <xsl:exciting-new-17.0-feature/> </xsl:when> <xsl:otherwise> <html> <head> <title>XSLT 17.0 required</title> </head> <body> <p>Sorry, this stylesheet requires XSLT 17.0.</p> </body> </html> </xsl:otherwise> </xsl:choose> </xsl:template> </xsl:stylesheet>
Note:
If a stylesheet depends crucially on a top-level element
introduced by a version of XSLT after 1.1, then
the stylesheet can use an xsl:message
element with
terminate="yes"
(see 13 Messages) to ensure
that XSLT processors implementing earlier versions of XSLT will not silently ignore the
top-level element. 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="system-property('xsl:version') < 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>
If an expression occurs in an attribute that is processed in forwards-compatible mode, then an XSLT processor must recover from errors in the expression as follows:
if the expression does not match the syntax allowed by the XPath grammar, then an error must not be signaled unless the expression is actually evaluated;
if the expression calls a function with an unprefixed name that is not part of the XSLT library, then an error must not be signaled unless the function is actually called;
if the expression calls a function with a number of arguments that XSLT does not allow or with arguments of types that XSLT does not allow, then an error must not be signaled unless the function is actually called.
XSLT provides two mechanisms to combine stylesheets:
an inclusion mechanism that allows stylesheets to be combined without changing the semantics of the stylesheets being combined, and
an import mechanism that allows stylesheets to override each other.
An XSLT stylesheet may include another XSLT stylesheet using an
xsl:include
element. The xsl:include
element
has an href
attribute whose value is a URI reference
identifying the stylesheet to be included. A relative URI is resolved
relative to the base URI of the xsl:include
element (see
3.2 Base URI).
The xsl:include
element is only allowed as a top-level element.
The inclusion works at the XML tree level. The resource located by
the href
attribute value is parsed as an XML document,
and the children of the xsl:stylesheet
element in this
document replace the xsl:include
element in the including
document. The fact that template rules or definitions are included
does not affect the way they are processed.
The included stylesheet may use the simplified syntax described in
2.3 Literal Result Element as Stylesheet. The included stylesheet
is treated the same as the equivalent xsl:stylesheet
element.
It is an error if a stylesheet directly or indirectly includes itself.
Note:
Including a stylesheet multiple times 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'.
An XSLT stylesheet may import another XSLT stylesheet using an
xsl:import
element. Importing a stylesheet is the same
as including it (see 2.6.1 Stylesheet Inclusion) except that definitions
and template rules in the importing stylesheet take precedence over
template rules and definitions in the imported stylesheet; this is
described in more detail below. The xsl:import
element
has an href
attribute whose value is a URI reference
identifying the stylesheet to be imported. A relative URI is resolved
relative to the base URI of the xsl:import
element (see
3.2 Base URI).
The xsl:import
element is only allowed as a top-level element. The
xsl:import
element children must precede all other
element children of an xsl:stylesheet
element, including
any xsl:include
element children. When
xsl:include
is used to include a stylesheet, any
xsl:import
elements in the included document are moved up
in the including document to after any existing
xsl:import
elements in the including document.
For example,
<xsl:stylesheet version="1.1" 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
xsl:stylesheet
elements encountered during processing of
a stylesheet that contains xsl:import
elements are
treated as forming an import tree. In the import tree,
each xsl:stylesheet
element has one import child for each
xsl:import
element that it contains. Any
xsl:include
elements are resolved before constructing the
import tree.] [Definition: An xsl:stylesheet
element in the import tree
is defined to have lower import precedence than another
xsl:stylesheet
element in the import tree if it would be
visited before that xsl:stylesheet
element in a
post-order traversal of the import tree (i.e. a traversal of the
import tree in which an xsl:stylesheet
element is visited
after its import children).] Each definition and template
rule has import precedence determined by the
xsl:stylesheet
element that contains it.
For example, suppose
stylesheet A imports stylesheets B and C in that order;
stylesheet B imports stylesheet D;
stylesheet C imports stylesheet E.
Then the order of import precedence (lowest first) is D, B, E, C, A.
Note:
Since xsl:import
elements are required to occur
before any definitions or template rules, an implementation that
processes imported stylesheets at the point at which it encounters the
xsl:import
element will encounter definitions and
template rules in increasing order of import precedence.
In general, a definition or template rule with higher import precedence takes precedence over a definition or template rule with lower import precedence. This is defined in detail for each kind of definition and for template rules.
It is an error if a stylesheet directly or indirectly imports
itself. Apart from this, the case where a stylesheet with a particular
URI is imported in multiple places is not treated specially. The
import tree will have a
separate xsl:stylesheet
for each place that it is
imported.
Note:
If xsl:apply-imports
is used (see 5.6 Overriding Template Rules), the behavior may be different from the
behavior if the stylesheet had been imported only at the place with
the highest import
precedence.
Normally an XSLT stylesheet is a complete XML document with the
xsl:stylesheet
element as the document element. However,
an XSLT stylesheet may also be embedded in another resource. Two forms
of embedding are possible:
the XSLT stylesheet may be textually embedded in a non-XML resource, or
thexsl:stylesheet
element may occur in an XML document other than as the document element.
To facilitate the second form of embedding, the
xsl:stylesheet
element is allowed to have an ID attribute
that specifies a unique identifier.
Note:
In order for such an attribute to be used with the XPath id function, it must actually be declared in the DTD as being an ID.
The following example shows how the xml-stylesheet
processing instruction [XML Stylesheet] can be used to allow a
document to contain its own stylesheet. The URI reference uses a
relative URI with a fragment identifier to locate the
xsl:stylesheet
element:
<?xml-stylesheet type="text/xml" href="#style1"?> <!DOCTYPE doc SYSTEM "doc.dtd"> <doc> <head> <xsl:stylesheet id="style1" version="1.1" 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 that is embedded in the document to which it is
to be applied or that may be included or imported into a stylesheet that is so embedded typically needs
to contain a template rule that specifies that
xsl:stylesheet
elements are to be ignored.
The data model used by XSLT is the same as that used by XPath with the additions described in this section. XSLT operates on source, result and stylesheet documents using the same data model. Any two XML documents that have the same tree will be treated the same by XSLT.
Processing instructions and comments in the stylesheet are ignored: the stylesheet is treated as if neither processing instruction nodes nor comment nodes were included in the tree that represents the stylesheet.
The normal restrictions on the children of the root node are relaxed for the result tree. The result tree may have any sequence of nodes as children that would be possible for an element node. In particular, it may have text node children, and any number of element node children. When written out using the XML output method (see 16 Output), it is possible that a result tree will not be a well-formed XML document; however, it will always be a well-formed external general parsed entity.
When the source tree is created by parsing a well-formed XML document, the root node of the source tree will automatically satisfy the normal restrictions of having no text node children and exactly one element child. When the source tree is created in some other way, for example by using the DOM, the usual restrictions are relaxed for the source tree as for the result tree.
Every node also has an associated URI called its base URI, which is used for resolving attribute values that represent relative URIs into absolute URIs. The base URI is determined as follows:
The base URI for a root node is the URI of the document entity.
The base URI for an element node is as specified in Section 4.2 of [XMLBASE].
The base URI for a processing instruction node is the base URI that Section 4.3 of [XMLBASE] specifies would be applicable to a URI reference occurring in the content of the processing instruction.
The base URI for a text node, a comment node or an attribute node is the base URI of the parent of the node.
The base URI for a namespace node is implementation-dependent.
The root node has a mapping that gives the URI for each unparsed entity declared in the document's DTD. The URI is generated from the system identifier and public identifier specified in the entity declaration. The XSLT processor may use the public identifier to generate a URI for the entity instead of the URI specified in the system identifier. If the XSLT processor does not use the public identifier to generate the URI, it must use the system identifier; if the system identifier is a relative URI, it must be resolved into an absolute URI using the URI of the resource containing the entity declaration as the base URI [RFC2396].
After the tree for a source document or stylesheet document has been constructed, but before it is otherwise processed by XSLT, some text nodes are stripped. A text node is never stripped unless it contains only whitespace characters. Stripping the text node removes the text node from the tree. The stripping process takes as input a set of element names for which whitespace must be preserved. The stripping process is applied to both stylesheets and source documents, but the set of whitespace-preserving element names is determined differently for stylesheets and for source documents.
A text node is preserved if any of the following apply:
The element name of the parent of the text node is in the set of whitespace-preserving element names.
The text node contains at least one non-whitespace character. As in XML, a whitespace character is #x20, #x9, #xD or #xA.
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 text node is stripped.
The xml:space
attributes are not stripped from the
tree.
Note:
This implies that if an xml:space
attribute is
specified on a literal result element, it will be included in the
result.
For stylesheets, the set of whitespace-preserving element names
consists of just xsl:text
.
For source documents, the set of
whitespace-preserving element names is specified by
xsl:strip-space
and xsl:preserve-space
top-level elements. Whether an
element name is included in the set of whitespace-preserving names is
determined by the best match amongst xsl:strip-space
or
xsl:preserve-space
elements: 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 NameTests; an element name matches an
xsl:strip-space
or xsl:preserve-space
element if it matches one of the NameTests. An element matches a NameTest if and only if the NameTest would be true for the
element as an XPath node
test. When more than one xsl:strip-space
and
xsl:preserve-space
element matches, the best matching
element is determined by the best matching NameTest. This is determined in the
same way as with 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.
It is an error if this leaves more than one match. An XSLT processor may signal the error; if it does not signal the error, it must recover by choosing, from amongst the matches that are left, the one that occurs last in the stylesheet.
In a tree constructed by parsing an XML document, the following constraints relating to namespace nodes will be satisfied:
If an element node has an expanded-name with a non-null namespace URI, then that element node will have at least one namespace node whose string-value is the same as that namespace URI.
If an attribute node has an expanded-name with a non-null namespace URI, then the parent element of that attribute will have at least one namespace node whose string-value is the same as that namespace URI and whose expanded-name has a non-empty local part.
If an element node has a namespace node with an expanded-name with a non-empty local part, then every child element of that element will also have a namespace node with that expanded-name (possibly with a different string-value).
Every element has a namespace node whose expanded-name has
local-part xml
and whose string-value is
http://www.w3.org/XML/1998/namespace
.
However, when a tree is being constructed as the result of an XSLT
transformation, these constraints may not be satisfied. In particular,
since xsl:element
and xsl:attribute
instructions do not create namespace nodes, they will often cause
these constraints not to be satisfied. [Definition: The process of
namespace fixup transforms a result tree by adding
namespace nodes so that it satisfies these constraints.]
What namespace nodes are added and where they are added by
namespace fixup is implementation-dependent, provided that the
resulting tree satisfies the constraints and provided that all
namespaces nodes in the resulting tree are allowable,
where a namespace node is allowable if any of the following conditions
applies:
The namespace node was in the tree before namespace fixup.
The local-part of the expanded-name of the namespace node is
xml
.
The namespace node has a string-value equal to the namespace URI of the expanded-name of the element that is the parent of the namespace node.
The namespace node has a string-value equal to the namespace URI of the expanded-name of an attribute of the element that is the parent of the namespace node; this applies only if the local part of the expanded-name of the namespace node is non-empty.
The element that is the parent of the namespace node has a parent element with a namespace node that is allowable and that has the same expanded-name and same string-value as the other namespace node; this applies only if the local part of the expanded-name of the namespace node is non-empty.
Namespace fixup must not result in an element having multiple namespace nodes with the same expanded-name.
Namespace fixup is performed in two situations:
It is applied before a result tree is output (see 16 Output).
It is applied when a tree is constructed and bound to a variable by a variable-binding element with content (see 11.2 Values of Variables and Parameters).
Editorial note | |
What about stylesheet parameters that are node-sets? |
Editorial note | |
What about extension functions returning node-sets? |
XSLT uses the expression language defined by XPath [XPath]. 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 the result tree.
[Definition: An expression must match the XPath production Expr.]
Expressions occur as the value of certain attributes on XSLT-defined elements and within curly braces in attribute value templates.
In XSLT, an outermost expression (i.e. an expression that is not part of another expression) gets its context as follows:
the context node comes from the current node
the context position comes from the position of the current node in the current node list; the first position is 1
the context size comes from the size of the current node list
the variable bindings are the bindings in scope on the element which has the attribute in which the expression occurs (see 11 Variables and Parameters)
the set of namespace declarations are those in scope on the
element which has the attribute in which the expression occurs;
this includes the implicit declaration of the prefix xml
required by the the XML Namespaces Recommendation [XML Names];
the default
namespace (as declared by xmlns
) is not part of this
set
the function library consists of the core function library together with the additional functions defined in 12 Additional Functions and extension functions as described in 14 Extensions; it is an error for an expression to include a call to any other function
A list of source nodes is processed to create a result tree fragment. The result tree is constructed by processing a list containing just the root node. A list of source nodes is processed by appending the result tree structure created by processing each of the members of the list in order. A node is processed by finding all the template rules with patterns that match the node, and choosing the best amongst them; the chosen rule's template is then instantiated with the node as the current node and with the list of source nodes as the current node list. A template typically contains instructions that select an additional list of source nodes for processing. The process of matching, instantiation and selection is continued recursively until no new source nodes are selected for processing.
Implementations are free to process the source document in any way that produces the same result as if it were processed using this processing model.
[Definition: Template rules identify the nodes to which they apply by using a pattern. As well as being used in template rules, patterns are used for numbering (see 7.7 Numbering) and for declaring keys (see 12.2 Keys). A pattern specifies a set of conditions on a node. A node that satisfies the conditions matches the pattern; a node that does not satisfy the conditions does not match the pattern. The syntax for patterns is a subset of the syntax for expressions. In particular, location paths that meet certain restrictions can be used as patterns. An expression that is also a pattern always evaluates to an object of type node-set. A node matches a pattern if the node is a member of the result of evaluating the pattern as an expression with respect to some possible context; the possible contexts are those whose context node is the node being matched or one of its ancestors.]
Here are some examples of patterns:
para
matches any para
element
*
matches any element
chapter|appendix
matches any
chapter
element and any appendix
element
olist/item
matches any item
element with
an olist
parent
appendix//para
matches any para
element with
an appendix
ancestor element
/
matches the root node
text()
matches any text node
processing-instruction()
matches any processing
instruction
node()
matches any node other than an attribute
node and the root node
id("W11")
matches the element with unique ID
W11
para[1]
matches any para
element
that is the first para
child element of its
parent
*[position()=1 and self::para]
matches any
para
element that is the first child element of its
parent
para[last()=1]
matches any para
element that is the only para
child element of its
parent
items/item[position()>1]
matches any
item
element that has an items
parent and that is not the
first item
child of its parent
item[position() mod 2 = 1]
would be true for any
item
element that is an odd-numbered item
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
A pattern must match the grammar for Pattern. A Pattern is
a set of location path patterns separated by |
. A
location path pattern is a location path whose steps all use only the
child
or attribute
axes. Although patterns
must not use the descendant-or-self
axis, patterns may
use the //
operator as well as the /
operator. Location path patterns can also start with an
id or key
function call
with a literal argument. Predicates in a pattern can use arbitrary
expressions just like predicates in a location path.
[1] | Pattern | ::= | LocationPathPattern |
| Pattern '|' LocationPathPattern | |||
[2] | LocationPathPattern | ::= | '/' RelativePathPattern? |
| IdKeyPattern (('/' | '//') RelativePathPattern)? | |||
| '//'? RelativePathPattern | |||
[3] | IdKeyPattern | ::= | 'id' '(' Literal ')' |
| 'key' '(' Literal ',' Literal ')' | |||
[4] | RelativePathPattern | ::= | StepPattern |
| RelativePathPattern '/' StepPattern | |||
| RelativePathPattern '//' StepPattern | |||
[5] | StepPattern | ::= |
ChildOrAttributeAxisSpecifier
NodeTest
Predicate*
|
[6] | ChildOrAttributeAxisSpecifier | ::= | AbbreviatedAxisSpecifier |
| ('child' | 'attribute') '::' |
A pattern is defined to match a node if and only if there is possible context such that when the pattern is evaluated as an expression with that context, the node is a member of the resulting node-set. When a node is being matched, the possible contexts have a context node that is the node being matched or any ancestor of that node, and a context node list containing just the context node.
For example, p
matches any p
element,
because for any p
if the expression p
is
evaluated with the parent of the p
element as context the
resulting node-set will contain that p
element as one of
its members.
Note:
This matches even a p
element that is the
document element, since the document root is the parent of the
document element.
Although the semantics of patterns are specified indirectly in
terms of expression evaluation, it is easy to understand the meaning
of a pattern directly without thinking in terms of expression
evaluation. In a pattern, |
indicates alternatives; a
pattern with one or more |
separated alternatives matches
if any one of the alternative matches. A pattern that consists of a
sequence of StepPatterns separated by
/
or //
is matched from right to left. The
pattern only matches if the rightmost StepPattern matches and a suitable element
matches the rest of the pattern; if the separator is /
then only the parent is a suitable element; if the separator is
//
, then any ancestor is a suitable element. A StepPattern that uses the child axis matches
if the NodeTest is true for the
node and the node is not an attribute node. A StepPattern that uses the attribute axis
matches if the NodeTest is true
for the node and the node is an attribute node. When []
is present, then the first PredicateExpr in a StepPattern is evaluated with the node being
matched as the context node and the siblings of the context node that
match the NodeTest as the
context node list, unless the node being matched is an attribute node,
in which case the context node list is all the attributes that have
the same parent as the attribute being matched and that match the NameTest.
For example
appendix//ulist/item[position()=1]
matches a node if and only if all of the following are true:
the NodeTest item
is
true for the node and the node is not an attribute; in other words the
node is an item
element
evaluating the PredicateExpr
position()=1
with the node as context node and the
siblings of the node that are item
elements as the
context node list yields true
the node has a parent that matches
appendix//ulist
; this will be true if the parent is a
ulist
element that has an appendix
ancestor
element.
A template rule is specified with the xsl:template
element. The match
attribute is a Pattern that identifies the source node or nodes
to which the rule applies. The match
attribute is
required unless the xsl:template
element has a
name
attribute (see 6 Named Templates).
It is an error for the value of the match
attribute to
contain a VariableReference. The
content of the xsl:template
element is the template that
is instantiated when the template rule is applied.
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:inline-sequence
formatting object with a
font-weight
property of bold
.
<xsl:template match="emph"> <fo:inline-sequence font-weight="bold"> <xsl:apply-templates/> </fo:inline-sequence> </xsl:template>
Note:
Examples in this document use the fo:
prefix for
the namespace http://www.w3.org/1999/XSL/Format
, which is
the namespace of the formatting objects defined in [XSL].
As described next, the xsl:apply-templates
element
recursively processes the children of the source element.
This example creates a block for a chapter
element and
then processes its immediate children.
<xsl:template match="chapter"> <fo:block> <xsl:apply-templates/> </fo:block> </xsl:template>
In the absence of a select
attribute, the
xsl:apply-templates
instruction processes all of the
children of the current node, including text nodes. However, text
nodes that have been stripped as specified in 3.4 Whitespace Stripping
will not be processed. If stripping of whitespace nodes has not been
enabled for an element, then all whitespace in the content of the
element will be processed as text, and thus whitespace
between child elements will count in determining the position of a
child element as returned by the position
function.
A select
attribute can be used to process nodes
selected by an expression instead of processing all children. The
value of the select
attribute is an expression. The expression must
evaluate to a node-set. The selected set of nodes is processed in
document order, unless a sorting specification is present (see
10 Sorting). The following example processes all of the
author
children of the author-group
:
<xsl:template match="author-group"> <fo:inline-sequence> <xsl:apply-templates select="author"/> </fo:inline-sequence> </xsl:template>
The following example processes all of the given-name
s
of the author
s that are children of
author-group
:
<xsl:template match="author-group"> <fo:inline-sequence> <xsl:apply-templates select="author/given-name"/> </fo:inline-sequence> </xsl:template>
This example processes all of the heading
descendant
elements of the book
element.
<xsl:template match="book"> <fo:block> <xsl:apply-templates select=".//heading"/> </fo:block> </xsl:template>
It is also possible to process elements that are not descendants of
the current 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>
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>
Note:
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.
Note:
Typically, xsl:apply-templates
is used to
process only nodes that are descendants of the current 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 current 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 source node to match more than one template rule. The template rule to be used is determined as follows:
First, all matching template rules that have lower import precedence than the matching template rule or rules with the highest import precedence are eliminated from consideration.
Next, all matching template rules that have lower priority
than the matching template rule or rules with the highest priority are
eliminated from consideration. The priority of a template rule is
specified by the priority
attribute on the template rule.
The value of this must be a real number (positive or negative),
matching the production Number
with an optional leading minus sign (-
). [Definition: The default
priority is computed as follows:]
If the pattern contains multiple alternatives separated by
|
, then it is treated equivalently to a set of template
rules, one for each alternative.
If the pattern has the form of a QName preceded by a ChildOrAttributeAxisSpecifier
or has the form
processing-instruction(
Literal)
preceded by a ChildOrAttributeAxisSpecifier,
then the priority is 0.
If the pattern has the form NCName:*
preceded by a
ChildOrAttributeAxisSpecifier,
then the priority is -0.25.
Otherwise, if the pattern consists of just a NodeTest preceded by a ChildOrAttributeAxisSpecifier, then the priority is -0.5.
Otherwise, the priority is 0.5.
Thus, the most common kind of pattern (a pattern that tests for a node with a particular type and a particular expanded-name) has priority 0. The next less specific kind of pattern (a pattern that tests for a node with a particular type and an expanded-name with a particular namespace URI) has priority -0.25. Patterns less specific than this (patterns that just tests for nodes with particular types) have priority -0.5. Patterns more specific than the most common kind of pattern have priority 0.5.
It is an error if this leaves more than one matching template rule. An XSLT processor may signal the error; if it does not signal the error, it must recover by choosing, from amongst the matching template rules that are left, the one that occurs last in the stylesheet.
A template rule that is being used to override a template rule in
an imported stylesheet (see 5.5 Conflict Resolution for Template Rules) can use the
xsl:apply-imports
element to invoke the overridden
template rule.
[Definition: At any point in the processing of a stylesheet, there is a
current template rule. Whenever a template rule is
chosen by matching a pattern, the template rule becomes the current
template rule for the instantiation of the rule's template. When an
xsl:for-each
element is instantiated, the current
template rule becomes null for the instantiation of the content of the
xsl:for-each
element.]
xsl:apply-imports
processes the current node using
only template rules that were imported into the stylesheet element
containing the current template rule; the node is processed in the
current template rule's mode.
An xsl:apply-imports
element may use
xsl:with-param
child elements to pass
parameters to the matching template rule's template
(see 11.6 Passing Parameters to Templates). It is an error if
xsl:apply-imports
is instantiated when the current
template rule is null.
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>
Modes allow an element to be processed multiple times, each time producing a different result.
Both xsl:template
and xsl:apply-templates
have an optional mode
attribute. The value of the
mode
attribute is a QName, which is expanded as described
in 2.4 Qualified Names. If xsl:template
does not have
a match
attribute, it must not have a mode
attribute. If an xsl:apply-templates
element has a
mode
attribute, then it applies only to those template
rules from xsl:template
elements that have a
mode
attribute with the same value; if an
xsl:apply-templates
element does not have a
mode
attribute, then it applies only to those template
rules from xsl:template
elements that do not have a
mode
attribute.
There is a built-in template rule to allow recursive processing to continue in the absence of a successful pattern match by an explicit template rule in the stylesheet. This template rule applies to both element nodes and the root node. The following shows the equivalent of the built-in template rule:
<xsl:template match="*|/"> <xsl:apply-templates/> </xsl:template>
There is also a built-in template rule for each mode, which allows
recursive processing to continue in the same mode in the absence of a
successful pattern match by an explicit template rule in the
stylesheet. This template rule applies to both element nodes and the
root node. The following shows the equivalent of the built-in
template rule for mode m
.
<xsl:template match="*|/" mode="m"> <xsl:apply-templates mode="m"/> </xsl:template>
There is also a built-in template rule for text and attribute nodes that copies text through:
<xsl:template match="text()|@*"> <xsl:value-of select="."/> </xsl:template>
The built-in template rule for processing instructions and comments is to do nothing.
<xsl:template match="processing-instruction()|comment()"/>
The built-in template rule for namespace nodes is also to do nothing. There is no pattern that can match a namespace node; so, the built-in template rule is the only template rule that is applied for namespace nodes.
The built-in template rules are treated as if they were imported implicitly before the stylesheet and so have lower import precedence than all other template rules. Thus, the author can override a built-in template rule by including an explicit template rule.
Templates can be invoked by name. An xsl:template
element with a name
attribute specifies a named template.
The value of the name
attribute is a QName, which is expanded as described
in 2.4 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
element invokes a template by name; it has a required
name
attribute that identifies the template to be
invoked. Unlike xsl:apply-templates
,
xsl:call-template
does not change the current node or the
current node list.
The match
, mode
and priority
attributes on an
xsl:template
element do not affect whether the template
is invoked by an xsl:call-template
element. Similarly,
the name
attribute on an xsl:template
element does not affect whether the template is invoked by an
xsl:apply-templates
element.
It is an error if a stylesheet contains more than one template with the same name and same import precedence.
This section describes instructions that directly create nodes in the result tree.
In a template, an element in the stylesheet that does not belong to the XSLT namespace and that is not an extension element (see 14.1 Using Extension Elements) is instantiated to create an element node with the same expanded-name. The content of the element is a template, which is instantiated to give the content of the created element node. The created element node will have the attribute nodes that were present on the element node in the stylesheet tree, other than attributes with names in the XSLT namespace.
The created element node will also 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 the
XSLT namespace URI (http://www.w3.org/1999/XSL/Transform
), a
namespace URI declared as an extension namespace (see 14.1 Using Extension Elements), or a namespace URI designated as an
excluded namespace. A namespace URI is designated as an excluded
namespace by using an exclude-result-prefixes
attribute
on an xsl:stylesheet
element or an
xsl:exclude-result-prefixes
attribute on a literal result
element. The value of both these attributes is a whitespace-separated
list of namespace prefixes. The namespace bound to each of the
prefixes is designated as an excluded namespace. It is an error if
there is no namespace bound to the prefix on the element bearing the
exclude-result-prefixes
or
xsl:exclude-result-prefixes
attribute. The default
namespace (as declared by xmlns
) may be designated as an
excluded namespace by including #default
in the list of
namespace prefixes. The designation of a namespace as an excluded
namespace is effective within the subtree of the stylesheet rooted at
the element bearing the exclude-result-prefixes
or
xsl:exclude-result-prefixes
attribute;
a subtree rooted at an xsl:stylesheet
element
does not include any stylesheets imported or included by children
of that xsl:stylesheet
element.
Note:
When a stylesheet uses a namespace declaration only for the
purposes of addressing the source tree, specifying the prefix in the
exclude-result-prefixes
attribute will avoid superfluous
namespace declarations in the result tree.
The value of an attribute of a literal result element is
interpreted as an attribute
value template: it can contain expressions contained
in curly braces ({}
).
Editorial note | |
Add note warning against using AVTs with
xml:base . |
[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.] This applies to:
the namespace URI in the expanded-name of a literal result element in the stylesheet
the namespace URI in the expanded-name of an attribute specified on a literal result element in the stylesheet
the string-value of a namespace node on a literal result element in the stylesheet
[Definition: A stylesheet can use the
xsl:namespace-alias
element to declare that one namespace
URI is an alias for another namespace URI.] When
a literal namespace
URI has been declared to be an alias for another namespace
URI, then the namespace URI in the result tree will be the namespace
URI that the literal namespace URI is an alias for, instead of the
literal namespace URI itself. The xsl:namespace-alias
element declares that the namespace URI bound to the prefix specified
by the stylesheet-prefix
attribute is an alias for the
namespace URI bound to the prefix specified by the
result-prefix
attribute. 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 a namespace URI
is declared to be an alias for multiple different namespace URIs, then
the declaration with the highest import precedence is used. It is
an error if there is more than one such declaration. An XSLT
processor may signal the error; if it does not signal the error, it
must recover by choosing, from amongst the declarations with the
highest import precedence, the one that occurs last in the
stylesheet.
When literal result elements are being used to create element, attribute, or namespace nodes that use the XSLT namespace URI, the stylesheet must use an alias. For example, the stylesheet
<xsl:stylesheet version="1.1" xmlns:xsl="http://www.w3.org/1999/XSL/Transform" xmlns:fo="http://www.w3.org/1999/XSL/Format" xmlns:axsl="http://www.w3.org/1999/XSL/TransformAlias"> <xsl:namespace-alias stylesheet-prefix="axsl" result-prefix="xsl"/> <xsl:template match="/"> <axsl:stylesheet> <xsl:apply-templates/> </axsl:stylesheet> </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>
Note:
It may be necessary also to use aliases for namespaces other than the XSLT namespace URI. For example, 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.
xsl:element
The xsl:element
element allows an element to be
created with a computed name. The expanded-name of the
element to be created is specified by a required name
attribute and an optional namespace
attribute. The
content of the xsl:element
element is a template for the
attributes and children of the created element.
The name
attribute is interpreted as an attribute value template.
It is an error if the string that results from instantiating the
attribute value template is not a QName. An XSLT processor may signal
the error; if it does not signal the error, then it must recover
by making the result of instantiating the xsl:element
element be the sequence of nodes created by instantiating
the content of the xsl:element
element, excluding
any initial attribute nodes. If the namespace
attribute is
not present then the QName is
expanded into an expanded-name using the namespace declarations in
effect for the xsl:element
element, including any default
namespace declaration.
If the namespace
attribute is present, then it also is
interpreted as an attribute
value template. The string that results from instantiating
the attribute value template should be a URI reference. It is not an
error if the string is not a syntactically legal URI reference. If
the string is empty, then the expanded-name of the element has a null
namespace URI. Otherwise, the string is used as the namespace URI of
the expanded-name of the element to be created. The local part of the
QName specified by the
name
attribute is used as the local part of the
expanded-name of the element to be created.
XSLT processors may make use of the prefix of the QName specified in the
name
attribute when selecting the prefix used for
outputting the created element as XML; however, they are not required
to do so.
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
. The expanded-name of the
attribute to be created is specified by a required name
attribute and an optional namespace
attribute.
Instantiating an xsl:attribute
element adds an attribute
node to the containing result element node. The content of the
xsl:attribute
element is a template for the value of the
created attribute.
The name
attribute is interpreted as an attribute value template.
It is an error if the string that results from instantiating the
attribute value template is not a QName or is the string
xmlns
. An XSLT processor may signal the error; if it
does not signal the error, it must recover by not adding the attribute
to the result tree. If the namespace
attribute is not
present, then the QName is
expanded into an expanded-name 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 also is
interpreted as an attribute
value template. The string that results from instantiating
it should be a URI reference. It is not an error if the string is not
a syntactically legal URI reference. If the string is empty, then the
expanded-name of the attribute has a null namespace URI. Otherwise,
the string is used as the namespace URI of the expanded-name of the
attribute to be created. The local part of the QName specified by the
name
attribute is used as the local part of the
expanded-name of the attribute to be created.
XSLT processors may make use of the prefix of the QName specified in the
name
attribute when selecting the prefix used for
outputting the created attribute as XML; however, they are not
required to do so and, if the prefix is xmlns
, they must
not do so. Thus, although it is not an error to do:
<xsl:attribute name="xmlns:xsl" namespace="whatever">http://www.w3.org/1999/XSL/Transform</xsl:attribute>
it will not result in a namespace declaration being output.
Adding an attribute to an element replaces any existing attribute of that element with the same expanded-name.
The following are all errors:
Adding an attribute to an element after children have been added to it; implementations may either signal the error or ignore the attribute.
Adding an attribute to a node that is not an element; implementations may either signal the error or ignore the attribute.
Creating nodes other than text nodes during the instantiation
of the content of the xsl:attribute
element;
implementations may either signal the error or ignore the offending
nodes together with their
content.
Note:
When an xsl:attribute
contains a text node with
a newline, then the XML output must contain a character reference.
For example,
<xsl:attribute name="a">x y</xsl:attribute>
will result in the output
a="x
y"
(or with any equivalent character reference). The XML output cannot be
a="x y"
This is because XML 1.0 requires newline characters in attribute values to be normalized into spaces but requires character references to newline characters not to be normalized. The attribute values in the data model represent the attribute value after normalization. If a newline occurring in an attribute value in the tree were output as a newline character rather than as character reference, then the attribute value in the tree created by reparsing the XML would contain a space not a newline, which would mean that the tree had not been output correctly.
The xsl:attribute-set
element defines a named set of
attributes. The name
attribute specifies the name of the
attribute set. The value of the name
attribute is a QName, which is expanded as described
in 2.4 Qualified Names. The content of the xsl:attribute-set
element consists of zero or more xsl:attribute
elements
that specify the attributes in the set.
Attribute sets are used by specifying a
use-attribute-sets
attribute on xsl:element
,
xsl:copy
(see 7.5 Copying) or
xsl:attribute-set
elements. The value of the
use-attribute-sets
attribute is a whitespace-separated
list of names of attribute sets. Each name is specified as a QName, which is expanded as described
in 2.4 Qualified Names. Specifying a
use-attribute-sets
attribute is equivalent to adding
xsl:attribute
elements for each of the attributes in each
of the named attribute sets to the beginning of the content of the
element with the use-attribute-sets
attribute, in the
same order in which the names of the attribute sets are specified in
the use-attribute-sets
attribute. It is an error if use
of use-attribute-sets
attributes on
xsl:attribute-set
elements causes an attribute set to
directly or indirectly use itself.
Attribute sets can also be used by specifying an
xsl:use-attribute-sets
attribute on a literal result
element. The value of the xsl:use-attribute-sets
attribute is a whitespace-separated list of names of attribute sets.
The xsl:use-attribute-sets
attribute has the same effect
as the use-attribute-sets
attribute on
xsl:element
with the additional rule that attributes
specified on the literal result element itself are treated as if they
were specified by xsl:attribute
elements before any
actual xsl:attribute
elements but after any
xsl:attribute
elements implied by the
xsl:use-attribute-sets
attribute. Thus, for a literal
result element, attributes from attribute sets named in an
xsl:use-attribute-sets
attribute will be added first, in
the order listed in the attribute; next, attributes specified on the
literal result element will be added; finally, any attributes
specified by xsl:attribute
elements will be added. Since
adding an attribute to an element replaces any existing attribute of
that element with the same name, this means that attributes specified
in attribute sets can be overridden by attributes specified on the
literal result element itself.
The template within each xsl:attribute
element in an
xsl:attribute-set
element is instantiated each time the
attribute set is used; it is instantiated using the same current node
and current node list as is used for instantiating the element bearing
the use-attribute-sets
or
xsl:use-attribute-sets
attribute. However, it is the
position in the stylesheet of the xsl:attribute
element
rather than of the element bearing the use-attribute-sets
or xsl:use-attribute-sets
attribute that determines which
variable bindings are visible (see 11 Variables and Parameters); thus,
only variables and parameters declared by top-level xsl:variable
and
xsl:param
elements are visible.
The following example creates a named attribute set
title-style
and uses it in a template rule.
<xsl:template match="chapter/heading"> <fo:block quadding="start" 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>
Multiple definitions of an attribute set with the same
expanded-name are merged. An attribute from a definition that has
higher import precedence
takes precedence over an attribute from a definition that has lower
import precedence. It
is an error if there are two attribute sets that have the same
expanded-name and equal import precedence and that both contain
the same attribute, unless there is a definition of the attribute set
with higher import
precedence that also contains the attribute. An XSLT
processor may signal the error; if it does not signal the error, it
must recover by choosing from amongst the definitions that specify the
attribute that have the highest import precedence the one that was
specified last in the stylesheet. Where the attributes in an
attribute set were specified is relevant only in merging the
attributes into the attribute set; it makes no difference when the
attribute set is used. For each
attribute set name occurring in a use-attribute-sets
attribute on
an xsl:attribute-set
element, all definitions of an
attribute set with that name must be merged before the
use-attribute-sets
attribute is replaced by the
equivalent sequence of xsl:attribute
child elements. Any
use-attribute-sets
attribute on an
xsl:attribute-set
element must be replaced by the
equivalent sequence of xsl:attribute
child elements
before that xsl:attribute-set
element is
merged with other xsl:attribute-set
elements with the
same expanded-name. When xsl:attribute-set
elements with
the same expanded-name are merged, any xsl:attribute
child elements added to replace a use-attribute-sets
attribute are treated exactly as if they had originally been specified
in the stylesheet as child elements.
A template can also contain text nodes. Each text node in a template remaining after whitespace has been stripped as specified in 3.4 Whitespace Stripping will create a text node with the same string-value in the result tree. Adjacent text nodes in the result tree are automatically merged.
Note that 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 externalized as an XML document
(unless output escaping is disabled as described in 16.4 Disabling Output Escaping).
Literal data characters may also be wrapped in an
xsl:text
element. This wrapping may change what
whitespace characters are stripped (see 3.4 Whitespace Stripping) but
does not affect how the characters are handled by the XSLT processor
thereafter.
Note:
The xml:lang
and xml:space
attributes are not treated specially by XSLT. In particular,
it is the responsibility of the stylesheet author explicitly
to generate any xml:lang
or xml:space
attributes that are needed in the result;
specifying an xml:lang
or xml:space
attribute on an element in the XSLT namespace will not cause any
xml:lang
or xml:space
attributes to appear
in the result.
The xsl:processing-instruction
element is instantiated
to create a processing instruction node. The content of the
xsl:processing-instruction
element is a template for the
string-value of the 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.
For example, this
<xsl:processing-instruction name="xml-stylesheet">href="book.css" type="text/css"</xsl:processing-instruction>
would create the processing instruction
<?xml-stylesheet href="book.css" type="text/css"?>
It is an error if the string that results from instantiating the
name
attribute is not both an NCName and a PITarget. An XSLT processor may signal
the error; if it does not signal the error, it must recover by not
adding the processing instruction to the result tree.
Note:
This means that xsl:processing-instruction
cannot be used to output an XML declaration. The
xsl:output
element should be used instead (see 16 Output).
It is an error if instantiating the content of
xsl:processing-instruction
creates nodes other than
text nodes. An XSLT processor may signal the error; if it does not
signal the error, it must recover by ignoring the offending nodes
together with their content.
It is an error if the result of instantiating the content of the
xsl:processing-instruction
contains the string
?>
. An XSLT processor may signal the error; if it does
not signal the error, it must recover by inserting a space after any
occurrence of ?
that is followed by a >
.
The xsl:comment
element is instantiated to create a
comment node in the result tree. The content of the
xsl:comment
element is a template for the string-value of
the comment node.
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!-->
It is an error if instantiating the content of
xsl:comment
creates nodes other than text nodes. An
XSLT processor may signal the error; if it does not signal the error,
it must recover by ignoring the offending nodes together with their
content.
It is an error if the result of instantiating the content of the
xsl:comment
contains the string --
or ends
with -
. An XSLT processor may signal the error; if it
does not signal the error, it must recover by inserting a space after
any occurrence of -
that is followed by another
-
or that ends the comment.
The xsl:copy
element provides an easy way of copying
the current node. Instantiating the xsl:copy
element
creates a copy of the current node. The namespace nodes of the
current node are automatically copied as well, but the attributes and
children of the node are not automatically copied. The content of the
xsl:copy
element is a template for the attributes and
children of the created node; the content is instantiated only for
nodes of types that can have attributes or children (i.e. root
nodes and element nodes).
The xsl:copy
element may have a
use-attribute-sets
attribute (see 7.1.4 Named Attribute Sets). This is used only when copying element
nodes.
The root node is treated specially because the root node of the
result tree is created implicitly. When the current node is the root
node, xsl:copy
will not create a root node, but will just
use the content template.
For example, the identity transformation can be written using
xsl:copy
as follows:
<xsl:template match="@*|node()"> <xsl:copy> <xsl:apply-templates select="@*|node()"/> </xsl:copy> </xsl:template>
When the current node is an attribute, then if it would be an error
to use xsl:attribute
to create an attribute with the same
name as the current node, then it is also an error to use
xsl:copy
(see 7.1.3 Creating Attributes with xsl:attribute).
When the current node is a namespace node, then copying it adds a namespace node to the containing node in the result tree. It is an error if this containing node is not an element; implementations may either signal the error or ignore the namespace node. It is an error to add a namespace node to an element after children have been added to it or after attributes have been added to it; implementations may either signal an error or ignore the namespace node. It is an error to add a namespace node to an element if the element already has a namespace node with the same name, unless both namespace nodes have the same string-value, in which case the duplicate is ignored. It is an error to add a namespace node to an element if the namespace node has a null name and the element has a null namespace URI.
The following example shows how xml:lang
attributes
can be easily copied through from source to result. If a stylesheet
defines the following named template:
<xsl:template name="apply-templates-copy-lang"> <xsl:for-each select="@xml:lang"> <xsl:copy/> </xsl:for-each> <xsl:apply-templates/> </xsl:template>
then it can simply do
<xsl:call-template name="apply-templates-copy-lang"/>
instead of
<xsl:apply-templates/>
when it wants to copy the xml:lang
attribute.
Within a template, the xsl:value-of
element can be
used to compute generated text, for example by extracting text from
the source tree or by inserting the value of a variable. The
xsl:value-of
element does this with an expression that is specified as the
value of the select
attribute. Expressions can
also be used inside attribute values of literal result elements by
enclosing the expression in curly braces ({}
).
xsl:value-of
The xsl:value-of
element is instantiated to create a
text node in the result tree. The required select
attribute is an expression;
this expression is evaluated and the resulting object is converted to
a string as if by a call to the string
function. The string specifies the string-value of the created text
node. If the string is empty, no text node will be created. The
created text node will be merged with any adjacent text nodes.
The xsl:copy-of
element can be used to copy a node-set
over to the result tree without converting it to a string. See 11.3 Using Values of Variables and Parameters with
xsl:copy-of.
For example, the following creates an HTML paragraph from a
person
element with given-name
and
family-name
attributes. The paragraph will contain the value
of the given-name
attribute of the current node followed
by a space and the value of the family-name
attribute of the
current node.
<xsl:template match="person"> <p> <xsl:value-of select="@given-name"/> <xsl:text> </xsl:text> <xsl:value-of select="@family-name"/> </p> </xsl:template>
For another example, the following creates an HTML paragraph from a
person
element with given-name
and
family-name
children elements. The paragraph will
contain the string-value of the first given-name
child
element of the current node followed by a space and the string-value
of the first family-name
child element of the current
node.
<xsl:template match="person"> <p> <xsl:value-of select="given-name"/> <xsl:text> </xsl:text> <xsl:value-of select="family-name"/> </p> </xsl:template>
The following precedes each procedure
element with a
paragraph containing the security level of the procedure. It assumes
that the security level that applies to a procedure is determined by a
security
attribute on the procedure element or on an
ancestor element of the procedure. It also assumes that if more than
one such element has a security
attribute then the
security level is determined by the element that is closest to the
procedure.
<xsl:template match="procedure"> <fo:block> <xsl:value-of select="ancestor-or-self::*[@security][1]/@security"/> </fo:block> <xsl:apply-templates/> </xsl:template>
[Definition: In an attribute value that is interpreted 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 braces ({}
)]. The
attribute value template is instantiated by replacing the expression
together with surrounding curly braces by the result of evaluating the
expression and converting the resulting object to a string as if by a
call to the string function. Curly braces are
not recognized in an attribute value in an XSLT stylesheet unless the
attribute is specifically stated to be one that is interpreted as an
attribute value template; in an element syntax summary, the value
of such attributes is surrounded by curly braces.
Note:
Not all attributes are interpreted as attribute value
templates. Attributes whose value is an expression or pattern,
attributes of top-level elements
and attributes that refer to named XSLT objects are not interpreted as
attribute value templates. In addition, xmlns
attributes
are not interpreted as attribute value templates; it would not be
conformant with the XML Namespaces Recommendation to do
this. The xsl:output
element is an
exception: although it is a top-level element, its attributes are all
interpreted as attribute value templates for consistency with
xsl:document
.
The following example creates an img
result element
from a photograph
element in the source; the value of the
src
attribute of the img
element is computed
from the value of the image-dir
variable and the
string-value of the href
child of the
photograph
element; the value of the width
attribute of the img
element is computed from the value
of the width
attribute of the size
child of
the photograph
element:
<xsl:variable name="image-dir">/images</xsl:variable> <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"/>
When an attribute value template is instantiated, a double left or right curly brace outside an expression will be replaced by a single curly brace. It is an error if a right curly brace occurs in an attribute value template outside an expression without being followed by a second right curly brace. A right curly brace inside a Literal in an expression is not recognized as terminating the expression.
Curly braces are not recognized recursively inside expressions. For example:
<a href="#{id({@ref})/title}">
is not allowed. Instead, use simply:
<a href="#{id(@ref)/title}">
The xsl:number
element is used to insert a formatted
number into the result tree. The number to be inserted may be
specified by an expression. The value
attribute contains
an expression. The expression
is evaluated and the resulting object is converted to a number as if
by a call to the number function. It is an error if the number is NaN, infinite
or less than 0.5; an XSLT processor may signal the error; if it does
not signal the error, it must recover by converting the number to a
string as if by a call to the string function
and inserting the resulting string into the result tree.
Otherwise, the number is
rounded to an integer and then converted to a string using the
attributes specified in 7.7.1 Number to String Conversion Attributes; in this
context, the value of each of these attributes is
interpreted as an attribute
value template. After conversion, the resulting string is
inserted in the result tree. For example, the following example
numbers a sorted list:
<xsl:template match="items"> <xsl:for-each select="item"> <xsl:sort select="."/> <p> <xsl:number value="position()" format="1. "/> <xsl:value-of select="."/> </p> </xsl:for-each> </xsl:template>
If no value
attribute is specified, then the
xsl:number
element inserts a number based on the position
of the current node in the source tree. The following attributes
control how the current node is to be numbered:
The level
attribute specifies what levels of the
source tree should be considered; it has the values
single
, multiple
or any
. The
default is single
.
The count
attribute is a pattern that specifies
what nodes should 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 type as the current node and, if
the current node has an expanded-name, with the same expanded-name as
the current node.
The from
attribute is a pattern that specifies
where counting starts.
In addition, the attributes specified in 7.7.1 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 list of
positive integers using the level
, count
and
from
attributes:
When level="single"
, it goes up to the first
node in the ancestor-or-self axis that matches
the count
pattern, and constructs a list of length one
containing one plus the number of preceding siblings of that ancestor
that match the count
pattern. If there is no such
ancestor, it constructs an empty list. If the from
attribute is specified, then the only ancestors that are searched are
those that are descendants of the nearest ancestor that matches the
from
pattern. Preceding siblings has the same meaning
here as with the preceding-sibling
axis.
When level="multiple"
, it constructs a list of all
ancestors of the current node in document order followed by the
element itself; it then selects from the list those nodes that match
the count
pattern; it then maps each node in the list to
one plus the number of preceding siblings of that node that match the
count
pattern. If the from
attribute is
specified, then the only ancestors that are searched are those that
are descendants of the nearest ancestor that matches the
from
pattern. Preceding siblings has the same meaning
here as with the preceding-sibling
axis.
When level="any"
, it constructs a list of length
one containing the number of nodes that match the count
pattern and belong to the set containing the current node and all
nodes at any level of the document that are before the current node in
document order, excluding any namespace and attribute nodes (in other
words the union of the members of the preceding
and
ancestor-or-self
axes).
If there are no matching nodes, it constructs an empty list.
If the from
attribute is specified, then only nodes after
the first node before the current node that match the
from
pattern are considered.
The list of numbers is then converted into a string using the attributes specified in 7.7.1 Number to String Conversion Attributes; in this context, the value of each of these attributes is interpreted as an attribute value template. After conversion, the resulting string is inserted in the result tree.
The following would 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 would 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.
<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>
The following example numbers notes sequentially within a chapter:
<xsl:template match="note"> <fo:block> <xsl:number level="any" from="chapter" format="(1) "/> <xsl:apply-templates/> </fo:block> </xsl:template>
The following example would number H4
elements in HTML
with a three-part label:
<xsl:template match="H4"> <fo:block> <xsl:number level="any" from="H1" count="H2"/> <xsl:text>.</xsl:text> <xsl:number level="any" from="H2" count="H3"/> <xsl:text>.</xsl:text> <xsl:number level="any" from="H3" count="H4"/> <xsl:text> </xsl:text> <xsl:apply-templates/> </fo:block> </xsl:template>
The following attributes are used to control conversion of a list of numbers into a string. The numbers are integers greater than 0. 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. The alphanumeric tokens (format tokens) specify the format
to be used for each number in the list. If the first token is a
non-alphanumeric token, then the constructed string will start with
that token; if the last token is non-alphanumeric token, then the
constructed string will end with that token. Non-alphanumeric tokens
that occur between two format tokens are separator tokens that are
used to join numbers in the list. The nth format token
will be used to format the nth number in the list. If
there are more numbers than format tokens, then the last format token
will be used to format remaining numbers. If there are no format
tokens, then a format token of 1
is used to format all
numbers. The format token specifies the string to be used to
represent the number 1. Each number after the first will be separated
from the preceding number by the separator token preceding the format
token used to format that number, or, if there are no separator
tokens, then by .
(a period character).
Format tokens are a superset of the allowed values for the
type
attribute for the OL
element in HTML
4.0 and 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),
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. Thus, a format token 1
generates the
sequence 1 2 ... 10 11 12 ...
, and a format token
01
generates the sequence 01 02 ... 09 10 11 12
... 99 100 101
.
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 ...
.
Any other format token indicates a numbering sequence that
starts with that token. If an implementation does not support a
numbering sequence that starts with that token, it must use a format
token of 1
.
When numbering with an alphabetic sequence, the lang
attribute specifies which language's alphabet is to be used; it has
the same range of values as xml:lang
[XML];
if no lang
value is specified, the language should be
determined from the system environment. Implementers should document
for which languages they support numbering.
Note:
Implementers should not make any assumptions about how numbering works in particular languages and should properly research the languages that they wish to support. The numbering conventions of many languages are very different from English.
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:
It is possible for two conforming XSLT processors not to
convert a number to exactly the same string. Some XSLT processors may not
support some languages. Furthermore, there may be variations possible
in the way conversions are performed for any particular language that
are not specifiable by the attributes on xsl:number
.
Future versions of XSLT may provide additional attributes to provide
control over these variations. Implementations may also use
implementation-specific namespaced attributes on
xsl:number
for this.
The grouping-separator
attribute gives the separator
used as a grouping (e.g. 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
. If only one
of the grouping-separator
and grouping-size
attributes is specified, then it is ignored.
Here are some examples of conversion specifications:
format="ア"
specifies Katakana
numbering
format="イ"
specifies Katakana
numbering in the "iroha" order
format="๑"
specifies numbering with
Thai digits
format="א" letter-value="traditional"
specifies "traditional" Hebrew numbering
format="ა" letter-value="traditional"
specifies Georgian numbering
format="α" letter-value="traditional"
specifies "classical" Greek numbering
format="а" letter-value="traditional"
specifies Old Slavic numbering
When the result has a known regular structure, it is useful to be
able to specify directly the template for selected nodes. The
xsl:for-each
instruction contains a template, which is
instantiated for each node selected by the expression specified by the
select
attribute. The select
attribute is
required. The expression must evaluate to a node-set. The template
is instantiated with the selected node as the current node, and with a list of all
of the selected nodes as the current node list. The nodes are
processed in document order, unless a sorting specification is present
(see 10 Sorting).
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>
There are two instructions in XSLT that support conditional
processing in a template: 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.
xsl:if
The xsl:if
element has a test
attribute,
which specifies an expression.
The content is a template. The expression is evaluated and the
resulting object is converted to a boolean as if by a call to the
boolean function. If the result is true, then
the content template is instantiated; otherwise, nothing is created.
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
The xsl:choose
element selects one among a number of
possible alternatives. It consists of a sequence of
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
template. When an xsl:choose
element is processed, each
of the xsl:when
elements is tested in turn, by evaluating
the expression and converting the resulting object to a boolean as if
by a call to the boolean function. The content
of the first, and only the first, xsl:when
element whose
test is true is instantiated. If no xsl:when
is true,
the content of the xsl:otherwise
element is
instantiated. If no xsl:when
element is true, and no
xsl:otherwise
element is present, nothing is created.
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>
Sorting is specified by adding xsl:sort
elements as
children of an xsl:apply-templates
or
xsl:for-each
element. The first xsl:sort
child specifies the primary sort key, the second xsl:sort
child specifies the secondary sort key and so on. When an
xsl:apply-templates
or xsl:for-each
element
has one or more xsl:sort
children, then instead of
processing the selected nodes in document order, it sorts the nodes
according to the specified sort keys and then processes them in sorted
order. When used in xsl:for-each
, xsl:sort
elements must occur first. When a template is instantiated by
xsl:apply-templates
and xsl:for-each
, the
current node list
consists of the complete list of nodes being processed in sorted
order.
xsl:sort
has a select
attribute whose
value is an expression. For
each node to be processed, the expression is evaluated with that node
as the current node and with the complete list of nodes being
processed in document
order as the current node list.
The resulting object is converted to a string as
if by a call to the string function; this string
is used as the sort key for that node. The default value of the
select
attribute is .
, which will cause the
string-value of the current node to be used as the sort key.
This string serves as a sort key for the node. The following
optional attributes on xsl:sort
control how the list of
sort keys are sorted; the values of all of these attributes are
interpreted as attribute
value templates.
order
specifies whether the strings should be
sorted in ascending or descending order; ascending
specifies ascending order; descending
specifies
descending order; the default is ascending
lang
specifies the language of the sort keys; it
has the same range of values as xml:lang
[XML]; if no lang
value is specified, the language
should be determined from the system environment
data-type
specifies the data type of the
strings; the following values are allowed:
text
specifies that the sort keys should be
sorted lexicographically in the culturally correct manner for the
language specified by lang
number
specifies that the sort keys should be
converted to numbers and then sorted according to the numeric value;
the sort key is converted to a number as if by a call to the
number function; the lang
attribute is ignored; in ascending order
a NaN precedes all other numeric values and in descending
order it follows them
a QName with a prefix is expanded into an expanded-name as described in 2.4 Qualified Names; the expanded-name identifies the data-type; the behavior in this case is not specified by this document
The default value is text
.
Note:
The XSL Working Group plans that future versions of XSLT will leverage XML Schemas to define further values for this attribute.
case-order
has the value
upper-first
or lower-first
; this applies
when data-type="text"
, and specifies that in ascending order upper-case
letters should sort before lower-case letters or vice-versa
respectively. For example, if lang="en"
, then A a B
b
are sorted in ascending
order with case-order="upper-first"
and a
A b B
are sorted in ascending
order with case-order="lower-first"
. In descending order, the effect is
reversed. For example, if lang="en"
, then b B a
A
are sorted in descending order with
case-order="upper-first"
. The default value is
language dependent.
Note:
It is possible for two conforming XSLT processors not to sort
exactly the same. Some XSLT processors may not support some
languages. Furthermore, there may be variations possible in the
sorting of any particular language that are not specified by the
attributes on xsl:sort
, for example, whether Hiragana or
Katakana is sorted first in Japanese. Future versions of XSLT may
provide additional attributes to provide control over these
variations. Implementations may also use implementation-specific
namespaced attributes on xsl:sort
for this.
Note:
It is recommended that implementers consult [UNICODE TR10] for information on internationalized sorting.
The sort must be stable: in the sorted list of nodes, any sub list that has sort keys that all compare equal must be in document order.
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>
A variable is a name that may be bound to a value. The value to
which a variable is bound (the value of the variable) can
be an object of any of the types that can be returned by expressions.
There are two elements that can be used to bind variables:
xsl:variable
and xsl:param
. The difference
is that the value specified on the xsl:param
variable is
only a default value for the binding; when the template or stylesheet
within which the xsl:param
element occurs is invoked,
parameters may be passed that are used in place of the default
values.
Both xsl:variable
and xsl:param
have a
required name
attribute, which specifies the name of the
variable. The value of the name
attribute is a QName, which is expanded as described
in 2.4 Qualified Names.
For any use of these variable-binding elements, there is a region of the stylesheet tree within which the binding is visible. The set of variable bindings in scope for an expression consists of those bindings that are visible at the point in the stylesheet where the expression occurs.
A variable-binding element can specify the value of the variable in three alternative ways.
If the variable-binding element has a select
attribute, then the value of the attribute must be an expression and the value of the variable
is the object that results from evaluating the expression. In this
case, the content must be empty.
If the variable-binding element does not have a select
attribute and has non-empty content (i.e. the variable-binding element
has one or more child nodes), then the content of the
variable-binding element specifies the value. The content of the
variable-binding element is a template; a new
document is constructed with a root node having as its children
the sequence of nodes that results from instantiating this template;
namespace fixup is
performed on this document (see 3.5 Namespace Fixup); the
value of the variable is a node-set that contains just the root node
of this newly constructed document.
The base URI of a node in this document is determined as
if all the nodes in the document came from a single entity whose URI
was the base URI of the variable-binding element (see 3.2 Base URI). Thus, the base URI of the root node will be equal
to the base URI of the variable-binding element; an
xml:base
attribute within this document will change the
base URI for its parent element and that element's descendants, just
as it would within a document constructed by parsing.
It is an error if a member of the sequence of nodes created by instantiating the template is an attribute node or a namespace node, since a root node cannot have an attribute node or a namespace node as a child. An XSLT processor may signal the error; if it does not signal the error, it must recover by not adding the attribute node or namespace node.
If the variable-binding element has empty content and does not have
a select
attribute, then the value of the variable is an
empty string. Thus
<xsl:variable name="x"/>
is equivalent to
<xsl:variable name="x" select="''"/>
Note:
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="item[$n]"/>
This will output the value of the first item element, because the
variable n
will be bound to a node-set, not a number. Instead, do either
<xsl:variable name="n" select="2"/> ... <xsl:value-of select="item[$n]"/>
or
<xsl:variable name="n">2</xsl:variable> ... <xsl:value-of select="item[position()=$n]"/>
Note:
One convenient way to specify the empty node-set as the default value of a parameter is:
<xsl:param name="x" select="/.."/>
xsl:copy-of
The xsl:copy-of
element can be used to insert a
node-set into the result tree, without
first converting it to a string as xsl:value-of
does (see
7.6.1 Generating Text with xsl:value-of). The required select
attribute contains an expression. When the
result of evaluating the expression is a node-set, all the
nodes in the set are copied in document order into the result tree;
copying an element node copies the attribute nodes, namespace nodes
and children of the element node as well as the element node itself; a
root node is copied by copying its children. For copying an attribute or namespace node, the same
rules apply as with xsl:copy
(see 7.5 Copying). When the result is not a
node-set, the result is converted to a string and then
inserted into the result tree, as with xsl:value-of
.
Both xsl:variable
and xsl:param
are
allowed as top-level elements.
A top-level variable-binding element declares a global variable that
is visible everywhere (except where it
is shadowed by another
binding). A top-level xsl:param
element
declares a parameter to the stylesheet; XSLT does not define the
mechanism by which parameters are passed to the stylesheet. If a stylesheet contains more than one
binding for a variable of a particular name, then the binding with the
highest import
precedence is used. It is an
error if a stylesheet contains more than one binding of a top-level
variable with the same name and same import precedence. At the
top-level, the expression or template specifying the variable value is
evaluated with the same context as that used to process the root node
of the source document: the current node is the root node of the
source document and the current node list is a list containing just
the root node of the source document. If the template or expression
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. It is an error if it
is impossible to do this for all global variable definitions; in other
words, it is an error if the definitions are circular.
This example declares a global variable para-font-size
,
which it references in an attribute value template.
<xsl:variable name="para-font-size">12pt</xsl:variable> <xsl:template match="para"> <fo:block font-size="{$para-font-size}"> <xsl:apply-templates/> </fo:block> </xsl:template>
As well as being allowed at the top-level, both
xsl:variable
and xsl:param
are also
allowed in templates. xsl:variable
is allowed anywhere
within a template that an instruction is allowed. In this case, the
binding is visible for all following siblings and their descendants.
Note that the binding is not visible for the xsl:variable
element itself. xsl:param
is allowed as a child
at the beginning of an xsl:template
element. In this
context, the binding is visible for all following siblings and their
descendants. Note that the binding is not visible for the
xsl:param
element itself.
[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 an error if a binding established by an
xsl:variable
or xsl:param
element within a
template shadows another binding
established by an xsl:variable
or xsl:param
element also within the template. It is not an error if a binding
established by an xsl:variable
or xsl:param
element in a template shadows
another binding established by an xsl:variable
or
xsl:param
top-level
element. In this case, the top-level
binding will not be visible in the region of the stylesheet where it
is shadowed by the other binding. Thus, the following is an
error:
<xsl:template name="foo"> <xsl:param name="x" select="1"/> <xsl:variable name="x" select="2"/> </xsl:template>
However, the following is allowed:
<xsl:param name="x" select="1"/> <xsl:template name="foo"> <xsl:variable name="x" select="2"/> </xsl:template>
Note:
The nearest equivalent in Java to an xsl:variable
element in a template is a final local variable declaration with an
initializer. For example,
<xsl:variable name="x" select="'value'"/>
has similar semantics to
final Object x = "value";
XSLT does not provide an equivalent to the Java assignment operator
x = "value";
because this 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.
Parameters are passed to templates using the
xsl:with-param
element. The required name
attribute specifies the name of the parameter (the variable the value
of whose binding is to be replaced). The value of the
name
attribute is a QName, which is expanded as described
in 2.4 Qualified Names. xsl:with-param
is allowed
within
xsl:call-template
,
xsl:apply-templates
and
xsl:apply-imports
.
It is an error if a single xsl:call-template
,
xsl:apply-templates
or xsl:apply-imports
element contains more than one xsl:with-param
element
with the same name.
The value of the parameter is
specified in the same way as for xsl:variable
and
xsl:param
. The current node and current node list used
for computing the value specified by xsl:with-param
element is the same as that used for the
xsl:apply-templates
,
xsl:apply-imports
, or
xsl:call-template
element within which it occurs. It is not an error to pass a
parameter x to a template that does not have an
xsl:param
element for x; the parameter is
simply ignored.
This example defines a named template for a
numbered-block
with an argument 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>
This section describes XSLT-specific additions to the core XPath function library. Some of these additional functions also make use of information specified by top-level elements in the stylesheet; this section also describes these elements.
node-set document(object , node-set?)
The document
function allows
access to XML documents other than the main source document.
When the document
function has exactly one
argument and the argument is a node-set, then the result is the union,
for each node in the argument node-set, of the result of calling the
document
function with the first argument being
the string-value
of the node, and the second argument being a node-set with the node as
its only member. When the document
function has
two arguments and the first argument is a node-set, then the result is
the union, for each node in the argument node-set, of the result of
calling the document
function with the first
argument being the string-value of the node,
and with the second argument being the second argument passed to the
document
function.
When the first argument to the document
function is not a node-set, the first argument is converted to a
string as if by a call to the string function.
This string is treated as a URI reference; the resource identified by
the URI is retrieved. The data resulting from the retrieval action is
parsed as an XML document and a tree is constructed in accordance with
the data model (see 3 Data Model). If there is an
error retrieving the resource, then the XSLT processor may signal an
error; if it does not signal an error, it must recover by returning an
empty node-set. One possible kind of retrieval error is that the XSLT
processor does not support the URI scheme used by the URI. An XSLT
processor is not required to support any particular URI schemes. The
documentation for an XSLT processor should specify which URI schemes
the XSLT processor supports.
If the URI reference does not contain a fragment identifier, then a node-set containing just the root node of the document is returned. If the URI reference does contain a fragment identifier, the function returns a node-set containing the nodes in the tree identified by the fragment identifier of the URI reference. The semantics of the fragment identifier are dependent on the media type of the result of retrieving the URI. If there is an error in processing the fragment identifier, the XSLT processor may signal the error; if it does not signal the error, it must recover by returning an empty node-set. Possible errors include:
The fragment identifier identifies something that cannot be represented by an XSLT node-set (such as a range of characters within a text node).
The XSLT processor does not support fragment identifiers for the media-type of the retrieval result. An XSLT processor is not required to support any particular media types. The documentation for an XSLT processor should specify for which media types the XSLT processor supports fragment identifiers.
The data resulting from the retrieval action is parsed as an XML
document regardless of the media type of the retrieval result; if the
top-level media type is text
, then it is parsed in the
same way as if the media type were text/xml
; otherwise,
it is parsed in the same way as if the media type were
application/xml
.
Note:
Since there is no top-level xml
media type, data
with a media type other than text/xml
or
application/xml
may in fact be XML.
The URI reference may be relative. The base URI (see 3.2 Base URI) of the node in the second argument node-set that is
first in document order is used as the base URI for resolving the
relative URI into an absolute URI. It
is an error if the second argument node-set is empty and the URI
reference is relative; the XSLT processor may signal the error; if it
does not signal an error, it must recover by returning an empty
node-set. If the second argument is omitted,
then it defaults to the node in the stylesheet that contains the
expression that includes the call to the document
function. Note that a zero-length URI reference is a reference to the
document relative to which the URI reference is being resolved; thus
document("")
refers to the root node of the stylesheet;
the tree representation of the stylesheet is exactly the same as if
the XML document containing the stylesheet was the initial source
document.
Two documents are treated as the same document if they are identified by the same URI. The URI used for the comparison is the absolute URI into which any relative URI was resolved and does not include any fragment identifier. One root node is treated as the same node as another root node if the two nodes are from the same document. Thus, the following expression will always be true:
generate-id(document("foo.xml"))=generate-id(document("foo.xml"))
The document
function gives rise to the
possibility that a node-set may contain nodes from more than one
document. With such a node-set, the relative document order of two
nodes in the same document is the normal document order defined by
XPath [XPath]. The relative document order of two nodes
in different documents is determined by an implementation-dependent
ordering of the documents containing the two nodes. There are no
constraints on how the implementation orders documents other than that
it must do so consistently: an implementation must always use the same
order for the same set of documents.
Keys provide a way to work with documents that contain an implicit
cross-reference structure. The ID
, IDREF
and IDREFS
attribute types in XML provide a mechanism to
allow XML documents to make their cross-reference explicit. XSLT
supports this through the XPath id function.
However, this mechanism has a number of limitations:
ID attributes must be declared as such in the DTD. If an ID
attribute is declared as an ID attribute only in the external DTD
subset, then it will be recognized as an ID attribute only if the XML
processor reads the external DTD subset. However, XML does not require
XML processors to read the external DTD, and they may well choose not
to do so, especially if the document is declared
standalone="yes"
.
A document can contain only a single set of unique IDs. There cannot be separate independent sets of unique IDs.
The ID of an element can only be specified in an attribute; it cannot be specified by the content of the element, or by a child element.
An ID is constrained to be an XML name. For example, it cannot contain spaces.
An element can have at most one ID.
At most one element can have a particular ID.
Because of these limitations XML documents sometimes contain a cross-reference structure that is not explicitly declared by ID/IDREF/IDREFS attributes.
A key is a triple containing:
the node which has the key
the name of the key (an expanded-name)
the value of the key (a string)
A stylesheet declares a set of keys for each document using the
xsl:key
element. When this set of keys contains a member
with node x, name y and value
z, we say that node x has a key with name
y and value z.
Thus, a key is a kind of generalized ID, which is not subject to the same limitations as an XML ID:
Keys are declared in the stylesheet using
xsl:key
elements.
A key has a name as well as a value; each key name may be thought of as distinguishing a separate, independent space of identifiers.
The value of a named key for an element may be specified in any convenient place; for example, in an attribute, in a child element or in content. An XPath expression is used to specify where to find the value for a particular named key.
The value of a key can be an arbitrary string; it is not constrained to be a name.
There can be multiple keys in a document with the same node, same key name, but different key values.
There can be multiple keys in a document with the same key name, same key value, but different nodes.
The xsl:key
element is used to declare keys. The
name
attribute specifies the name of the key. The value
of the name
attribute is a QName, which is expanded as described
in 2.4 Qualified Names. The match
attribute is a Pattern; an xsl:key
element gives
information about the keys of any node that matches the pattern
specified in the match attribute. The use
attribute is
an expression specifying the
values of the key; the expression is evaluated once for each node that
matches the pattern. If the result is a node-set, then for each node
in the node-set, the node that matches the pattern has a key of the
specified name whose value is the string-value of the node in the
node-set; otherwise, the result is converted to a string, and the node
that matches the pattern has a key of the specified name with value
equal to that string. Thus, a node x has a key with name
y and value z if and only if there is an
xsl:key
element such that:
x matches the pattern specified in the
match
attribute of the xsl:key
element;
the value of the name
attribute of the
xsl:key
element is equal to y;
and
when the expression specified in the use
attribute of the xsl:key
element is evaluated with
x as the current node and with a node list containing
just x as the current node list resulting in an object
u, then either z is equal to the result of
converting u to a string as if by a call to the
string function, or u is a
node-set and z is equal to the string-value of one or
more of the nodes in u.
Note also that there may be more than one xsl:key
element that matches a given node; all of the matching
xsl:key
elements are used, even if they do not have the
same import
precedence.
It is an error for the value of either the use
attribute or the match
attribute to contain a VariableReference, or a call to the
key
function.
node-set key(string, object)
The key
function does for keys what the
id function does for IDs. The first argument
specifies the name of the key. The value of the argument must be a
QName, which is expanded as
described in 2.4 Qualified Names. When the second argument to the
key
function is of type node-set, then the result
is the union of the result of applying the key
function to the string-value of
each of the nodes in the argument node-set. When the second argument
to key
is of any other type, the argument is
converted to a string as if by a call to the
string function; it returns a node-set
containing the nodes in the same document as the context node that
have a value for the named key equal to this string.
For example, given a declaration
<xsl:key name="idkey" match="div" use="@id"/>
an expression key("idkey",@ref)
will return the same
node-set 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 current node
contains no whitespace.
Suppose a document describing a function library uses a
prototype
element to define functions
<prototype name="key" return-type="node-set"> <arg type="string"/> <arg type="object"/> </prototype>
and a function
element to refer to function names
<function>key</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>
The key
always
returns nodes that are in the same document as the current node; to
retrieve a key from any other document, it is necessary first to
change the current node. 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:for-each select="document('bib.xml')"> <xsl:apply-templates select="key('bib',$name)"/> </xsl:for-each> </xsl:template>
string format-number(number, string, string?)
The format-number
function converts its first
argument to a string using the format pattern string specified by the
second argument and the decimal-format named by the third argument, or
the default decimal-format, if there is no third argument. The format
pattern string is in the syntax specified by the JDK 1.1 DecimalFormat class. The format pattern string is in a
localized notation: the decimal-format determines what characters have
a special meaning in the pattern (with the exception of the quote
character, which is not localized). The format pattern must not
contain the currency sign (#x00A4); support for this feature was added
after the initial release of JDK 1.1. The decimal-format name must be
a QName, which is expanded as
described in 2.4 Qualified Names. It is an error if the stylesheet
does not contain a declaration of the decimal-format with the specified
expanded-name.
Note:
Implementations are not required to use the JDK 1.1 implementation, nor are implementations required to be implemented in Java.
Note:
Stylesheets can use other facilities in XPath to control rounding.
The xsl:decimal-format
element declares a
decimal-format, which controls the interpretation of a format pattern
used by the format-number
function. If there is
a name
attribute, then the element declares a named
decimal-format; otherwise, it declares the default decimal-format.
The value of the name
attribute is a QName, which is expanded as described
in 2.4 Qualified Names. It is an error to declare either the
default decimal-format or a decimal-format with a given name more than
once (even with different import
precedence), unless it is declared every time with the same
value for all attributes (taking into account any default values). If a stylesheet does not contain a declaration of
the default decimal format, a declaration equivalent to
an xsl:decimal-format
element with no attributes
is implied.
The other attributes on xsl:decimal-format
correspond
to the methods on the JDK 1.1 DecimalFormatSymbols class. For each
get
/set
method pair there is an attribute
defined for the xsl:decimal-format
element.
The following attributes both control the interpretation of characters in the format pattern and specify characters that may appear in the result of formatting the number:
decimal-separator
specifies the character used
for the decimal sign; the default value is the period character
(.
)
grouping-separator
specifies the character used
as a grouping (e.g. thousands) separator; the default value is the
comma character (,
)
percent
specifies the character used as a
percent sign; the default value is the percent character
(%
)
per-mille
specifies the character used as a per
mille sign; the default value is the Unicode per-mille character
(#x2030)
zero-digit
specifies the character used as the
digit zero; the default value is the digit zero
(0
)
The following attributes control the interpretation of characters in the format pattern:
digit
specifies the character used for a digit
in the format pattern; the default value is the number sign character
(#
)
pattern-separator
specifies the character used
to separate positive and negative sub patterns in a pattern; 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
infinity; the default value is the string
Infinity
NaN
specifies the string used to represent the
NaN value; the default value is the string NaN
minus-sign
specifies the character used as the
default minus sign; the default value is the hyphen-minus character
(-
, #x2D)
node-set current()
The current
function returns a node-set that
has the current node as its
only member. For an outermost expression (an expression not occurring
within another expression), the current node is always the same as the
context node. Thus,
<xsl:value-of select="current()"/>
means the same as
<xsl:value-of select="."/>
However, within square brackets the current node is usually different from the context node. For example,
<xsl:apply-templates select="//glossary/item[@name=current()/@ref]"/>
will process all item
elements that have a
glossary
parent element and that have a name
attribute with value equal to the value of the current node's
ref
attribute. This is different from
<xsl:apply-templates select="//glossary/item[@name=./@ref]"/>
which means the same as
<xsl:apply-templates select="//glossary/item[@name=@ref]"/>
and so would process all item
elements that have a
glossary
parent element and that have a name
attribute and a ref
attribute with the same value.
It is an error to use the current
function in
a pattern.
string unparsed-entity-uri(string)
The unparsed-entity-uri
returns the URI of the
unparsed entity with the specified name in the same document as the
context node (see 3.3 Unparsed Entities). It returns the
empty string if there is no such entity.
string generate-id(node-set?)
The generate-id
function returns a string that
uniquely identifies the node in the argument node-set that is first in
document order. The unique identifier must consist of ASCII
alphanumeric characters and must start with an alphabetic character.
Thus, the string is syntactically an XML name. An implementation is
free to generate an identifier in any convenient way provided that it
always generates the same identifier for the same node and that
different identifiers are always generated from different nodes. An
implementation is under no obligation to generate the same identifiers
each time a document is transformed. There is no guarantee that a
generated unique identifier will be distinct from any unique IDs
specified in the source document. If the argument node-set is empty,
the empty string is returned. If the argument is omitted, it defaults
to the context node.
object system-property(string)
The argument must evaluate to a string that is a QName. The QName is expanded into a name using
the namespace declarations in scope for the expression. The
system-property
function returns an object
representing the value of the system property identified by the name.
If there is no such system property, the empty string should be
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 XSLT processors implementing the version of XSLT specified by this document, this is the number 1.0xsl:vendor
, a string identifying the vendor of the XSLT processorxsl:vendor-url
, a string containing a URL identifying the vendor of the XSLT processor; typically this is the host page (home page) of the vendor's Web site.
Vendors must not define additional system properties in the XSLT namespace.
The xsl:message
instruction sends a message in a way
that is dependent on the XSLT processor. The content of the
xsl:message
instruction is a template. The
xsl:message
is instantiated by instantiating the content
to create an XML fragment. This XML fragment is the content of the
message.
Note:
An XSLT processor might implement xsl:message
by
popping up an alert box or by writing to a log file.
If the terminate
attribute has the value
yes
, then the XSLT processor should terminate processing
after sending the message. The default value is no
.
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/', $lang, '.xml'))/messages"/> <xsl:template name="localized-message"> <xsl:param name="name"/> <xsl:message> <xsl:value-of select="$messages/message[@name=$name]"/> </xsl:message> </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>
XSLT allows two kinds of extension, extension elements and extension functions.
This version of XSLT does not provide a mechanism for defining implementations of extension elements. It does provide a mechanism for defining extension functions; however, XSLT does not require that XSLT processors support any particular languages for implementing extensions. 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 XSLT processor by which it is being processed has implementations of particular extensions available, and to specify what should happen 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 work with any XSLT implementation.
[Definition: The element extension 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 template, 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
template, non-XSLT top-level 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
extension-element-prefixes
attribute on an
xsl:stylesheet
element or an
xsl:extension-element-prefixes
attribute on a literal
result element or extension element.
The value of both these attributes is a
whitespace-separated list of namespace prefixes. The namespace bound
to each of the prefixes is designated as an extension namespace. It
is an error if there is no namespace bound to the prefix on the
element bearing the extension-element-prefixes
or
xsl:extension-element-prefixes
attribute. The default
namespace (as declared by xmlns
) may be designated as an
extension namespace by including #default
in the list of
namespace prefixes. The designation of a namespace as an extension
namespace is effective within the subtree of the stylesheet rooted at
the element bearing the extension-element-prefixes
or
xsl:extension-element-prefixes
attribute;
a subtree rooted at an xsl:stylesheet
element
does not include any stylesheets imported or included by children
of that xsl:stylesheet
element.
If the XSLT processor does not have an implementation of a
particular extension element available, then the
element-available
function must return false for
the name of the element. When such an extension element is
instantiated, then the XSLT processor must perform fallback for the
element as specified in 15 Fallback. An XSLT processor
must not signal an error merely because a template contains an
extension element for which no implementation is available.
If the XSLT processor has an implementation of a particular
extension element available, then the
element-available
function must return true for
the name of the element.
If a FunctionName in a FunctionCall expression is not an NCName (i.e. if it contains a colon), then it is treated as a call to an extension function. The FunctionName is expanded to a name using the namespace declarations from the evaluation context.
If the XSLT processor does not have an implementation of an
extension function of a particular name available, then the
function-available
function must return false for
that name. If such an extension function occurs in an expression and
the extension function is actually called, the XSLT processor must
signal an error. An XSLT processor must not signal an error merely
because an expression contains an extension function for which no
implementation is available.
If the XSLT processor has an implementation of an extension
function of a particular name available, then the
function-available
function must return
true for that name. If such an extension is called, then the XSLT
processor must call the implementation passing it the function call
arguments; the result returned by the implementation is returned as
the result of the function call.
Editorial note | |
Say something about automatic argument conversions here. |
Typically, implementations of extension functions represent strings as a sequence of code values (usually 16-bit integers or bytes). It is possible for an extension function to return a sequence of code values that cannot be mapped to a sequence of legal XML characters. The behavior of an XSLT processor in this case is implementation-dependent.
Note:
Requiring the XSLT processor to check the contents of every string returned by an extension function could be a significant performance burden.
[Definition: Support for extension functions introduces an additional data-type into the expression language. This additional data type is called an external object. A variable may be bound to an object of type external object instead of one of the four XPath data-types (string, number, boolean, node-set). An external object represents an object that is not convertible to one of the four XPath data types which is created by an external programming language and returned by an extension function. Expressions can only return values of type external object by referencing variables of type external object or calling extension functions that return an external object.]
An external object may only be passed as an argument to another
extension function. It may not be copied to the result tree or
converted (implicitly or explicitly) to any of the XPath data types.
So, for example, if the myvar
variable is bound an
external object, then the following are not allowed:
<xsl:copy-of select="$myvar"/> <!--
Cannot copy to result tree -->
<xsl:value-of select="$myvar"/> <!--
Cannot implicitly convert to String -->
<xsl:value-of select="string($myvar)"/>
<!-- Cannot explicitly convert to String -->
If an external object is passed to an extension function with an expanded-name whose namespace URI is different from the namespace URI of the expanded-name of the extension function that returned that external object, the behavior is implementation-dependent.
An extension function can be used to convert the argument to a
string or return an XML fragment to be copied to the result tree if
desired. For example, assuming the myext:print()
extension function accepts an argument of a compatible data type and
returns a string, the following is allowed:
<!-- Convert to string with extension function --> <xsl:value-of select="myext:print($myvar)"/>
Issue (issue-null-external-object):
Should the spec have the
concept that an external object may be null, and provide a way for
testing this, for example, by conversion to
boolean
?
Editorial note | |
Define the idea that an external object "wraps" an object created by an external programming language. |
The top-level xsl:script
element provides an
implementation of extension functions in a particular namespace. The
function implementations may be provided as a separate resource. Some
language bindings also allow the function implementations to be
provided directly in the content of the xsl:script
.
Editorial note | |
Make sure that it is clear that it is allowed to call extension functions without using xsl:script to define them. |
The implements-prefix
attribute specifies a namespace
prefix. This prefix is expanded into a URI using the namespace
declarations in scope on the xsl:script
element. This
URI is the namespace URI of the expanded-names of the functions of
which an implementation is being provided. The implementation of the
extension functions identifies the local names of the functions that
is is implementing.
The language
attribute identifies the language used by
the implementation being provided. It also identifies the way
arguments are passed by the XSLT processor to the implementation of
the extension function, the way results are returned from the
implementation of the extension function, and the way the XSLT
expression context is made available to the extension function
(collectively known as the language binding). The value must be a
QName. If the QName does not have a prefix, then it
identifies a language binding specified in this document and must be
ecmascript
, javascript
or java
.
If the QName has a prefix, then
the QName is expanded into an
expanded-name as
described in 2.4 Qualified Names; the expanded-name identifies the
language binding; the language binding in this case is not specified
by this document. XSLT processors are not required to support any
particular language binding. xsl:script
elements with
language
values not supported by the processor are
ignored.
When the function implementations are provided as a separate
resource, the content of the xsl:script
element must be
empty and the src
attribute is required. The
src
attribute is a URI reference that identifies the
resource containing the implementation of the extension functions.
For example,
A Java class:
src="java:com.example.datestuff.DateRoutines"
An ECMAScript library:
src="http://example.org/somecode.js"
When a function implementation is provided locally in the content
of the xsl:script
element, the src
attribute must not be specified. For example,
<xsl:script implements-prefix="pref" language="lang"> // Function Declarations in Supported Language Syntax function f(x) { ... } function g(y,z) { ... } </xsl:script>
The archive
attribute is a whitespace-separated list
of URI references, each pointing to an archive to be loaded by the
processor before executing the extension function. The
archive
attribute may be used on an
xsl:script
element regardless of whether that
xsl:script
element has a src
attribute.
The function-available
function can be used to
detect the availability of an extension function provided by an
xsl:script
element. The precise details of what it
means for an extension function to be available is specific to the
language-binding.
A stylesheet can contain any number of xsl:script
elements. The order of these elements is not significant in the
stylesheet, except for fallback behavior. In particular, calls to
extension function can occur before xsl:script
elements
that provide implementations of those extension functions.
If there are multiple xsl:script
elements with the
same namespace URI but different implementation languages, then each
implementation language corresponds to an alternative implementation
of the same extension functions. If an XSLT processor supports two
or more of the languages in which an extension function implementation
is provided, then it is free to choose any of its supported
languages, provided that it always chooses the same implementation for
the same extension function namespace URI. A processor is under no
obligation to choose the same implementation each time a document is
transformed.
If there are multiple xsl:script
elements with the
same namespace URI and the same language but different import
precedences, a processor must reconcile the separate elements using
the import precedence. The manner in which the elements are
reconciled is determined by the language binding. For example, some
language bindings may simply use the xsl:script
element
with the highest import precedence; others may merge the
xsl:script
elements in some way. It is an error for two
xsl:script
elements with the same import precedence to
implement the same namespace URI for the same language. An XSLT
processor may signal the error; if it does not signal the error, it
must recover by treating the two xsl:script
elements as
if the xsl:script
element that occurs later in the
stylesheet had a higher import precedence than the other
xsl:script
element.
Normally, instantiating an xsl:fallback
element does
nothing. However, when an XSLT processor performs fallback for an
instruction element, if the instruction element has one or more
xsl:fallback
children, then the content of each of the
xsl:fallback
children must be instantiated in sequence;
otherwise, an error must be signaled. The content of an
xsl:fallback
element is a template.
The following functions can be used with the
xsl:choose
and xsl:if
instructions to
explicitly control how a stylesheet should behave if particular
elements or functions are not available.
boolean element-available(string)
The argument must evaluate to a string that is a QName. The QName is expanded into an expanded-name using the
namespace declarations in scope for the expression. If there is a default namespace in scope,
then it is used to expand an unprefixed QName. The
element-available
function returns true if and
only if the expanded-name is the name of an instruction. If the
expanded-name has a namespace URI equal to the XSLT namespace URI,
then it refers to an element defined by XSLT. Otherwise, it refers to
an extension element. If the expanded-name has a null namespace URI,
the element-available
function will return
false.
boolean function-available(string)
The argument must evaluate to a string that is a QName. The QName is expanded into an expanded-name using the
namespace declarations in scope for the expression. The
function-available
function returns true if and
only if the expanded-name is the name of a function in the function
library. If the expanded-name has a non-null namespace URI, then it
refers to an extension function; otherwise, it refers to a function
defined by XPath or XSLT.
An XSLT processor may output the result tree as a sequence of
bytes, although it is not required to be able to do so (see 17 Conformance). The xsl:output
element allows
stylesheet authors to specify how they wish the result tree to be
output. If an XSLT processor outputs the result tree, it should do so
as specified by the xsl:output
element; however, it is
not required to do so. Before the result tree
is output, namespace fixup
is performed (see 3.5 Namespace Fixup).
The xsl:output
element is only allowed as a top-level element.
All attributes on xsl:output
are interpreted as attribute value
templates. Expressions recognized in the attributes of
xsl:output
are evaluated with the same context as used to
process the root node of the source document: the current node is the
root node of the source document and the current node list is a list
containing just the root node of the source document.
The method
attribute on xsl:output
identifies the overall method that should be used for outputting the
result tree. The value must be a QName. If the QName does not have a prefix, then it
identifies a method specified in this document and must be one of
xml
, html
or text
. If the QName has a prefix, then the QName is expanded into an expanded-name as described
in 2.4 Qualified Names; the expanded-name identifies the output
method; the behavior in this case is not specified by this
document.
The default for the method
attribute is chosen as
follows. If
the root node of the result tree has an element child,
the expanded-name of the first element child of the root node
(i.e. the document element) of the result tree has local part
html
(in any combination of upper and lower case) and a
null namespace URI, and
any text nodes preceding the first element child of the root node of the result tree contain only whitespace characters,
then the default output method is html
; otherwise, the
default output method is xml
. The default output method
should be used if there are no xsl:output
elements or if
none of the xsl:output
elements specifies a value for the
method
attribute.
The other attributes on xsl:output
provide parameters
for the output method. The following attributes are allowed:
version
specifies the version of the output
method
indent
specifies whether the XSLT processor may
add additional whitespace when outputting the result tree; the value
must be yes
or no
encoding
specifies the preferred character
encoding that the XSLT processor should use to encode sequences of
characters as sequences of bytes; the value of the attribute should be
treated case-insensitively; the value must contain only characters in
the range #x21 to #x7E (i.e. printable ASCII characters); the value
should either be a charset
registered with the Internet
Assigned Numbers Authority [IANA], [RFC2278] or start with X-
media-type
specifies the media type (MIME
content type) of the data that results from outputting the result
tree; the charset
parameter should not be specified
explicitly; instead, when the top-level media type is
text
, a charset
parameter should be added
according to the character encoding actually used by the output
method
doctype-system
specifies the system identifier
to be used in the document type declaration
doctype-public
specifies the public identifier
to be used in the document type declaration
omit-xml-declaration
specifies whether the XSLT
processor should output an XML declaration; the value must be
yes
or no
standalone
specifies whether the XSLT processor
should output a standalone document declaration; the value must be
yes
or no
cdata-section-elements
specifies a list of the
names of elements whose text node children should be output using
CDATA sections
The detailed semantics of each attribute will be described separately for each output method for which it is applicable. If the semantics of an attribute are not described for an output method, then it is not applicable to that output method.
A stylesheet may contain multiple xsl:output
elements
and may include or import stylesheets that also contain
xsl:output
elements. All the xsl:output
elements occurring in a stylesheet are merged into a single effective
xsl:output
element. For the
cdata-section-elements
attribute, the effective value is
the union of the specified values. For other attributes, the
effective value is the specified value with the highest import precedence. It is an error
if there is more than one such value for an attribute. An XSLT
processor may signal the error; if it does not signal the error, if
should recover by using the value that occurs last in the stylesheet.
The values of attributes are defaulted after the
xsl:output
elements have been merged; different output
methods may have different default values for an attribute.
The xml
output method outputs the result tree as a
well-formed XML external general parsed entity. If the root node of
the result tree has a single element node child and no text node
children, then the entity should also be a well-formed XML document
entity. When the entity is referenced within a trivial XML document
wrapper like this
<!DOCTYPE doc [ <!ENTITY e SYSTEM "entity-URI"> ]> <doc>&e;</doc>
where entity-URI
is a URI for the entity,
then the wrapper
document as a whole should be a well-formed XML document conforming to
the XML Namespaces Recommendation [XML Names]. In
addition, the output should be such that if a new tree was constructed
by parsing the wrapper as an XML document as specified in 3 Data Model, and then removing the document element, making its
children instead be children of the root node, then the new tree would
be the same as the result tree, with the following possible
exceptions:
The order of attribute and namespace nodes in the two trees may be different.
The base URIs of nodes in the two trees may be different.
If the XSLT processor generated a document type declaration because
of the doctype-system
attribute or generated a standalone document declaration because
of the standalone
attribute, then the output must be a well-formed XML
document, and the above requirements apply to the tree constructed by parsing that document
directly, without any wrapper, using an XML processor that does not
process the DTD.
Note:
Processing the DTD might cause additional attributes to appear in the tree because of attribute defaulting.
The version
attribute specifies the version of XML to
be used for outputting the result tree. If the XSLT processor does
not support this version of XML, it should use a version of XML that
it does support. The version output in the XML declaration (if an XML
declaration is output) should correspond to the version of XML that
the processor used for outputting the result tree. The value of the
version
attribute should match the VersionNum production of the XML
Recommendation [XML]. The default value is
1.0
.
The encoding
attribute specifies the preferred
encoding to use for outputting the result tree. XSLT processors are
required to respect values of UTF-8
and
UTF-16
. For other values, if the XSLT processor does not
support the specified encoding it may signal an error; if it does not
signal an error it should use UTF-8
or
UTF-16
instead. The XSLT processor must not use an
encoding whose name does not match the EncName production of the XML
Recommendation [XML]. If no encoding
attribute is specified, then the XSLT processor should use either
UTF-8
or UTF-16
. It is possible that the
result tree will contain a character that cannot be represented in the
encoding that the XSLT processor is using for output. In this case,
if the character occurs in a context where XML recognizes character
references (i.e. in the value of an attribute node or text node), then
the character should be output as a character reference; otherwise
(for example if the character occurs in the name of an element) the
XSLT processor should signal an error.
If the indent
attribute has the value
yes
, then the xml
output method may output
whitespace in addition to the whitespace in the result tree (possibly
based on whitespace stripped from either the source document or the
stylesheet) in order to indent the result nicely; if the
indent
attribute has the value no
, it should
not output any additional whitespace. The default value is
no
. The xml
output method should use an
algorithm to output additional whitespace that ensures that the result
if whitespace were to be stripped from the output using the process
described in 3.4 Whitespace Stripping with the set of
whitespace-preserving elements consisting of just
xsl:text
would be the same when additional whitespace is
output as when additional whitespace is not output.
Note:
It is usually not safe to use indent="yes"
with
document types that include element types with mixed content.
The cdata-section-elements
attribute contains a
whitespace-separated list of QNames. Each QName is expanded into an
expanded-name using the namespace declarations in effect on the
xsl:output
element in which the QName occurs; if there is a default
namespace, it is used for QNames
that do not have a prefix. The expansion is performed before the
merging of multiple xsl:output
elements into a single
effective xsl:output
element. If the expanded-name of the
parent of a text node is a member of the list, then the text node
should be output as a CDATA section. For example,
<xsl:output cdata-section-elements="example"/>
would cause a literal result element written in the stylesheet as
<example><foo></example>
or as
<example><![CDATA[<foo>]]></example>
to be output as
<example><![CDATA[<foo>]]></example>
If the text node contains the sequence of characters
]]>
, then the currently open CDATA section should be
closed following the ]]
and a new CDATA section opened
before the >
. For example, a literal result element
written in the stylesheet as
<example>]]></example>
would be output as
<example><![CDATA[]]]]><![CDATA[>]]></example>
If the text node contains a character that is not representable in the character encoding being used to output the result tree, then the currently open CDATA section should be closed before the character, the character should be output using a character reference or entity reference, and a new CDATA section should be opened for any further characters in the text node.
CDATA sections should not be used except for text nodes that the
cdata-section-elements
attribute explicitly specifies
should be output using CDATA sections.
The xml
output method should output an XML declaration
unless the omit-xml-declaration
attribute has the value
yes
. The XML declaration should include both version
information and an encoding declaration. If the
standalone
attribute is specified, it should include a
standalone document declaration with the same value as the value as
the value of the standalone
attribute. Otherwise, it
should not include a standalone document declaration; this ensures
that it is both an XML
declaration (allowed at the beginning of a document entity) and a text
declaration (allowed at the beginning of an external general parsed
entity).
If the doctype-system
attribute is specified, the
xml
output method should output a document type
declaration immediately before the first element. The name following
<!DOCTYPE
should be the name of the first element. If
doctype-public
attribute is also specified, then the
xml
output method should output PUBLIC
followed by the public identifier and then the system identifier;
otherwise, it should output SYSTEM
followed by the system
identifier. The internal subset should be empty. The
doctype-public
attribute should be ignored unless the
doctype-system
attribute is specified.
The media-type
attribute is applicable for the
xml
output method. The default value for the
media-type
attribute is text/xml
.
The html
output method outputs the result tree as
HTML; for example,
<xsl:stylesheet version="1.1" xmlns:xsl="http://www.w3.org/1999/XSL/Transform"> <xsl:output method="html"/> <xsl:template match="/"> <html> <xsl:apply-templates/> </html> </xsl:template> ... </xsl:stylesheet>
The version
attribute indicates the version of the
HTML. The default value is 4.0
, which specifies that the
result should be output as HTML conforming to the HTML 4.0
Recommendation [HTML].
The html
output method should not output an element
differently from the xml
output method unless the
expanded-name of the element has a null namespace URI; an element
whose expanded-name has a non-null namespace URI should be output as
XML. If the expanded-name of the element has a null namespace URI,
but the local part of the expanded-name is not recognized as the name
of an HTML element, the element should output in the same way as a
non-empty, inline element such as span
.
The html
output method should not output an end-tag
for empty elements. For HTML 4.0, the empty elements are
area
, base
, basefont
,
br
, col
, frame
,
hr
, img
, input
,
isindex
, link
, meta
and
param
. For example, an element written as
<br/>
or <br></br>
in the
stylesheet should be output as <br>
.
The html
output method should recognize the names of
HTML elements regardless of case. For example, elements named
br
, BR
or Br
should all be
recognized as the HTML br
element and output without an
end-tag.
The html
output method should not perform escaping for
the content of the script
and style
elements. For example, a literal result element written in the
stylesheet as
<script>if (a < b) foo()</script>
or
<script><![CDATA[if (a < b) foo()]]></script>
should be output as
<script>if (a < b) foo()</script>
The html
output method should not escape
<
characters occurring in attribute values.
If the indent
attribute has the value
yes
, then the html
output method may add or
remove whitespace as it outputs the result tree, so long as it does
not change how an HTML user agent would render the output. The
default value is yes
.
The html
output method should escape non-ASCII
characters in URI attribute values using the method recommended in
Section
B.2.1 of the HTML 4.0 Recommendation.
The html
output method may output a character using a
character entity reference, if one is defined for it in the version of
HTML that the output method is using.
The html
output method should terminate processing
instructions with >
rather than
?>
.
The html
output method should output boolean
attributes (that is attributes with only a single allowed value that
is equal to the name of the attribute) in minimized form. For example,
a start-tag written in the stylesheet as
<OPTION selected="selected">
should be output as
<OPTION selected>
The html
output method should not escape a
&
character occurring in an attribute value
immediately followed by a {
character (see Section
B.7.1 of the HTML 4.0 Recommendation). For example, a start-tag
written in the stylesheet as
<BODY bgcolor='&{{randomrbg}};'>
should be output as
<BODY bgcolor='&{randomrbg};'>
The encoding
attribute specifies the preferred
encoding to be used. If there is a HEAD
element, then the
html
output method should add a META
element
immediately after the start-tag of the HEAD
element
specifying the character encoding actually used. For example,
<HEAD> <META http-equiv="Content-Type" content="text/html; charset=EUC-JP"> ...
It is possible that the result tree will contain a character that
cannot be represented in the encoding that the XSLT processor is using
for output. In this case, if the character occurs in a context where
HTML recognizes character references, then the character should be
output as a character entity reference or decimal numeric character
reference; otherwise (for example, in a
script
or style
element or in a comment),
the XSLT processor should signal an error.
If the doctype-public
or doctype-system
attributes are specified, then the html
output method
should output a document type declaration immediately before the first
element. The name following <!DOCTYPE
should be
HTML
or html
. If the
doctype-public
attribute is specified, then the output
method should output PUBLIC
followed by the specified
public identifier; if the doctype-system
attribute is
also specified, it should also output the specified system identifier
following the public identifier. If the doctype-system
attribute is specified but the doctype-public
attribute
is not specified, then the output method should output
SYSTEM
followed by the specified system identifier.
The media-type
attribute is applicable for the
html
output method. The default value is
text/html
.
The text
output method outputs the result tree by
outputting the string-value of every text node in the result tree in
document order without any escaping.
The media-type
attribute is applicable for the
text
output method. The default value for the
media-type
attribute is text/plain
.
The encoding
attribute identifies the encoding that
the text
output method should use to convert sequences of
characters to sequences of bytes. The default is system-dependent. If
the result tree contains a character that cannot be represented in the
encoding that the XSLT processor is using for output, the XSLT
processor should signal an error.
Normally, the xml
output method escapes & and <
(and possibly other characters) when outputting text nodes. This
ensures that the output is well-formed XML. 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 provides a
mechanism for disabling output escaping. 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 a text node generated by
instantiating the xsl:value-of
or xsl:text
element should be output without any escaping. For example,
<xsl:text disable-output-escaping="yes"><</xsl:text>
should generate the single character <
.
It is an error for output escaping to be disabled for a text node
that is used for something other than a text node in the result tree.
Thus, it is an error to disable output escaping for an
xsl:value-of
or xsl:text
element that is
used to generate the string-value of a comment, processing instruction
or attribute node; it is also an error to convert a node-set to a number or a string if the node-set contains a text node for which escaping
was disabled. In both cases, an XSLT processor may signal the error;
if it does not signal the error, it must recover by ignoring the
disable-output-escaping
attribute.
When a root node is copied using an
xsl:copy-of
element (see 11.3 Using Values of Variables and Parameters with
xsl:copy-of) and
escaping was disabled for a text node descendant of that root node,
then escaping should also be disabled for the resulting copy of that
text node. For example
<xsl:variable name="x"> <xsl:text disable-output-escaping="yes"><</xsl:text> </xsl:variable> <xsl:copy-of select="$x"/>
should output <
not
<
.
Text nodes for which escaping is disabled are subject to merging with text nodes that are adjacent in the result tree in the same way as text nodes for which is escaping is not disabled. An element or root node in the result tree never has two consecutive text node children. Thus, it is possible for a escaping to be disabled for some but not all of the characters in a text node.
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 it
does not perform any output escaping.
An XSLT processor will only be able to disable output escaping if
it controls how the result tree is output. This may not always be the
case. For example, the result tree may be used as the source tree for
another XSLT transformation instead of being output. An XSLT
processor is not required to support disabling output escaping. If an
xsl:value-of
or xsl:text
specifies that
output escaping should be disabled and the XSLT processor does not
support this, the XSLT processor may signal an error; if it does not
signal an error, it must recover by not disabling output escaping.
If output escaping is disabled for a character that is not representable in the encoding that the XSLT processor is using for output, then the XSLT processor may signal an error; if it does not signal an error, it must recover by not disabling output escaping.
Since disabling output escaping may not work with all XSLT processors and can result in XML that is not well-formed, it should be used only when there is no alternative.
The xsl:document
element is used to create multiple
result documents. As well as the main result document, there can be
subsidiary result documents. Each subsidiary result document is
created using an xsl:document
element. The content of the
xsl:document
element is a template; this is instantiated
to create a sequence of nodes; a root node is created with this
sequence of nodes as its children; the tree with this root node
represents the subsidiary result document. The href
attribute specifies where the subsidiary document should be stored; it
must be an absolute or relative URI; it must not have a fragment
identifier. For example, the following would create a main result
document specifying an HTML frameset with two frames, together with
two subsidiary documents, one for the contents of each frame:
<xsl:template match="/"> <html> <head><title>Frame example</title></head> <frameset cols="20%, 80%"> <frame src="toc.html"/> <xsl:document href="toc.html"> <html> <head><title>Table of Contents</title></head> <body> <xsl:apply-templates mode="toc" select="*"/> </body> </html> </xsl:document> <frame src="body.html"/> <xsl:document href="body.html"> <html> <head><title>Body</title></head> <body> <xsl:apply-templates select="*"/> </body> </html> </xsl:document> </frameset> </html> </xsl:template>
The attributes on xsl:output
elements affect only the
main result document. The output of a subsidiary result document is
controlled by the attributes on the xsl:document
element
that was used to create that subsidiary result document. With the
exception of the href
attribute which is allowed only on
xsl:document
, the attributes on xsl:document
are applied to a subsidiary result document in the same way that the
attributes on xsl:output
are applied to the main result
document. In particular, the method
attribute on an
xsl:document
element is defaulted based on the content of
the subsidiary document created by that xsl:document
element, not based on the content of the main result document.
Normally, xsl:document
can be understood as directly
creating an additional result document. However, when
xsl:document
is used within xsl:variable
or
xsl:param
elements, the following more sophisticated
conceptual model is needed.
Documents involved in XSLT processing can be divided into two categories.
One category contains the documents that the XSLT processor
constructs by instantiating templates; these are the main
result document, subsidiary documents created by
xsl:document
, and documents created by a variable-binding
element with content.
The other category contains the documents
constructed by parsing or other processes external to the XSLT
processor; these are the main source document and documents
returned by the document
function.
With each document in the former category, an XSLT processor
associates a possibly empty set of subsidiary documents. The
relationship between a document and its associated subsidiary
documents thus organizes documents in this category into one or more
unordered trees, where the associated subsidiary documents of a
document are considered the children of that document. The main
result document is the root of one such tree; the documents created by
variable-binding elements with content are the roots of the other
trees. Each subsidiary document created by an
xsl:document
element has a parent within this tree of
documents.
During the processing of a stylesheet, there is a current result
document; initially this is the main result document; the current
result document is changed by the xsl:document
element
and by variable-binding elements with content. When an
xsl:document
element is instantiated, the content is
instantiated with the subsidiary document being created by that
xsl:document
element as the current result document. When
a variable-binding element with content is instantiated, the content
is instantiated with the document being created (that is, the document
whose root node is the sole member of the node-set that will be the
value of the variable defined by that element) as the current result
document. A document created by the instantiation of an
xsl:document
is not automatically output; instead, it is
added to the set of subsidiary documents associated with the current
result document.
Note:
The xsl:document
is allowed inside
xsl:attribute
, xsl:comment
and
xsl:processing-instruction
and behaves in those contexts
in the same way as elsewhere.
When a root node is copied with xsl:copy
or
xsl:copy-of
, the subsidiary documents associated with the
document of which it is the root node are copied and added to the set
of subsidiary documents associated with the current result document.
Copying a subsidiary document copies its subsidiary documents
recursively.
Output conceptually follows the construction of the main result document and any subsidiary documents. The XSLT processor outputs the main result document and its associated subsidiary documents; when the XSLT processor outputs a subsidiary document it also recursively outputs its associated subsidiary documents. Apart from this, no other subsidiary documents are output. A subsidiary document associated with the document created by a variable-binding element with content is not output; only copies created by the copying of the root node of that document are ever output.
For each document that is output, there is an absolute URI that
can, in the appropriate circumstances, be used to access that
document. Call this the output URI of the document. The output URI
of the main result document is system-dependent, typically specified
when the XSLT processor is invoked. When the href
attribute of a subsidiary document is an absolute URI, then that
absolute URI serves as the output URI. When the href
attribute of a subsidiary document is a relative URI, the
relative URI is resolved into an absolute URI only if and when the
subsidiary document is output. The output URI of the document with
which the subsidiary document is associated (ie the output URI of its
parent in the tree of documents) is used as the base URI. The
resulting absolute URI is used as the output URI of the subsidiary
document.
Note:
The output URI of a document is not dependent on the base URI of the root node of the document.
It is an error if the set of documents to be output as the result of a single XSLT transformation (that is, the main result document and its subsidiary documents recursively) contain two documents with the same output URI.
A conforming XSLT processor must be able to use a stylesheet to transform source trees into result trees as specified in this document. A conforming XSLT processor need not be able to output the result in XML or in any other form.
Note:
Vendors of XSLT processors are strongly encouraged to provide a way to verify that their processor is behaving conformingly by allowing the result tree to be output as XML or by providing access to the result tree through a standard API such as the DOM or SAX.
A conforming XSLT processor must signal any errors except for those that this document specifically allows an XSLT processor not to signal. A conforming XSLT processor may but need not recover from any errors that it signals.
A conforming XSLT processor may impose limits on the processing resources consumed by the processing of a stylesheet.
The specification of each XSLT-defined element type is preceded by a summary of its syntax in the form of a model for elements of that element type. The meaning of syntax summary notation is as follows:
An attribute is required if and only if its name is in bold.
The string that occurs in the place of an attribute value
specifies the allowed values of the attribute. If this is surrounded
by curly braces, then the attribute value is treated as an attribute value template,
and the string occurring within curly braces specifies the allowed
values of the result of instantiating 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.
If the element is allowed not to be empty, then the element
contains a comment specifying the allowed content. The allowed
content is specified in a similar way to an element type declaration
in XML; template means that any mixture of text nodes,
literal result elements, extension elements, and XSLT elements from
the instruction
category is allowed;
top-level-elements means that any mixture of XSLT
elements from the top-level-element
category is
allowed.
The element is prefaced by comments indicating if it belongs
to the instruction
category or
top-level-element
category or both. The category of an
element just affects whether it is allowed in the content of elements
that allow a template or
top-level-elements.
This appendix defines three language bindings for extension functions, each of which use the DOM2 core.
XSLT Trees are presented to extensions functions in the form of Document Object Model (DOM) Level 2 [DOM2] core interfaces.
Since the The DOM Structure Model and the XSLT Data Model, along with the XPath Data Model, are not fully equivalent, it is necessary to define the mapping between the two models, and identify where tree presentations may not be consistent between XSLT processors that use different implementation strategies. The two types of XSLT processors that we are concerned with are:
The processor creates its own internal tree structure (or internal XPath cache), and presents that structure to extensions via DOM interfaces. In this case, the processor is fully in control of the structure of the tree.
The XPath/XSLT data model is implemented as a view over the a DOM that was passed to the XSLT processor. In this case the XSLT processor generally has a contract with the caller that it can not mutate the DOM, and so the XSLT processor is not fully in control of the structure of the tree. For XSLT processors that are passed a DOM, this DOM should be able to be presented to extensions without modification.
Thus, in order for an extension function to be fully interoperable, it must take into account that it may be given node structures that are not consistent from implementation to implementation. For instance, Text nodes could be broken into several chunks, or could be a single node. The text below enumerates the guidelines for how nodes are to be passed to extension functions, and how node results are to be returned.
An XSLT processor maintains a mapping that associates each XSLT document with the DOM Document or DocumentFragment that represents it. An XSLT processor need not create a DOM Document or DocumentFragment to represent an XSLT document until a node from that XSLT document is passed to an extension function using a DOM-based language binding. Distinct XSLT documents are mapped to distinct DOM Documents or DocumentFragments.
A XPath node-set is mapped to a DOM NodeList, by building a list of the XPath nodes in document order and then mapping each XPath node in the list to a DOM node.
XPath nodes are mapped to DOM nodes as follows.
A root node is presented as a Document node.
An element node is presented as an Element node.
An attribute node is presented as an Attr node.
The DOM tree may contain additional Attr nodes with the name "xmlns" or "xmlns:*" to represent namespaces. Since a DOM may use namespaces that are not declared, an extension function can not rely on these namespace declarations being present.
A text node is presented as a Text node (which might or might not be normalized). This Text may be a derived CDATASection.
A comment node is presented as a Comment node.
A processing instruction node is presented as a ProcessingInstruction node.
The DOM tree may or may not contain nodes to represent constructs that are absent from the XPath data model, for example entity references, and Notation nodes.
Where whitespace has been stripped from the XPath tree, the DOM tree may or may not contain nodes representing such whitespace. Extension functions should not rely on the presence or absense of such whitespace.
The extension function may navigate freely from the nodes actually supplied to other nodes in the tree, using the standard DOM interfaces. Attempting to modify the tree is not recommended: the processor may throw a DOMException if such an attempt is made. In any case, the effect of mutation of the source tree during transformation is undefined.
The result of calling methods that create new nodes, for example
createElement
, is undefined; the processor may throw a
DOMException if such an attempt is made. This restriction does not
apply to the DOM Document
that is the value
of the ownerDocument attribute on XSLTContext.
The names and values of DOM nodes will follow the standard DOM
semantics, not the XPath semantics. For example the name of a comment
node will be #comment
.
The result of calling getDocumentType
is undefined:
the processor may throw a DOMException if such an attempt is made.
The result of calling getSpecified
on an
Attr
node is undefined, since this information is not
available in the XPath data model.
When the implementation of an extension function returns a DOM Node, an XSLT processor will attempt to map that Node to an XSLT node as follows:
First, it determines the root of the DOM tree containing this
DOM Node by using the parentNode
Node
attribute and the ownerElement
Attr
attribute. It is an error if this root is neither a DOM
Document
nor a DOM
DocumentFragment
.
Next, it determines which XSLT document is associated with
this DOM Document
or DocumentFragment
root.
If there is no such XSLT document, then the XSLT processor attempts to
create a new XSLT document from the DOM Document
or
DocumentFragment
root. It is only required to be able to
do so in the case where the root is a DocumentFragment
whose ownerDocument
is the same as the
XSLTContext
ownerDocument
attribute. When
it creates a new XSLT document, namespace fixup (see 3.5 Namespace Fixup) is performed; whitespace stripping
(see 3.4 Whitespace Stripping) is not performed.
Once an XSLT document has
been created for a particular DOM Document
or
DocumentFragment
, modification to that
Document
or DocumentFragment
is no longer
allowed; the XSLT processor may throw a DOM exception if an extension
function attempts this. The newly created XSLT document is associated
with the DOM Document
or DocumentFragment
root from which it was created, so that if an extension function
subsequently returns that same Document
or
DocumentFragment
, it will be mapped to the same XSLT
document.
Finally, it determines which node in that XSLT document
corresponds to the DOM Node
that is being mapped.
Thus, if a node-set containing a single node is passed to an
extension function as a DOM Node
and the implementation
of the extension function returns that same DOM Node
,
then the result of calling function will be a node-set containing a
single node, which is the same node as the node in the node-set passed
to the extension function.
An implementation of an extension function may also return a DOM
NodeList
. In this case, each DOM Node
in
the NodeList
is converted to an XSLT node and the
NodeList
is converted to a node-set containing all of the
resulting nodes.
The implementation of an extension function can use the
XSLTContext
ownerDocument
attribute to
create DOM Node
s. Before an implementation of an
extension function returns DOM Node
s that it has created,
it should also create a DocumentFragment
in the same way
and add those Node
s to that
DocumentFragment
. It can also return the
DocumentFragment
itself, which will be mapped to an XSLT
root node.
The only operations allowed on the Document
that is
the value of the XSLTContext
ownerDocument
attribute are calls to the following methods:
createDocumentFragment
, createElement
,
createElementNS
, createAttribute
,
createAttributeNS
, createTextNode
,
createComment
, createProcessingInstruction
,
importNode
. The result of calling any other methods or
accessing any attributes is implementation-dependent.
The following specifies the XSLTContext
interface in
IDL:
// File: xslt.idl #pragma prefix "w3c.org" #include "dom.idl" module xslt { typedef sequence<unsigned short> XPathString; interface XSLTContext { // ---- Properties/Attributes ---- // context node from XPath expression context readonly attribute dom::Node contextNode; // context position from XPath expression context readonly attribute unsigned long contextPosition; // context size from XPath expression context readonly attribute unsigned long contextSize; // current node from XSLT context; same as calling // current() function from the XPath expression context readonly attribute dom::Node currentNode; // Document to be used for creating nodes readonly attribute dom::Document ownerDocument; // ---- Methods ---- // XSLT System Property Object systemProperty(in XPathString namespaceURI, in XPathString localName); // Return the string value of the Node passed in stringValue(in dom::Node n); }; };
This section defines the ECMAScript [ECMA262] language binding for XSLT extension functions.
To implement an extension function in ECMAScript, stylesheet
developers associate an implementation to their extension function
namespace prefix using an xsl:script
element with
language="ecmascript"
or language="javascript"
as in the following example:
<xsl:stylesheet version="1.1" xmlns:xsl="http://www.w3.org/1999/XSL/Transform" xmlns:date="http://www.example.com/2000/XSLT/library/date"> <xsl:param name="upperCust" select="true()"/> <xsl:script implements-prefix="date" language="ecmascript" src="DateRoutines.js"/> <xsl:script implements-prefix="util" language="ecmascript"> function upper(n) { return n.toUpperCase(); } function lower(n) { return n.toLowerCase(); } function iff(arg1, arg2, arg3) { if (arg1) { return arg2; } else { return arg3; } } </xsl:script> <xsl:template match="/"> <CustomerId> <xsl:value-of select="util:iff($upperCust, util:upper(/order/custid), util:lower(/order/custid))"/> </CustomerId> <OrderDate> <xsl:value-of select="date:format(/order/date,'MM/DD/YY')"/> </OrderDate> </xsl:template> </xsl:stylesheet>
For ECMAScript, the value of the src
attribute on
xsl:script
is a URI reference of an ECMAScript resource
that defines the functions associated with the namespace URI specified
by the implements-prefix
attribute. The implementation
can also be provided locally by omitting the src
attribute and including the script function definitions as the content
of the xsl:script
element.
The ECMAScript standard [ECMA262] allows conforming implementations to provide additional types, values, objects properties and program syntax beyond that described in the ECMAScript standard. For maximum portability, implementations of extension functions should rely only what is defined in the ECMAScript standard itself.
Functions provided by xsl:script
elements with
distinct namespace URIs execute in distinct contexts to avoid name
collisions.
Editorial note | |
Figure out what the correct way to say this is in terms of the ECMAScript standard. Probably need to say there is a distinct global object for each namespace URI. |
When multiple xsl:script
elements with the same
namespace URI and the ecmascript
language are
encountered, the scripts for each element are concatenated in import
precedence order, lowest precedence first. This allows a function
provided by an xsl:script
element of higher import
precedence to redefine a function of the same name provided by an
xsl:script
element of lower import precedence.
A function with given local name and namespace URI is considered to
be available for the purposes of the function-available
function if, after executing all the scripts associated with that
namespace URI, the global object for the namespace URI has a property
with the specified local name whose value is a function.
The local part of the expanded-name of the extension function is
converted to the ECMAScript function name as follows. For each hyphen
in the local part of the expanded-name of the function, the character
following the hyphen is converted to upper-case using the
toUpperCase
method of the ECMAScript String
object, and then the hyphen is removed. For example, the name
get-value
would be treated as equivalent to
getValue
.
The following function argument conversions are performed:
An XPath string
object is mapped to an ECMAScript
string
value
An XPath number
object is mapped to an ECMAScript
number
value
An XPath boolean
object is mapped to an ECMAScript
boolean
value
An XPath node-set
object is mapped to the ECMAScript
binding for the DOM NodeList
An XSLT external object is mapped to the ECMAScript
object
that it wraps
The following conversions are performed on return values.
An ECMAScript string value or String object is mapped to an XPath string object.
An ECMAScript number value or Number object is mapped to an XPath number object.
An ECMAScript boolean value or Boolean object is mapped to an XPath boolean object.
An ECMAScript objects that is an instance of any of the following objects:
DocumentFragment
Document
Node
NodeList
Attr
Element
Text
Comment
CDATASection
EntityReference
ProcessingInstruction
are mapped to an XPath node-set
.
The ECMAScript null value is mapped to an XSLT external object.
The ECMAScript undefined value is mapped to an empty node-set.
Any other ECMAScript object is mapped to an XSLT external object.
The following specifies the XSLTContext
object
language binding for ECMAScript. It is accessible as a property
of the global object.
Object XSLTContext // Property: context node from XPath expression context // Type: Node contextNode // Property: context position from XPath expression context // Type: number contextPosition // Property: context size from XPath expression context // Type: number contextSize // Property: current node from XSLT context // Type: Node currentNode // Property: Document to be used for creating nodes // Type: Document ownerDocument // Method: Return the system property of the specified name // Returns: Object systemProperty(String namespaceURI, String localName) // Method: Return the XPath string value of the node passed in // Returns: string value stringValue(Node n)
This section defines the Java language binding for XSLT extension functions.
Editorial note | |
Need normative reference to Java language spec. |
To implement an extension function in Java, stylesheet developers
associate an implementation to their extension function namespace
prefix using an xsl:script
element with
language="java"
as in the following example:
<?xml version="1.0"?> <xsl:stylesheet xmlns:xsl="http://www.w3.org/1999/XSL/Transform" version="1.0" xmlns:date="uri.any"> <xsl:script implements-prefix="date" language="java" src="java:com.example.datestuff.DateRoutines"/> <xsl:template match="/"> <OrderDate> <xsl:value-of select="date:format(/order/date,'MM/DD/YY')"/> </OrderDate> </xsl:template> </xsl:stylesheet>
For Java, the value of the src
attribute on
xsl:script
is a URI reference identifying a Java class;
the methods of this class implement the functions whose expanded-names
have the namespace URI specified by the implements-prefix
attribute. The URI specified by the src
attribute may
use the java:
URI scheme:
src="java:fully.qualified.ClassName"
; the XSLT
processor may also allow the URI to use other URI schemes to locate
a resource containing the Java class file.
When multiple xsl:script
elements implementing
the same prefix for the same language are encountered, the processor
will use the xsl:script
element with the highest
import precedence to identify the code unit for the extension
function namespace.
The function-available
function returns true
if the named class can be loaded and if it has at least one public
method with the specified name. The expression
function-available('xyz:new')
evaluates to true if the
associated class has any constructor. If
function-available
returns false, then a call on
the function will fail; if it returns true, there is no guarantee that
any particular call will succeed.
If a Java extension function throws an unhandled exception, it will be considered an error in the XSLT processing, the transformation may stop, and the error message from the exception should be reported.
Issue (issue-java-extension-state):
At the moment, there is no way for
the implementation of a function in Java to cache information in a
thread-safe way. For example, there is no way to implement an
extension function that would behave like the built-in
document
function, which needs to keep a URI-to-Document
mapping, in order to ensure that it always returns the same Document
for the same URI.
The local part of the expanded-name of the
extension function specifies the name of the method to be called. To
invoke an instance method for a particular Java object, that Java
object is passed as the first argument to the function call. A
constructor is treated as a static method named new
.
Names are "camel-cased" as follows. For each hyphen in
the local part of the expanded-name of the function, the character
following the hyphen is converted to upper-case using the
toUpperCase
method of java.lang.Character
,
and then the hyphen is removed. For example, the name
get-value
would be treated as equivalent to
getValue
.
It is not possible to invoke a Java method whose name is not an NCName, for example, a name containing a dollar sign character.
Java allows method overloading: a class may have more than one method with the same name, so long as each method has a different signature (different argument types). The XSLT processor uses the arguments passed to the extension function to determine which method to call and resolve the method name to a particular method. The algorithm used for method resolution is based on [LC3]; this uses an approach that is similar to the approach that the Java language uses to resolve method names.
The first step in resolving a method invocation is to determine which methods of a class are accessible and applicable. A Java method is accessible and applicable if all of the following are true:
The method is public.
The method name is the same as the local name of the extension function after camel-casing.
The number of parameters in the method declaration equals the number of argument expressions in the function call expression with the following exceptions:
The method may have an optional, leading
XSLTContext
argument. In this case the method would have one more
than the number of argument expressions in the method invocation.
If the method is an instance method, the current instance of the object is passed as the first extension function argument. In this case, the method would have one fewer than the number of argument expressions in the function call expression.
The type of each actual argument can be converted according to the rules specified in C.4.2 Argument Conversions below.
If there are no applicable methods for an invocation, an error occurs. If there is only one applicable method, it is the one invoked. If there is more than one applicable method, then the following algorithm is applied to determine which to invoke.
When determining which of the applicable methods to invoke, the processor must apply the algorithm described below with a special test for an XSLTContext object (see C.4.4 Accessing XSLT Context Information), as the first argument to the method. Methods that have the XSLTContext as the first argument are preferred over methods that do not.
When choosing between two or more applicable methods, an algorithm is used that is similar in spirit to the ones used in Java and C++. Suppose that U and S are both applicable methods for an invocation, each having n parameters. Suppose, moreover, that the Java types of the parameters for method U are u1,...,un and the Java types of the parameters for method S are s1,...,sn. Finally, the runtime XSLT types of the actual arguments are t1,...,tn. Then the method U is preferred over method S if and only if for all j from 1 to n:
uj and sj are the same type, or
conversion to type uj is preferred to the conversion to type sj when converting from tj
A method is said to be maximally preferred for a method invocation if it is applicable and there is no more preferred applicable method. If there is only one maximally preferred method, that method is necessarily preferred to all other applicable methods and it is the one invoked. If there is more than one maximally preferred method, an error should be thrown.
The following table specifies the allowed conversions of XSLT objects to Java values when converting arguments for method invocation. If a conversion is not specifically listed below, then it is disallowed. In each section corresponding to an XPath type below, Java types are listed in order of preference, most preferred first. Types that are equally preferred are listed in the same table cell.
XSLT argument type | Java argument type | Conversion technique |
---|---|---|
boolean | boolean | Convert XSLT true, false objects to corresponding Java true, false values. |
java.lang.Boolean | ||
java.lang.Object | Convert as for java.lang.Boolean. | |
java.lang.String | Convert to a string as if by a call to the string function. | |
double, float, long, int, short, byte | Convert to a number as if by a call to the number and then use the rules for converting from an XSLT number. | |
java.lang.Double, java.lang.Float, java.lang.Long, java.lang.Integer, java.lang.Short, java.lang.Byte | ||
number | double | Transfer exact value to Java without any conversion. |
java.lang.Double | ||
float | Round XSLT number to float precision. Values that are to large to be represented by a float are converted to positive or negative infinity. | |
java.lang.Float | ||
long | Truncate XSLT number to integral value by eliminating fractional part. NaNs or numbers with a magnitude too large to be represented in the target integral type result in a runtime error. | |
java.lang.Long | ||
int | ||
java.lang.Integer | ||
short | ||
java.lang.Short | ||
char | ||
java.lang.Character | ||
byte | ||
java.lang.Byte | ||
boolean | Convert number to boolean as if by a call to the boolean function. | |
java.lang.Boolean | ||
java.lang.String | Convert number to string as if by a call to the string function. | |
java.lang.Object | Convert as for java.lang.Double. | |
string | java.lang.String | Convert from XSLT string to java.lang.String |
java.lang.Object | Convert as for java.lang.String. | |
char | For one-character strings, result is Unicode character. For strings longer than 1 character, an error is raised. | |
java.lang.Character | ||
double, float, long, int, short, byte | Convert string to number as if by a call to the number function, and then use the rules for converting from an XSLT number. | |
java.lang.Double, java.lang.Float, java.lang.Long, java.lang.Integer, java.lang.Short, java.lang.Byte | ||
boolean | Convert string to boolean as if by a call to the boolean function. | |
java.lang.Boolean | ||
node-set | org.w3c.dom.NodeList | Map the node-set to a org.w3c.dom.NodeList as described in C.1.1 Passing an XPath node-set to an Extension Function. |
org.w3c.dom.Node, org.w3c.dom.Attr, org.w3c.dom.CDATASection, org.w3c.dom.CharacterData, org.w3c.dom.Comment, org.w3c.dom.Document, org.w3c.dom.Element, org.w3c.dom.ProcessingInstruction, org.w3c.dom.Text | Take first node from node-set, and map to a Node as described in the section on C.1.1 Passing an XPath node-set to an Extension Function. It is a runtime error if the resulting Node is not assignable to the Java argument type. | |
java.lang.String | Convert node-set to string as if by a call to the string function. | |
java.lang.Object | Convert as to org.w3c.dom.NodeList | |
char | Convert node-set to string as if by a call to the string function; then use the rule for converting from an XSLT string to a char. | |
java.lang.Character | ||
double, float, long, int, short, byte | Convert node-set to number as if by a call to the number function, then use the rules for converting from an XSLT number. | |
java.lang.Double, java.lang.Float, java.lang.Long, java.lang.Integer, java.lang.Short, java.lang.Byte | ||
boolean | Convert node-set to boolean as if by a call to the boolean function. | |
java.lang.Boolean | ||
external object | Any interface or class that is
assignment-compatible with the Java object wrapped by the external
object, i.e. the wrapped Java object is an
instanceof the Java argument type |
Use the Java object wrapped by the external object. |
java.lang.String | Call the wrapped object's toString method
and return the result as a new java.lang.String. |
|
char | Call the wrapped object's toString method
and convert the string to a char using the rules
for converting from an XSLT string. |
|
java.lang.Character | ||
double, float, long, int, short, byte | Call the wrapped object's toString method,
and convert the resulting string to an XSLT number
as by a call to the number function.
Then convert the number using the rules
for converting from an XSLT number. |
|
java.lang.Double, java.lang.Float, java.lang.Long, java.lang.Integer, java.lang.Short, java.lang.Byte |
Among Java class or interface types, further processing is required. Intuitively, the rule for preference among Java types when converting from a Java object that is wrapped in an XSLT external object is that the most specific class or interface is preferred. More formally, let T be the Java class of the Java object wrapped by an external object. Let S and U be class or interface types. S is preferred to U if and only if:
An instance of T is assignable to a variable of type S, i.e. T instanceof S is true
An instance of S is assignable to a variable of type U, i.e. S instanceof U is true
S and U are not the same types
Values returned by an extension function implemented by a Java method are converted as follows.
If the Java method returns void, the XPath function returns an empty node-set.
If the Java method returns null, the XPath function returns an external object that wraps null.
If the Java method returns a String, the XPath function returns the equivalent string. This string must consist of characters that are valid in XML.
If the Java method returns a double
, int
,
float
, long
, short
,
char
, byte
or their object equivalents, the
XPath function returns the equivalent number.
If the Java method returns a boolean
or
Boolean
, the XPath function returns the equivalent
boolean.
If the Java method returns an org.w3c.dom.NodeList
, the
XPath function returns a node-set.
If the Java method returns a DOM Node or an object of a type from a DOM Node, then XPath function returns a node-set with a single member.
If the Java method returns any other object, the XPath function returns a external object that wraps that object.
The way in which the XSLTContext object is passed to an extension
function is specified in C.4.1 Identifying the Java Method. The
XSLTContext
interface is as follows:
package org.w3c.xsl; import org.w3c.dom.Node; import org.w3c.dom.Document; /** * Interface to be used with XSLT extension functions written in Java */ interface XSLTContext { /** * Return context node from the XPath expression context. */ Node getContextNode(); /** * Returns the context position from the XPath expression context. */ int getContextPosition(); /** * Returns the context size from the XPath expression context. */ int getContextSize(); /** * Returns the current node from the XSLT context; the same * as calling current() function from the XPath expression context. */ Node getCurrentNode(); /** * Returns a Document to be used for creating nodes. */ Document getOwnerDocument(); /** * Returns an Object representing the value of the system property * whose expanded-name has the specified namespace URI and local part. */ Object systemProperty(String namespaceURI, String localName); /** * Returns the string-value of the specified Node. */ String stringValue(Node n); };
Note:
This DTD Fragment is not normative because XML 1.0 DTDs do not support XML Namespaces and thus cannot correctly describe the allowed structure of an XSLT stylesheet.
The following entity can be used to construct a DTD for XSLT
stylesheets that create instances of a particular result DTD. Before
referencing the entity, the stylesheet DTD must define a
result-elements
parameter entity listing the allowed
result element types. For example:
<!ENTITY % result-elements " | fo:inline-sequence | fo:block ">
Such result elements should be declared to have
xsl:use-attribute-sets
and
xsl:extension-element-prefixes
attributes. The following
entity declares the result-element-atts
parameter for
this purpose. The content that XSLT allows for result elements is the
same as it allows for the XSLT elements that are declared in the
following entity with a content model of %template;
. The
DTD may use a more restrictive content model than
%template;
to reflect the constraints of the result
DTD.
The DTD may define the non-xsl-top-level
parameter
entity to allow additional top-level elements from namespaces other
than the XSLT namespace.
The use of the xsl:
prefix in this DTD does not imply
that XSLT stylesheets are required to use this prefix. Any of the
elements declared in this DTD may have attributes whose name starts
with xmlns:
or is equal to xmlns
in addition
to the attributes declared in this DTD.
<!ENTITY % char-instructions " | xsl:apply-templates | xsl:call-template | xsl:apply-imports | xsl:for-each | xsl:value-of | xsl:copy-of | xsl:number | xsl:choose | xsl:if | xsl:text | xsl:copy | xsl:variable | xsl:message | xsl:fallback | xsl:document "> <!ENTITY % instructions " %char-instructions; | xsl:processing-instruction | xsl:comment | xsl:element | xsl:attribute "> <!ENTITY % char-template " (#PCDATA %char-instructions;)* "> <!ENTITY % template " (#PCDATA %instructions; %result-elements;)* "> <!-- Used for the type of an attribute value that is a URI reference.--> <!ENTITY % URI "CDATA"> <!-- Used for the type of an attribute value that is list of URI references. --> <!ENTITY % URIs "CDATA"> <!-- Used for the type of an attribute value that is a pattern.--> <!ENTITY % pattern "CDATA"> <!-- Used for the type of an attribute value that is an attribute value template.--> <!ENTITY % avt "CDATA"> <!-- Used for the type of an attribute value that is a QName; the prefix gets expanded by the XSLT processor. --> <!ENTITY % qname "NMTOKEN"> <!-- Like qname but a whitespace-separated list of QNames. --> <!ENTITY % qnames "NMTOKENS"> <!-- Used for the type of an attribute value that is an NCName. --> <!ENTITY % ncname "NMTOKEN"> <!-- Used for the type of an attribute value that is an expression.--> <!ENTITY % expr "CDATA"> <!-- Used for the type of an attribute value that consists of a single character.--> <!ENTITY % char "CDATA"> <!-- Used for the type of an attribute value that is a priority. --> <!ENTITY % priority "NMTOKEN"> <!ENTITY % space-att "xml:space (default|preserve) #IMPLIED"> <!-- This may be overridden to customize the set of elements allowed at the top-level. --> <!ENTITY % non-xsl-top-level ""> <!ENTITY % top-level " (xsl:import*, (xsl:include | xsl:strip-space | xsl:preserve-space | xsl:output | xsl:key | xsl:decimal-format | xsl:attribute-set | xsl:variable | xsl:param | xsl:template | xsl:namespace-alias | xsl:script %non-xsl-top-level;)*) "> <!ENTITY % top-level-atts ' extension-element-prefixes CDATA #IMPLIED exclude-result-prefixes CDATA #IMPLIED id ID #IMPLIED version NMTOKEN #REQUIRED xmlns:xsl CDATA #FIXED "http://www.w3.org/1999/XSL/Transform" %space-att; '> <!-- This entity is defined for use in the ATTLIST declaration for result elements. --> <!ENTITY % result-element-atts ' xsl:extension-element-prefixes CDATA #IMPLIED xsl:exclude-result-prefixes CDATA #IMPLIED xsl:use-attribute-sets %qnames; #IMPLIED xsl:version NMTOKEN #IMPLIED '> <!ENTITY % output-atts ' method %avt; #IMPLIED version %avt; #IMPLIED encoding %avt; #IMPLIED omit-xml-declaration %avt; #IMPLIED standalone %avt; #IMPLIED doctype-public %avt; #IMPLIED doctype-system %avt; #IMPLIED cdata-section-elements %avt; #IMPLIED indent %avt; #IMPLIED media-type %avt; #IMPLIED '> <!ELEMENT xsl:stylesheet %top-level;> <!ATTLIST xsl:stylesheet %top-level-atts;> <!ELEMENT xsl:transform %top-level;> <!ATTLIST xsl:transform %top-level-atts;> <!ELEMENT xsl:import EMPTY> <!ATTLIST xsl:import href %URI; #REQUIRED> <!ELEMENT xsl:include EMPTY> <!ATTLIST xsl:include href %URI; #REQUIRED> <!ELEMENT xsl:strip-space EMPTY> <!ATTLIST xsl:strip-space elements CDATA #REQUIRED> <!ELEMENT xsl:preserve-space EMPTY> <!ATTLIST xsl:preserve-space elements CDATA #REQUIRED> <!ELEMENT xsl:output EMPTY> <!ATTLIST xsl:output %output-atts;> <!ELEMENT xsl:key EMPTY> <!ATTLIST xsl:key name %qname; #REQUIRED match %pattern; #REQUIRED use %expr; #REQUIRED > <!ELEMENT xsl:decimal-format EMPTY> <!ATTLIST xsl:decimal-format name %qname; #IMPLIED decimal-separator %char; "." grouping-separator %char; "," infinity CDATA "Infinity" minus-sign %char; "-" NaN CDATA "NaN" percent %char; "%" per-mille %char; "‰" zero-digit %char; "0" digit %char; "#" pattern-separator %char; ";" > <!ELEMENT xsl:namespace-alias EMPTY> <!ATTLIST xsl:namespace-alias stylesheet-prefix CDATA #REQUIRED result-prefix CDATA #REQUIRED > <!ELEMENT xsl:template (#PCDATA %instructions; %result-elements; | xsl:param)* > <!ATTLIST xsl:template match %pattern; #IMPLIED name %qname; #IMPLIED priority %priority; #IMPLIED mode %qname; #IMPLIED %space-att; > <!ELEMENT xsl:value-of EMPTY> <!ATTLIST xsl:value-of select %expr; #REQUIRED disable-output-escaping (yes|no) "no" > <!ELEMENT xsl:copy-of EMPTY> <!ATTLIST xsl:copy-of select %expr; #REQUIRED> <!ELEMENT xsl:number EMPTY> <!ATTLIST xsl:number level (single|multiple|any) "single" count %pattern; #IMPLIED from %pattern; #IMPLIED value %expr; #IMPLIED format %avt; '1' lang %avt; #IMPLIED letter-value %avt; #IMPLIED grouping-separator %avt; #IMPLIED grouping-size %avt; #IMPLIED > <!ELEMENT xsl:apply-templates (xsl:sort|xsl:with-param)*> <!ATTLIST xsl:apply-templates select %expr; "node()" mode %qname; #IMPLIED > <!ELEMENT xsl:apply-imports EMPTY> <!-- xsl:sort cannot occur after any other elements or any non-whitespace character --> <!ELEMENT xsl:for-each (#PCDATA %instructions; %result-elements; | xsl:sort)* > <!ATTLIST xsl:for-each select %expr; #REQUIRED %space-att; > <!ELEMENT xsl:sort EMPTY> <!ATTLIST xsl:sort select %expr; "." lang %avt; #IMPLIED data-type %avt; "text" order %avt; "ascending" case-order %avt; #IMPLIED > <!ELEMENT xsl:if %template;> <!ATTLIST xsl:if test %expr; #REQUIRED %space-att; > <!ELEMENT xsl:choose (xsl:when+, xsl:otherwise?)> <!ATTLIST xsl:choose %space-att;> <!ELEMENT xsl:when %template;> <!ATTLIST xsl:when test %expr; #REQUIRED %space-att; > <!ELEMENT xsl:otherwise %template;> <!ATTLIST xsl:otherwise %space-att;> <!ELEMENT xsl:attribute-set (xsl:attribute)*> <!ATTLIST xsl:attribute-set name %qname; #REQUIRED use-attribute-sets %qnames; #IMPLIED > <!ELEMENT xsl:call-template (xsl:with-param)*> <!ATTLIST xsl:call-template name %qname; #REQUIRED > <!ELEMENT xsl:with-param %template;> <!ATTLIST xsl:with-param name %qname; #REQUIRED select %expr; #IMPLIED > <!ELEMENT xsl:variable %template;> <!ATTLIST xsl:variable name %qname; #REQUIRED select %expr; #IMPLIED > <!ELEMENT xsl:param %template;> <!ATTLIST xsl:param name %qname; #REQUIRED select %expr; #IMPLIED > <!ELEMENT xsl:text (#PCDATA)> <!ATTLIST xsl:text disable-output-escaping (yes|no) "no" > <!ELEMENT xsl:processing-instruction %char-template;> <!ATTLIST xsl:processing-instruction name %avt; #REQUIRED %space-att; > <!ELEMENT xsl:element %template;> <!ATTLIST xsl:element name %avt; #REQUIRED namespace %avt; #IMPLIED use-attribute-sets %qnames; #IMPLIED %space-att; > <!ELEMENT xsl:attribute %char-template;> <!ATTLIST xsl:attribute name %avt; #REQUIRED namespace %avt; #IMPLIED %space-att; > <!ELEMENT xsl:comment %char-template;> <!ATTLIST xsl:comment %space-att;> <!ELEMENT xsl:copy %template;> <!ATTLIST xsl:copy %space-att; use-attribute-sets %qnames; #IMPLIED > <!ELEMENT xsl:message %template;> <!ATTLIST xsl:message %space-att; terminate (yes|no) "no" > <!ELEMENT xsl:fallback %template;> <!ATTLIST xsl:fallback %space-att;> <!ELEMENT xsl:document %template;> <!ATTLIST xsl:document href %avt; #REQUIRED %output-atts; > <!ELEMENT xsl:script (#PCDATA)> <!ATTLIST xsl:script implements-prefix %ncname; #REQUIRED language %qname; #REQUIRED src %URI; #IMPLIED archive %URIs; #IMPLIED >
This example is a stylesheet for transforming documents that conform to a simple DTD into XHTML [XHTML]. The DTD is:
<!ELEMENT doc (title, chapter*)> <!ELEMENT chapter (title, (para|note)*, section*)> <!ELEMENT section (title, (para|note)*)> <!ELEMENT title (#PCDATA|emph)*> <!ELEMENT para (#PCDATA|emph)*> <!ELEMENT note (#PCDATA|emph)*> <!ELEMENT emph (#PCDATA|emph)*>
The stylesheet is:
<xsl:stylesheet version="1.1" xmlns:xsl="http://www.w3.org/1999/XSL/Transform" xmlns="http://www.w3.org/TR/xhtml1"> <xsl:strip-space elements="doc chapter section"/> <xsl:output method="xml" indent="yes" encoding="iso-8859-1" /> <xsl:template match="doc"> <html> <head> <title> <xsl:value-of select="title"/> </title> </head> <body> <xsl:apply-templates/> </body> </html> </xsl:template> <xsl:template match="doc/title"> <h1> <xsl:apply-templates/> </h1> </xsl:template> <xsl:template match="chapter/title"> <h2> <xsl:apply-templates/> </h2> </xsl:template> <xsl:template match="section/title"> <h3> <xsl:apply-templates/> </h3> </xsl:template> <xsl:template match="para"> <p> <xsl:apply-templates/> </p> </xsl:template> <xsl:template match="note"> <p class="note"> <b>NOTE: </b> <xsl:apply-templates/> </p> </xsl:template> <xsl:template match="emph"> <em> <xsl:apply-templates/> </em> </xsl:template> </xsl:stylesheet>
With the following input document
<!DOCTYPE doc SYSTEM "doc.dtd"> <doc> <title>Document Title</title> <chapter> <title>Chapter Title</title> <section> <title>Section Title</title> <para>This is a test.</para> <note>This is a note.</note> </section> <section> <title>Another Section Title</title> <para>This is <emph>another</emph> test.</para> <note>This is another note.</note> </section> </chapter> </doc>
it would produce the following result
<?xml version="1.0" encoding="iso-8859-1"?> <html xmlns="http://www.w3.org/TR/xhtml1"> <head> <title>Document Title</title> </head> <body> <h1>Document Title</h1> <h2>Chapter Title</h2> <h3>Section Title</h3> <p>This is a test.</p> <p class="note"> <b>NOTE: </b>This is a note.</p> <h3>Another Section Title</h3> <p>This is <em>another</em> test.</p> <p class="note"> <b>NOTE: </b>This is another note.</p> </body> </html>
This is an example of transforming some data represented in XML using three different XSLT stylesheets to produce three different representations of the data, HTML, SVG and VRML.
The input data is:
<sales> <division id="North"> <revenue>10</revenue> <growth>9</growth> <bonus>7</bonus> </division> <division id="South"> <revenue>4</revenue> <growth>3</growth> <bonus>4</bonus> </division> <division id="West"> <revenue>6</revenue> <growth>-1.5</growth> <bonus>2</bonus> </division> </sales>
The following stylesheet, which uses the simplified syntax described in 2.3 Literal Result Element as Stylesheet, transforms the data into HTML:
<html xsl:version="1.1" xmlns:xsl="http://www.w3.org/1999/XSL/Transform" lang="en"> <head> <title>Sales Results By Division</title> </head> <body> <table border="1"> <tr> <th>Division</th> <th>Revenue</th> <th>Growth</th> <th>Bonus</th> </tr> <xsl:for-each select="sales/division"> <!-- order the result by revenue --> <xsl:sort select="revenue" data-type="number" order="descending"/> <tr> <td> <em><xsl:value-of select="@id"/></em> </td> <td> <xsl:value-of select="revenue"/> </td> <td> <!-- highlight negative growth in red --> <xsl:if test="growth < 0"> <xsl:attribute name="style"> <xsl:text>color:red</xsl:text> </xsl:attribute> </xsl:if> <xsl:value-of select="growth"/> </td> <td> <xsl:value-of select="bonus"/> </td> </tr> </xsl:for-each> </table> </body> </html>
The HTML output is:
<html lang="en"> <head> <meta http-equiv="Content-Type" content="text/html; charset=iso-8859-1"> <title>Sales Results By Division</title> </head> <body> <table border="1"> <tr> <th>Division</th><th>Revenue</th><th>Growth</th><th>Bonus</th> </tr> <tr> <td><em>North</em></td><td>10</td><td>9</td><td>7</td> </tr> <tr> <td><em>West</em></td><td>6</td><td style="color:red">-1.5</td><td>2</td> </tr> <tr> <td><em>South</em></td><td>4</td><td>3</td><td>4</td> </tr> </table> </body> </html>
The following stylesheet transforms the data into SVG:
<xsl:stylesheet version="1.1" xmlns:xsl="http://www.w3.org/1999/XSL/Transform" xmlns="http://www.w3.org/Graphics/SVG/SVG-19990812.dtd"> <xsl:output method="xml" indent="yes" media-type="image/svg"/> <xsl:template match="/"> <svg width = "3in" height="3in"> <g style = "stroke: #000000"> <!-- draw the axes --> <line x1="0" x2="150" y1="150" y2="150"/> <line x1="0" x2="0" y1="0" y2="150"/> <text x="0" y="10">Revenue</text> <text x="150" y="165">Division</text> <xsl:for-each select="sales/division"> <!-- define some useful variables --> <!-- the bar's x position --> <xsl:variable name="pos" select="(position()*40)-30"/> <!-- the bar's height --> <xsl:variable name="height" select="revenue*10"/> <!-- the rectangle --> <rect x="{$pos}" y="{150-$height}" width="20" height="{$height}"/> <!-- the text label --> <text x="{$pos}" y="165"> <xsl:value-of select="@id"/> </text> <!-- the bar value --> <text x="{$pos}" y="{145-$height}"> <xsl:value-of select="revenue"/> </text> </xsl:for-each> </g> </svg> </xsl:template> </xsl:stylesheet>
The SVG output is:
<svg width="3in" height="3in" xmlns="http://www.w3.org/Graphics/SVG/svg-19990412.dtd"> <g style="stroke: #000000"> <line x1="0" x2="150" y1="150" y2="150"/> <line x1="0" x2="0" y1="0" y2="150"/> <text x="0" y="10">Revenue</text> <text x="150" y="165">Division</text> <rect x="10" y="50" width="20" height="100"/> <text x="10" y="165">North</text> <text x="10" y="45">10</text> <rect x="50" y="110" width="20" height="40"/> <text x="50" y="165">South</text> <text x="50" y="105">4</text> <rect x="90" y="90" width="20" height="60"/> <text x="90" y="165">West</text> <text x="90" y="85">6</text> </g> </svg>
The following stylesheet transforms the data into VRML:
<xsl:stylesheet version="1.1" xmlns:xsl="http://www.w3.org/1999/XSL/Transform"> <!-- generate text output as mime type model/vrml, using default charset --> <xsl:output method="text" encoding="UTF-8" media-type="model/vrml"/> <xsl:template match="/">#VRML V2.0 utf8 # externproto definition of a single bar element EXTERNPROTO bar [ field SFInt32 x field SFInt32 y field SFInt32 z field SFString name ] "http://www.vrml.org/WorkingGroups/dbwork/barProto.wrl" # inline containing the graph axes Inline { url "http://www.vrml.org/WorkingGroups/dbwork/barAxes.wrl" } <xsl:for-each select="sales/division"> bar { x <xsl:value-of select="revenue"/> y <xsl:value-of select="growth"/> z <xsl:value-of select="bonus"/> name "<xsl:value-of select="@id"/>" } </xsl:for-each> </xsl:template> </xsl:stylesheet>
The VRML output is:
#VRML V2.0 utf8 # externproto definition of a single bar element EXTERNPROTO bar [ field SFInt32 x field SFInt32 y field SFInt32 z field SFString name ] "http://www.vrml.org/WorkingGroups/dbwork/barProto.wrl" # inline containing the graph axes Inline { url "http://www.vrml.org/WorkingGroups/dbwork/barAxes.wrl" } bar { x 10 y 9 z 7 name "North" } bar { x 4 y 3 z 4 name "South" } bar { x 6 y -1.5 z 2 name "West" }
The following have contributed to authoring this draft:
Scott Boag, Lotus
Michael Kay, ICL
Daniel Lipkin, Saba
Jonathan Marsh, Microsoft
Steve Muench, Oracle
Henry Thompson, University of Edinburgh
Norman Walsh, Arbortext
Steve Zilles, Adobe
This specification was developed and approved for publication by the W3C XSL Working Group (WG). WG approval of this specification does not necessarily imply that all WG members voted for its approval. The current members of the XSL WG are:
The members of the XSL WG at the time of the publication of XSLT 1.0 were:
The following are the changes since XSLT 1.0:
The result tree fragment data-type has been eliminated. Variable-binding elements with content now construct node-sets (see 11.2 Values of Variables and Parameters).
Instead of the allowing the output method complete freedom to add namespace nodes, a process of namespace fixup is applied to the result tree before it is output; this same namespace fixup process is also applied to documents constructed variable-binding elements with content (see 3.5 Namespace Fixup).
Support for XML Base has been added (see 3.2 Base URI).
Multiple output documents can be created using the
xsl:document
element (see 16.5 Multiple Output Documents). For consistency with
xsl:document
, the attributes on xsl:output
are now interpreted as attribute value templates.
An xsl:apply-imports
element is allowed to have
parameters (see 5.6 Overriding Template Rules and 11.6 Passing Parameters to Templates).
Extension functions can be defined using the
xsl:script
function (see 14.4 Defining Extension Functions).
Extension functions are allowed to return "external" objects, which do not have any of the builtin XPath types.
Reported errors have also been fixed.