Please refer to the errata for this document, which may include some normative corrections.
See also translations .
This document is also available in these non-normative formats: XML .
Copyright © 2007 W3C ® ( MIT , ERCIM , Keio), All Rights Reserved. W3C liability, trademark and document use rules apply.
XPath 2.0 is an expression language that allows the processing of values conforming to the data model defined in [XQuery/XPath Data Model (XDM)]. The data model provides a tree representation of XML documents as well as atomic values such as integers, strings, and booleans, and sequences that may contain both references to nodes in an XML document and atomic values. The result of an XPath expression may be a selection of nodes from the input documents, or an atomic value, or more generally, any sequence allowed by the data model. The name of the language derives from its most distinctive feature, the path expression, which provides a means of hierarchic addressing of the nodes in an XML tree. XPath 2.0 is a superset of [XPath 1.0], with the added capability to support a richer set of data types, and to take advantage of the type information that becomes available when documents are validated using XML Schema. A backwards compatibility mode is provided to ensure that nearly all XPath 1.0 expressions continue to deliver the same result with XPath 2.0; exceptions to this policy are noted in [ I Backwards Compatibility with XPath 1.0 ].
This section describes the status of this document at the time of its publication. Other documents may supersede this document. A list of current W3C publications and the latest revision of this technical report can be found in the W3C technical reports index at http://www.w3.org/TR/.
This is one document in a set of eight documents that have progressed to Recommendation together (XQuery 1.0, XQueryX 1.0, XSLT 2.0, Data Model, Functions and Operators, Formal Semantics, Serialization, XPath 2.0).
This is a Recommendation of the W3C. It has been jointly developed by the W3C XSL Working Group and the W3C XML Query Working Group, each of which is part of the XML Activity.
This document has been reviewed by W3C Members, by software developers, and by other W3C groups and interested parties, and is endorsed by the Director as a W3C Recommendation. It is a stable document and may be used as reference material or cited from another document. W3C's role in making the Recommendation is to draw attention to the specification and to promote its widespread deployment. This enhances the functionality and interoperability of the Web.
No substantive changes have been made to this specification since its publication as a Proposed Recommendation.
Please report errors in this document using W3C's public Bugzilla system (instructions can be found at http://www.w3.org/XML/2005/04/qt-bugzilla). If access to that system is not feasible, you may send your comments to the W3C XSLT/XPath/XQuery public comments mailing list, public-qt-comments@w3.org. It will be very helpful if you include the string “[ XPath ]” in the subject line of your report, whether made in Bugzilla or in email. Each Bugzilla entry and email message should contain only one error report. Archives of the comments and responses are available at http://lists.w3.org/Archives/Public/public-qt-comments/.
This document was produced by groups operating under the 5 February 2004 W3C Patent Policy. W3C maintains a public list of any patent disclosures made in connection with the deliverables of the XML Query Working Group and also maintains a public list of any patent disclosures made in connection with the deliverables of the XSL Working Group; those pages also include instructions for disclosing a patent. An individual who has actual knowledge of a patent which the individual believes contains Essential Claim(s) must disclose the information in accordance with section 6 of the W3C Patent Policy.
1 Introduction
2 Basics
2.1 Expression
Context
2.1.1 Static Context
2.1.2 Dynamic Context
2.2 Processing Model
2.2.1 Data
Model Generation
2.2.2 Schema Import
Processing
2.2.3 Expression Processing
2.2.3.1 Static Analysis
Phase
2.2.3.2 Dynamic
Evaluation Phase
2.2.4 Serialization
2.2.5 Consistency Constraints
2.3 Error Handling
2.3.1 Kinds of Errors
2.3.2 Identifying
and Reporting Errors
2.3.3 Handling Dynamic Errors
2.3.4 Errors and Optimization
2.4 Concepts
2.4.1 Document Order
2.4.2 Atomization
2.4.3 Effective Boolean Value
2.4.4 Input Sources
2.5 Types
2.5.1 Predefined Schema Types
2.5.2 Typed Value and String Value
2.5.3 SequenceType Syntax
2.5.4 SequenceType Matching
2.5.4.1 Matching a SequenceType and a
Value
2.5.4.2 Matching an
ItemType and an Item
2.5.4.3 Element Test
2.5.4.4 Schema Element Test
2.5.4.5 Attribute Test
2.5.4.6 Schema Attribute Test
2.6 Comments
3 Expressions
3.1 Primary Expressions
3.1.1 Literals
3.1.2 Variable References
3.1.3 Parenthesized Expressions
3.1.4 Context Item Expression
3.1.5 Function Calls
3.2 Path Expressions
3.2.1 Steps
3.2.1.1 Axes
3.2.1.2 Node Tests
3.2.2 Predicates
3.2.3 Unabbreviated Syntax
3.2.4 Abbreviated Syntax
3.3 Sequence Expressions
3.3.1 Constructing Sequences
3.3.2 Filter Expressions
3.3.3 Combining Node Sequences
3.4 Arithmetic Expressions
3.5 Comparison
Expressions
3.5.1 Value Comparisons
3.5.2 General Comparisons
3.5.3 Node Comparisons
3.6
Logical Expressions
3.7 For Expressions
3.8 Conditional Expressions
3.9 Quantified Expressions
3.10 Expressions on SequenceTypes
3.10.1 Instance Of
3.10.2 Cast
3.10.3 Castable
3.10.4 Constructor Functions
3.10.5 Treat
A XPath Grammar
A.1 EBNF
A.1.1 Notation
A.1.2 Extra-grammatical Constraints
A.1.3 Grammar Notes
A.2 Lexical structure
A.2.1 Terminal
Symbols
A.2.2 Terminal Delimitation
A.2.3 End-of-Line Handling
A.2.3.1 XML 1.0 End-of-Line
Handling
A.2.3.2 XML
1.1 End-of-Line Handling
A.2.4 Whitespace Rules
A.2.4.1 Default Whitespace
Handling
A.2.4.2 Explicit Whitespace Handling
A.3 Reserved Function Names
A.4 Precedence Order
B Type Promotion and Operator
Mapping
B.1 Type Promotion
B.2 Operator
Mapping
C Context Components
C.1 Static
Context Components
C.2 Dynamic Context Components
D Implementation-Defined Items
E References
E.1 Normative References
E.2 Non-normative References
E.3 Background Material
F Conformance
F.1 Static Typing Feature
F.1.1 Static Typing Extensions
G Error
Conditions
H Glossary (Non-Normative)
I Backwards Compatibility with XPath 1.0 (Non-Normative)
I.1 Incompatibilities when Compatibility Mode is true
I.2 Incompatibilities when Compatibility Mode is false
I.3 Incompatibilities when using a Schema
J Revision Log (Non-Normative)
The primary purpose of XPath is to address the nodes of [XML 1.0] or [XML 1.1] trees. XPath gets its name from its use of a path notation for navigating through the hierarchical structure of an XML document. XPath uses a compact, non-XML syntax to facilitate use of XPath within URIs and XML attribute values.
[Definition: XPath operates on the abstract, logical structure of an XML document, rather than its surface syntax. This logical structure, known as the data model, is defined in [XQuery/XPath Data Model (XDM)].]
XPath is designed to be embedded in a host language such as [XSLT 2.0] or [XQuery]. XPath has a natural subset that can be used for matching (testing whether or not a node matches a pattern); this use of XPath is described in [XSLT 2.0].
XQuery Version 1.0 is an extension of XPath Version 2.0. Any expression that is syntactically valid and executes successfully in both XPath 2.0 and XQuery 1.0 will return the same result in both languages. Since these languages are so closely related, their grammars and language descriptions are generated from a common source to ensure consistency, and the editors of these specifications work together closely.
XPath also depends on and is closely related to the following specifications:
[XQuery/XPath Data Model (XDM)] defines the data model that underlies all XPath expressions.
[XQuery 1.0 and XPath 2.0 Formal Semantics] defines the static semantics of XPath and also contains a formal but non-normative description of the dynamic semantics that may be useful for implementors and others who require a formal definition.
The type system of XPath is based on [XML Schema].
The built-in function library and the operators supported by XPath are defined in [XQuery 1.0 and XPath 2.0 Functions and Operators].
This document specifies a grammar for XPath, using the same basic EBNF notation used in [XML 1.0]. Unless otherwise noted (see A.2 Lexical structure ), whitespace is not significant in expressions . Grammar productions are introduced together with the features that they describe, and a complete grammar is also presented in the appendix [ A XPath Grammar ]. The appendix is the normative version.
In the grammar productions in this document, named symbols are underlined and literal text is enclosed in double quotes. For example, the following production describes the syntax of a function call:
[48] |
FunctionCall
|
::= |
QName "(" (ExprSingle ("," ExprSingle)*)? ")"
|
The production should be read as follows: A function call consists of a QName followed by an open-parenthesis. The open-parenthesis is followed by an optional argument list. The argument list (if present) consists of one or more expressions, separated by commas. The optional argument list is followed by a close-parenthesis.
Certain aspects of language processing are described in this specification as implementation-defined or implementation-dependent.
[Definition: Implementation-defined indicates an aspect that may differ between implementations, but must be specified by the implementor for each particular implementation.]
[Definition: Implementation-dependent indicates an aspect that may differ between implementations, is not specified by this or any W3C specification, and is not required to be specified by the implementor for any particular implementation.]
A language aspect described in this specification as implementation-defined or implementation dependent may be further constrained by the specifications of a host language in which XPath is embedded.
This document normatively defines the dynamic semantics of XPath. The static semantics of XPath are normatively defined in [XQuery 1.0 and XPath 2.0 Formal Semantics]. In this document, examples and material labeled as "Note" are provided for explanatory purposes and are not normative.
The basic building block of XPath is the expression, which is a string of [Unicode] characters (the version of Unicode to be used is implementation-defined.) The language provides several kinds of expressions which may be constructed from keywords, symbols, and operands. In general, the operands of an expression are other expressions. XPath allows expressions to be nested with full generality.
Note:
This specification contains no assumptions or requirements regarding the character set encoding of strings of [Unicode] characters.
Like XML, XPath is a case-sensitive language. Keywords in XPath use lower-case characters and are not reserved—that is, names in XPath expressions are allowed to be the same as language keywords, except for certain unprefixed function-names listed in A.3 Reserved Function Names .
[Definition: In the data model, a value is always a sequence.] [Definition: A sequence is an ordered collection of zero or more items.] [Definition: An item is either an atomic value or
a node.] [Definition: An atomic value is a value in the value space of
an atomic type, as defined in [XML Schema].] [Definition: A node is an instance of one of the
node kinds defined in [XQuery/XPath Data Model (XDM)].] Each node has a unique node identity, a typed value, and a string value.
In addition, some nodes have a name. The typed value of a node is a sequence of zero or more atomic values. The string value of a node is a value of type
xs:string
. The name of a node is a value of type xs:QName
.
[Definition: A sequence containing exactly one item is called a singleton.] An item is identical to a singleton sequence containing that item. Sequences are never nested—for example, combining the values 1, (2, 3), and ( ) into a single sequence results in the sequence (1, 2, 3). [Definition: A sequence containing zero items is called an empty sequence.]
[Definition: The term XDM instance is used, synonymously with the term value, to denote an unconstrained sequence of nodes and/or atomic values in the data model.]
Names in XPath are called QNames, and conform to the syntax in [XML Names]. [Definition: Lexically, a
QName consists of an optional namespace prefix and a local name. If the namespace prefix is present, it is separated from the local name by a colon.] A lexical QName can be
converted into an expanded QName by resolving its namespace prefix to a namespace URI, using the statically
known namespaces [err:XPST0081]. [Definition: An
expanded QName consists of an optional namespace URI and a local name. An expanded QName also retains its original namespace prefix (if any), to facilitate casting the
expanded QName into a string.] The namespace URI value is whitespace normalized according to the rules for the xs:anyURI
type in [XML Schema]. Two
expanded QNames are equal if their namespace URIs are equal and their local names are equal (even if their namespace prefixes are not equal). Namespace URIs and local names are compared
on a codepoint basis, without further normalization.
This document uses the following namespace prefixes to represent the namespace URIs with which they are listed. Use of these namespace prefix bindings in this document is not normative.
xs = http://www.w3.org/2001/XMLSchema
fn = http://www.w3.org/2005/xpath-functions
err = http://www.w3.org/2005/xqt-errors
(see
2.3.2 Identifying and Reporting Errors
).
Element nodes have a property called in-scope namespaces. [Definition: The in-scope namespaces property of an element node is a set of namespace bindings, each of which associates a namespace prefix with a URI, thus defining the set of namespace prefixes that are available for interpreting QNames within the scope of the element. For a given element, one namespace binding may have an empty prefix; the URI of this namespace binding is the default namespace within the scope of the element.]
In [XPath 1.0], the in-scope namespaces of an element node are represented by a collection of namespace nodes arranged on a namespace axis. In XPath Version 2.0, the namespace axis is deprecated and need not be supported by a host language. A host language that does not support the namespace axis need not represent namespace bindings in the form of nodes.
[Definition: Within this specification, the term URI refers to a Universal Resource Identifier as defined in [RFC3986] and extended in [RFC3987] with the new name IRI.] The term URI has been retained in preference to IRI to avoid introducing new names for concepts such as "Base URI" that are defined or referenced across the whole family of XML specifications.
[Definition: The expression context for a given expression consists of all the information that can affect the result of the expression.] This information is organized into two categories called the static context and the dynamic context.
[Definition: The static context of an expression is the information that is available during static analysis of the expression, prior to its evaluation.] This information can be used to decide whether the expression contains a static error. If analysis of an expression relies on some component of the static context that has not been assigned a value, a static error is raised [err:XPST0001].
The individual components of the static context are summarized below. A default initial value for each component may be specified by the host language. The scope of each component is specified in C.1 Static Context Components .
[Definition: XPath 1.0 compatibility mode.
This value is true
if rules for backward compatibility with XPath Version 1.0 are in effect; otherwise it is false
.
]
[Definition: Statically known namespaces. This is a set of (prefix,
URI) pairs that define all the namespaces that are known during static processing of a given expression.] The URI value is whitespace normalized according to the rules for
the xs:anyURI
type in [XML Schema]. Note the difference between in-scope
namespaces, which is a dynamic property of an element node, and statically known namespaces,
which is a static property of an expression.
[Definition: Default element/type namespace. This is a namespace URI
or "none". The namespace URI, if present, is used for any unprefixed QName appearing in a position where an element or type name is expected.] The URI value is whitespace
normalized according to the rules for the xs:anyURI
type in [XML Schema].
[Definition: Default function namespace. This is a namespace URI or "none". The
namespace URI, if present, is used for any unprefixed QName appearing in a position where a function name is expected.] The URI value is whitespace normalized according to
the rules for the xs:anyURI
type in [XML Schema].
[Definition: In-scope schema definitions. This is a generic term for all the element declarations, attribute declarations, and schema type definitions that are in scope during processing of an expression.] It includes the following three parts:
[Definition: In-scope schema types. Each schema type definition is identified either by an expanded QName (for a named type) or by an implementation-dependent type identifier (for an anonymous type). The in-scope schema types include the predefined schema types described in 2.5.1 Predefined Schema Types . ]
[Definition: In-scope element declarations. Each element declaration is identified either by an expanded QName (for a top-level element declaration) or by an implementation-dependent element identifier (for a local element declaration). ] An element declaration includes information about the element's substitution group affiliation.
[Definition: Substitution groups are defined in [XML Schema] Part 1, Section 2.2.2.2. Informally, the substitution group headed by a given element (called the head element) consists of the set of elements that can be substituted for the head element without affecting the outcome of schema validation.]
[Definition: In-scope attribute declarations. Each attribute declaration is identified either by an expanded QName (for a top-level attribute declaration) or by an implementation-dependent attribute identifier (for a local attribute declaration). ]
[Definition: In-scope variables. This is a set of (expanded QName, type) pairs. It defines the set of variables that are available for reference within an expression. The expanded QName is the name of the variable, and the type is the static type of the variable.]
An expression that binds a variable (such as a for
, some
, or every
expression) extends the in-scope variables of its subexpressions with the new bound variable and its type.
[Definition: Context item static type. This component defines the static type of the context item within the scope of a given expression.]
[Definition: Function signatures. This component defines the set of functions that are available to be called from within an expression. Each function is uniquely identified by its expanded QName and its arity (number of parameters).] In addition to the name and arity, each function signature specifies the static types of the function parameters and result.
The function signatures include the signatures of constructor functions, which are discussed in 3.10.4 Constructor Functions .
[Definition: Statically known collations. This is an implementation-defined set of (URI, collation) pairs. It defines the names of the collations that are available for use in processing expressions.] [Definition: A collation is a specification of the manner in which strings and URIs are compared and, by extension, ordered. For a more complete definition of collation, see [XQuery 1.0 and XPath 2.0 Functions and Operators].]
[Definition: Default collation. This identifies one of the collations in statically known collations as the collation to be used by functions and operators for comparing and
ordering values of type xs:string
and xs:anyURI
(and types derived from them) when no explicit collation is specified.]
[Definition: Base URI. This is an absolute URI, used when necessary in the resolution of relative URIs
(for example, by the fn:resolve-uri
function.)] The URI value is whitespace normalized according to the rules for the xs:anyURI
type in [XML Schema].
[Definition: Statically known documents. This is a mapping from strings onto types.
The string represents the absolute URI of a resource that is potentially available using the fn:doc
function. The type is the static type of a call to fn:doc
with the given URI as its literal argument. ] If the argument to fn:doc
is a string
literal that is not present in statically known documents, then the static type of fn:doc
is
document-node()?
.
Note:
The purpose of the statically known documents is to provide static type information, not to determine which documents are available. A URI need not be found in the
statically known documents to be accessed using fn:doc
.
[Definition: Statically known collections. This is a mapping from
strings onto types. The string represents the absolute URI of a resource that is potentially available using the fn:collection
function. The type is the type of
the sequence of nodes that would result from calling the fn:collection
function with this URI as its argument.] If the argument to fn:collection
is
a string literal that is not present in statically known collections, then the static type of
fn:collection
is node()*
.
Note:
The purpose of the statically known collections is to provide static type information, not to determine which collections are available. A URI need not be found in
the statically known collections to be accessed using fn:collection
.
[Definition: Statically known default
collection type. This is the type of the sequence of nodes that would result from calling the fn:collection
function with no arguments.] Unless
initialized to some other value by an implementation, the value of statically known default collection type is node()*
.
[Definition: The dynamic context of an expression is defined as information that is available at the time the expression is evaluated.] If evaluation of an expression relies on some part of the dynamic context that has not been assigned a value, a dynamic error is raised [err:XPDY0002].
The individual components of the dynamic context are summarized below. Further rules governing the semantics of these components can be found in C.2 Dynamic Context Components .
The dynamic context consists of all the components of the static context, and the additional components listed below.
[Definition: The first three components of the dynamic context (context item, context position, and context size) are called the focus of the expression. ] The focus enables the processor to keep track of which items are being processed by the expression.
Certain language constructs, notably the path expression
E1/E2
and the predicate
E1[E2]
, create a new focus for the evaluation of a sub-expression. In these constructs, E2
is evaluated once for each item in the sequence that results
from evaluating E1
. Each time E2
is evaluated, it is evaluated with a different focus. The focus for evaluating E2
is referred to below as
the inner focus, while the focus for evaluating E1
is referred to as the outer focus. The inner focus exists only while E2
is being
evaluated. When this evaluation is complete, evaluation of the containing expression continues with its original focus unchanged.
[Definition: The context item is the item currently being processed. An item is either an
atomic value or a node.][Definition: When the context item is a node, it can also be referred to as
the context node.] The context item is returned by an expression consisting of a single dot (.
). When an expression E1/E2
or
E1[E2]
is evaluated, each item in the sequence obtained by evaluating E1
becomes the context item in the inner focus for an evaluation of
E2
.
[Definition: The context position is the position of the context item within the
sequence of items currently being processed.] It changes whenever the context item changes. When the focus is defined, the value of the context position is an integer
greater than zero. The context position is returned by the expression fn:position()
. When an expression E1/E2
or E1[E2]
is evaluated,
the context position in the inner focus for an evaluation of E2
is the position of the context item in the sequence obtained by evaluating E1
. The
position of the first item in a sequence is always 1 (one). The context position is always less than or equal to the context size.
[Definition: The context size is the number of items in the sequence of items currently being
processed.] Its value is always an integer greater than zero. The context size is returned by the expression fn:last()
. When an expression E1/E2
or
E1[E2]
is evaluated, the context size in the inner focus for an evaluation of E2
is the number of items in the sequence obtained by evaluating
E1
.
[Definition: Variable values. This is a set of (expanded QName, value) pairs. It contains the same expanded QNames as the in-scope variables in the static context for the expression. The expanded QName is the name of the variable and the value is the dynamic value of the variable, which includes its dynamic type.]
[Definition: Function implementations. Each function in function signatures has a function implementation that enables the function to map instances of its parameter types into an instance of its result type. ]
[Definition: Current dateTime. This information represents an implementation-dependent point in time during the processing of
an expression
, and includes an explicit timezone. It can be retrieved by the fn:current-dateTime
function. If invoked multiple times during the execution of
an expression
, this function always returns the same result.]
[Definition: Implicit timezone. This is the timezone to be used when a date, time, or dateTime
value that does not have a timezone is used in a comparison or arithmetic operation. The implicit timezone is an implementation-defined value of type xs:dayTimeDuration
. See [XML Schema] for the range of legal
values of a timezone.]
[Definition: Available documents. This is a mapping of strings onto document nodes.
The string represents the absolute URI of a resource. The document node is the root of a tree that represents that resource using the data model. The document node is returned by the fn:doc
function when applied to that URI.] The set of available documents is not
limited to the set of statically known documents, and it may be empty.
If there are one or more URIs in available documents that map to a document node D
, then the
document-uri property of D
must either be absent, or must be one of these URIs.
Note:
This means that given a document node $N
, the result of fn:doc(fn:document-uri($N)) is $N
will always be True, unless
fn:document-uri($N)
is an empty sequence.
[Definition: Available collections. This is a mapping of strings
onto sequences of nodes. The string represents the absolute URI of a resource. The sequence of nodes represents the result of the fn:collection
function when
that URI is supplied as the argument. ] The set of available collections is not limited to the set of statically known collections, and it may be empty.
For every document node D
that is in the target of a mapping in available collections, or
that is the root of a tree containing such a node, the document-uri property of D
must either be absent, or must be a URI U
such that available documents contains a mapping from U
to D
."
Note:
This means that for any document node $N
retrieved using the fn:collection
function, either directly or by navigating to the root of a node that
was returned, the result of fn:doc(fn:document-uri($N)) is $N
will always be True, unless fn:document-uri($N)
is an empty sequence. This implies
a requirement for the fn:doc
and fn:collection
functions to be consistent in their effect. If the implementation uses catalogs or user-supplied
URI resolvers to dereference URIs supplied to the fn:doc
function, the implementation of the fn:collection
function must take these mechanisms
into account. For example, an implementation might achieve this by mapping the collection URI to a set of document URIs, which are then resolved using the same catalog or
URI resolver that is used by the fn:doc
function.
[Definition: Default collection. This is the sequence of nodes that would
result from calling the fn:collection
function with no arguments.] The value of default collection may be initialized by the implementation.
XPath is defined in terms of the data model and the expression context.
Figure 1: Processing Model Overview
Figure 1 provides a schematic overview of the processing steps that are discussed in detail below. Some of these steps are completely outside the domain of XPath; in Figure 1, these are depicted outside the line that represents the boundaries of the language, an area labeled external processing. The external processing domain includes generation of an XDM instance that represents the data to be queried (see 2.2.1 Data Model Generation ), schema import processing (see 2.2.2 Schema Import Processing ) and serialization (see 2.2.4 Serialization ). The area inside the boundaries of the language is known as the XPath processing domain , which includes the static analysis and dynamic evaluation phases (see 2.2.3 Expression Processing ). Consistency constraints on the XPath processing domain are defined in 2.2.5 Consistency Constraints .
Before an expression can be processed, its input data must be represented as an XDM instance. This process occurs outside the domain of XPath, which is why Figure 1 represents it in the external processing domain. Here are some steps by which an XML document might be converted to an XDM instance:
A document may be parsed using an XML parser that generates an XML Information Set (see [XML Infoset]). The parsed document may then be validated against one or more schemas. This process, which is described in [XML Schema], results in an abstract information structure called the Post-Schema Validation Infoset (PSVI). If a document has no associated schema, its Information Set is preserved. (See DM1 in Fig. 1.)
The Information Set or PSVI may be transformed into an XDM instance by a process described in [XQuery/XPath Data Model (XDM)]. (See DM2 in Fig. 1.)
The above steps provide an example of how an XDM instance might be constructed. An XDM instance might also be synthesized directly from a relational database, or constructed in some other way (see DM3 in Fig. 1.) XPath is defined in terms of the data model, but it does not place any constraints on how XDM instances are constructed.
[Definition: Each element node and attribute node in an XDM instance has a type annotation (referred to in [XQuery/XPath Data Model (XDM)] as its type-name
property.) The type annotation of a node is a schema type that describes the relationship between the string value of the node and its typed value.] If the XDM instance was derived from a validated XML document as described in Section 3.3
Construction from a PSVI
DM
, the type annotations of the element and attribute nodes are derived from schema validation. XPath does not provide a way to directly access the type annotation of an
element or attribute node.
The value of an attribute is represented directly within the attribute node. An attribute node whose type is unknown (such as might occur in a schemaless document) is given the type annotation
xs:untypedAtomic
.
The value of an element is represented by the children of the element node, which may include text nodes and other element nodes. The type annotation of an element node indicates how the values in its child text nodes are to be interpreted. An element that has not been validated
(such as might occur in a schemaless document) is annotated with the schema type xs:untyped
. An element that has been validated and found to be partially valid is
annotated with the schema type xs:anyType
. If an element node is annotated as xs:untyped
, all its descendant element nodes are also annotated as
xs:untyped
. However, if an element node is annotated as xs:anyType
, some of its descendant element nodes may have a more specific type annotation.
The in-scope schema definitions in the static context are provided by the host language (see step SI1 in Figure 1) and must satisfy the consistency constraints defined in 2.2.5 Consistency Constraints .
XPath defines two phases of processing called the static analysis phase and the dynamic evaluation phase (see Fig. 1). During the static analysis phase, static errors, dynamic errors, or type errors may be raised. During the dynamic evaluation phase, only dynamic errors or type errors may be raised. These kinds of errors are defined in 2.3.1 Kinds of Errors .
Within each phase, an implementation is free to use any strategy or algorithm whose result conforms to the specifications in this document.
[Definition: The static analysis phase depends on the expression itself and on the static context. The static analysis phase does not depend on input data (other than schemas).]
During the static analysis phase, the XPath expression is parsed into an internal representation called the operation tree (step SQ1 in Figure 1). A parse error is raised as a static error [err:XPST0003]. The static context is initialized by the implementation (step SQ2). The static context is used to resolve schema type names, function names, namespace prefixes, and variable names (step SQ4). If a name of one of these kinds in the operation tree is not found in the static context, a static error ([err:XPST0008] or [err:XPST0017]) is raised (however, see exceptions to this rule in 2.5.4.3 Element Test and 2.5.4.5 Attribute Test .)
The operation tree is then normalized by making explicit the implicit operations such as atomization and extraction of Effective Boolean Values (step SQ5). The normalization process is described in [XQuery 1.0 and XPath 2.0 Formal Semantics].
Each expression is then assigned a static type (step SQ6). [Definition: The static type of an expression is a type such that, when the expression is evaluated, the resulting value will always conform to the static type.] If the Static Typing Feature is supported, the static types of various expressions are inferred according to the rules described in [XQuery 1.0 and XPath 2.0 Formal Semantics]. If the Static Typing Feature is not supported, the static types that are assigned are implementation-dependent.
During the static analysis phase, if the Static Typing Feature is in effect and an operand of an expression is found to have a static type that is not appropriate for that operand, a type error is raised [err:XPTY0004]. If static type checking raises no errors and assigns a static type T to an expression, then execution of the expression on valid input data is guaranteed either to produce a value of type T or to raise a dynamic error.
The purpose of the Static Typing Feature is to provide early detection of type errors and to infer type information that may be useful in optimizing the evaluation of an expression.
[Definition: The dynamic evaluation phase is the phase during which the value of an expression is computed.] It occurs after completion of the static analysis phase.
The dynamic evaluation phase can occur only if no errors were detected during the static analysis phase. If the Static Typing Feature is in effect, all type errors are detected during static analysis and serve to inhibit the dynamic evaluation phase.
The dynamic evaluation phase depends on the operation tree of the expression being evaluated (step DQ1), on the input data (step DQ4), and on the dynamic context (step DQ5), which in turn draws information from the external environment (step DQ3) and the static context (step DQ2). The dynamic evaluation phase may create new data-model values (step DQ4) and it may extend the dynamic context (step DQ5)—for example, by binding values to variables.
[Definition: A dynamic type is associated with each value as it is computed. The dynamic type of
a value may be more specific than the static type of the expression that computed it (for example, the static type of an
expression might be xs:integer*
, denoting a sequence of zero or more integers, but at evaluation time its value may have the dynamic type xs:integer
,
denoting exactly one integer.)]
If an operand of an expression is found to have a dynamic type that is not appropriate for that operand, a type error is raised [err:XPTY0004].
Even though static typing can catch many type errors before an expression is executed, it is possible for an expression to raise
an error during evaluation that was not detected by static analysis. For example, an expression may contain a cast of a string into an integer, which is statically valid.
However, if the actual value of the string at run time cannot be cast into an integer, a dynamic error will result.
Similarly, an expression may apply an arithmetic operator to a value whose static type is xs:untypedAtomic
. This
is not a static error, but at run time, if the value cannot be successfully cast to a numeric type, a dynamic error will be raised.
When the Static Typing Feature is in effect, it is also possible for static analysis of an expression to raise a type error, even though execution of the expression on certain inputs would be successful. For example, an expression might contain a function that requires an element as its parameter, and the static analysis phase might infer the static type of the function parameter to be an optional element. This case is treated as a type error and inhibits evaluation, even though the function call would have been successful for input data in which the optional element is present.
[Definition: Serialization is the process of converting an XDM instance into a sequence of octets (step DM4 in Figure 1.) ] The general framework for serialization is described in [XSLT 2.0 and XQuery 1.0 Serialization].
The host language may provide a serialization option.
In order for XPath to be well defined, the input XDM instance, the static context, and the dynamic context must be mutually consistent. The consistency constraints listed below are prerequisites for correct functioning of an XPath implementation. Enforcement of these consistency constraints is beyond the scope of this specification. This specification does not define the result of an expression under any condition in which one or more of these constraints is not satisfied.
Some of the consistency constraints use the term data model schema. [Definition: For a given node in an XDM instance, the data model schema is defined as the schema from which the type annotation of that node was derived.] For a node that was constructed by some process other than schema validation, the data model schema consists simply of the schema type definition that is represented by the type annotation of the node.
For every node that has a type annotation, if that type annotation is found in the in-scope schema definitions (ISSD), then its definition in the ISSD must be equivalent to its definition in the data model schema. Furthermore, all types that are derived by extension from the given type in the data model schema must also be known by equivalent definitions in the ISSD.
For every element name EN that is found both in an XDM instance and in the in-scope schema definitions (ISSD), all elements that are known in the data model schema to be in the substitution group headed by EN must also be known in the ISSD to be in the substitution group headed by EN.
Every element name, attribute name, or schema type name referenced in in-scope variables or function signatures must be in the in-scope schema definitions, unless it is an element name referenced as part of an ElementTest or an attribute name referenced as part of an AttributeTest.
Any reference to a global element, attribute, or type name in the in-scope schema definitions must have a corresponding element, attribute or type definition in the in-scope schema definitions.
For each mapping of a string to a document node in available documents, if there exists a mapping of the same string to a document type in statically known documents, the document node must match the document type, using the matching rules in 2.5.4 SequenceType Matching .
For each mapping of a string to a sequence of nodes in available collections, if there exists a mapping of the same string to a type in statically known collections, the sequence of nodes must match the type, using the matching rules in 2.5.4 SequenceType Matching .
The sequence of nodes in the default collection must match the statically known default collection type, using the matching rules in 2.5.4 SequenceType Matching .
The value of the context item must match the context item static type, using the matching rules in 2.5.4 SequenceType Matching .
For each (variable, type) pair in in-scope variables and the corresponding (variable, value) pair in variable values such that the variable names are equal, the value must match the type, using the matching rules in 2.5.4 SequenceType Matching .
In the statically known namespaces, the prefix xml
must not be bound to any namespace
URI other than http://www.w3.org/XML/1998/namespace
, and no prefix other than xml
may be bound to this namespace URI.
As described in 2.2.3 Expression Processing , XPath defines a static analysis phase, which does not depend on input data, and a dynamic evaluation phase, which does depend on input data. Errors may be raised during each phase.
[Definition: A static error is an error that must be detected during the static analysis phase. A syntax error is an example of a static error.]
[Definition: A dynamic error is an error that must be detected during the dynamic evaluation phase and may be detected during the static analysis phase. Numeric overflow is an example of a dynamic error. ]
[Definition: A type error may be raised during the static analysis phase or the dynamic evaluation phase. During the static analysis phase, a type error occurs when the static type of an expression does not match the expected type of the context in which the expression occurs. During the dynamic evaluation phase, a type error occurs when the dynamic type of a value does not match the expected type of the context in which the value occurs.]
The outcome of the static analysis phase is either success or one or more type errors, static errors, or statically-detected dynamic errors. The result of the dynamic evaluation phase is either a result value, a type error, or a dynamic error.
If more than one error is present, or if an error condition comes within the scope of more than one error defined in this specification, then any non-empty subset of these errors may be reported.
During the static analysis phase, if the Static Typing Feature is in effect and the static type assigned to an expression other than ()
or
data(())
is empty-sequence()
, a static error is raised [err:XPST0005]. This catches cases in which a query refers to an element or attribute that is not present in the in-scope schema definitions, possibly because of a spelling error.
Independently of whether the Static Typing Feature is in effect, if an implementation can determine
during the static analysis phase that an expression, if evaluated, would necessarily raise a type error or a dynamic error, the implementation may (but is not required
to) report that error during the static analysis phase. However, the fn:error()
function must not be
evaluated during the static analysis phase.
[Definition: In addition to static errors, dynamic errors, and type errors, an XPath implementation may raise warnings, either during the static analysis phase or the dynamic evaluation phase. The circumstances in which warnings are raised, and the ways in which warnings are handled, are implementation-defined.]
In addition to the errors defined in this specification, an implementation may raise a dynamic error for a reason beyond the scope of this specification. For example, limitations may exist on the maximum numbers or sizes of various objects. Any such limitations, and the consequences of exceeding them, are implementation-dependent.
The errors defined in this specification are identified by QNames that have the form err:XPYYnnnn
, where:
err
denotes the namespace for XPath and XQuery errors, http://www.w3.org/2005/xqt-errors
. This binding of the namespace prefix err
is
used for convenience in this document, and is not normative.
XP
identifies the error as an XPath error.
YY
denotes the error category, using the following encoding:
ST
denotes a static error.
DY
denotes a dynamic error.
TY
denotes a type error.
nnnn
is a unique numeric code.
Note:
The namespace URI for XPath and XQuery errors is not expected to change from one version of XPath to another. However, the contents of this namespace may be extended to include additional error definitions.
The method by which an XPath processor reports error information to the external environment is implementation-defined.
An error can be represented by a URI reference that is derived from the error QName as follows: an error with namespace URI
NS
and local part
LP
can be represented as the URI reference
NS
#
LP
. For example, an error whose QName is err:XPST0017
could be represented as http://www.w3.org/2005/xqt-errors#XPST0017
.
Note:
Along with a code identifying an error, implementations may wish to return additional information, such as the location of the error or the processing phase in which it was detected. If an implementation chooses to do so, then the mechanism that it uses to return this information is implementation-defined.
Except as noted in this document, if any operand of an expression raises a dynamic error, the expression also raises a dynamic error. If an expression can validly return a value or raise a dynamic error, the implementation may choose to return
the value or raise the dynamic error. For example, the logical expression expr1 and expr2
may return the value false
if either operand returns
false
, or may raise a dynamic error if either operand raises a dynamic error.
If more than one operand of an expression raises an error, the implementation may choose which error is raised by the expression. For example, in this expression:
($x div $y) + xs:decimal($z)
both the sub-expressions ($x div $y)
and xs:decimal($z)
may raise an error. The implementation may choose which error is raised by the "+
"
expression. Once one operand raises an error, the implementation is not required, but is permitted, to evaluate any other operands.
[Definition: In addition to its identifying QName, a dynamic error may also carry a descriptive string and one or more additional values called error values.] An implementation may provide a mechanism whereby an application-defined error handler can process error values and produce diagnostic messages.
A dynamic error may be raised by a built-in function or operator. For example, the div
operator raises
an error if its operands are xs:decimal
values and its second operand is equal to zero. Errors raised by built-in functions and operators are defined in [XQuery 1.0 and XPath 2.0 Functions and Operators].
A dynamic error can also be raised explicitly by calling the fn:error
function, which only raises an error and never returns a value. This function is defined in [XQuery 1.0 and XPath 2.0 Functions and Operators]. For example, the following function call raises a dynamic error, providing a QName that
identifies the error, a descriptive string, and a diagnostic value (assuming that the prefix app
is bound to a namespace containing application-defined error codes):
fn:error(xs:QName("app:err057"), "Unexpected value", fn:string($v))
Because different implementations may choose to evaluate or optimize an expression in different ways, certain aspects of the detection and reporting of dynamic errors are implementation-dependent, as described in this section.
An implementation is always free to evaluate the operands of an operator in any order.
In some cases, a processor can determine the result of an expression without accessing all the data that would be implied by the formal expression semantics. For example, the
formal description of filter expressions suggests that $s[1]
should be evaluated by examining all the
items in sequence $s
, and selecting all those that satisfy the predicate position()=1
. In practice, many implementations will recognize that they can
evaluate this expression by taking the first item in the sequence and then exiting. If $s
is defined by an expression such as //book[author eq
'Berners-Lee']
, then this strategy may avoid a complete scan of a large document and may therefore greatly improve performance. However, a consequence of this strategy is
that a dynamic error or type error that would be detected if the expression semantics were followed literally might not be detected at all if the evaluation exits early. In this
example, such an error might occur if there is a book
element in the input data with more than one author
subelement.
The extent to which a processor may optimize its access to data, at the cost of not detecting errors, is defined by the following rules.
Consider an expression Q that has an operand (sub-expression) E. In general the value of E is a sequence. At an intermediate stage during evaluation of the sequence, some of its items will be known and others will be unknown. If, at such an intermediate stage of evaluation, a processor is able to establish that there are only two possible outcomes of evaluating Q, namely the value V or an error, then the processor may deliver the result V without evaluating further items in the operand E. For this purpose, two values are considered to represent the same outcome if their items are pairwise the same, where nodes are the same if they have the same identity, and values are the same if they are equal and have exactly the same type.
There is an exception to this rule: If a processor evaluates an operand E (wholly or in part), then it is required to establish that the actual value of the operand
E does not violate any constraints on its cardinality. For example, the expression $e eq 0
results in a type error if the value of $e
contains
two or more items. A processor is not allowed to decide, after evaluating the first item in the value of $e
and finding it equal to zero, that the only possible
outcomes are the value true
or a type error caused by the cardinality violation. It must establish that the value of $e
contains no more than one item.
These rules apply to all the operands of an expression considered in combination: thus if an expression has two operands E1 and E2, it may be evaluated using any samples of the respective sequences that satisfy the above rules.
The rules cascade: if A is an operand of B and B is an operand of C, then the processor needs to evaluate only a sufficient sample of B to determine the value of C, and needs to evaluate only a sufficient sample of A to determine this sample of B.
The effect of these rules is that the processor is free to stop examining further items in a sequence as soon as it can establish that further items would not affect the result
except possibly by causing an error. For example, the processor may return true
as the result of the expression S1 = S2
as soon as it finds a pair of
equal values from the two sequences.
Another consequence of these rules is that where none of the items in a sequence contributes to the result of an expression, the processor is not obliged to evaluate any part of the sequence. Again, however, the processor cannot dispense with a required cardinality check: if an empty sequence is not permitted in the relevant context, then the processor must ensure that the operand is not an empty sequence.
Examples:
If an implementation can find (for example, by using an index) that at least one item returned by $expr1
in the following example has the value 47
,
it is allowed to return true
as the result of the some
expression, without searching for another item returned by $expr1
that would
raise an error if it were evaluated.
some $x in $expr1 satisfies $x = 47
In the following example, if an implementation can find (for example, by using an index) the product
element-nodes that have an id
child with the
value 47
, it is allowed to return these nodes as the result of the path expression, without searching
for another product
node that would raise an error because it has an id
child whose value is not an integer.
//product[id = 47]
For a variety of reasons, including optimization, implementations are free to rewrite expressions into equivalent expressions. Other than the raising or not raising of errors, the result of evaluating an equivalent expression must be the same as the result of evaluating the original expression. Expression rewrite is illustrated by the following examples.
Consider the expression //part[color eq "Red"]
. An implementation might choose to rewrite this expression as //part[color = "Red"][color eq "Red"]
.
The implementation might then process the expression as follows: First process the "=
" predicate by probing an index on parts by color to quickly find all the
parts that have a Red color; then process the "eq
" predicate by checking each of these parts to make sure it has only a single color. The result would be as
follows:
Parts that have exactly one color that is Red are returned.
If some part has color Red together with some other color, an error is raised.
The existence of some part that has no color Red but has multiple non-Red colors does not trigger an error.
The expression in the following example cannot raise a casting error if it is evaluated exactly as written (i.e., left to right). Since neither predicate depends on the context position, an implementation might choose to reorder the predicates to achieve better performance (for example, by taking advantage of an index). This reordering could cause the expression to raise an error.
$N[@x castable as xs:date][xs:date(@x) gt xs:date("2000-01-01")]
To avoid unexpected errors caused by expression rewrite, tests that are designed to prevent dynamic errors should be expressed using conditional expressions. Conditional
expressions raise only dynamic errors that occur in the branch that is actually selected. Thus, unlike the previous example, the following example cannot raise a dynamic
error if @x
is not castable into an xs:date
:
$N[if (@x castable as xs:date) then xs:date(@x) gt xs:date("2000-01-01") else false()]
This section explains some concepts that are important to the processing of XPath expressions.
An ordering called document order is defined among all the nodes accessible during processing of a given expression , which may consist of one or more trees (documents or fragments). Document order is defined in [XQuery/XPath Data Model (XDM)], and its definition is repeated here for convenience. [Definition: The node ordering that is the reverse of document order is called reverse document order.]
Document order is a total ordering, although the relative order of some nodes is implementation-dependent. [Definition: Informally, document order is the order in which nodes appear in the XML serialization of a document.] [Definition: Document order is stable, which means that the relative order of two nodes will not change during the processing of a given expression , even if this order is implementation-dependent.]
Within a tree, document order satisfies the following constraints:
The root node is the first node.
Every node occurs before all of its children and descendants.
Namespace nodes immediately follow the element node with which they are associated. The relative order of namespace nodes is stable but implementation-dependent.
Attribute nodes immediately follow the namespace nodes of the element node with which they are associated. The relative order of attribute nodes is stable but implementation-dependent.
The relative order of siblings is the order in which they occur in the children
property of their parent node.
Children and descendants occur before following siblings.
The relative order of nodes in distinct trees is stable but implementation-dependent, subject to the following constraint: If any node in a given tree T1 is before any node in a different tree T2, then all nodes in tree T1 are before all nodes in tree T2.
The semantics of some XPath operators depend on a process called atomization. Atomization is applied to a value when the value is
used in a context in which a sequence of atomic values is required. The result of atomization is either a sequence of atomic values or a type error [err:FOTY0012]. [Definition: Atomization of a sequence is defined
as the result of invoking the fn:data
function on the sequence, as defined in [XQuery 1.0 and XPath 2.0 Functions and
Operators].]
The semantics of fn:data
are repeated here for convenience. The result of fn:data
is the sequence of atomic values produced by applying the following
rules to each item in the input sequence:
If the item is an atomic value, it is returned.
If the item is a node, its typed value is returned (err:FOTY0012 is raised if the node has no typed value.)
Atomization is used in processing the following types of expressions:
Arithmetic expressions
Comparison expressions
Function calls and returns
Cast expressions
Under certain circumstances (listed below), it is necessary to find the effective boolean value of a value. [Definition: The effective boolean value of a value is defined as the result of applying the fn:boolean
function to the value, as defined in [XQuery 1.0 and XPath 2.0 Functions and Operators].]
The dynamic semantics of fn:boolean
are repeated here for convenience:
If its operand is an empty sequence, fn:boolean
returns false
.
If its operand is a sequence whose first item is a node, fn:boolean
returns true
.
If its operand is a singleton value of type xs:boolean
or derived from xs:boolean
,
fn:boolean
returns the value of its operand unchanged.
If its operand is a singleton value of type xs:string
, xs:anyURI
, xs:untypedAtomic
, or a
type derived from one of these, fn:boolean
returns false
if the operand value has zero length; otherwise it returns true
.
If its operand is a singleton value of any numeric type or derived from a numeric
type, fn:boolean
returns false
if the operand value is NaN
or is numerically equal to zero; otherwise it returns
true
.
In all other cases, fn:boolean
raises a type error [err:FORG0006].
Note:
The static semantics of fn:boolean
are defined in Section 7.2.4 The fn:boolean function
FS
.
The effective boolean value of a sequence is computed implicitly during processing of the following types of expressions:
Logical expressions (and
, or
)
The fn:not
function
Certain types of predicates, such as a[b]
Conditional expressions (if
)
Quantified expressions (some
, every
)
General comparisons, in XPath 1.0 compatibility mode.
Note:
The definition of effective boolean value is not used when casting a value to the type xs:boolean
,
for example in a cast
expression or when passing a value to a function whose expected parameter is of type xs:boolean
.
XPath has a set of functions that provide access to input data. These functions are of particular importance because they provide a way in which an expression can reference a document or a collection of documents. The input functions are described informally here; they are defined in [XQuery 1.0 and XPath 2.0 Functions and Operators].
An expression can access input data either by calling one of the input functions or by referencing some part of the dynamic context that is initialized by the external environment, such as a variable or context item.
The input functions supported by XPath are as follows:
The fn:doc
function takes a string containing a URI. If that URI is associated with a document in available documents, fn:doc
returns a document node whose content is the data model representation of the
given document; otherwise it raises a dynamic error (see [XQuery 1.0 and XPath 2.0
Functions and Operators] for details).
The fn:collection
function with one argument takes a string containing a URI. If that URI is associated with a collection in available collections, fn:collection
returns the data model representation of that collection; otherwise it raises a dynamic error (see [XQuery 1.0 and XPath 2.0 Functions and Operators] for
details). A collection may be any sequence of nodes. For example, the expression fn:collection("http://example.org")//customer
identifies all the
customer
elements that are descendants of nodes found in the collection whose URI is http://example.org
.
The fn:collection
function with zero arguments returns the default collection, an implementation-dependent sequence of nodes.
The type system of XPath is based on [XML Schema], and is formally defined in [XQuery 1.0 and XPath 2.0 Formal Semantics].
[Definition: A sequence type is a type that can be expressed using the SequenceType syntax. Sequence types are used whenever it is necessary to refer to a type in an XPath expression. The term sequence type suggests that this syntax is used to describe the type of an XPath value, which is always a sequence.]
[Definition: A schema type is a type that is (or could be) defined using the facilities of [XML Schema] (including the built-in types of [XML Schema]).] A schema type can be used as a type annotation on an element or
attribute node (unless it is a non-instantiable type such as xs:NOTATION
or xs:anyAtomicType
, in which case its derived types can be so used). Every schema
type is either a complex type or a simple type; simple types are further subdivided into list types, union types, and atomic types (see [XML Schema] for definitions and explanations of these terms.)
Atomic types represent the intersection between the categories of sequence type and schema type. An atomic type, such as xs:integer
or my:hatsize
, is both a sequence type and a schema type.
The in-scope schema types in the static context
are initialized with a set of predefined schema types that is determined by the host language. This set may include some or all of the schema types in the namespace
http://www.w3.org/2001/XMLSchema
, represented in this document by the namespace prefix xs
. The schema types in this namespace are defined in [XML Schema] and augmented by additional types defined in [XQuery/XPath Data Model (XDM)]. The schema types defined in [XQuery/XPath Data Model (XDM)] are summarized below.
[Definition: xs:untyped
is used as the type
annotation of an element node that has not been validated, or has been validated in skip
mode.] No predefined schema types are derived from
xs:untyped
.
[Definition: xs:untypedAtomic
is an atomic type that is used to denote untyped
atomic data, such as text that has not been assigned a more specific type.] An attribute that has been validated in skip
mode is represented in the data model by an attribute node with the type annotation
xs:untypedAtomic
. No predefined schema types are derived from xs:untypedAtomic
.
[Definition: xs:dayTimeDuration
is derived by restriction from
xs:duration
. The lexical representation of xs:dayTimeDuration
is restricted to contain only day, hour, minute, and second components.]
[Definition: xs:yearMonthDuration
is derived by restriction from
xs:duration
. The lexical representation of xs:yearMonthDuration
is restricted to contain only year and month components.]
[Definition: xs:anyAtomicType
is an atomic type that includes all atomic values
(and no values that are not atomic). Its base type is xs:anySimpleType
from which all simple types, including atomic, list, and union types, are derived. All
primitive atomic types, such as xs:integer
, xs:string
, and xs:untypedAtomic
, have xs:anyAtomicType
as their base type.]
Note:
xs:anyAtomicType
will not appear as the type of an actual value in an XDM instance.
The relationships among the schema types in the xs
namespace are illustrated in Figure 2. A more complete description of the XPath type hierarchy can be found in [XQuery 1.0 and XPath 2.0 Functions and Operators].
Figure 2: Hierarchy of Schema Types used in XPath
Every node has a typed value and a string value. [Definition: The typed value of a node
is a sequence of atomic values and can be extracted by applying the fn:data
function to the node.] [Definition: The string value of a node is a string and can be extracted by applying the fn:string
function to the node.]
Definitions of fn:data
and fn:string
can be found in [XQuery 1.0 and XPath 2.0 Functions and Operators].
An implementation may store both the typed value and the string value of a
node, or it may store only one of these and derive the other as needed. The string value of a node must be a valid lexical representation of the typed value of the node, but the
node is not required to preserve the string representation from the original source document. For example, if the typed value of a node is the xs:integer
value
30
, its string value might be "30
" or "0030
".
The typed value, string value, and type annotation of a node are closely related. If the node was created by mapping from an Infoset or PSVI, the relationships among these properties are defined by rules in [XQuery/XPath Data Model (XDM)].
As a convenience to the reader, the relationship between typed value and string value for various kinds of nodes is summarized and illustrated by examples below.
For text and document nodes, the typed value of the node is the same as its string value, as an instance of the type xs:untypedAtomic
. The string value of a
document node is formed by concatenating the string values of all its descendant text nodes, in document order.
The typed value of a comment
, namespace,
or processing instruction node is the same as its string value. It is an instance of the type xs:string
.
The typed value of an attribute node with the type annotation
xs:anySimpleType
or xs:untypedAtomic
is the same as its string value, as an instance of xs:untypedAtomic
. The typed value of an
attribute node with any other type annotation is derived from its string value and type annotation using the lexical-to-value-space mapping defined in [XML Schema] Part 2 for the relevant type.
Example: A1 is an attribute having string value "3.14E-2"
and type annotation xs:double
. The typed value of A1 is the xs:double
value
whose lexical representation is 3.14E-2
.
Example: A2 is an attribute with type annotation xs:IDREFS
, which is a list datatype whose item type is the atomic datatype xs:IDREF
. Its string
value is "bar baz faz
". The typed value of A2 is a sequence of three atomic values ("bar
", "baz
", "faz
"), each of type
xs:IDREF
. The typed value of a node is never treated as an instance of a named list type. Instead, if the type annotation of a node is a list type (such as
xs:IDREFS
), its typed value is treated as a sequence of the atomic type from which it is derived (such as xs:IDREF
).
For an element node, the relationship between typed value and string value depends on the node's type annotation, as follows:
If the type annotation is xs:untyped
or xs:anySimpleType
or denotes a complex type with mixed content (including xs:anyType
),
then the typed value of the node is equal to its string value, as an instance of xs:untypedAtomic
. However, if the nilled
property of the
node is true
, then its typed value is the empty sequence.
Example: E1 is an element node having type annotation xs:untyped
and string value "1999-05-31
". The typed value of E1 is
"1999-05-31
", as an instance of xs:untypedAtomic
.
Example: E2 is an element node with the type annotation formula
, which is a complex type with mixed content. The content of E2 consists of the character
"H
", a child element named subscript
with string value "2
", and the character "O
". The typed value of E2 is
"H2O
" as an instance of xs:untypedAtomic
.
If the type annotation denotes a simple type or a complex type with simple content, then the typed value of the node is derived from its string value and its type
annotation in a way that is consistent with schema validation. However, if the nilled
property of the node is true
, then its typed value is
the empty sequence.
Example: E3 is an element node with the type annotation cost
, which is a complex type that has several attributes and a simple content type of
xs:decimal
. The string value of E3 is "74.95
". The typed value of E3 is 74.95
, as an instance of xs:decimal
.
Example: E4 is an element node with the type annotation hatsizelist
, which is a simple type derived from the atomic type hatsize
, which in
turn is derived from xs:integer
. The string value of E4 is "7 8 9
". The typed value of E4 is a sequence of three values (7
,
8
, 9
), each of type hatsize
.
Example: E5 is an element node with the type annotation my:integer-or-string
which is a union type with member types xs:integer
and
xs:string
. The string value of E5 is "47
". The typed value of E5 is 47
as an xs:integer
, since
xs:integer
is the member type that validated the content of E5. In general, when the type annotation of a node is a union type, the typed value of the
node will be an instance of one of the member types of the union.
Note:
If an implementation stores only the string value of a node, and the type annotation of the node is a union type, the implementation must be able to deliver the typed value of the node as an instance of the appropriate member type.
If the type annotation denotes a complex type with empty content, then the typed value of the node is the empty sequence and its string value is the zero-length string.
If the type annotation denotes a complex type with element-only content, then the typed value of the node is undefined. The fn:data
function raises a type error [err:FOTY0012] when applied to such a node. The string value of such a node is equal to the concatenated
string values of all its text node descendants, in document order.
Example: E6 is an element node with the type annotation weather
, which is a complex type whose content type specifies element-only
. E6 has
two child elements named temperature
and precipitation
. The typed value of E6 is undefined, and the fn:data
function applied to
E6 raises an error.
Whenever it is necessary to refer to a type in an XPath expression, the SequenceType syntax is used.
With the exception of the special type empty-sequence()
, a sequence type consists of an item type that
constrains the type of each item in the sequence, and a cardinality that constrains the number of items in the sequence. Apart from the item type item()
, which
permits any kind of item, item types divide into node types (such as element()
) and atomic types (such as xs:integer
).
Item types representing element and attribute nodes may specify the required type annotations of those nodes, in the form
of a schema type. Thus the item type element(*, us:address)
denotes any element node whose type annotation is (or is
derived from) the schema type named us:address
.
Here are some examples of sequence types that might be used in XPath expressions:
xs:date
refers to the built-in atomic schema type named xs:date
attribute()?
refers to an optional attribute node
element()
refers to any element node
element(po:shipto, po:address)
refers to an element node that has the name po:shipto
and has the type annotation po:address
(or a
schema type derived from po:address
)
element(*, po:address)
refers to an element node of any name that has the type annotation po:address
(or a type derived from
po:address
)
element(customer)
refers to an element node named customer
with any type annotation
schema-element(customer)
refers to an element node whose name is customer
(or is in the substitution group headed by customer
) and
whose type annotation matches the schema type declared for a customer
element in the in-scope
element declarations
node()*
refers to a sequence of zero or more nodes of any kind
item()+
refers to a sequence of one or more nodes or atomic values
[Definition: During evaluation of an expression, it is sometimes necessary to
determine whether a value with a known dynamic type "matches" an expected sequence type. This process is known as SequenceType matching.] For example, an instance of
expression returns true
if the dynamic type of a given value matches a given sequence type, or
false
if it does not.
QNames appearing in a sequence type have their prefixes expanded to namespace URIs by means of the statically known namespaces and (where applicable) the default element/type namespace. An unprefixed attribute QName is in no namespace. Equality of QNames is defined by the
eq
operator.
The rules for SequenceType matching compare the dynamic type of a value with an expected sequence type. These rules are a subset of the formal rules that match a value with an expected type defined in [XQuery 1.0 and XPath 2.0 Formal Semantics], because the Formal Semantics must be able to match values against types that are not expressible using the SequenceType syntax.
Some of the rules for SequenceType matching require determining whether a given schema type is the same as or derived from an expected schema type. The given schema type may be "known" (defined in the in-scope schema definitions), or "unknown" (not defined in the in-scope schema definitions). An unknown schema type might be encountered, for example, if a source document has been validated using a schema that was not imported into the static context. In this case, an implementation is allowed (but is not required) to provide an implementation-dependent mechanism for determining whether the unknown schema type is derived from the expected schema type. For example, an implementation might maintain a data dictionary containing information about type hierarchies.
[Definition: The use of a value whose dynamic type is derived from an expected type is known as subtype substitution.] Subtype substitution does not change the actual type of a
value. For example, if an xs:integer
value is used where an xs:decimal
value is expected, the value retains its type as xs:integer
.
The definition of SequenceType matching relies on a pseudo-function named derives-from(
AT,
ET)
, which takes an actual simple or complex schema type AT and an expected simple or complex schema type ET, and either returns a boolean
value or raises a type error [err:XPTY0004]. The pseudo-function
derives-from
is defined below and is defined formally in [XQuery 1.0 and XPath 2.0 Formal Semantics].
derives-from(
AT, ET)
returns true
if ET is a known type and any of the following three conditions is true:
AT is a schema type found in the in-scope schema definitions, and is the same as ET or is derived by restriction or extension from ET
AT is a schema type not found in the in-scope schema definitions, and an implementation-dependent mechanism is able to determine that AT is derived by restriction from ET
There exists some schema type IT such that derives-from(
IT, ET)
and derives-from(
AT, IT)
are true.
derives-from(
AT, ET)
returns false
if ET is a known type and either the first and third or the second and
third of the following conditions are true:
AT is a schema type found in the in-scope schema definitions, and is not the same as ET, and is not derived by restriction or extension from ET
AT is a schema type not found in the in-scope schema definitions, and an implementation-dependent mechanism is able to determine that AT is not derived by restriction from ET
No schema type IT exists such that derives-from(
IT, ET)
and derives-from(
AT, IT)
are
true.
derives-from(
AT, ET)
raises a type error [err:XPTY0004] if:
ET is an unknown type, or
AT is an unknown type, and the implementation is not able to determine whether AT is derived by restriction from ET.
The rules for SequenceType matching are given below, with examples (the examples are for purposes of illustration, and do not cover all possible cases).
The sequence type
empty-sequence()
matches a value that is the empty sequence.
An ItemType with no OccurrenceIndicator matches any value that contains exactly one item if the ItemType matches that item (see 2.5.4.2 Matching an ItemType and an Item ).
An ItemType with an OccurrenceIndicator matches a value if the number of items in the value matches the OccurrenceIndicator and the ItemType matches each of the items in the value.
An OccurrenceIndicator specifies the number of items in a sequence, as follows:
?
matches zero or one items
*
matches zero or more items
+
matches one or more items
As a consequence of these rules, any sequence type whose OccurrenceIndicator
is *
or ?
matches a value that is an empty sequence.
An ItemType consisting simply of a QName is interpreted as an AtomicType. An AtomicType
AtomicType matches an atomic value whose actual type is AT if derives-from(
AT, AtomicType)
is true
.
If a QName that is used as an AtomicType is not defined as an atomic type in the in-scope schema types, a static error is raised [err:XPST0051].
Example: The AtomicType
xs:decimal
matches the value 12.34
(a decimal literal). xs:decimal
also matches a value whose type is shoesize
, if
shoesize
is an atomic type derived by restriction from xs:decimal
.
Note:
The names of non-atomic types such as xs:IDREFS
are not accepted in this context, but can often be replaced by an atomic type with an occurrence
indicator, such as xs:IDREF+
.
item()
matches any single item.
Example: item()
matches the atomic value 1
or the element <a/>
.
node()
matches any node.
text()
matches any text node.
processing-instruction()
matches any processing-instruction node.
processing-instruction(
N)
matches any processing-instruction node whose name (called its "PITarget" in XML) is equal to N,
where N is an NCName.
Example: processing-instruction(xml-stylesheet)
matches any processing instruction whose PITarget is xml-stylesheet
.
For backward compatibility with XPath 1.0, the PITarget of a processing instruction may also be expressed as a string literal, as in this example:
processing-instruction("xml-stylesheet")
.
comment()
matches any comment node.
document-node()
matches any document node.
document-node(
E)
matches any document node that contains exactly one element node, optionally accompanied by one or more comment and
processing instruction nodes, if E is an ElementTest or SchemaElementTest that
matches the element node (see
2.5.4.3 Element Test
and
2.5.4.4 Schema Element Test
).
Example: document-node(element(book))
matches a document node containing exactly one element node that is matched by the ElementTest
element(book)
.
An ItemType that is an ElementTest, SchemaElementTest, AttributeTest, or SchemaAttributeTest matches an element or attribute node as described in the following sections.
An ElementTest is used to match an element node by its name and/or type annotation. An ElementTest may take any of the following forms. In these forms, ElementName need not be present in the in-scope element declarations, but TypeName must be present in the in-scope schema types [err:XPST0008]. Note that substitution groups do not affect the semantics of ElementTest.
element()
and element(*)
match any single element node, regardless of its name or type annotation.
element(
ElementName)
matches any element node whose name is ElementName, regardless of its type annotation or nilled
property.
Example: element(person)
matches any element node whose name is person
.
element(
ElementName,
TypeName)
matches an element node whose name is ElementName if
derives-from(
AT, TypeName
)
is true
, where AT is the type annotation of the element node, and the nilled
property of the node is false
.
Example: element(person, surgeon)
matches a non-nilled element node whose name is person
and whose type annotation is surgeon
(or
is derived from surgeon
).
element(
ElementName, TypeName
?)
matches an element node whose name is ElementName if derives-from(
AT, TypeName)
is true
, where AT is the type annotation of the element node. The nilled
property of the node may be either true
or false
.
Example: element(person, surgeon?)
matches a nilled or non-nilled element node whose name is person
and whose type annotation is
surgeon
(or is derived from surgeon
).
element(*,
TypeName)
matches an element node regardless of its name, if derives-from(
AT, TypeName
)
is true
, where AT is the type annotation of the element node, and the nilled
property of the node is false
.
Example: element(*, surgeon)
matches any non-nilled element node whose type annotation is surgeon
(or is derived from surgeon
),
regardless of its name.
element(*,
TypeName
?)
matches an element node regardless of its name, if derives-from(
AT, TypeName
)
is true
, where AT is the type annotation of the element node. The nilled
property of the node may be either
true
or false
.
Example: element(*, surgeon?)
matches any nilled or non-nilled element node whose type annotation is surgeon
(or is derived from
surgeon
), regardless of its name.
A SchemaElementTest matches an element node against a corresponding element declaration found in the in-scope element declarations. It takes the following form:
schema-element(
ElementName
)
If the ElementName specified in the SchemaElementTest is not found in the in-scope element declarations, a static error is raised [err:XPST0008].
A SchemaElementTest matches a candidate element node if all three of the following conditions are satisfied:
The name of the candidate node matches the specified ElementName or matches the name of an element in a substitution group headed by an element named ElementName.
derives-from(
AT, ET)
is true
, where AT is the type annotation of the candidate node and ET is the schema
type declared for element ElementName in the in-scope element
declarations.
If the element declaration for ElementName in the in-scope element
declarations is not nillable
, then the nilled
property of the candidate node is false
.
Example: The SchemaElementTest
schema-element(customer)
matches a candidate element node if customer
is a top-level element declaration in the in-scope element declarations, the name of the candidate node is customer
or is in a substitution group headed by customer
, the type annotation of the candidate node is the same as or derived from the schema type
declared for the customer
element, and either the candidate node is not nilled
or customer
is declared to be nillable
.
An AttributeTest is used to match an attribute node by its name and/or type annotation. An AttributeTest any take any of the following forms. In these forms, AttributeName need not be present in the in-scope attribute declarations, but TypeName must be present in the in-scope schema types [err:XPST0008].
attribute()
and attribute(*)
match any single attribute node, regardless of its name or type annotation.
attribute(
AttributeName)
matches any attribute node whose name is AttributeName, regardless of its type annotation.
Example: attribute(price)
matches any attribute node whose name is price
.
attribute(
AttributeName, TypeName)
matches an attribute node whose name
is AttributeName if derives-from(
AT, TypeName
)
is true
, where AT is the type annotation of the attribute node.
Example: attribute(price, currency)
matches an attribute node whose name is price
and whose type annotation is currency
(or is
derived from currency
).
attribute(*,
TypeName)
matches an attribute node regardless of its name, if derives-from(
AT, TypeName)
is true
, where AT is the type annotation of the attribute node.
Example: attribute(*, currency)
matches any attribute node whose type annotation is currency
(or is derived from currency
),
regardless of its name.
A SchemaAttributeTest matches an attribute node against a corresponding attribute declaration found in the in-scope attribute declarations. It takes the following form:
schema-attribute(
AttributeName
)
If the AttributeName specified in the SchemaAttributeTest is not found in the in-scope attribute declarations, a static error is raised [err:XPST0008].
A SchemaAttributeTest matches a candidate attribute node if both of the following conditions are satisfied:
The name of the candidate node matches the specified AttributeName.
derives-from(
AT, ET)
is true
, where AT is the type annotation of the candidate node and ET is the schema
type declared for attribute AttributeName in the in-scope attribute
declarations.
Example: The SchemaAttributeTest
schema-attribute(color)
matches a candidate attribute node if color
is a top-level attribute declaration in the in-scope attribute declarations, the name of the candidate node is color
, and the type annotation of the candidate
node is the same as or derived from the schema type declared for the color
attribute.
[77] |
Comment
|
::= |
"(:" (CommentContents | Comment)* ":)"
|
[82] |
CommentContents
|
::= |
(Char+ - (Char* ('(:' | ':)') Char*))
|
Comments may be used to provide informative annotation for an expression . Comments are lexical constructs only, and do not affect expression processing.
Comments are strings, delimited by the symbols (:
and :)
. Comments may be nested.
A comment may be used anywhere ignorable whitespace is allowed (see A.2.4.1 Default Whitespace Handling ).
The following is an example of a comment:
(: Houston, we have a problem :)
This section discusses each of the basic kinds of expression. Each kind of expression has a name such as PathExpr
, which is introduced on the left side of the grammar
production that defines the expression. Since XPath is a composable language, each kind of expression is defined in terms of other expressions whose operators have a higher precedence.
In this way, the precedence of operators is represented explicitly in the grammar.
The order in which expressions are discussed in this document does not reflect the order of operator precedence. In general, this document introduces the simplest kinds of expressions first, followed by more complex expressions. For the complete grammar, see Appendix [ A XPath Grammar ].
The highest-level symbol in the XPath grammar is XPath.
[1] |
XPath
|
::= |
Expr
|
[2] |
Expr
|
::= |
ExprSingle ("," ExprSingle)*
|
[3] |
ExprSingle
|
::= |
ForExpr
|
The XPath operator that has lowest precedence is the comma operator, which is used to combine two operands to form a sequence. As shown in the grammar, a general expression (Expr) can consist of multiple ExprSingle operands, separated by commas. The name ExprSingle denotes an expression that does not contain a top-level comma operator (despite its name, an ExprSingle may evaluate to a sequence containing more than one item.)
The symbol ExprSingle is used in various places in the grammar where an expression is not allowed to contain a top-level comma. For example, each of the arguments of a function call must be an ExprSingle, because commas are used to separate the arguments of a function call.
After the comma, the expressions that have next lowest precedence are ForExpr, QuantifiedExpr, IfExpr, and OrExpr. Each of these expressions is described in a separate section of this document.
[Definition: Primary expressions are the basic primitives of the language. They include literals, variable references, context item expressions, and function calls. A primary expression may also be created by enclosing any expression in parentheses, which is sometimes helpful in controlling the precedence of operators.]
[41] |
PrimaryExpr
|
::= |
Literal | VarRef | ParenthesizedExpr | ContextItemExpr | FunctionCall
|
[Definition: A literal is a direct syntactic representation of an atomic value.] XPath supports two kinds of literals: numeric literals and string literals.
[42] |
Literal
|
::= |
NumericLiteral | StringLiteral
|
[43] |
NumericLiteral
|
::= |
IntegerLiteral | DecimalLiteral | DoubleLiteral
|
[71] |
IntegerLiteral
|
::= |
Digits
|
[72] |
DecimalLiteral
|
::= |
("." Digits) | (Digits "." [0-9]*)
|
[73] |
DoubleLiteral
|
::= |
(("." Digits) | (Digits ("." [0-9]*)?)) [eE] [+-]? Digits
|
[74] |
StringLiteral
|
::= |
('"' (EscapeQuot | [^"])* '"') | ("'" (EscapeApos | [^'])* "'")
|
[75] |
EscapeQuot
|
::= |
'""'
|
[76] |
EscapeApos
|
::= |
"''"
|
[81] |
Digits
|
::= |
[0-9]+
|
The value of a numeric literal containing no ".
" and no e
or E
character is an atomic value of type xs:integer
. The
value of a numeric literal containing ".
" but no e
or E
character is an atomic value of type xs:decimal
. The value of a numeric
literal containing an e
or E
character is an atomic value of type xs:double
. The value of the numeric literal is determined by casting it to
the appropriate type according to the rules for casting from xs:untypedAtomic
to a numeric type as specified in Section 17.1.1 Casting from xs:string and xs:untypedAtomic
FO
.
The value of a string literal is an atomic value whose type is xs:string
and whose value is the string denoted by the characters between the delimiting
apostrophes or quotation marks. If the literal is delimited by apostrophes, two adjacent apostrophes within the literal are interpreted as a single apostrophe. Similarly, if the
literal is delimited by quotation marks, two adjacent quotation marks within the literal are interpreted as one quotation mark.
Here are some examples of literal expressions:
"12.5"
denotes the string containing the characters '1', '2', '.', and '5'.
12
denotes the xs:integer
value twelve.
12.5
denotes the xs:decimal
value twelve and one half.
125E2
denotes the xs:double
value twelve thousand, five hundred.
"He said, ""I don't like it."""
denotes a string containing two quotation marks and one apostrophe.
Note:
When XPath expressions are embedded in contexts where quotation marks have special significance, such as inside XML attributes, additional escaping may be needed.
The xs:boolean
values true
and false
can be represented by calls to the built-in
functions
fn:true()
and fn:false()
, respectively.
Values of other atomic types can be constructed by calling the constructor function for the given type. The constructor functions for XML Schema built-in types are defined in [XQuery 1.0 and XPath 2.0 Functions and Operators]. In general, the name of a constructor function for a given type is the same as the name of the type (including its namespace). For example:
xs:integer("12")
returns the integer value twelve.
xs:date("2001-08-25")
returns an item whose type is xs:date
and whose value represents the date 25th August 2001.
xs:dayTimeDuration("PT5H")
returns an item whose type is xs:dayTimeDuration
and whose value represents a duration of five hours.
Constructor functions can also be used to create special values that have no literal representation, as in the following examples:
xs:float("NaN")
returns the special floating-point value, "Not a Number."
xs:double("INF")
returns the special double-precision value, "positive infinity."
It is also possible to construct values of various types by using a cast
expression. For example:
9 cast as hatsize
returns the atomic value 9
whose type is hatsize
.
[44] |
VarRef
|
::= |
"$" VarName
|
[45] |
VarName
|
::= |
QName
|
[Definition: A variable reference is a QName preceded by a $-sign.] Two variable references are equivalent if their local names are the same and their namespace prefixes are bound to the same namespace URI in the statically known namespaces. An unprefixed variable reference is in no namespace.
Every variable reference must match a name in the in-scope variables, which include variables from the following sources:
The in-scope variables may be augmented by implementation-defined variables.
A variable may be bound by an XPath expression.
The kinds of expressions that can bind variables are for
expressions (
3.7 For Expressions
) and quantified expressions (
3.9 Quantified Expressions
).
Every variable binding has a static scope. The scope defines where references to the variable can validly occur. It is a static error [err:XPST0008] to reference a variable that is not in scope. If a variable is bound in the static context for an expression, that variable is in scope for the entire expression.
If a variable reference matches two or more variable bindings that are in scope, then the reference is taken as referring to the inner binding, that is, the one whose scope is smaller. At evaluation time, the value of a variable reference is the value of the expression to which the relevant variable is bound. The scope of a variable binding is defined separately for each kind of expression that can bind variables.
[46] |
ParenthesizedExpr
|
::= |
"(" Expr? ")"
|
Parentheses may be used to enforce a particular evaluation order in expressions that contain multiple operators. For example, the expression (2 + 4) * 5
evaluates to
thirty, since the parenthesized expression (2 + 4)
is evaluated first and its result is multiplied by five. Without parentheses, the expression 2 + 4 * 5
evaluates to twenty-two, because the multiplication operator has higher precedence than the addition operator.
Empty parentheses are used to denote an empty sequence, as described in 3.3.1 Constructing Sequences .
[47] |
ContextItemExpr
|
::= |
"."
|
A context item expression evaluates to the context item, which may be either a node (as in the expression
fn:doc("bib.xml")/books/book[fn:count(./author)>1]
) or an atomic value (as in the expression (1 to 100)[. mod 5 eq 0]
).
If the context item is undefined, a context item expression raises a dynamic error [err:XPDY0002].
[Definition: The built-in functions supported by XPath are defined in [XQuery 1.0 and XPath 2.0 Functions and Operators].] Additional functions may be provided in the static context. XPath per se does not provide a way to declare functions, but a host language may provide such a mechanism.
[48] |
FunctionCall
|
::= |
QName "(" (ExprSingle ("," ExprSingle)*)? ")"
|
A function call consists of a QName followed by a parenthesized list of zero or more expressions, called arguments. If the QName in the function call has no namespace prefix, it is considered to be in the default function namespace.
If the expanded QName and number of arguments in a function call do not match the name and arity of a function signature in the static context, a static error is raised [err:XPST0017].
A function call is evaluated as follows:
Argument expressions are evaluated, producing argument values. The order of argument evaluation is implementation-dependent and a function need not evaluate an argument if the function can evaluate its body without evaluating that argument.
Each argument value is converted by applying the function conversion rules listed below.
The function is evaluated using the converted argument values. The result is either an instance of the function's declared return type or a dynamic error. The dynamic type of a function result may be a type that is derived from the declared return type. Errors raised by functions are defined in [XQuery 1.0 and XPath 2.0 Functions and Operators].
The function conversion rules are used to convert an argument value to its expected type; that is, to the declared type of the function parameter. The expected type is expressed as a sequence type. The function conversion rules are applied to a given value as follows:
If XPath 1.0 compatibility mode is true
and an argument is not of the expected type,
then the following conversions are applied sequentially to the argument value V:
If the expected type calls for a single item or optional single item (examples: xs:string
, xs:string?
, xs:untypedAtomic
,
xs:untypedAtomic?
, node()
, node()?
, item()
, item()?
), then the value V is effectively replaced by
V[1].
If the expected type is xs:string
or xs:string?
, then the value V
is effectively replaced by fn:string(V)
.
If the expected type is xs:double
or xs:double?
, then the value V
is effectively replaced by fn:number(V)
.
If the expected type is a sequence of an atomic type (possibly with an occurrence indicator *
, +
, or ?
), the following conversions are
applied:
Atomization is applied to the given value, resulting in a sequence of atomic values.
Each item in the atomic sequence that is of type xs:untypedAtomic
is cast to the expected atomic type. For built-in functions where the expected type is specified as numeric, arguments of type
xs:untypedAtomic
are cast to xs:double
.
For each numeric item in the atomic sequence that can be promoted to the expected atomic type using numeric promotion as described in B.1 Type Promotion , the promotion is done.
For each item of type xs:anyURI
in the atomic sequence that can be promoted to the expected atomic
type using URI promotion as described in
B.1 Type Promotion
, the promotion is done.
If, after the above conversions, the resulting value does not match the expected type according to the rules for SequenceType Matching, a type error is raised [err:XPTY0004]. Note that the rules for SequenceType Matching permit a value of a derived type to be substituted for a value of its base type.
Since the arguments of a function call are separated by commas, any argument expression that contains a top-level comma operator must be enclosed in parentheses. Here are some illustrative examples of function calls:
my:three-argument-function(1, 2, 3)
denotes a function call with three arguments.
my:two-argument-function((1, 2), 3)
denotes a function call with two arguments, the first of which is a sequence of two values.
my:two-argument-function(1, ())
denotes a function call with two arguments, the second of which is an empty sequence.
my:one-argument-function((1, 2, 3))
denotes a function call with one argument that is a sequence of three values.
my:one-argument-function(( ))
denotes a function call with one argument that is an empty sequence.
my:zero-argument-function( )
denotes a function call with zero arguments.
[25] |
PathExpr
|
::= |
("/" RelativePathExpr?)
|
[26] |
RelativePathExpr
|
::= |
StepExpr (("/" | "//") StepExpr)*
|
[Definition: A path expression can be used to locate nodes within trees. A path expression
consists of a series of one or more steps, separated by "/
" or "//
", and optionally beginning with "/
" or
"//
".] An initial "/
" or "//
" is an abbreviation for one or more initial steps that are implicitly added to the beginning of the path
expression, as described below.
A path expression consisting of a single step is evaluated as described in 3.2.1 Steps .
A "/
" at the beginning of a path expression is an abbreviation for the initial step fn:root(self::node()) treat as document-node()/
(however, if the
"/
" is the entire path expression, the trailing "/
" is omitted from the expansion.) The effect of this initial step is to begin the path at the root node
of the tree that contains the context node. If the context item is not a node, a type error is raised [err:XPTY0020]. At evaluation time, if the root node above the context node is not a document node, a dynamic error is raised [err:XPDY0050].
A "//
" at the beginning of a path expression is an abbreviation for the initial steps fn:root(self::node()) treat as
document-node()/descendant-or-self::node()/
(however, "//
" by itself is not a valid path expression [err:XPST0003].) The effect of these initial steps is to establish an initial node sequence that contains the root of the tree in which the context node is found, plus all nodes
descended from this root. This node sequence is used as the input to subsequent steps in the path expression. If the context item is not a node, a type error is raised [err:XPTY0020]. At evaluation time, if the root node above the context node is not a
document node, a dynamic error is raised [err:XPDY0050].
Note:
The descendants of a node do not include attribute nodes or namespace nodes .
Each non-initial occurrence of "//
" in a path expression is expanded as described in
3.2.4 Abbreviated Syntax
, leaving a sequence of steps separated by "/
". This sequence of steps is then evaluated from left to right. Each operation E1/E2
is evaluated as
follows: Expression E1
is evaluated, and if the result is not a (possibly empty) sequence of nodes, a type error is
raised [err:XPTY0019]. Each node resulting from the evaluation of E1
then serves in turn to provide an inner focus
for an evaluation of E2
, as described in
2.1.2 Dynamic Context
. The sequences resulting from all the evaluations of E2
are combined as follows:
If every evaluation of E2
returns a (possibly empty) sequence of nodes, these sequences are combined, and duplicate nodes are eliminated based on node identity.
The resulting node sequence is returned in document order.
If every evaluation of E2
returns a (possibly empty) sequence of atomic values, these sequences are concatenated
, in order,
and returned.
If the multiple evaluations of E2
return at least one node and at least one atomic value, a type error is raised
[err:XPTY0018].
Note:
Since each step in a path provides context nodes for the following step, in effect, only the last step in a path is allowed to return a sequence of atomic values.
As an example of a path expression, child::div1/child::para
selects the para
element children of the div1
element children of the context node,
or, in other words, the para
element grandchildren of the context node that have div1
parents.
Note:
The "/
" character can be used either as a complete path expression or as the beginning of a longer path expression such as "/*
".
Also, "*
" is both the multiply operator and a wildcard in path expressions. This can cause parsing difficulties when "/
" appears on the left hand side of
"*
". This is resolved using the leading-lone-slash constraint. For example, "/*
" and "/ *
"
are valid path expressions containing wildcards, but "/*5
" and "/ * 5
" raise syntax errors. Parentheses must be used when "/
" is used on the
left hand side of an operator, as in "(/) * 5
". Similarly, "4 + / * 5
" raises a syntax error, but "4 + (/) * 5
" is a valid expression. The
expression "4 + /
" is also valid, because /
does not occur on the left hand side of the operator.
[27] |
StepExpr
|
::= |
FilterExpr | AxisStep
|
[28] |
AxisStep
|
::= |
(ReverseStep | ForwardStep) PredicateList
|
[29] |
ForwardStep
|
::= |
(ForwardAxis
NodeTest) | AbbrevForwardStep
|
[32] |
ReverseStep
|
::= |
(ReverseAxis
NodeTest) | AbbrevReverseStep
|
[39] |
PredicateList
|
::= |
Predicate*
|
[Definition: A step is a part of a path expression that generates a sequence of items and then filters the sequence by zero or more predicates. The value of the step consists of those items that satisfy the predicates, working from left to right. A step may be either an axis step or a filter expression.] Filter expressions are described in 3.3.2 Filter Expressions .
[Definition: An axis step returns a sequence of nodes that are reachable from the context node via a specified axis. Such a step has two parts: an axis, which defines the "direction of movement" for the step, and a node test, which selects nodes based on their kind, name, and/or type annotation.] If the context item is a node, an axis step returns a sequence of zero or more nodes; otherwise, a type error is raised [err:XPTY0020]. The resulting node sequence is returned in document order. An axis step may be either a forward step or a reverse step, followed by zero or more predicates.
In the abbreviated syntax for a step, the axis can be omitted and other shorthand notations can be used as described in 3.2.4 Abbreviated Syntax .
The unabbreviated syntax for an axis step consists of the axis name and node test separated by a double colon. The result of the step consists of the nodes reachable from the
context node via the specified axis that have the node kind, name, and/or type annotation specified by the node test. For
example, the step child::para
selects the para
element children of the context node: child
is the name of the axis, and para
is
the name of the element nodes to be selected on this axis. The available axes are described in
3.2.1.1 Axes
. The available node tests are described in
3.2.1.2 Node Tests
. Examples of steps are provided in
3.2.3 Unabbreviated Syntax
and
3.2.4 Abbreviated Syntax
.
[30] |
ForwardAxis
|
::= |
("child" "::")
|
[33] |
ReverseAxis
|
::= |
("parent" "::")
|
XPath defines a full set of axes for traversing documents, but a host language may define a subset of these axes. The following axes are defined:
The child
axis contains the children of the context node, which are the nodes returned by the dm:children
accessor in [XQuery/XPath Data Model (XDM)].
Note:
Only document nodes and element nodes have children. If the context node is any other kind of node, or if the context node is an empty document or element node, then the child axis is an empty sequence. The children of a document node or element node may be element, processing instruction, comment, or text nodes. Attribute , namespace, and document nodes can never appear as children.
the descendant
axis is defined as the transitive closure of the child axis; it contains the descendants of the context node (the children, the children of
the children, and so on)
the parent
axis contains the sequence returned by the dm:parent
accessor in [XQuery/XPath Data Model (XDM)], which
returns the parent of the context node, or an empty sequence if the context node has no parent
Note:
An attribute node may have an element node as its parent, even though the attribute node is not a child of the element node.
the ancestor
axis is defined as the transitive closure of the parent axis; it contains the ancestors of the context node (the parent, the parent of the
parent, and so on)
Note:
The ancestor axis includes the root node of the tree in which the context node is found, unless the context node is the root node.
the following-sibling
axis contains the context node's following siblings, those children of the context node's parent that occur after the context node in
document order; if the context node is an attribute
or namespace
node, the following-sibling
axis is empty
the preceding-sibling
axis contains the context node's preceding siblings, those children of the context node's parent that occur before the context node in
document order; if the context node is an attribute
or namespace
node, the preceding-sibling
axis is empty
the following
axis contains all nodes that are descendants of the root of the tree in which the context node is found, are not descendants of the context
node, and occur after the context node in document order
the preceding
axis contains all nodes that are descendants of the root of the tree in which the context node is found, are not ancestors of the context node,
and occur before the context node in document order
the attribute
axis contains the attributes of the context node, which are the nodes returned by the dm:attributes
accessor in [XQuery/XPath Data Model (XDM)]; the axis will be empty unless the context node is an element
the self
axis contains just the context node itself
the descendant-or-self
axis contains the context node and the descendants of the context node
the ancestor-or-self
axis contains the context node and the ancestors of the context node; thus, the ancestor-or-self axis will always include the root
node
the namespace
axis contains the namespace nodes of the context node, which are the nodes returned by the dm:namespace-nodes
accessor in [XQuery/XPath Data Model (XDM)]; this axis is empty unless the context node is an element node. The namespace
axis is deprecated in
XPath 2.0. If XPath 1.0 compatibility mode is true
, the namespace
axis
must be supported. If XPath 1.0 compatibility mode is false
, then support for the
namespace
axis is implementation-defined. An implementation that does not support
the namespace
axis when XPath 1.0 compatibility mode is false
must
raise a static error [err:XPST0010] if it is used. Applications
needing information about the in-scope namespaces of an element should use the functions
fn:in-scope-prefixes
and fn:namespace-uri-for-prefix
defined in [XQuery 1.0 and XPath 2.0 Functions and
Operators].
Axes can be categorized as forward axes and reverse axes. An axis that only ever contains the context node or nodes that are after the context node in document order is a forward axis. An axis that only ever contains the context node or nodes that are before the context node in document order is a reverse axis.
The parent
, ancestor
, ancestor-or-self
, preceding
, and preceding-sibling
axes are reverse axes; all other axes
are forward axes. The ancestor
, descendant
, following
, preceding
and self
axes partition a document (ignoring
attribute
and namespace
nodes): they do not overlap and together they contain all the nodes in the document.
[Definition: Every axis has a principal node kind. If an axis can contain elements, then the principal node kind is element; otherwise, it is the kind of nodes that the axis can contain.] Thus:
For the attribute axis, the principal node kind is attribute.
For the namespace axis, the principal node kind is namespace.
For all other axes, the principal node kind is element.
[Definition: A node test is a condition that must be true for each node selected by a step.] The condition may be based on the kind of the node (element, attribute, text, document, comment, or processing instruction), the name of the node, or (in the case of element, attribute, and document nodes), the type annotation of the node.
[35] |
NodeTest
|
::= |
KindTest | NameTest
|
[36] |
NameTest
|
::= |
QName | Wildcard
|
[37] |
Wildcard
|
::= |
"*"
|
[Definition: A node test that consists only of a QName or a Wildcard is called a name test.] A name test
is true if and only if the kind of the node is the principal node kind for the step axis and the expanded QName of the node is equal (as defined by the eq
operator) to the expanded QName specified by the name test. For example, child::para
selects the para
element children of the context
node; if the context node has no para
children, it selects an empty set of nodes. attribute::abc:href
selects the attribute of the context node with
the QName abc:href
; if the context node has no such attribute, it selects an empty set of nodes.
A QName in a name test is resolved into an expanded QName using the statically known namespaces in the expression context. It is a static error [err:XPST0081] if the QName has a prefix that does not correspond to any statically known namespace. An unprefixed QName, when used as a name test on an axis whose principal node kind is element, has the namespace URI of the default element/type namespace in the expression context; otherwise, it has no namespace URI.
A name test is not satisfied by an element node whose name does not match the expanded QName of the name test, even if it is in a substitution group whose head is the named element.
A node test *
is true for any node of the principal node kind of the step axis. For example,
child::*
will select all element children of the context node, and attribute::*
will select all attributes of the context node.
A node test can have the form NCName:*
. In this case, the prefix is expanded in the same way as with a QName, using the statically known namespaces in the static context. If the prefix is not found
in the statically known namespaces, a static error is raised [err:XPST0081].
The node test is true for any node of the principal node kind of the step axis whose expanded QName has the namespace URI to which the prefix is bound, regardless of the local part of the name.
A node test can also have the form *:NCName
. In this case, the node test is true for any node of the principal node kind of the step axis whose local name matches the given NCName, regardless of its namespace or lack of a namespace.
[Definition: An alternative form of a node test called a kind test can select nodes based on their kind, name, and type annotation.] The syntax and semantics of a kind test are described in 2.5.3 SequenceType Syntax and 2.5.4 SequenceType Matching . When a kind test is used in a node test, only those nodes on the designated axis that match the kind test are selected. Shown below are several examples of kind tests that might be used in path expressions:
node()
matches any node.
text()
matches any text node.
comment()
matches any comment node.
element()
matches any element node.
schema-element(person)
matches any element node whose name is person
(or is in the substitution group headed by person
), and whose type annotation is the same as (or is derived from) the declared type of the person
element in the in-scope element declarations.
element(person)
matches any element node whose name is person
, regardless of its type annotation.
element(person, surgeon)
matches any non-nilled element node whose name is person
, and whose type annotation is surgeon
or is
derived from surgeon
.
element(*, surgeon)
matches any non-nilled element node whose type annotation is surgeon
(or is derived from surgeon
), regardless
of its name.
attribute()
matches any attribute node.
attribute(price)
matches any attribute whose name is price
, regardless of its type annotation.
attribute(*, xs:decimal)
matches any attribute whose type annotation is xs:decimal
(or is derived from xs:decimal
), regardless of
its name.
document-node()
matches any document node.
document-node(element(book))
matches any document node whose content consists of a single element node that satisfies the kind test
element(book)
, interleaved with zero or more comments and processing instructions.
[40] |
Predicate
|
::= |
"[" Expr "]"
|
[Definition: A predicate consists of an expression, called a predicate expression, enclosed in square brackets. A predicate serves to filter a sequence, retaining some items and discarding others.] In the case of multiple adjacent predicates, the predicates are applied from left to right, and the result of applying each predicate serves as the input sequence for the following predicate.
For each item in the input sequence, the predicate expression is evaluated using an inner focus, defined as follows: The context item is the item currently being tested against the predicate. The context size is the number of items in the input sequence. The context position is the position of the context item within the input sequence. For the purpose of evaluating the context position within a predicate, the input sequence is considered to be sorted as follows: into document order if the predicate is in a forward-axis step, into reverse document order if the predicate is in a reverse-axis step, or in its original order if the predicate is not in a step.
For each item in the input sequence, the result of the predicate expression is coerced to an xs:boolean
value, called the predicate truth value, as described
below. Those items for which the predicate truth value is true
are retained, and those for which the predicate truth value is false
are discarded.
The predicate truth value is derived by applying the following rules, in order:
If the value of the predicate expression is a singleton atomic value of a numeric
type or derived from a numeric type, the predicate truth value is true
if the value of the predicate expression is
equal (by the eq
operator) to the context position, and is false
otherwise. [Definition: A predicate whose predicate expression returns a numeric type is called a numeric predicate.]
Otherwise, the predicate truth value is the effective boolean value of the predicate expression.
Here are some examples of axis steps that contain predicates:
This example selects the second chapter
element that is a child of the context node:
child::chapter[2]
This example selects all the descendants of the context node that are elements named "toy"
and whose color
attribute has the value
"red"
:
descendant::toy[attribute::color = "red"]
This example selects all the employee
children of the context node that have both a secretary
child element and an assistant
child
element:
child::employee[secretary][assistant]
Note:
When using predicates with a sequence of nodes selected using a reverse axis, it is important to remember that the the
context positions for such a sequence are assigned in reverse document order. For example,
preceding::foo[1]
returns the first qualifying foo
element in reverse document
order, because the predicate is part of an axis step using a reverse axis. By contrast, (preceding::foo)[1]
returns the first qualifying foo
element in document order, because the parentheses cause
(preceding::foo)
to be parsed as a primary expression in which context positions are assigned in
document order. Similarly, ancestor::*[1]
returns the nearest ancestor element, because the ancestor
axis is a reverse axis, whereas
(ancestor::*)[1]
returns the root element (first ancestor in document order).
The fact that a reverse-axis step assigns context positions in reverse document order for the purpose of evaluating predicates does not alter the fact that the final result of the step is always in document order.
This section provides a number of examples of path expressions in which the axis is explicitly specified in each step. The syntax used in these examples is called the unabbreviated syntax. In many common cases, it is possible to write path expressions more concisely using an abbreviated syntax, as explained in 3.2.4 Abbreviated Syntax .
child::para
selects the para
element children of the context node
child::*
selects all element children of the context node
child::text()
selects all text node children of the context node
child::node()
selects all the children of the context node. Note that no attribute nodes are returned, because attributes are not children.
attribute::name
selects the name
attribute of the context node
attribute::*
selects all the attributes of the context node
parent::node()
selects the parent of the context node. If the context node is an attribute node, this expression returns the element node (if any) to which the
attribute node is attached.
descendant::para
selects the para
element descendants of the context node
ancestor::div
selects all div
ancestors of the context node
ancestor-or-self::div
selects the div
ancestors of the context node and, if the context node is a div
element, the context node as
well
descendant-or-self::para
selects the para
element descendants of the context node and, if the context node is a para
element, the
context node as well
self::para
selects the context node if it is a para
element, and otherwise returns an empty sequence
child::chapter/descendant::para
selects the para
element descendants of the chapter
element children of the context node
child::*/child::para
selects all para
grandchildren of the context node
/
selects the root of the tree that contains the context node, but raises a dynamic error if this root is not a document node
/descendant::para
selects all the para
elements in the same document as the context node
/descendant::list/child::member
selects all the member
elements that have a list
parent and that are in the same document as the
context node
child::para[fn:position() = 1]
selects the first para
child of the context node
child::para[fn:position() = fn:last()]
selects the last para
child of the context node
child::para[fn:position() = fn:last()-1]
selects the last but one para
child of the context node
child::para[fn:position() > 1]
selects all the para
children of the context node other than the first para
child of the context
node
following-sibling::chapter[fn:position() = 1]
selects the next chapter
sibling of the context node
preceding-sibling::chapter[fn:position() = 1]
selects the previous chapter
sibling of the context node
/descendant::figure[fn:position() = 42]
selects the forty-second figure
element in the document containing the context node
/child::book/child::chapter[fn:position() = 5]/child::section[fn:position() = 2]
selects the second section
of the fifth chapter
of
the book
whose parent is the document node that contains the context node
child::para[attribute::type eq "warning"]
selects all para
children of the context node that have a type
attribute with value
warning
child::para[attribute::type eq 'warning'][fn:position() = 5]
selects the fifth para
child of the context node that has a type
attribute
with value warning
child::para[fn:position() = 5][attribute::type eq "warning"]
selects the fifth para
child of the context node if that child has a type
attribute with value warning
child::chapter[child::title = 'Introduction']
selects the chapter
children of the context node that have one or more title
children
whose typed value is equal to the string Introduction
child::chapter[child::title]
selects the chapter
children of the context node that have one or more title
children
child::*[self::chapter or self::appendix]
selects the chapter
and appendix
children of the context node
child::*[self::chapter or self::appendix][fn:position() = fn:last()]
selects the last chapter
or appendix
child of the context
node
[31] |
AbbrevForwardStep
|
::= |
"@"? NodeTest
|
[34] |
AbbrevReverseStep
|
::= |
".."
|
The abbreviated syntax permits the following abbreviations:
The attribute axis attribute::
can be abbreviated by @
. For example, a path expression para[@type="warning"]
is short for
child::para[attribute::type="warning"]
and so selects para
children with a type
attribute with value equal to
warning
.
If the axis name is omitted from an axis step, the default axis is child
unless the axis step contains an AttributeTest or SchemaAttributeTest; in that case, the default axis is
attribute
. For example, the path expression section/para
is an abbreviation for child::section/child::para
, and the path expression
section/@id
is an abbreviation for child::section/attribute::id
. Similarly, section/attribute(id)
is an abbreviation for
child::section/attribute::attribute(id)
. Note that the latter expression contains both an axis specification and a node test.
Each non-initial occurrence of //
is effectively replaced by /descendant-or-self::node()/
during processing of a path expression. For example,
div1//para
is short for child::div1/descendant-or-self::node()/child::para
and so will select all para
descendants of
div1
children.
Note:
The path expression //para[1]
does not mean the same as the path expression /descendant::para[1]
. The latter selects the first
descendant para
element; the former selects all descendant para
elements that are the first para
children of their respective
parents.
A step consisting of ..
is short for parent::node()
. For example, ../title
is short for parent::node()/child::title
and
so will select the title
children of the parent of the context node.
Note:
The expression .
, known as a context item expression, is a primary expression, and is
described in
3.1.4 Context Item Expression
.
Here are some examples of path expressions that use the abbreviated syntax:
para
selects the para
element children of the context node
*
selects all element children of the context node
text()
selects all text node children of the context node
@name
selects the name
attribute of the context node
@*
selects all the attributes of the context node
para[1]
selects the first para
child of the context node
para[fn:last()]
selects the last para
child of the context node
*/para
selects all para
grandchildren of the context node
/book/chapter[5]/section[2]
selects the second section
of the fifth chapter
of the book
whose parent is the document node
that contains the context node
chapter//para
selects the para
element descendants of the chapter
element children of the context node
//para
selects all the para
descendants of the root document node and thus selects all para
elements in the same document as the
context node
//@version
selects all the version
attribute nodes that are in the same document as the context node
//list/member
selects all the member
elements in the same document as the context node that have a list
parent
.//para
selects the para
element descendants of the context node
..
selects the parent of the context node
../@lang
selects the lang
attribute of the parent of the context node
para[@type="warning"]
selects all para
children of the context node that have a type
attribute with value warning
para[@type="warning"][5]
selects the fifth para
child of the context node that has a type
attribute with value
warning
para[5][@type="warning"]
selects the fifth para
child of the context node if that child has a type
attribute with value
warning
chapter[title="Introduction"]
selects the chapter
children of the context node that have one or more title
children whose typed value is equal to the string Introduction
chapter[title]
selects the chapter
children of the context node that have one or more title
children
employee[@secretary and @assistant]
selects all the employee
children of the context node that have both a secretary
attribute and an
assistant
attribute
book/(chapter|appendix)/section
selects every section
element that has a parent that is either a chapter
or an appendix
element, that in turn is a child of a book
element that is a child of the context node.
If E
is any expression that returns a sequence of nodes, then the expression E/.
returns the same nodes in document order, with duplicates eliminated based on node identity.
XPath supports operators to construct, filter, and combine sequences of items. Sequences are never
nested—for example, combining the values 1
, (2, 3)
, and ( )
into a single sequence results in the sequence (1, 2, 3)
.
[2] |
Expr
|
::= |
ExprSingle ("," ExprSingle)*
|
[11] |
RangeExpr
|
::= |
AdditiveExpr ( "to" AdditiveExpr )?
|
[Definition: One way to construct a sequence is by using the comma operator, which evaluates each of its operands and concatenates the resulting sequences, in order, into a single result sequence.] Empty parentheses can be used to denote an empty sequence.
A sequence may contain duplicate atomic values or nodes, but a sequence is never an item in another sequence. When a new sequence is created by concatenating two or more input sequences, the new sequence contains all the items of the input sequences and its length is the sum of the lengths of the input sequences.
Note:
In places where the grammar calls for ExprSingle, such as the arguments of a function call, any expression that contains a top-level comma operator must be enclosed in parentheses.
Here are some examples of expressions that construct sequences:
The result of this expression is a sequence of five integers:
(10, 1, 2, 3, 4)
This expression combines four sequences of length one, two, zero, and two, respectively, into a single sequence of length five. The result of this expression is the sequence
10, 1, 2, 3, 4
.
(10, (1, 2), (), (3, 4))
The result of this expression is a sequence containing all salary
children of the context node followed by all bonus
children.
(salary, bonus)
Assuming that $price
is bound to the value 10.50
, the result of this expression is the sequence 10.50, 10.50
.
($price, $price)
A range expression can be used to construct a sequence of consecutive integers. Each of the operands of the to
operator is converted as though it was an
argument of a function with the expected parameter type xs:integer?
. If either operand is an empty sequence, or if the integer derived from the first operand is
greater than the integer derived from the second operand, the result of the range expression is an empty sequence. If the two operands convert to the same integer, the result of
the range expression is that integer. Otherwise, the result is a sequence containing the two integer operands and every integer between the two operands, in increasing order.
This example uses a range expression as one operand in constructing a sequence. It evaluates to the sequence 10, 1, 2, 3, 4
.
(10, 1 to 4)
This example constructs a sequence of length one containing the single integer 10
.
10 to 10
The result of this example is a sequence of length zero.
15 to 10
This example uses the fn:reverse
function to construct a sequence of six integers in decreasing order. It evaluates to the sequence 15, 14, 13, 12, 11,
10
.
fn:reverse(10 to 15)
[38] |
FilterExpr
|
::= |
PrimaryExpr
PredicateList
|
[39] |
PredicateList
|
::= |
Predicate*
|
[Definition: A filter expression consists simply of a primary expression followed by zero or more predicates. The result of the filter expression consists of the items returned by the primary expression, filtered by applying each predicate in turn, working from left to right.] If no predicates are specified, the result is simply the result of the primary expression. The ordering of the items returned by a filter expression is the same as their order in the result of the primary expression. Context positions are assigned to items based on their ordinal position in the result sequence. The first context position is 1.
Here are some examples of filter expressions:
Given a sequence of products in a variable, return only those products whose price is greater than 100.
$products[price gt 100]
List all the integers from 1 to 100 that are divisible by 5. (See
3.3.1 Constructing Sequences
for an explanation of the to
operator.)
(1 to 100)[. mod 5 eq 0]
The result of the following expression is the integer 25:
(21 to 29)[5]
The following example returns the fifth through ninth items in the sequence bound to variable $orders
.
$orders[fn:position() = (5 to 9)]
The following example illustrates the use of a filter expression as a step in a path expression. It returns the last chapter or appendix within the book bound to variable $book
:
$book/(chapter | appendix)[fn:last()]
The following example also illustrates the use of a filter expression as a step in a path expression. It returns the element node within the specified document whose ID value is tiger
:
fn:doc("zoo.xml")/fn:id('tiger')
[14] |
UnionExpr
|
::= |
IntersectExceptExpr ( ("union" | "|") IntersectExceptExpr )*
|
[15] |
IntersectExceptExpr
|
::= |
InstanceofExpr ( ("intersect" | "except") InstanceofExpr )*
|
XPath provides the following operators for combining sequences of nodes:
The union
and |
operators are equivalent. They take two node sequences as operands and return a sequence containing all the nodes that occur in
either of the operands.
The intersect
operator takes two node sequences as operands and returns a sequence containing all the nodes that occur in both operands.
The except
operator takes two node sequences as operands and returns a sequence containing all the nodes that occur in the first operand but not in the second
operand.
All these operators eliminate duplicate nodes from their result sequences based on node identity. The resulting sequence is returned in document order.
If an operand of union
, intersect
, or except
contains an item that is not a node, a type
error is raised [err:XPTY0004].
Here are some examples of expressions that combine sequences. Assume the existence of three element nodes that we will refer to by symbolic names A, B, and C. Assume that the
variables $seq1
, $seq2
and $seq3
are bound to the following sequences of these nodes:
$seq1
is bound to (A, B)
$seq2
is bound to (A, B)
$seq3
is bound to (B, C)
Then:
$seq1 union $seq2
evaluates to the sequence (A, B).
$seq2 union $seq3
evaluates to the sequence (A, B, C).
$seq1 intersect $seq2
evaluates to the sequence (A, B).
$seq2 intersect $seq3
evaluates to the sequence containing B only.
$seq1 except $seq2
evaluates to the empty sequence.
$seq2 except $seq3
evaluates to the sequence containing A only.
In addition to the sequence operators described here, [XQuery 1.0 and XPath 2.0 Functions and Operators] includes functions for indexed access to items or sub-sequences of a sequence, for indexed insertion or removal of items in a sequence, and for removing duplicate items from a sequence.
XPath provides arithmetic operators for addition, subtraction, multiplication, division, and modulus, in their usual binary and unary forms.
[12] |
AdditiveExpr
|
::= |
MultiplicativeExpr ( ("+" | "-") MultiplicativeExpr )*
|
[13] |
MultiplicativeExpr
|
::= |
UnionExpr ( ("*" | "div" | "idiv" | "mod") UnionExpr )*
|
[20] |
UnaryExpr
|
::= |
("-" | "+")* ValueExpr
|
[21] |
ValueExpr
|
::= |
PathExpr
|
A subtraction operator must be preceded by whitespace if it could otherwise be interpreted as part of the previous token. For example, a-b
will be interpreted as a name,
but a - b
and a -b
will be interpreted as arithmetic expressions. (See
A.2.4 Whitespace Rules
for further details on whitespace handling.)
The first step in evaluating an arithmetic expression is to evaluate its operands. The order in which the operands are evaluated is implementation-dependent.
If XPath 1.0 compatibility mode is true
, each operand is evaluated by applying
the following steps, in order:
Atomization is applied to the operand. The result of this operation is called the atomized operand.
If the atomized operand is an empty sequence, the result of the arithmetic expression is the xs:double
value NaN
, and the implementation need not
evaluate the other operand or apply the operator. However, an implementation may choose to evaluate the other operand in order to determine whether it raises an error.
If the atomized operand is a sequence of length greater than one, any items after the first item in the sequence are discarded.
If the atomized operand is now an instance of type xs:boolean
, xs:string
, xs:decimal
(including xs:integer
),
xs:float
, or xs:untypedAtomic
, then it is converted to the type xs:double
by applying the fn:number
function. (Note
that fn:number
returns the value NaN
if its operand cannot be converted to a number.)
If XPath 1.0 compatibility mode is false
, each
operand is evaluated by applying the following steps, in order:
Atomization is applied to the operand. The result of this operation is called the atomized operand.
If the atomized operand is an empty sequence, the result of the arithmetic expression is an empty sequence, and the implementation need not evaluate the other operand or apply the operator. However, an implementation may choose to evaluate the other operand in order to determine whether it raises an error.
If the atomized operand is a sequence of length greater than one, a type error is raised [err:XPTY0004].
If the atomized operand is of type xs:untypedAtomic
, it is cast to xs:double
. If the cast fails, a dynamic error is raised. [err:FORG0001]
After evaluation of the operands, if the types of the operands are a valid combination for the given arithmetic operator, the operator is applied to the operands, resulting in an atomic value or a dynamic error (for example, an error might result from dividing by zero.) The combinations of atomic types that are accepted by the various arithmetic operators, and their respective result types, are listed in B.2 Operator Mapping together with the operator functions that define the semantics of the operator for each type combination, including the dynamic errors that can be raised by the operator. The definitions of the operator functions are found in [XQuery 1.0 and XPath 2.0 Functions and Operators].
If the types of the operands, after evaluation, are not a valid combination for the given operator, according to the rules in B.2 Operator Mapping , a type error is raised [err:XPTY0004].
XPath supports two division operators named div
and idiv
. Each of these operators accepts two operands of any numeric type. As described in [XQuery 1.0 and XPath 2.0 Functions and Operators], $arg1 idiv $arg2
is equivalent to
($arg1 div $arg2) cast as xs:integer?
except for error cases.
Here are some examples of arithmetic expressions:
The first expression below returns the xs:decimal
value -1.5
, and the second expression returns the xs:integer
value -1
:
-3 div 2 -3 idiv 2
Subtraction of two date values results in a value of type xs:dayTimeDuration
:
$emp/hiredate - $emp/birthdate
This example illustrates the difference between a subtraction operator and a hyphen:
$unit-price - $unit-discount
Unary operators have higher precedence than binary operators, subject of course to the use of parentheses. Therefore, the following two examples have different meanings:
-$bellcost + $whistlecost -($bellcost + $whistlecost)
Note:
Multiple consecutive unary arithmetic operators are permitted by XPath for compatibility with [XPath 1.0].
Comparison expressions allow two values to be compared. XPath provides three kinds of comparison expressions, called value comparisons, general comparisons, and node comparisons.
[10] |
ComparisonExpr
|
::= |
RangeExpr ( (ValueComp
|
[23] |
ValueComp
|
::= |
"eq" | "ne" | "lt" | "le" | "gt" | "ge"
|
[22] |
GeneralComp
|
::= |
"=" | "!=" | "<" | "<=" | ">" | ">="
|
[24] |
NodeComp
|
::= |
"is" | "<<" | ">>"
|
Note:
When an XPath expression is written within an XML document, the XML escaping rules for special characters must be followed; thus "<
" must be
written as "<
".
The value comparison operators are eq
, ne
, lt
, le
, gt
, and ge
. Value comparisons are used for
comparing single values.
The first step in evaluating a value comparison is to evaluate its operands. The order in which the operands are evaluated is implementation-dependent. Each operand is evaluated by applying the following steps, in order:
Atomization is applied to the operand. The result of this operation is called the atomized operand.
If the atomized operand is an empty sequence, the result of the value comparison is an empty sequence, and the implementation need not evaluate the other operand or apply the operator. However, an implementation may choose to evaluate the other operand in order to determine whether it raises an error.
If the atomized operand is a sequence of length greater than one, a type error is raised [err:XPTY0004].
If the atomized operand is of type xs:untypedAtomic
, it is cast to xs:string
.
Note:
The purpose of this rule is to make value comparisons transitive. Users should be aware that the general comparison operators have a different rule for casting of
xs:untypedAtomic
operands. Users should also be aware that transitivity of value comparisons may be compromised by loss of precision during type
conversion (for example, two xs:integer
values that differ slightly may both be considered equal to the same xs:float
value because
xs:float
has less precision than xs:integer
).
Next, if possible, the two operands are converted to their least common type by a combination of type promotion and subtype substitution. For example, if the operands are of type hatsize
(derived from
xs:integer
) and shoesize
(derived from xs:float
), their least common type is xs:float
.
Finally, if the types of the operands are a valid combination for the given operator, the operator is applied to the operands. The combinations of atomic types that are accepted by the various value comparison operators, and their respective result types, are listed in B.2 Operator Mapping together with the operator functions that define the semantics of the operator for each type combination. The definitions of the operator functions are found in [XQuery 1.0 and XPath 2.0 Functions and Operators].
Informally, if both atomized operands consist of exactly one atomic value, then the result of the comparison is true
if the value of the first operand is (equal, not
equal, less than, less than or equal, greater than, greater than or equal) to the value of the second operand; otherwise the result of the comparison is false
.
If the types of the operands, after evaluation, are not a valid combination for the given operator, according to the rules in B.2 Operator Mapping , a type error is raised [err:XPTY0004].
Here are some examples of value comparisons:
The following comparison atomizes the node(s) that are returned by the expression $book/author
. The comparison is true only if the result of atomization is the
value "Kennedy" as an instance of xs:string
or xs:untypedAtomic
. If the result of atomization is an empty sequence, the result of the comparison is
an empty sequence. If the result of atomization is a sequence containing more than one value, a type error is raised [err:XPTY0004].
$book1/author eq "Kennedy"
The following path expression contains a predicate that selects products whose weight is greater than 100. For any
product that does not have a weight
subelement, the value of the predicate is the empty sequence, and the product is not selected. This example assumes that
weight
is a validated element with a numeric type.
//product[weight gt 100]
The following comparison is true if my:hatsize
and my:shoesize
are both user-defined types that are derived by restriction from a primitive numeric type:
my:hatsize(5) eq my:shoesize(5)
The following comparison is true. The eq
operator compares two QNames by performing codepoint-comparisons of their namespace URIs and their local names,
ignoring their namespace prefixes.
fn:QName("http://example.com/ns1", "this:color") eq fn:QName("http://example.com/ns1", "that:color")
The general comparison operators are =
, !=
, <
, <=
, >
, and >=
. General
comparisons are existentially quantified comparisons that may be applied to operand sequences of any length. The result of a general comparison that does not raise an error is
always true
or false
.
If XPath 1.0 compatibility mode is true
, a general comparison is evaluated
by applying the following rules, in order:
If either operand is a single atomic value that is an instance of xs:boolean
, then the other operand is converted to xs:boolean
by taking its effective boolean value.
Atomization is applied to each operand. After atomization, each operand is a sequence of atomic values.
If the comparison operator is <
, <=
, >
, or >=
, then each item in both of the operand
sequences is converted to the type xs:double
by applying the fn:number
function. (Note that fn:number
returns the value
NaN
if its operand cannot be converted to a number.)
The result of the comparison is true
if and only if there is a pair of atomic values, one in the first operand sequence and the other in the second operand
sequence, that have the required magnitude relationship. Otherwise the result of the comparison is false
. The magnitude relationship between
two atomic values is determined by applying the following rules. If a cast
operation called for by these rules is not successful, a dynamic error is raised.
[err:FORG0001]
If at least one of the two atomic values is an instance of a numeric type, then both atomic values are converted to the
type xs:double
by applying the fn:number
function.
If at least one of the two atomic values is an instance of xs:string
, or if both atomic values are instances of xs:untypedAtomic
, then
both atomic values are cast to the type xs:string
.
If one of the atomic values is an instance of xs:untypedAtomic
and the other is not an instance of xs:string
,
xs:untypedAtomic
, or any numeric type, then the xs:untypedAtomic
value is cast to the dynamic type of the other value.
After performing the conversions described above, the atomic values are compared using one of the value comparison operators eq
, ne
,
lt
, le
, gt
, or ge
, depending on whether the general comparison operator was =
, !=
,
<
, <=
, >
, or >=
. The values have the required magnitude relationship if
and only if the result of this value comparison is true
.
If XPath 1.0 compatibility mode is false
, a
general comparison is evaluated by applying the following rules, in order:
Atomization is applied to each operand. After atomization, each operand is a sequence of atomic values.
The result of the comparison is true
if and only if there is a pair of atomic values, one in the first operand sequence and the other in the second operand
sequence, that have the required magnitude relationship. Otherwise the result of the comparison is false
. The magnitude relationship between two
atomic values is determined by applying the following rules. If a cast
operation called for by these rules is not successful, a dynamic error is raised.
[err:FORG0001]
If one of the atomic values is an instance of xs:untypedAtomic
and the other is an instance of a numeric type,
then the xs:untypedAtomic
value is cast to the type xs:double
.
If one of the atomic values is an instance of xs:untypedAtomic
and the other is an instance of xs:untypedAtomic
or xs:string
,
then the xs:untypedAtomic
value (or values) is (are) cast to the type xs:string
.
If one of the atomic values is an instance of xs:untypedAtomic
and the other is not an instance of xs:string
, xs:untypedAtomic
,
or any numeric type, then the xs:untypedAtomic
value is cast to the dynamic type of the other value.
After performing the conversions described above, the atomic values are compared using one of the value comparison operators eq
, ne
,
lt
, le
, gt
, or ge
, depending on whether the general comparison operator was =
, !=
,
<
, <=
, >
, or >=
. The values have the required magnitude relationship if and
only if the result of this value comparison is true
.
When evaluating a general comparison in which either operand is a sequence of items, an implementation may return true
as soon as it finds an item in the first
operand and an item in the second operand that have the required magnitude relationship. Similarly, a general comparison may raise a dynamic error as soon as it encounters an error in evaluating either operand, or in comparing a pair of items from the two operands. As a result of
these rules, the result of a general comparison is not deterministic in the presence of errors.
Here are some examples of general comparisons:
The following comparison is true if the typed value of any author
subelement of $book1
is
"Kennedy" as an instance of xs:string
or xs:untypedAtomic
:
$book1/author = "Kennedy"
The following example contains three general comparisons. The value of the first two comparisons is true
, and the value of the third comparison is
false
. This example illustrates the fact that general comparisons are not transitive.
(1, 2) = (2, 3) (2, 3) = (3, 4) (1, 2) = (3, 4)
The following example contains two general comparisons, both of which are true
. This example illustrates the fact that the =
and !=
operators are not inverses of each other.
(1, 2) = (2, 3) (1, 2) != (2, 3)
Suppose that $a
, $b
, and $c
are bound to element nodes with type annotation xs:untypedAtomic
, with string values "1
", "2
", and "2.0
" respectively. Then ($a, $b) = ($c,
3.0)
returns false
, because $b
and $c
are compared as strings. However, ($a, $b) = ($c, 2.0)
returns
true
, because $b
and 2.0
are compared as numbers.
Node comparisons are used to compare two nodes, by their identity or by their document order. The result of a node comparison is defined by the following rules:
The operands of a node comparison are evaluated in implementation-dependent order.
If either operand is an empty sequence, the result of the comparison is an empty sequence, and the implementation need not evaluate the other operand or apply the operator. However, an implementation may choose to evaluate the other operand in order to determine whether it raises an error.
Each operand must be either a single node or an empty sequence; otherwise a type error is raised [err:XPTY0004].
A comparison with the is
operator is true
if the two operand nodes have the same identity, and are thus the same node; otherwise it is
false
. See [XQuery/XPath Data Model (XDM)] for a definition of node identity.
A comparison with the <<
operator returns true
if the left operand node precedes the right operand node in document order; otherwise it returns false
.
A comparison with the >>
operator returns true
if the left operand node follows the right operand node in document order; otherwise it returns false
.
Here are some examples of node comparisons:
The following comparison is true only if the left and right sides each evaluate to exactly the same single node:
/books/book[isbn="1558604820"] is /books/book[call="QA76.9 C3845"]
The following comparison is true only if the node identified by the left side occurs before the node identified by the right side in document order:
/transactions/purchase[parcel="28-451"] << /transactions/sale[parcel="33-870"]
A logical expression is either an and-expression or an or-expression. If a logical expression does not raise an error, its value is always one of the boolean
values true
or false
.
[8] |
OrExpr
|
::= |
AndExpr ( "or" AndExpr )*
|
[9] |
AndExpr
|
::= |
ComparisonExpr ( "and" ComparisonExpr )*
|
The first step in evaluating a logical expression is to find the effective boolean value of each of its operands (see 2.4.3 Effective Boolean Value ).
The value of an and-expression is determined by the effective boolean values (EBV's) of its operands, as shown in the following table:
AND: | EBV2 = true |
EBV2 = false |
error in EBV2 |
EBV1 = true |
true
|
false
|
error |
EBV1 = false |
false
|
false
|
if XPath 1.0 compatibility mode is true , then
false ; otherwise either false or error.
|
error in EBV1 | error |
if XPath 1.0 compatibility mode is true , then error; otherwise
either false or error.
|
error |
The value of an or-expression is determined by the effective boolean values (EBV's) of its operands, as shown in the following table:
OR: | EBV2 = true |
EBV2 = false |
error in EBV2 |
EBV1 = true |
true
|
true
|
if XPath 1.0 compatibility mode is true , then true ;
otherwise either true or error.
|
EBV1 = false |
true
|
false
|
error |
error in EBV1 |
if XPath 1.0 compatibility mode is true , then error; otherwise
either true or error.
|
error | error |
If XPath 1.0 compatibility mode is true
, the order in which the operands of a
logical expression are evaluated is effectively prescribed. Specifically, it is defined that when there is no need to evaluate the second operand in order to determine the result,
then no error can occur as a result of evaluating the second operand.
If XPath 1.0 compatibility mode is false
, the order in which the operands
of a logical expression are evaluated is implementation-dependent. In this case,
an or-expression can return true
if the first expression evaluated is true, and it can raise an error if evaluation of the first expression raises an error.
Similarly, an and-expression can return false
if the first expression evaluated is false, and it can raise an error if evaluation of the first expression raises an
error. As a result of these rules, a logical expression is not deterministic in the presence of errors, as illustrated in the examples below.
Here are some examples of logical expressions:
The following expressions return true
:
1 eq 1 and 2 eq 2
1 eq 1 or 2 eq 3
The following expression may return either false
or raise a dynamic error
(in XPath 1.0 compatibility mode, the result must be false
)
:
1 eq 2 and 3 idiv 0 = 1
The following expression may return either true
or raise a dynamic error
(in XPath 1.0 compatibility mode, the result must be true
)
:
1 eq 1 or 3 idiv 0 = 1
The following expression must raise a dynamic error:
1 eq 1 and 3 idiv 0 = 1
In addition to and- and or-expressions, XPath provides a function named fn:not
that takes a general sequence as parameter and returns a boolean value. The
fn:not
function is defined in [XQuery 1.0 and XPath 2.0 Functions and Operators]. The fn:not
function reduces its
parameter to an effective boolean value. It then returns true
if the effective boolean value of its parameter is
false
, and false
if the effective boolean value of its parameter is true
. If an error is encountered in finding the effective boolean value
of its operand, fn:not
raises the same error.
XPath provides an iteration facility called a for expression.
[4] |
ForExpr
|
::= |
SimpleForClause "return" ExprSingle
|
[5] |
SimpleForClause
|
::= |
"for" "$" VarName "in" ExprSingle ("," "$" VarName "in" ExprSingle)*
|
A for
expression is evaluated as follows:
If the for
expression uses multiple variables, it is first expanded to a set of nested for
expressions, each of which uses only one variable. For
example, the expression for $x in X, $y in Y return $x + $y
is expanded to for $x in X return for $y in Y return $x + $y
.
In a single-variable for
expression, the variable is called the range variable, the value of the expression that follows the in
keyword is
called the binding sequence, and the expression that follows the return
keyword is called the return expression. The result of the
for
expression is obtained by evaluating the return
expression once for each item in the binding sequence, with the range variable bound to that
item. The resulting sequences are concatenated (as if by the comma operator) in the order of the items in the binding
sequence from which they were derived.
The following example illustrates the use of a for
expression in restructuring an input document. The example is based on the following input:
<bib> <book> <title>TCP/IP Illustrated</title> <author>Stevens</author> <publisher>Addison-Wesley</publisher> </book> <book> <title>Advanced Programming in the Unix Environment</title> <author>Stevens</author> <publisher>Addison-Wesley</publisher> </book> <book> <title>Data on the Web</title> <author>Abiteboul</author> <author>Buneman</author> <author>Suciu</author> </book> </bib>
The following example transforms the input document into a list in which each author's name appears only once, followed by a list of titles of books written by that author. This
example assumes that the context item is the bib
element in the input document.
for $a in fn:distinct-values(book/author) return (book/author[. = $a][1], book[author = $a]/title)
The result of the above expression consists of the following sequence of elements. The titles of books written by a given author are listed after the name of the author. The
ordering of author
elements in the result is implementation-dependent due to the semantics
of the fn:distinct-values
function.
<author>Stevens</author> <title>TCP/IP Illustrated</title> <title>Advanced Programming in the Unix environment</title> <author>Abiteboul</author> <title>Data on the Web</title> <author>Buneman</author> <title>Data on the Web</title> <author>Suciu</author> <title>Data on the Web</title>
The following example illustrates a for
expression containing more than one variable:
for $i in (10, 20), $j in (1, 2) return ($i + $j)
The result of the above expression, expressed as a sequence of numbers, is as follows: 11, 12, 21, 22
The scope of a variable bound in a for
expression comprises all subexpressions of the for
expression that appear after the variable binding. The scope
does not include the expression to which the variable is bound. The following example illustrates how a variable binding may reference another variable bound earlier in the same
for
expression:
for $x in $z, $y in f($x) return g($x, $y)
Note:
The focus for evaluation of the return
clause of a for
expression is the same as the focus for evaluation of the for
expression itself.
The following example, which attempts to find the total value of a set of order-items, is therefore incorrect:
fn:sum(for $i in order-item return @price * @qty)
Instead, the expression must be written to use the variable bound in the for
clause:
fn:sum(for $i in order-item return $i/@price * $i/@qty)
XPath supports a conditional expression based on the keywords if
, then
, and else
.
[7] |
IfExpr
|
::= |
"if" "(" Expr ")" "then" ExprSingle "else" ExprSingle
|
The expression following the if
keyword is called the test expression, and the expressions following the then
and else
keywords are
called the then-expression and else-expression, respectively.
The first step in processing a conditional expression is to find the effective boolean value of the test expression, as defined in 2.4.3 Effective Boolean Value .
The value of a conditional expression is defined as follows: If the effective boolean value of the test expression is true
, the value of the then-expression is returned.
If the effective boolean value of the test expression is false
, the value of the else-expression is returned.
Conditional expressions have a special rule for propagating dynamic errors. If the effective value of the test expression is
true
, the conditional expression ignores (does not raise) any dynamic errors encountered in the else-expression. In this case, since the else-expression can have no
observable effect, it need not be evaluated. Similarly, if the effective value of the test expression is false
, the conditional expression ignores any dynamic errors encountered in the then-expression, and the then-expression need not be evaluated.
Here are some examples of conditional expressions:
In this example, the test expression is a comparison expression:
if ($widget1/unit-cost < $widget2/unit-cost) then $widget1 else $widget2
In this example, the test expression tests for the existence of an attribute named discounted
, independently of its value:
if ($part/@discounted) then $part/wholesale else $part/retail
Quantified expressions support existential and universal quantification. The value of a quantified expression is always true
or false
.
[6] |
QuantifiedExpr
|
::= |
("some" | "every") "$" VarName "in" ExprSingle ("," "$" VarName
"in" ExprSingle)* "satisfies" ExprSingle
|
A quantified expression begins with a quantifier, which is the keyword some
or every
, followed by one or more in-clauses that are used to bind
variables, followed by the keyword satisfies
and a test expression. Each in-clause associates a variable with an expression that returns a sequence of items, called the
binding sequence for that variable. The in-clauses generate tuples of variable bindings, including a tuple for each combination of items in the binding sequences of the
respective variables. Conceptually, the test expression is evaluated for each tuple of variable bindings. Results depend on the effective boolean value of the test expressions, as defined in
2.4.3 Effective Boolean Value
. The value of the quantified expression is defined by the following rules:
If the quantifier is some
, the quantified expression is true
if at least one evaluation of the test expression has the effective boolean value
true
; otherwise the quantified expression is false
. This rule implies that, if the in-clauses generate zero binding tuples, the value of the
quantified expression is false
.
If the quantifier is every
, the quantified expression is true
if every evaluation of the test expression has the effective boolean value
true
; otherwise the quantified expression is false
. This rule implies that, if the in-clauses generate zero binding tuples, the value of the
quantified expression is true
.
The scope of a variable bound in a quantified expression comprises all subexpressions of the quantified expression that appear after the variable binding. The scope does not include the expression to which the variable is bound.
The order in which test expressions are evaluated for the various binding tuples is implementation-dependent. If the quantifier is some
, an implementation may return true
as soon as it finds one binding tuple for which the test
expression has an effective boolean value of true
, and it may raise a dynamic error as soon as it finds one binding tuple for which the test expression raises an error. Similarly, if the quantifier is every
, an
implementation may return false
as soon as it finds one binding tuple for which the test expression has an effective
boolean value of false
, and it may raise a dynamic error as soon as it finds one binding tuple for which the
test expression raises an error. As a result of these rules, the value of a quantified expression is not deterministic in the presence of errors, as illustrated in the examples
below.
Here are some examples of quantified expressions:
This expression is true
if every part
element has a discounted
attribute (regardless of the values of these attributes):
every $part in /parts/part satisfies $part/@discounted
This expression is true
if at least one employee
element satisfies the given comparison expression:
some $emp in /emps/employee satisfies ($emp/bonus > 0.25 * $emp/salary)
In the following examples, each quantified expression evaluates its test expression over nine tuples of variable bindings, formed from the Cartesian product of the sequences
(1, 2, 3)
and (2, 3, 4)
. The expression beginning with some
evaluates to true
, and the expression beginning with
every
evaluates to false
.
some $x in (1, 2, 3), $y in (2, 3, 4) satisfies $x + $y = 4
every $x in (1, 2, 3), $y in (2, 3, 4) satisfies $x + $y = 4
This quantified expression may either return true
or raise a type error, since its test expression returns
true
for one variable binding and raises a type error for another:
some $x in (1, 2, "cat") satisfies $x * 2 = 4
This quantified expression may either return false
or raise a type error, since its test expression returns
false
for one variable binding and raises a type error for another:
every $x in (1, 2, "cat") satisfies $x * 2 = 4
sequence types are used in instance of
, cast
, castable
, and treat
expressions.
[16] |
InstanceofExpr
|
::= |
TreatExpr ( "instance" "of" SequenceType )?
|
The boolean operator instance of
returns true
if the value of its first operand matches the SequenceType in its
second operand, according to the rules for SequenceType matching; otherwise it returns false
.
For example:
5 instance of xs:integer
This example returns true
because the given value is an instance of the given type.
5 instance of xs:decimal
This example returns true
because the given value is an integer literal, and xs:integer
is derived by restriction from xs:decimal
.
(5, 6) instance of xs:integer+
This example returns true
because the given sequence contains two integers, and is a valid instance of the specified type.
. instance of element()
This example returns true
if the context item is an element node or false
if the context item is defined but is not an element node. If the context
item is undefined, a dynamic error is raised [err:XPDY0002].
[19] |
CastExpr
|
::= |
UnaryExpr ( "cast" "as" SingleType )?
|
[49] |
SingleType
|
::= |
AtomicType "?"?
|
Occasionally it is necessary to convert a value to a specific datatype. For this purpose, XPath provides a cast
expression that creates a new value of a specific type
based on an existing value. A cast
expression takes two operands: an input expression and a target type. The type of the input expression is called the
input type. The target type must be an atomic type that is in the in-scope schema types [err:XPST0051]. In addition, the target type cannot be xs:NOTATION
or xs:anyAtomicType
[err:XPST0080]. The optional occurrence indicator "?
" denotes that an empty sequence is permitted. If the target type has no namespace
prefix, it is considered to be in the default element/type namespace. The semantics of the
cast
expression are as follows:
Atomization is performed on the input expression.
If the result of atomization is a sequence of more than one atomic value, a type error is raised [err:XPTY0004].
If the result of atomization is an empty sequence:
If ?
is specified after the target type, the result of the cast
expression is an empty sequence.
If ?
is not specified after the target type, a type error is raised [err:XPTY0004].
If the result of atomization is a single atomic value, the result of the cast expression depends on the input type and the target type. In general, the cast expression attempts to create a new value of the target type based on the input value. Only certain combinations of input type and target type are supported. A summary of the rules are listed below— the normative definition of these rules is given in [XQuery 1.0 and XPath 2.0 Functions and Operators]. For the purpose of these rules, an implementation may determine that one type is derived by restriction from another type either by examining the in-scope schema definitions or by using an alternative, implementation-dependent mechanism such as a data dictionary.
cast
is supported for the combinations of input type and target type listed in Section 17.1 Casting from primitive types to primitive types
FO
. For each of these combinations, both the input type and the target type are primitive schema types. For
example, a value of type xs:string
can be cast into the schema type xs:decimal
. For each of these built-in combinations, the semantics of
casting are specified in [XQuery 1.0 and XPath 2.0 Functions and Operators].
If the target type of a cast
expression is xs:QName
, or is a type that is derived from xs:QName
or xs:NOTATION
, and
if the base type of the input is not the same as the base type of the target type, then the input expression must be a string literal [err:XPTY0004].
Note:
The reason for this rule is that construction of an instance of one of these target types from a string requires knowledge about namespace bindings. If the input expression is a non-literal string, it might be derived from an input document whose namespace bindings are different from the statically known namespaces.
cast
is supported if the input type is a non-primitive atomic type that is derived by restriction from the target type. In this case, the input value is
mapped into the value space of the target type, unchanged except for its type. For example, if shoesize
is derived by restriction from
xs:integer
, a value of type shoesize
can be cast into the schema type xs:integer
.
cast
is supported if the target type is a non-primitive atomic type and the input type is xs:string
or xs:untypedAtomic
. The
input value is first converted to a value in the lexical space of the target type by applying the whitespace normalization rules for the target type (as defined in [XML Schema]); a dynamic error [err:FORG0001] is raised if the resulting lexical value
does not satisfy the pattern facet of the target type. The lexical value is then converted to the value space of the target type using the schema-defined rules for the
target type; a dynamic error [err:FORG0001] is raised if the resulting value does not satisfy all the facets of
the target type.
cast
is supported if the target type is a non-primitive atomic type that is derived by restriction from the input type. The input value must satisfy all
the facets of the target type (in the case of the pattern facet, this is checked by generating a string representation of the input value, using the rules for casting
to xs:string
). The resulting value is the same as the input value, but with a different dynamic
type.
If a primitive type P1 can be cast into a primitive type P2, then any type derived by restriction from P1 can be cast into any type derived by restriction from P2, provided that the facets of the target type are satisfied. First the input value is cast to P1 using rule (b) above. Next, the value of type P1 is cast to the type P2, using rule (a) above. Finally, the value of type P2 is cast to the target type, using rule (d) above.
For any combination of input type and target type that is not in the above list, a cast
expression raises a type error [err:XPTY0004].
If casting from the input type to the target type is supported but nevertheless it is not possible to cast the input value into the value space of the target type, a dynamic error is raised. [err:FORG0001] This includes the case when any facet of the target type is not satisfied. For
example, the expression "2003-02-31" cast as xs:date
would raise a dynamic error.
[18] |
CastableExpr
|
::= |
CastExpr ( "castable" "as" SingleType )?
|
[49] |
SingleType
|
::= |
AtomicType "?"?
|
XPath provides an expression that tests whether a given value is castable into a given target type. The target type must be an atomic type that is in the in-scope schema types [err:XPST0051]. In addition, the target type cannot be
xs:NOTATION
or xs:anyAtomicType
[err:XPST0080]. The optional occurrence indicator "?
"
denotes that an empty sequence is permitted.
The expression V castable as T
returns true
if the value V
can be successfully cast into the target type T
by using a
cast
expression; otherwise it returns false
. The castable
expression can be used as a predicate to avoid errors at evaluation time. It can also be used to select an appropriate type for processing of a given value, as illustrated in the following example:
if ($x castable as hatsize) then $x cast as hatsize else if ($x castable as IQ) then $x cast as IQ else $x cast as xs:string
Note:
If the target type of a castable
expression is xs:QName
, or is a type that is derived from xs:QName
or xs:NOTATION
, and the
input argument of the expression is of type xs:string
but it is not a literal string, the result of the castable
expression is false
.
For every atomic type in the in-scope schema types (except xs:NOTATION
and xs:anyAtomicType
,
which are not instantiable), a constructor function is implicitly defined. In each case, the name of the constructor function is the same as the name of its target type
(including namespace). The signature of the constructor function for type T is as follows:
T($arg as xs:anyAtomicType?) as T?
[Definition: The constructor function for a given type is used to convert
instances of other atomic types into the given type. The semantics of the constructor function call T($arg)
are defined to be equivalent to the expression
(($arg) cast as T?)
.]
The constructor functions for xs:QName
and for types derived from xs:QName
and xs:NOTATION
require their arguments to be string literals or
to have a base type that is the same as the base type of the target type; otherwise a type error [err:XPTY0004] is raised. This
rule is consistent with the semantics of cast
expressions for these types, as defined in
3.10.2 Cast
.
The following examples illustrate the use of constructor functions:
This example is equivalent to ("2000-01-01" cast as xs:date?)
.
xs:date("2000-01-01")
This example is equivalent to (($floatvalue * 0.2E-5) cast as xs:decimal?)
.
xs:decimal($floatvalue * 0.2E-5)
This example returns a xs:dayTimeDuration
value equal to 21 days. It is equivalent to ("P21D" cast as xs:dayTimeDuration?)
.
xs:dayTimeDuration("P21D")
If usa:zipcode
is a user-defined atomic type in the in-scope schema types, then the following expression
is equivalent to the expression ("12345" cast as usa:zipcode?)
.
usa:zipcode("12345")
Note:
An instance of an atomic type that is not in a namespace can be constructed in either of the following ways:
By using a cast
expression, if the default element/type namespace is "none".
17 cast as apple
By using a constructor function, if the default function namespace is "none".
apple(17)
[17] |
TreatExpr
|
::= |
CastableExpr ( "treat" "as" SequenceType )?
|
XPath provides an expression called treat
that can be used to modify the static type of its operand.
Like cast
, the treat
expression takes two operands: an expression and a SequenceType. Unlike cast
,
however, treat
does not change the dynamic type or value of its operand. Instead, the purpose of
treat
is to ensure that an expression has an expected dynamic type at evaluation time.
The semantics of
expr1
treat as
type1
are as follows:
During static analysis:
The static type of the treat
expression is
type1
. This enables the expression to be used as an argument of a function that requires a parameter of
type1
.
During expression evaluation:
If
expr1
matches
type1
, using the rules for SequenceType matching, the treat
expression returns the value
of
expr1
; otherwise, it raises a dynamic error [err:XPDY0050]. If the
value of
expr1
is returned, its identity is preserved. The treat
expression ensures that the value of its expression operand conforms to the expected type at
run-time.
Example:
$myaddress treat as element(*, USAddress)
The static type of $myaddress
may be element(*, Address)
, a less specific type than
element(*, USAddress)
. However, at run-time, the value of $myaddress
must match the type element(*, USAddress)
using rules for SequenceType matching; otherwise a dynamic error
is raised [err:XPDY0050].
The grammar of XPath uses the same simple Extended Backus-Naur Form (EBNF) notation as [XML 1.0] with the following minor differences.
All named symbols have a name that begins with an uppercase letter.
It adds a notation for referring to productions in external specs.
Comments or extra-grammatical constraints on grammar productions are between '/*' and '*/' symbols.
A 'xgc:' prefix is an extra-grammatical constraint, the details of which are explained in A.1.2 Extra-grammatical Constraints
A 'ws:' prefix explains the whitespace rules for the production, the details of which are explained in A.2.4 Whitespace Rules
A 'gn:' prefix means a 'Grammar Note', and is meant as a clarification for parsing rules, and is explained in A.1.3 Grammar Notes . These notes are not normative.
The terminal symbols for this grammar include the quoted strings used in the production rules below, and the terminal symbols defined in section A.2.1 Terminal Symbols .
The EBNF notation is described in more detail in A.1.1 Notation .
To increase readability, the EBNF in the main body of this document omits some of these notational features. This appendix is the normative version of the EBNF.
The following definitions will be helpful in defining precisely this exposition.
[Definition: Each rule in the grammar defines one symbol, using the following format:
symbol ::= expression
]
[Definition: A terminal is a symbol or string or pattern that can appear in the right-hand side of a rule, but never appears on the left hand side in the main grammar, although it may appear on the left-hand side of a rule in the grammar for terminals.] The following constructs are used to match strings of one or more characters in a terminal:
matches any Char with a value in the range(s) indicated (inclusive).
matches any Char with a value among the characters enumerated.
matches any Char with a value not among the characters given.
matches the sequence of characters that appear inside the double quotes.
matches the sequence of characters that appear inside the single quotes.
matches any string matched by the production defined in the external specification as per the provided reference.
Patterns (including the above constructs) can be combined with grammatical operators to form more complex patterns, matching more complex sets of character strings. In the examples that follow, A and B represent (sub-)patterns.
A
is treated as a unit and may be combined as described in this list.
matches A
or nothing; optional A
.
matches A
followed by B
. This operator has higher precedence than alternation; thus A B | C D
is identical to (A B) | (C
D)
.
matches A
or B
but not both.
matches any string that matches A
but does not match B
.
matches one or more occurrences of A
. Concatenation has higher precedence than alternation; thus A+ | B+
is identical to (A+) |
(B+)
.
matches zero or more occurrences of A
. Concatenation has higher precedence than alternation; thus A* | B*
is identical to (A*) |
(B*)
This section contains constraints on the EBNF productions, which are required to parse legal sentences. The notes below are referenced from the right side of the production, with the notation: /* xgc: <id> */.
Constraint: leading-lone-slash
A single slash may appear either as a complete path expression or as the first part of a path expression in which it is followed by a RelativePathExpr, which can take the form of a NameTest ("*" or a QName). In contexts where operators like "*", "union", etc., can occur, parsers may have difficulty distinguishing operators from NameTests. For example, without lookahead the first part of the expression "/ * 5", for example is easily taken to be a complete expression, "/ *", which has a very different interpretation (the child nodes of "/").
To reduce the need for lookahead, therefore, if the token immediately following a slash is "*" or a keyword, then the slash must be the beginning, but not the entirety, of a PathExpr (and the following token must be a NameTest, not an operator).
A single slash may be used as the left-hand argument of an operator by parenthesizing it: (/) * 5
. The expression 5 * /
, on the other hand, is legal
without parentheses.
An implementation's choice to support the [XML 1.0] and [XML Names], or [XML 1.1] and [XML Names 1.1] lexical specification determines the external document from which to obtain the definition for this production. The EBNF only has references to the 1.0
versions. In some cases, the XML 1.0 and XML 1.1 definitions may be exactly the same. Also please note that these external productions follow the whitespace rules of their
respective specifications, and not the rules of this specification, in particular
A.2.4.1 Default Whitespace Handling
. Thus prefix : localname
is not a valid QName for purposes of this specification, just as it is not permitted in a XML document. Also, comments are not
permissible on either side of the colon. Also extra-grammatical constraints such as well-formedness constraints must be taken into account.
Constraint: reserved-function-names
Unprefixed function names spelled the same way as language keywords could make the language harder to recognize. For instance, if(foo)
could be taken either as a
FunctionCall or as the beginning of an IfExpr. Therefore it is not legal syntax for a user to invoke
functions with unprefixed names which match any of the names in
A.3 Reserved Function Names
.
A function named "if" can be called by binding its namespace to a prefix and using the prefixed form: "library:if(foo)" instead of "if(foo)".
Constraint: occurrence-indicators
As written, the grammar in
A XPath Grammar
is ambiguous for some forms using the '+' and '*' Kleene operators. The ambiguity is resolved as follows: these operators are tightly bound to the SequenceType expression, and have higher precedence than other uses of these symbols. Any occurrence of '+' and '*', as well as '?',
following a sequence type is assumed to be an occurrence indicator. That is, a "+", "*", or "?" immediately following an ItemType must be an
OccurrenceIndicator. Thus, 4 treat as item() + - 5
must be interpreted as (4 treat as item()+) - 5
,
taking the '+' as an OccurrenceIndicator and the '-' as a subtraction operator. To force the interpretation of "+" as an addition operator (and the corresponding interpretation
of the "-" as a unary minus), parentheses may be used: the form (4 treat as item()) + -5
surrounds the SequenceType
expression with parentheses and leads to the desired interpretation.
This rule has as a consequence that certain forms which would otherwise be legal and unambiguous are not recognized: in "4 treat as item() + 5", the "+" is taken as an OccurrenceIndicator, and not as an operator, which means this is not a legal expression.
This section contains general notes on the EBNF productions, which may be helpful in understanding how to interpret and implement the EBNF. These notes are not normative. The notes below are referenced from the right side of the production, with the notation: /* gn: <id> */.
Note:
Look-ahead is required to distinguish FunctionCall from a QName or keyword followed by a Comment.
For example: address (: this may be empty :)
may be mistaken for a call to a function named "address" unless this lookahead is employed. Another example is
for (: whom the bell :) $tolls in 3 return $tolls
, where the keyword "for" must not be mistaken for a function name.
Comments are allowed everywhere that ignorable whitespace is allowed, and the Comment symbol does not explicity appear on the right-hand side of the grammar (except in its own production). See A.2.4.1 Default Whitespace Handling .
A comment can contain nested comments, as long as all "(:" and ":)" patterns are balanced, no matter where they occur within the outer comment.
Note:
Lexical analysis may typically handle nested comments by incrementing a counter for each "(:" pattern, and decrementing the counter for each ":)" pattern. The comment does not terminate until the counter is back to zero.
Some illustrative examples:
(: commenting out a (: comment :) may be confusing, but often helpful :)
is a legal Comment, since balanced nesting of comments is allowed.
"this is just a string :)"
is a legal expression. However, (: "this is just a string :)" :)
will cause a syntax error. Likewise,
"this is another string (:"
is a legal expression, but (: "this is another string (:" :)
will cause a syntax error. It is a limitation
of nested comments that literal content can cause unbalanced nesting of comments.
for (: set up loop :) $i in $x return $i
is syntactically legal, ignoring the comment.
5 instance (: strange place for a comment :) of xs:integer
is also syntactically legal.
The terminal symbols assumed by the grammar above are described in this section.
Quoted strings appearing in production rules are terminal symbols.
Other terminal symbols are defined in A.2.1 Terminal Symbols .
A host language may choose whether the lexical rules of [XML 1.0] and [XML Names] are followed, or alternatively, the lexical rules of [XML 1.1] and [XML Names 1.1] are followed.
When tokenizing, the longest possible match that is valid in the current context is used.
All keywords are case sensitive. Keywords are not reserved—that is, any QName may duplicate a keyword except as noted in A.3 Reserved Function Names .
[71] |
IntegerLiteral
|
::= |
Digits
|
|
[72] |
DecimalLiteral
|
::= |
("." Digits) | (Digits "." [0-9]*)
|
/* ws: explicit */ |
[73] |
DoubleLiteral
|
::= |
(("." Digits) | (Digits ("." [0-9]*)?)) [eE] [+-]? Digits
|
/* ws: explicit */ |
[74] |
StringLiteral
|
::= |
('"' (EscapeQuot | [^"])* '"') | ("'" (EscapeApos | [^'])* "'")
|
/* ws: explicit */ |
[75] |
EscapeQuot
|
::= |
'""'
|
|
[76] |
EscapeApos
|
::= |
"''"
|
|
[77] |
Comment
|
::= |
"(:" (CommentContents | Comment)* ":)"
|
/* ws: explicit */ |
/* gn: comments */ | ||||
[78] |
QName
|
::= |
[http://www.w3.org/TR/REC-xml-names/#NT-QName]
Names
|
/* xgs: xml-version */ |
[79] |
NCName
|
::= |
[http://www.w3.org/TR/REC-xml-names/#NT-NCName]
Names
|
/* xgs: xml-version */ |
[80] |
Char
|
::= |
[http://www.w3.org/TR/REC-xml#NT-Char]
XML
|
/* xgs: xml-version */ |
The following symbols are used only in the definition of terminal symbols; they are not terminal symbols in the grammar of A.1 EBNF .
[81] |
Digits
|
::= |
[0-9]+
|
[82] |
CommentContents
|
::= |
(Char+ - (Char* ('(:' | ':)') Char*))
|
XPath 2.0 expressions consist of terminal symbols and symbol separators.
Terminal symbols that are not used exclusively in /* ws: explicit */ productions are of two kinds: delimiting and non-delimiting.
[Definition: The delimiting terminal symbols are: "-", (comma), (colon), "::", "!=", "?", "/", "//", (dot), "..", StringLiteral, "(", ")", "[", "]", "@", "$", "*", "+", "<", "<<", "<=", "=", ">", ">=", ">>", "|"]
[Definition: The non-delimiting terminal symbols are: IntegerLiteral, NCName, QName, DecimalLiteral, DoubleLiteral, "ancestor", "ancestor-or-self", "and", "as", "attribute", "cast", "castable", "child", "comment", "descendant", "descendant-or-self", "div", "document-node", "element", "else", "empty-sequence", "eq", "every", "except", "external", "following", "following-sibling", "for", "ge", "gt", "idiv", "if", "in", "instance", "intersect", "is", "item", "le", "lt", "mod", "namespace", "ne", "node", "of", "or", "parent", "preceding", "preceding-sibling", "processing-instruction", "return", "satisfies", "schema-attribute", "schema-element", "self", "some", "text", "then", "to", "treat", "union"]
[Definition: Whitespace and Comments function as symbol separators. For the most part, they are not mentioned in the grammar, and may occur between any two terminal symbols mentioned in the grammar, except where that is forbidden by the /* ws: explicit */ annotation in the EBNF, or by the /* xgs: xml-version */ annotation. ]
It is customary to separate consecutive terminal symbols by whitespace and Comments, but this is required only when otherwise two non-delimiting symbols would be adjacent to each other. There are two exceptions to this, that of "." and "-", which do require a symbol separator if they follow a QName or NCName. Also, "." requires a separator if it precedes or follows a numeric literal.
The XPath processor must behave as if it normalized all line breaks on input, before parsing. The normalization should be done according to the choice to support either [XML 1.0] or [XML 1.1] lexical processing.
For [XML 1.0] processing, all of the following must be translated to a single #xA character:
the two-character sequence #xD #xA
any #xD character that is not immediately followed by #xA.
For [XML 1.1] processing, all of the following must be translated to a single #xA character:
the two-character sequence #xD #xA
the two-character sequence #xD #x85
the single character #x85
the single character #x2028
any #xD character that is not immediately followed by #xA or #x85.
[Definition: A whitespace character is any of the characters defined by [http://www.w3.org/TR/REC-xml#NT-S].]
[Definition: Ignorable whitespace consists of any whitespace characters that may occur between terminals, unless these characters occur in the context of a production marked with a ws:explicit annotation, in which case they can occur only where explicitly specified (see A.2.4.2 Explicit Whitespace Handling ).] Ignorable whitespace characters are not significant to the semantics of an expression. Whitespace is allowed before the first terminal and after the last terminal of a module. Whitespace is allowed between any two terminals. Comments may also act as "whitespace" to prevent two adjacent terminals from being recognized as one. Some illustrative examples are as follows:
foo- foo
results in a syntax error. "foo-" would be recognized as a QName.
foo -foo
is syntactically equivalent to foo - foo
, two QNames separated by a subtraction operator.
foo(: This is a comment :)- foo
is syntactically equivalent to foo - foo
. This is because the comment prevents the two adjacent terminals from
being recognized as one.
foo-foo
is syntactically equivalent to single QName. This is because "-" is a valid character in a QName. When used as an operator after the characters of a
name, the "-" must be separated from the name, e.g. by using whitespace or parentheses.
10div 3
results in a syntax error.
10 div3
also results in a syntax error.
10div3
also results in a syntax error.
Explicit whitespace notation is specified with the EBNF productions, when it is different from the default rules, using the notation shown below. This notation is not inherited. In other words, if an EBNF rule is marked as /* ws: explicit */, the notation does not automatically apply to all the 'child' EBNF productions of that rule.
/* ws: explicit */ means that the EBNF notation explicitly notates, with S
or otherwise, where whitespace
characters are allowed. In productions with the /* ws: explicit */ annotation,
A.2.4.1 Default Whitespace Handling
does not apply. Comments are also not allowed in these productions.
The following names are not allowed as function names in an unprefixed form because expression syntax takes precedence.
attribute
comment
document-node
element
empty-sequence
if
item
node
processing-instruction
schema-attribute
schema-element
text
typeswitch
Note:
Although the keyword typeswitch
is not used in XPath, it is considered a reserved function name for compatibility with XQuery.
The grammar in A.1 EBNF normatively defines built-in precedence among the operators of XPath. These operators are summarized here to make clear the order of their precedence from lowest to highest. Operators that have a lower precedence number cannot be contained by operators with a higher precedence number. The associativity column indicates the order in which operators of equal precedence in an expression are applied.
# | Operator | Associativity |
---|---|---|
1 | , (comma) | left-to-right |
3 | for, some, every, if | left-to-right |
4 | or | left-to-right |
5 | and | left-to-right |
6 | eq, ne, lt, le, gt, ge, =, !=, <, <=, >, >=, is, <<, >> | left-to-right |
7 | to | left-to-right |
8 | +, - | left-to-right |
9 | *, div, idiv, mod | left-to-right |
10 | union, | | left-to-right |
11 | intersect, except | left-to-right |
12 | instance of | left-to-right |
13 | treat | left-to-right |
14 | castable | left-to-right |
15 | cast | left-to-right |
16 | -(unary), +(unary) | right-to-left |
17 | ?, *(OccurrenceIndicator), +(OccurrenceIndicator) | left-to-right |
18 | /, // | left-to-right |
19 | [ ], ( ), {} | left-to-right |
[Definition: Under certain circumstances, an atomic value can be promoted from one type to another. Type promotion is used in evaluating function calls (see 3.1.5 Function Calls ) and operators that accept numeric or string operands (see B.2 Operator Mapping ).] The following type promotions are permitted:
Numeric type promotion:
A value of type xs:float
(or any type derived by restriction from xs:float
) can be promoted to the type xs:double
. The result is
the xs:double
value that is the same as the original value.
A value of type xs:decimal
(or any type derived by restriction from xs:decimal
) can be promoted to either of the types xs:float
or
xs:double
. The result of this promotion is created by casting the original value to the required type. This kind of promotion may cause loss of
precision.
URI type promotion: A value of type xs:anyURI
(or any type derived by restriction from xs:anyURI
) can be promoted to the type xs:string
.
The result of this promotion is created by casting the original value to the type xs:string
.
Note:
Since xs:anyURI
values can be promoted to xs:string
, functions and operators that compare strings using the default collation also compare xs:anyURI
values using the default
collation. This ensures that orderings that include strings, xs:anyURI
values, or any combination of the two types are consistent and well-defined.
Note that type promotion is different from subtype substitution. For example:
A function that expects a parameter $p
of type xs:float
can be invoked with a value of type xs:decimal
. This is an example of type promotion. The value is actually converted to the expected type. Within the body of the function, $p instance
of xs:decimal
returns false
.
A function that expects a parameter $p
of type xs:decimal
can be invoked with a value of type xs:integer
. This is an example of subtype substitution. The value retains its original type. Within the body of the function, $p
instance of xs:integer
returns true
.
The operator mapping tables in this section list the combinations of types for which the various operators of XPath are defined. [Definition: For each operator and valid combination of operand types, the operator mapping tables specify a result type and an operator function that implements the semantics of the operator for the given types.] The definitions of the operator functions are given in [XQuery 1.0 and XPath 2.0 Functions and Operators]. The result of an operator may be the raising of an error by its operator function, as defined in [XQuery 1.0 and XPath 2.0 Functions and Operators]. In some cases, the operator function does not implement the full semantics of a given operator. For the definition of each operator (including its behavior for empty sequences or sequences of length greater than one), see the descriptive material in the main part of this document.
The and
and or
operators are defined directly in the main body of this document, and do not occur in the operator mapping tables.
If an operator in the operator mapping tables expects an operand of type ET, that operator can be applied to an operand of type AT if type AT can be
converted to type ET by a combination of type promotion and subtype substitution. For example, a table entry indicates that the gt
operator may be applied to two xs:date
operands,
returning xs:boolean
. Therefore, the gt
operator may also be applied to two (possibly different) subtypes of xs:date
, also returning
xs:boolean
.
[Definition: When referring to a type, the term numeric denotes the types xs:integer
,
xs:decimal
, xs:float
, and xs:double
.] An operator whose operands and result are designated as numeric
might be thought of as representing four operators, one for each of the numeric types. For example, the numeric +
operator might be thought of as representing the
following four operators:
Operator | First operand type | Second operand type | Result type |
+
|
xs:integer
|
xs:integer
|
xs:integer
|
+
|
xs:decimal
|
xs:decimal
|
xs:decimal
|
+
|
xs:float
|
xs:float
|
xs:float
|
+
|
xs:double
|
xs:double
|
xs:double
|
A numeric operator may be validly applied to an operand of type AT if type AT can be converted to any of the four numeric types by a combination of type promotion and subtype substitution. If the result
type of an operator is listed as numeric, it means "the first type in the ordered list (xs:integer, xs:decimal, xs:float, xs:double)
into which all operands can be
converted by subtype substitution and type promotion." As
an example, suppose that the type hatsize
is derived from xs:integer
and the type shoesize
is derived from xs:float
. Then if the
+
operator is invoked with operands of type hatsize
and shoesize
, it returns a result of type xs:float
. Similarly, if
+
is invoked with two operands of type hatsize
it returns a result of type xs:integer
.
[Definition: In the operator mapping tables, the term Gregorian refers to the types xs:gYearMonth
,
xs:gYear
, xs:gMonthDay
, xs:gDay
, and xs:gMonth
.] For binary operators that accept two Gregorian-type operands, both operands
must have the same type (for example, if one operand is of type xs:gDay
, the other operand must be of type xs:gDay
.)
Operator | Type(A) | Type(B) | Function | Result type |
---|---|---|---|---|
A + B | numeric | numeric | op:numeric-add(A, B) | numeric |
A + B | xs:date | xs:yearMonthDuration | op:add-yearMonthDuration-to-date(A, B) | xs:date |
A + B | xs:yearMonthDuration | xs:date | op:add-yearMonthDuration-to-date(B, A) | xs:date |
A + B | xs:date | xs:dayTimeDuration | op:add-dayTimeDuration-to-date(A, B) | xs:date |
A + B | xs:dayTimeDuration | xs:date | op:add-dayTimeDuration-to-date(B, A) | xs:date |
A + B | xs:time | xs:dayTimeDuration | op:add-dayTimeDuration-to-time(A, B) | xs:time |
A + B | xs:dayTimeDuration | xs:time | op:add-dayTimeDuration-to-time(B, A) | xs:time |
A + B | xs:dateTime | xs:yearMonthDuration | op:add-yearMonthDuration-to-dateTime(A, B) | xs:dateTime |
A + B | xs:yearMonthDuration | xs:dateTime | op:add-yearMonthDuration-to-dateTime(B, A) | xs:dateTime |
A + B | xs:dateTime | xs:dayTimeDuration | op:add-dayTimeDuration-to-dateTime(A, B) | xs:dateTime |
A + B | xs:dayTimeDuration | xs:dateTime | op:add-dayTimeDuration-to-dateTime(B, A) | xs:dateTime |
A + B | xs:yearMonthDuration | xs:yearMonthDuration | op:add-yearMonthDurations(A, B) | xs:yearMonthDuration |
A + B | xs:dayTimeDuration | xs:dayTimeDuration | op:add-dayTimeDurations(A, B) | xs:dayTimeDuration |
A - B | numeric | numeric | op:numeric-subtract(A, B) | numeric |
A - B | xs:date | xs:date | op:subtract-dates(A, B) | xs:dayTimeDuration |
A - B | xs:date | xs:yearMonthDuration | op:subtract-yearMonthDuration-from-date(A, B) | xs:date |
A - B | xs:date | xs:dayTimeDuration | op:subtract-dayTimeDuration-from-date(A, B) | xs:date |
A - B | xs:time | xs:time | op:subtract-times(A, B) | xs:dayTimeDuration |
A - B | xs:time | xs:dayTimeDuration | op:subtract-dayTimeDuration-from-time(A, B) | xs:time |
A - B | xs:dateTime | xs:dateTime | op:subtract-dateTimes(A, B) | xs:dayTimeDuration |
A - B | xs:dateTime | xs:yearMonthDuration | op:subtract-yearMonthDuration-from-dateTime(A, B) | xs:dateTime |
A - B | xs:dateTime | xs:dayTimeDuration | op:subtract-dayTimeDuration-from-dateTime(A, B) | xs:dateTime |
A - B | xs:yearMonthDuration | xs:yearMonthDuration | op:subtract-yearMonthDurations(A, B) | xs:yearMonthDuration |
A - B | xs:dayTimeDuration | xs:dayTimeDuration | op:subtract-dayTimeDurations(A, B) | xs:dayTimeDuration |
A * B | numeric | numeric | op:numeric-multiply(A, B) | numeric |
A * B | xs:yearMonthDuration | numeric | op:multiply-yearMonthDuration(A, B) | xs:yearMonthDuration |
A * B | numeric | xs:yearMonthDuration | op:multiply-yearMonthDuration(B, A) | xs:yearMonthDuration |
A * B | xs:dayTimeDuration | numeric | op:multiply-dayTimeDuration(A, B) | xs:dayTimeDuration |
A * B | numeric | xs:dayTimeDuration | op:multiply-dayTimeDuration(B, A) | xs:dayTimeDuration |
A idiv B | numeric | numeric | op:numeric-integer-divide(A, B) | xs:integer |
A div B | numeric | numeric | op:numeric-divide(A, B) | numeric; but xs:decimal if both operands are xs:integer |
A div B | xs:yearMonthDuration | numeric | op:divide-yearMonthDuration(A, B) | xs:yearMonthDuration |
A div B | xs:dayTimeDuration | numeric | op:divide-dayTimeDuration(A, B) | xs:dayTimeDuration |
A div B | xs:yearMonthDuration | xs:yearMonthDuration | op:divide-yearMonthDuration-by-yearMonthDuration (A, B) | xs:decimal |
A div B | xs:dayTimeDuration | xs:dayTimeDuration | op:divide-dayTimeDuration-by-dayTimeDuration (A, B) | xs:decimal |
A mod B | numeric | numeric | op:numeric-mod(A, B) | numeric |
A eq B | numeric | numeric | op:numeric-equal(A, B) | xs:boolean |
A eq B | xs:boolean | xs:boolean | op:boolean-equal(A, B) | xs:boolean |
A eq B | xs:string | xs:string | op:numeric-equal(fn:compare(A, B), 0) | xs:boolean |
A eq B | xs:date | xs:date | op:date-equal(A, B) | xs:boolean |
A eq B | xs:time | xs:time | op:time-equal(A, B) | xs:boolean |
A eq B | xs:dateTime | xs:dateTime | op:dateTime-equal(A, B) | xs:boolean |
A eq B | xs:duration | xs:duration | op:duration-equal(A, B) | xs:boolean |
A eq B | Gregorian | Gregorian | op:gYear-equal(A, B) etc. | xs:boolean |
A eq B | xs:hexBinary | xs:hexBinary | op:hex-binary-equal(A, B) | xs:boolean |
A eq B | xs:base64Binary | xs:base64Binary | op:base64-binary-equal(A, B) | xs:boolean |
A eq B | xs:anyURI | xs:anyURI | op:numeric-equal(fn:compare(A, B), 0) | xs:boolean |
A eq B | xs:QName | xs:QName | op:QName-equal(A, B) | xs:boolean |
A eq B | xs:NOTATION | xs:NOTATION | op:NOTATION-equal(A, B) | xs:boolean |
A ne B | numeric | numeric | fn:not(op:numeric-equal(A, B)) | xs:boolean |
A ne B | xs:boolean | xs:boolean | fn:not(op:boolean-equal(A, B)) | xs:boolean |
A ne B | xs:string | xs:string | fn:not(op:numeric-equal(fn:compare(A, B), 0)) | xs:boolean |
A ne B | xs:date | xs:date | fn:not(op:date-equal(A, B)) | xs:boolean |
A ne B | xs:time | xs:time | fn:not(op:time-equal(A, B)) | xs:boolean |
A ne B | xs:dateTime | xs:dateTime | fn:not(op:dateTime-equal(A, B)) | xs:boolean |
A ne B | xs:duration | xs:duration | fn:not(op:duration-equal(A, B)) | xs:boolean |
A ne B | Gregorian | Gregorian | fn:not(op:gYear-equal(A, B)) etc. | xs:boolean |
A ne B | xs:hexBinary | xs:hexBinary | fn:not(op:hex-binary-equal(A, B)) | xs:boolean |
A ne B | xs:base64Binary | xs:base64Binary | fn:not(op:base64-binary-equal(A, B)) | xs:boolean |
A ne B | xs:anyURI | xs:anyURI | fn:not(op:numeric-equal(fn:compare(A, B), 0)) | xs:boolean |
A ne B | xs:QName | xs:QName | fn:not(op:QName-equal(A, B)) | xs:boolean |
A ne B | xs:NOTATION | xs:NOTATION | fn:not(op:NOTATION-equal(A, B)) | xs:boolean |
A gt B | numeric | numeric | op:numeric-greater-than(A, B) | xs:boolean |
A gt B | xs:boolean | xs:boolean | op:boolean-greater-than(A, B) | xs:boolean |
A gt B | xs:string | xs:string | op:numeric-greater-than(fn:compare(A, B), 0) | xs:boolean |
A gt B | xs:date | xs:date | op:date-greater-than(A, B) | xs:boolean |
A gt B | xs:time | xs:time | op:time-greater-than(A, B) | xs:boolean |
A gt B | xs:dateTime | xs:dateTime | op:dateTime-greater-than(A, B) | xs:boolean |
A gt B | xs:yearMonthDuration | xs:yearMonthDuration | op:yearMonthDuration-greater-than(A, B) | xs:boolean |
A gt B | xs:dayTimeDuration | xs:dayTimeDuration | op:dayTimeDuration-greater-than(A, B) | xs:boolean |
A gt B | xs:anyURI | xs:anyURI | op:numeric-greater-than(fn:compare(A, B), 0) | xs:boolean |
A lt B | numeric | numeric | op:numeric-less-than(A, B) | xs:boolean |
A lt B | xs:boolean | xs:boolean | op:boolean-less-than(A, B) | xs:boolean |
A lt B | xs:string | xs:string | op:numeric-less-than(fn:compare(A, B), 0) | xs:boolean |
A lt B | xs:date | xs:date | op:date-less-than(A, B) | xs:boolean |
A lt B | xs:time | xs:time | op:time-less-than(A, B) | xs:boolean |
A lt B | xs:dateTime | xs:dateTime | op:dateTime-less-than(A, B) | xs:boolean |
A lt B | xs:yearMonthDuration | xs:yearMonthDuration | op:yearMonthDuration-less-than(A, B) | xs:boolean |
A lt B | xs:dayTimeDuration | xs:dayTimeDuration | op:dayTimeDuration-less-than(A, B) | xs:boolean |
A lt B | xs:anyURI | xs:anyURI | op:numeric-less-than(fn:compare(A, B), 0) | xs:boolean |
A ge B | numeric | numeric | op:numeric-greater-than(A, B) or op:numeric-equal(A, B) | xs:boolean |
A ge B | xs:boolean | xs:boolean | fn:not(op:boolean-less-than(A, B)) | xs:boolean |
A ge B | xs:string | xs:string | op:numeric-greater-than(fn:compare(A, B), -1) | xs:boolean |
A ge B | xs:date | xs:date | fn:not(op:date-less-than(A, B)) | xs:boolean |
A ge B | xs:time | xs:time | fn:not(op:time-less-than(A, B)) | xs:boolean |
A ge B | xs:dateTime | xs:dateTime | fn:not(op:dateTime-less-than(A, B)) | xs:boolean |
A ge B | xs:yearMonthDuration | xs:yearMonthDuration | fn:not(op:yearMonthDuration-less-than(A, B)) | xs:boolean |
A ge B | xs:dayTimeDuration | xs:dayTimeDuration | fn:not(op:dayTimeDuration-less-than(A, B)) | xs:boolean |
A ge B | xs:anyURI | xs:anyURI | op:numeric-greater-than(fn:compare(A, B), -1) | xs:boolean |
A le B | numeric | numeric | op:numeric-less-than(A, B) or op:numeric-equal(A, B) | xs:boolean |
A le B | xs:boolean | xs:boolean | fn:not(op:boolean-greater-than(A, B)) | xs:boolean |
A le B | xs:string | xs:string | op:numeric-less-than(fn:compare(A, B), 1) | xs:boolean |
A le B | xs:date | xs:date | fn:not(op:date-greater-than(A, B)) | xs:boolean |
A le B | xs:time | xs:time | fn:not(op:time-greater-than(A, B)) | xs:boolean |
A le B | xs:dateTime | xs:dateTime | fn:not(op:dateTime-greater-than(A, B)) | xs:boolean |
A le B | xs:yearMonthDuration | xs:yearMonthDuration | fn:not(op:yearMonthDuration-greater-than(A, B)) | xs:boolean |
A le B | xs:dayTimeDuration | xs:dayTimeDuration | fn:not(op:dayTimeDuration-greater-than(A, B)) | xs:boolean |
A le B | xs:anyURI | xs:anyURI | op:numeric-less-than(fn:compare(A, B), 1) | xs:boolean |
A is B | node() | node() | op:is-same-node(A, B) | xs:boolean |
A << B | node() | node() | op:node-before(A, B) | xs:boolean |
A >> B | node() | node() | op:node-after(A, B) | xs:boolean |
A union B | node()* | node()* | op:union(A, B) | node()* |
A | B | node()* | node()* | op:union(A, B) | node()* |
A intersect B | node()* | node()* | op:intersect(A, B) | node()* |
A except B | node()* | node()* | op:except(A, B) | node()* |
A to B | xs:integer | xs:integer | op:to(A, B) | xs:integer* |
A , B | item()* | item()* | op:concatenate(A, B) | item()* |
Operator | Operand type | Function | Result type |
---|---|---|---|
+ A | numeric | op:numeric-unary-plus(A) | numeric |
- A | numeric | op:numeric-unary-minus(A) | numeric |
The tables in this section describe the scope (range of applicability) of the various components in the static context and dynamic context.
The following table describes the components of the static context. For each component, "global" indicates that the value of the component applies throughout an XPath expression, whereas "lexical" indicates that the value of the component applies only within the subexpression in which it is defined.
Component | Scope |
---|---|
XPath 1.0 Compatibility Mode | global |
Statically known namespaces | global |
Default element/type namespace | global |
Default function namespace | global |
In-scope schema types | global |
In-scope element declarations | global |
In-scope attribute declarations | global |
In-scope variables | lexical; for-expressions and quantified expressions can bind new variables |
Context item static type | lexical |
Function signatures | global |
Statically known collations | global |
Default collation | global |
Base URI | global |
Statically known documents | global |
Statically known collections | global |
Statically known default collection type | global |
The following table describes how values are assigned to the various components of the dynamic context. All these components are initialized by mechanisms defined by the host language. For each component, "global" indicates that the value of the component remains constant throughout evaluation of the XPath expression, whereas "dynamic" indicates that the value of the component can be modified by the evaluation of subexpressions.
Component | Scope |
---|---|
Context item | dynamic; changes during evaluation of path expressions and predicates |
Context position | dynamic; changes during evaluation of path expressions and predicates |
Context size | dynamic; changes during evaluation of path expressions and predicates |
Variable values | dynamic; for-expressions and quantified expressions can bind new variables |
Current date and time | global; must be initialized by implementation |
Implicit timezone | global; must be initialized by implementation |
Available documents | global; must be initialized by implementation |
Available collections | global; must be initialized by implementation |
Default collection | global; overwriteable by implementation |
The following items in this specification are implementation-defined:
The version of Unicode that is used to construct expressions.
The implicit timezone.
The circumstances in which warnings are raised, and the ways in which warnings are handled.
The method by which errors are reported to the external processing environment.
Whether the implementation is based on the rules of [XML 1.0] and [XML Names] or the rules of [XML 1.1] and [XML Names 1.1]. One of these sets of rules must be applied consistently by all aspects of the implementation.
Whether the implementation supports the namespace axis.
Any static typing extensions supported by the implementation, if the Static Typing Feature is supported.
Note:
Additional implementation-defined items are listed in [XQuery/XPath Data Model (XDM)] and [XQuery 1.0 and XPath 2.0 Functions and Operators].
XPath is intended primarily as a component that can be used by other specifications. Therefore, XPath relies on specifications that use it (such as [XPointer] and [XSLT 2.0]) to specify conformance criteria for XPath in their respective environments. Specifications that set conformance criteria for their use of XPath must not change the syntactic or semantic definitions of XPath as given in this specification, except by subsetting and/or compatible extensions.
[Definition: The Static Typing Feature is an optional feature of XPath that provides support for the static semantics defined in [XQuery 1.0 and XPath 2.0 Formal Semantics], and requires implementations to detect and report type errors during the static analysis phase.] Specifications that use XPath may specify conformance criteria for use of the Static Typing Feature.
If an implementation does not support the Static Typing Feature, but can nevertheless determine during the static analysis phase that an expression will necessarily raise a type error if evaluated at run time, the implementation may raise that error during the static analysis phase. The choice of whether to raise such an error at analysis time is implementation dependent.
In some cases, the static typing rules defined in [XQuery 1.0 and XPath 2.0 Formal Semantics] are not very precise (see, for example, the
type inference rules for the ancestor axes—parent, ancestor, and ancestor-or-self—and for the function fn:root
). Some implementations may wish to support more
precise static typing rules.
A conforming implementation that implements the Static Typing Feature may also provide one or more static typing extensions. [Definition: A static typing extension is an implementation-defined type inference rule that infers a more precise static type than that inferred by the type inference rules in [XQuery 1.0 and XPath 2.0 Formal Semantics].] See Section 6.1.1 Static Typing Extensions FS for a formal definition of the constraints on static typing extensions.
It is a static error if analysis of an expression relies on some component of the static context that has not been assigned a value.
It is a dynamic error if evaluation of an expression relies on some part of the dynamic context that has not been assigned a value.
It is a static error if an expression is not a valid instance of the grammar defined in A.1 EBNF .
It is a type error if, during the static analysis phase, an expression is found to have a static type that is not appropriate for the context in which the expression occurs, or during the dynamic evaluation phase, the dynamic type of a value does not match a required type as specified by the matching rules in 2.5.4 SequenceType Matching .
During the analysis phase, it is a static error if the static type assigned
to an expression other than the expression ()
or data(())
is empty-sequence()
.
(Not currently used.)
(Not currently used.)
It is a static error if an expression refers to an element name, attribute name, schema type name, namespace prefix, or variable name that is not defined in the static context, except for an ElementName in an ElementTest or an AttributeName in an AttributeTest.
An implementation must raise a static error if it encounters a reference to an axis that it does not support.
It is a static error if the expanded QName and number of arguments in a function call do not match the name and arity of a function signature in the static context.
It is a type error if the result of the last step in a path expression contains both nodes and atomic values.
It is a type error if the result of a step (other than the last step) in a path expression contains an atomic value.
It is a type error if, in an axis step, the context item is not a node.
(Not currently used.)
It is a dynamic error if the dynamic type of the operand of a
treat
expression does not match the sequence type specified by the treat
expression. This error
might also be raised by a path expression beginning with "/
" or "//
" if the context node is not in a tree that is rooted at a document node. This is
because a leading "/
" or "//
" in a path expression is an abbreviation for an initial step that includes the clause treat as
document-node()
.
It is a static error if a QName that is used as an AtomicType in a SequenceType is not defined in the in-scope schema types as an atomic type.
It is a static error if the target type of a cast
or castable
expression is xs:NOTATION
or xs:anyAtomicType
.
It is a static error if a QName used in an expression contains a namespace prefix that cannot be expanded into a namespace URI by using the statically known namespaces.
(Not currently used.)
An atomic value is a value in the value space of an atomic type, as defined in [XML Schema].
Atomization of a sequence is defined as the result of invoking the fn:data
function on the sequence, as defined in [XQuery 1.0
and XPath 2.0 Functions and Operators].
Available collections. This is a mapping of strings onto sequences of nodes. The string represents the absolute URI of a resource. The sequence of nodes represents the
result of the fn:collection
function when that URI is supplied as the argument.
Available documents. This is a mapping of strings onto document nodes. The string represents the absolute URI of a resource. The document node is the root of a tree that
represents that resource using the data model. The document node is returned by the fn:doc
function when applied to
that URI.
An axis step returns a sequence of nodes that are reachable from the context node via a specified axis. Such a step has two parts: an axis, which defines the "direction of movement" for the step, and a node test, which selects nodes based on their kind, name, and/or type annotation.
Base URI. This is an absolute URI, used when necessary in the resolution of relative URIs (for example, by the fn:resolve-uri
function.)
The built-in functions supported by XPath are defined in [XQuery 1.0 and XPath 2.0 Functions and Operators].
A collation is a specification of the manner in which strings and URIs are compared and, by extension, ordered. For a more complete definition of collation, see [XQuery 1.0 and XPath 2.0 Functions and Operators].
One way to construct a sequence is by using the comma operator, which evaluates each of its operands and concatenates the resulting sequences, in order, into a single result sequence.
The constructor function for a given type is used to convert instances of other atomic types into the given type. The semantics of the constructor function call
T($arg)
are defined to be equivalent to the expression (($arg) cast as T?)
.
The context item is the item currently being processed. An item is either an atomic value or a node.
Context item static type. This component defines the static type of the context item within the scope of a given expression.
When the context item is a node, it can also be referred to as the context node.
The context position is the position of the context item within the sequence of items currently being processed.
The context size is the number of items in the sequence of items currently being processed.
Current dateTime. This information represents an implementation-dependent point in time during
the processing of
an expression
, and includes an explicit timezone. It can be retrieved by the fn:current-dateTime
function. If invoked multiple times during the execution of
an expression
, this function always returns the same result.
XPath operates on the abstract, logical structure of an XML document, rather than its surface syntax. This logical structure, known as the data model, is defined in [XQuery/XPath Data Model (XDM)].
For a given node in an XDM instance, the data model schema is defined as the schema from which the type annotation of that node was derived.
Default collation. This identifies one of the collations in statically known collations as the
collation to be used by functions and operators for comparing and ordering values of type xs:string
and xs:anyURI
(and types derived from them) when no
explicit collation is specified.
Default collection. This is the sequence of nodes that would result from calling the fn:collection
function with no arguments.
Default element/type namespace. This is a namespace URI or "none". The namespace URI, if present, is used for any unprefixed QName appearing in a position where an element or type name is expected.
Default function namespace. This is a namespace URI or "none". The namespace URI, if present, is used for any unprefixed QName appearing in a position where a function name is expected.
The delimiting terminal symbols are: "-", (comma), (colon), "::", "!=", "?", "/", "//", (dot), "..", StringLiteral, "(", ")", "[", "]", "@", "$", "*", "+", "<", "<<", "<=", "=", ">", ">=", ">>", "|"
Informally, document order is the order in which nodes appear in the XML serialization of a document.
The dynamic context of an expression is defined as information that is available at the time the expression is evaluated.
A dynamic error is an error that must be detected during the dynamic evaluation phase and may be detected during the static analysis phase. Numeric overflow is an example of a dynamic error.
The dynamic evaluation phase is the phase during which the value of an expression is computed.
A dynamic type is associated with each value as it is computed. The dynamic type of a value may be more specific than the static type of the expression that computed it (for example, the static type of an expression might be xs:integer*
, denoting a sequence of zero or more
integers, but at evaluation time its value may have the dynamic type xs:integer
, denoting exactly one integer.)
The effective boolean value of a value is defined as the result of applying the fn:boolean
function to the value, as defined in [XQuery 1.0 and XPath 2.0 Functions and Operators].
A sequence containing zero items is called an empty sequence.
In addition to its identifying QName, a dynamic error may also carry a descriptive string and one or more additional values called error values.
An expanded QName consists of an optional namespace URI and a local name. An expanded QName also retains its original namespace prefix (if any), to facilitate casting the expanded QName into a string.
The expression context for a given expression consists of all the information that can affect the result of the expression.
A filter expression consists simply of a primary expression followed by zero or more predicates. The result of the filter expression consists of the items returned by the primary expression, filtered by applying each predicate in turn, working from left to right.
The first three components of the dynamic context (context item, context position, and context size) are called the focus of the expression.
Function implementations. Each function in function signatures has a function implementation that enables the function to map instances of its parameter types into an instance of its result type.
Function signatures. This component defines the set of functions that are available to be called from within an expression. Each function is uniquely identified by its expanded QName and its arity (number of parameters).
In the operator mapping tables, the term Gregorian refers to the types xs:gYearMonth
, xs:gYear
, xs:gMonthDay
, xs:gDay
,
and xs:gMonth
.
Ignorable whitespace consists of any whitespace characters that may occur between terminals, unless these characters occur in the context of a production marked with a ws:explicit annotation, in which case they can occur only where explicitly specified (see A.2.4.2 Explicit Whitespace Handling ).
Implementation-defined indicates an aspect that may differ between implementations, but must be specified by the implementor for each particular implementation.
Implementation-dependent indicates an aspect that may differ between implementations, is not specified by this or any W3C specification, and is not required to be specified by the implementor for any particular implementation.
Implicit timezone. This is the timezone to be used when a date, time, or dateTime value that does not have a timezone is used in a comparison or arithmetic operation. The
implicit timezone is an implementation-defined value of type xs:dayTimeDuration
. See [XML Schema] for the range of legal values of a timezone.
In-scope attribute declarations. Each attribute declaration is identified either by an expanded QName (for a top-level attribute declaration) or by an implementation-dependent attribute identifier (for a local attribute declaration).
In-scope element declarations. Each element declaration is identified either by an expanded QName (for a top-level element declaration) or by an implementation-dependent element identifier (for a local element declaration).
The in-scope namespaces property of an element node is a set of namespace bindings, each of which associates a namespace prefix with a URI, thus defining the set of namespace prefixes that are available for interpreting QNames within the scope of the element. For a given element, one namespace binding may have an empty prefix; the URI of this namespace binding is the default namespace within the scope of the element.
In-scope schema definitions. This is a generic term for all the element declarations, attribute declarations, and schema type definitions that are in scope during processing of an expression.
In-scope schema types. Each schema type definition is identified either by an expanded QName (for a named type) or by an implementation-dependent type identifier (for an anonymous type). The in-scope schema types include the predefined schema types described in 2.5.1 Predefined Schema Types .
In-scope variables. This is a set of (expanded QName, type) pairs. It defines the set of variables that are available for reference within an expression. The expanded QName is the name of the variable, and the type is the static type of the variable.
An item is either an atomic value or a node.
An alternative form of a node test called a kind test can select nodes based on their kind, name, and type annotation.
A literal is a direct syntactic representation of an atomic value.
A node test that consists only of a QName or a Wildcard is called a name test.
A node is an instance of one of the node kinds defined in [XQuery/XPath Data Model (XDM)].
A node test is a condition that must be true for each node selected by a step.
The non-delimiting terminal symbols are: IntegerLiteral, NCName, QName, DecimalLiteral, DoubleLiteral, "ancestor", "ancestor-or-self", "and", "as", "attribute", "cast", "castable", "child", "comment", "descendant", "descendant-or-self", "div", "document-node", "element", "else", "empty-sequence", "eq", "every", "except", "external", "following", "following-sibling", "for", "ge", "gt", "idiv", "if", "in", "instance", "intersect", "is", "item", "le", "lt", "mod", "namespace", "ne", "node", "of", "or", "parent", "preceding", "preceding-sibling", "processing-instruction", "return", "satisfies", "schema-attribute", "schema-element", "self", "some", "text", "then", "to", "treat", "union"
When referring to a type, the term numeric denotes the types xs:integer
, xs:decimal
, xs:float
, and xs:double
.
A predicate whose predicate expression returns a numeric type is called a numeric predicate.
For each operator and valid combination of operand types, the operator mapping tables specify a result type and an operator function that implements the semantics of the operator for the given types.
A path expression can be used to locate nodes within trees. A path expression consists of a series of one or more steps, separated by
"/
" or "//
", and optionally beginning with "/
" or "//
".
A predicate consists of an expression, called a predicate expression, enclosed in square brackets. A predicate serves to filter a sequence, retaining some items and discarding others.
Primary expressions are the basic primitives of the language. They include literals, variable references, context item expressions, and function calls. A primary expression may also be created by enclosing any expression in parentheses, which is sometimes helpful in controlling the precedence of operators.
Every axis has a principal node kind. If an axis can contain elements, then the principal node kind is element; otherwise, it is the kind of nodes that the axis can contain.
Lexically, a QName consists of an optional namespace prefix and a local name. If the namespace prefix is present, it is separated from the local name by a colon.
The node ordering that is the reverse of document order is called reverse document order.
A schema type is a type that is (or could be) defined using the facilities of [XML Schema] (including the built-in types of [XML Schema]).
A sequence is an ordered collection of zero or more items.
A sequence type is a type that can be expressed using the SequenceType syntax. Sequence types are used whenever it is necessary to refer to a type in an XPath expression. The term sequence type suggests that this syntax is used to describe the type of an XPath value, which is always a sequence.
During evaluation of an expression, it is sometimes necessary to determine whether a value with a known dynamic type "matches" an expected sequence type. This process is known as SequenceType matching.
Serialization is the process of converting an XDM instance into a sequence of octets (step DM4 in Figure 1.)
A sequence containing exactly one item is called a singleton.
Document order is stable, which means that the relative order of two nodes will not change during the processing of a given expression , even if this order is implementation-dependent.
Statically known collations. This is an implementation-defined set of (URI, collation) pairs. It defines the names of the collations that are available for use in processing expressions.
Statically known collections. This is a mapping from strings onto types. The string represents the absolute URI of a resource that is potentially available using the
fn:collection
function. The type is the type of the sequence of nodes that would result from calling the fn:collection
function with this URI as its
argument.
Statically known default collection type. This is the type of the sequence of nodes that would result from calling the fn:collection
function with no
arguments.
Statically known documents. This is a mapping from strings onto types. The string represents the absolute URI of a resource that is potentially available using the
fn:doc
function. The type is the static type of a call to fn:doc
with the given URI as its literal
argument.
Statically known namespaces. This is a set of (prefix, URI) pairs that define all the namespaces that are known during static processing of a given expression.
The static analysis phase depends on the expression itself and on the static context. The static analysis phase does not depend on input data (other than schemas).
The static context of an expression is the information that is available during static analysis of the expression, prior to its evaluation.
A static error is an error that must be detected during the static analysis phase. A syntax error is an example of a static error.
The static type of an expression is a type such that, when the expression is evaluated, the resulting value will always conform to the static type.
A static typing extension is an implementation-defined type inference rule that infers a more precise static type than that inferred by the type inference rules in [XQuery 1.0 and XPath 2.0 Formal Semantics].
The Static Typing Feature is an optional feature of XPath that provides support for the static semantics defined in [XQuery 1.0 and XPath 2.0 Formal Semantics], and requires implementations to detect and report type errors during the static analysis phase.
A step is a part of a path expression that generates a sequence of items and then filters the sequence by zero or more predicates. The value of the step consists of those items that satisfy the predicates, working from left to right. A step may be either an axis step or a filter expression.
The string value of a node is a string and can be extracted by applying the fn:string
function to the node.
Substitution groups are defined in [XML Schema] Part 1, Section 2.2.2.2. Informally, the substitution group headed by a given element (called the head element) consists of the set of elements that can be substituted for the head element without affecting the outcome of schema validation.
The use of a value whose dynamic type is derived from an expected type is known as subtype substitution.
Each rule in the grammar defines one symbol, using the following format:
symbol ::= expression
Whitespace and Comments function as symbol separators. For the most part, they are not mentioned in the grammar, and may occur between any two terminal symbols mentioned in the grammar, except where that is forbidden by the /* ws: explicit */ annotation in the EBNF, or by the /* xgs: xml-version */ annotation.
A terminal is a symbol or string or pattern that can appear in the right-hand side of a rule, but never appears on the left hand side in the main grammar, although it may appear on the left-hand side of a rule in the grammar for terminals.
Each element node and attribute node in an XDM instance has a type annotation (referred to in [XQuery/XPath Data Model (XDM)] as its type-name
property.) The type annotation of a node is a schema type that describes the relationship between the string value of the node and its typed value.
The typed value of a node is a sequence of atomic values and can be extracted by applying the fn:data
function to the node.
A type error may be raised during the static analysis phase or the dynamic evaluation phase. During the static analysis phase, a type error occurs when the static type of an expression does not match the expected type of the context in which the expression occurs. During the dynamic evaluation phase, a type error occurs when the dynamic type of a value does not match the expected type of the context in which the value occurs.
Under certain circumstances, an atomic value can be promoted from one type to another. Type promotion is used in evaluating function calls (see 3.1.5 Function Calls ) and operators that accept numeric or string operands (see B.2 Operator Mapping ).
Within this specification, the term URI refers to a Universal Resource Identifier as defined in [RFC3986] and extended in [RFC3987] with the new name IRI.
In the data model, a value is always a sequence.
A variable reference is a QName preceded by a $-sign.
Variable values. This is a set of (expanded QName, value) pairs. It contains the same expanded QNames as the in-scope variables in the static context for the expression. The expanded QName is the name of the variable and the value is the dynamic value of the variable, which includes its dynamic type.
In addition to static errors, dynamic errors, and type errors, an XPath implementation may raise warnings, either during the static analysis phase or the dynamic evaluation phase. The circumstances in which warnings are raised, and the ways in which warnings are handled, are implementation-defined.
A whitespace character is any of the characters defined by [http://www.w3.org/TR/REC-xml#NT-S].
The term XDM instance is used, synonymously with the term value, to denote an unconstrained sequence of nodes and/or atomic values in the data model.
XPath 1.0 compatibility mode.
This value is true
if rules for backward compatibility with XPath Version 1.0 are in effect; otherwise it is false
.
xs:anyAtomicType
is an atomic type that includes all atomic values (and no values that are not atomic). Its base type is xs:anySimpleType
from which all
simple types, including atomic, list, and union types, are derived. All primitive atomic types, such as xs:integer
, xs:string
, and
xs:untypedAtomic
, have xs:anyAtomicType
as their base type.
xs:dayTimeDuration
is derived by restriction from xs:duration
. The lexical representation of xs:dayTimeDuration
is restricted to contain
only day, hour, minute, and second components.
xs:untyped
is used as the type annotation of an element node that has not been validated, or has been
validated in skip
mode.
xs:untypedAtomic
is an atomic type that is used to denote untyped atomic data, such as text that has not been assigned a more specific type.
xs:yearMonthDuration
is derived by restriction from xs:duration
. The lexical representation of xs:yearMonthDuration
is restricted to contain
only year and month components.
This appendix provides a summary of the areas of incompatibility between XPath 2.0 and [XPath 1.0].
Three separate cases are considered:
Incompatibilities that exist when source documents have no schema, and when running with XPath 1.0 compatibility mode set to true. This specification has been designed to reduce the number of incompatibilities in this situation to an absolute minumum, but some differences remain and are listed individually.
Incompatibilities that arise when XPath 1.0 compatibility mode is set to false. In this case, the number of expressions where compatibility is lost is rather greater.
Incompatibilities that arise when the source document is processed using a schema (whether or not XPath 1.0 compatibility mode is set to true). Processing the document with a schema changes the way that the values of nodes are interpreted, and this can cause an XPath expression to return different results.
The list below contains all known areas, within the scope of this specification, where an XPath 2.0 processor running with compatibility mode set to true will produce different
results from an XPath 1.0 processor evaluating the same expression, assuming that the expression was valid in XPath 1.0, and that the nodes in the source document have no type
annotations other than xs:untyped
and xs:untypedAtomic
.
Incompatibilities in the behavior of individual functions are not listed here, but are included in an appendix of [XQuery 1.0 and XPath 2.0 Functions and Operators].
Since both XPath 1.0 and XPath 2.0 leave some aspects of the specification implementation-defined, there may be incompatiblities in the behavior of a particular implementation that are outside the scope of this specification. Equally, some aspects of the behavior of XPath are defined by the host language.
Consecutive comparison operators such as A < B < C
were supported in XPath 1.0, but are not permitted by the XPath 2.0 grammar. In most cases such
comparisons in XPath 1.0 did not have the intuitive meaning, so it is unlikely that they have been widely used in practice. If such a construct is found, an XPath 2.0
processor will report a syntax error, and the construct can be rewritten as (A < B) < C
When converting strings to numbers (either explicitly when using the number
function, or implicitly say on a function call), certain strings that converted to
the special value NaN
under XPath 1.0 will convert to values other than NaN
under XPath 2.0. These include any number written with a leading
+
sign, any number in exponential floating point notation (for example 1.0e+9
), and the strings INF
and -INF
.
XPath 2.0 does not allow a token starting with a letter to follow immediately after a numeric literal, without intervening whitespace. For example, 10div 3
was
permitted in XPath 1.0, but in XPath 2.0 must be written as 10 div 3
.
The namespace axis is deprecated in XPath 2.0. Implementations may support the namespace axis for backward compatibility with XPath 1.0, but they are not required to do so. (XSLT 2.0 requires that if XPath backwards compatibility mode is supported, then the namespace axis must also be supported; but other host languages may define the conformance rules differently.)
Even when the setting of the XPath 1.0 compatibility mode is false, many XPath expressions will still produce the same results under XPath 2.0 as under XPath 1.0. The exceptions are described in this section.
In all cases it is assumed that the expression in question was valid under XPath 1.0, that XPath 1.0 compatibility mode is false, and that all elements and attributes are
annotated with the types xs:untyped
and xs:untypedAtomic
respectively.
In the description below, the terms node-set and number are used with their XPath 1.0 meanings, that is, to describe expressions which according to the rules of XPath 1.0 would have generated a node-set or a number respectively.
When a node-set containing more than one node is supplied as an argument to a function or operator that expects a single node or value, the XPath 1.0 rule was that all nodes
after the first were discarded. Under XPath 2.0, a type error occurs if there is more than one node. The XPath 1.0 behavior can always be restored by using the predicate
[1]
to explicitly select the first node in the node-set.
In XPath 1.0, the <
and >
operators, when applied to two strings, attempted to convert both the strings to numbers and then made a
numeric comparison between the results. In XPath 2.0, these operators perform a string comparison using the default collating sequence. (If either value is numeric, however,
the results are compatible with XPath 1.0)
When an empty node-set is supplied as an argument to a function or operator that expects a number, the value is no longer converted implicitly to NaN. The XPath 1.0 behavior
can always be restored by using the number
function to perform an explicit conversion.
More generally, the supplied arguments to a function or operator are no longer implicitly converted to the required type, except in the case where the supplied argument is
of type xs:untypedAtomic
(which will commonly be the case when a node in a schemaless document is supplied as the argument). For example, the function call
substring-before(10 div 3, ".")
raises a type error under XPath 2.0, because the arguments to the substring-before
function must be strings
rather than numbers. The XPath 1.0 behavior can be restored by performing an explicit conversion to the required type using a constructor function or cast.
The rules for comparing a node-set to a boolean have changed. In XPath 1.0, an expression such as $node-set = true()
was evaluated by converting the node-set to
a boolean and then performing a boolean comparison: so this expression would return true
if $node-set
was non-empty. In XPath 2.0, this expression
is handled in the same way as other comparisons between a sequence and a singleton: it is true
if $node-set
contains at least one node whose value,
after atomization and conversion to a boolean using the casting rules, is true
.
This means that if $node-set
is empty, the result under XPath 2.0 will be false
regardless of the value of the boolean operand, and regardless of
which operator is used. If $node-set
is non-empty, then in most cases the comparison with a boolean is likely to fail, giving a dynamic error. But if a node has
the value "0", "1", "true", or "false", evaluation of the expression may succeed.
Comparisons of a number to a boolean, a number to a string, or a string to a boolean are not allowed in XPath 2.0: they result in a type error. In XPath 1.0 such comparisons
were allowed, and were handled by converting one of the operands to the type of the other. So for example in XPath 1.0 4 = true()
was true; 4 =
"+4"
was false (because the string +4
converts to NaN
), and false = "false"
was false (because the string "false"
converts to the boolean true
). In XPath 2.0 all these comparisons are type errors.
Additional numeric types have been introduced, with the effect that arithmetic may now be done as an integer, decimal, or single- or double-precision floating point
calculation where previously it was always performed as double-precision floating point. The result of the div
operator when dividing two integers is now a
value of type decimal rather than double. The expression 10 div 0
raises an error rather than returning positive infinity.
The rules for converting numbers to strings have changed. These may affect the way numbers are displayed in the output of a stylesheet. For numbers whose absolute value is
in the range 1E-6 to 1E+6, the result should be the same, but outside this range, scientific format is used for non-integral xs:float
and xs:double
values.
The rules for converting strings to numbers have changed. In addition to the changes that apply when XPath 1.0 compatibility mode is true, when compatibility mode is false
the strings Infinity
and -Infinity
are no longer recognized as representations of positive and negative infinity. Note also that while the
number
function continues to convert all unrecognized strings to NaN
, operations that cast a string to a number react to such strings with a
dynamic error.
Many operations in XPath 2.0 produce an empty sequence as their result when one of the arguments or operands is an empty sequence. Where the operation expects a string, an
empty sequence is usually considered equivalent to a zero-length string, which is compatible with the XPath 1.0 behavior. Where the operation expects a number, however, the
result is not the same. For example, if @width
returns an empty sequence, then in XPath 1.0 the result of @width+1
was NaN
, while with
XPath 2.0 it is ()
. This has the effect that a filter expression such as item[@width+1 != 2]
will select items having no width
attribute under XPath 1.0, and will not select them under XPath 2.0.
The typed value of a comment node, processing instruction node, or namespace node under XPath 2.0 is of type xs:string
, not xs:untypedAtomic
. This
means that no implicit conversions are applied if the value is used in a context where a number is expected. If a processing-instruction node is used as an operand of an
arithmetic operator, for example, XPath 1.0 would attempt to convert the string value of the node to a number (and deliver NaN
if unsuccessful), while XPath 2.0
will report a type error.
In XPath 1.0, it was defined that with an expression of the form A and B
, B would not be evaluated if A was false. Similarly in the case of A or B
,
B would not be evaluated if A was true. This is no longer guaranteed with XPath 2.0: the implementation is free to evaluate the two operands in either order or in parallel.
This change has been made to give more scope for optimization in situations where XPath expressions are evaluated against large data collections supported by indexes.
Implementations may choose to retain backwards compatibility in this area, but they are not obliged to do so.
An XPath expression applied to a document that has been processed against a schema will not always give the same results as the same expression applied to the same document in the absence of a schema. Since schema processing had no effect on the result of an XPath 1.0 expression, this may give rise to further incompatibilities. This section gives a few examples of the differences that can arise.
Suppose that the context node is an element node derived from the following markup: <background color="red green blue"/>
. In XPath 1.0, the predicate
[@color="blue"]
would return false
. In XPath 2.0, if the color
attribute is defined in a schema to be of type xs:NMTOKENS
,
the same predicate will return true
.
Similarly, consider the expression @birth < @death
applied to the element <person birth="1901-06-06" death="1991-05-09"/>
. With
XPath 1.0, this expression would return false, because both attributes are converted to numbers, which returns NaN
in each case. With XPath 2.0, in the presence of a
schema that annotates these attributes as dates, the expression returns true
.
Once schema validation is applied, elements and attributes cannot be used as operands and arguments of expressions that expect a different data type. For example, it is no longer
possible to apply the substring
function to a date to extract the year component, or to a number to extract the integer part. Similarly, if an attribute is annotated
as a boolean then it is not possible to compare it with the strings "true"
or "false"
. All such operations lead to type errors. The remedy when such
errors occur is to introduce an explicit conversion, or to do the computation in a different way. For example, substring-after(@temperature, "-")
might be rewritten
as abs(@temperature)
.
In the case of an XPath 2.0 implementation that provides the static typing feature, many further type errors will be reported in respect of expressions that worked under XPath
1.0. For example, an expression such as round(../@price)
might lead to a static type error because the processor cannot infer statically that ../@price
is guaranteed to be numeric.
Schema validation will in many cases perform whitespace normalization on the contents of elements (depending on their type). This will change the result of operations such as the
string-length
function.
Schema validation augments the data model by adding default values for omitted attributes and empty elements.