W3C XML Schema Definition Language (XSD) 1.1 Part 1: Structures
W3C Recommendation 5 April 2012
- This version:
- http://www.w3.org/TR/2012/REC-xmlschema11-1-20120405/
- Latest version:
- http://www.w3.org/TR/xmlschema11-1/
- Previous version:
- http://www.w3.org/TR/2012/PR-xmlschema11-1-20120119/
- Editors (Version 1.1):
- Shudi (Sandy) Gao 高殊镝, IBM <sandygao@ca.ibm.com>
- C. M. Sperberg-McQueen, Black Mesa Technologies LLC <cmsmcq@blackmesatech.com>
- Henry S. Thompson, University of Edinburgh <ht@inf.ed.ac.uk>
- Editors (Version 1.0):
- Henry S. Thompson, University of Edinburgh <ht@inf.ed.ac.uk>
- Noah Mendelsohn, IBM (retired) <nrm@arcanedomain.com>
- David Beech, Oracle Corporation (retired) <davidbeech@earthlink.net>
- Murray Maloney, Muzmo Communications <murray@muzmo.com>
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, XHTML with changes since version 1.0 marked, XHTML with changes since previous Working Draft marked, Independent copy of the schema for schema documents, Independent copy of the DTD for schema documents, Independent tabulation of components and microcomponents, and List of translations.
Copyright © 2012 W3C® (MIT, ERCIM, Keio), All Rights Reserved. W3C liability, trademark and document use rules apply.
Abstract
This document specifies the XML Schema Definition Language, which offers facilities for describing the structure and constraining the contents of XML documents, including those which exploit the XML Namespace facility. The schema language, which is itself represented in an XML vocabulary and uses namespaces, substantially reconstructs and considerably extends the capabilities found in XML document type definitions (DTDs). This specification depends on XML Schema Definition Language 1.1 Part 2: Datatypes.
Status of this Document
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 W3C Recommendation specifies the W3C XML Schema Definition Language (XSD) 1.1. It is here made available for use by W3C members and the public. XSD 1.1 retains all the essential features of XSD 1.0 but adds several new features to support functionality requested by users, fixes many errors in XSD 1.0, and clarifies wording.
- Some minor errors, typographic and otherwise, have been corrected.
For those primarily interested in the changes since version 1.0, the appendix Changes since version 1.0 (non-normative) (§G) is the recommended starting point. It summarizes both changes made since XSD 1.0 and some changes which were expected (and predicted in earlier drafts of this specification) but have not been made after all. Accompanying versions of this document display in color all changes to normative text since version 1.0 and since the previous Working Draft.
Comments on this document should be made in W3C's public installation of Bugzilla, specifying "XML Schema" as the product. Instructions can be found at http://www.w3.org/XML/2006/01/public-bugzilla. If access to Bugzilla is not feasible, please send your comments to the W3C XML Schema comments mailing list, www-xml-schema-comments@w3.org (archive) and note explicitly that you have not made a Bugzilla entry for the comment. Each Bugzilla entry and email message should contain only one comment.
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.
An implementation report for XSD 1.1 was prepared and used in the Director's decision to publish the previous version of this specification as a Proposed Recommendation. The Director's decision to publish this document as a W3C Recommendation is based on consideration of reviews of the Proposed Recommendation by the public and by the members of the W3C Advisory committee.
The W3C XML Schema Working Group intends to process comments made about this recommendation, with any approved changes being handled as errata to be published separately.
This document has been produced by the W3C XML Schema Working Group as part of the W3C XML Activity. The goals of XSD 1.1 are discussed in the document Requirements for XML Schema 1.1. The authors of this document are the members of the XML Schema Working Group. Different parts of this specification have different editors.
This document was produced by a group operating under the 5 February 2004 W3C Patent Policy. W3C maintains a public list of any patent disclosures made in connection with the deliverables of the group; that page also includes instructions for disclosing a patent. An individual who has actual knowledge of a patent which the individual believes contains Essential Claim(s) must disclose the information in accordance with section 6 of the W3C Patent Policy.
The English version of this specification is the only normative version. Information about translations of this document is available at http://www.w3.org/2003/03/Translations/byTechnology?technology=xmlschema.
Table of Contents
1.1 Introduction to Version 1.1
1.2 Purpose
1.3 Namespaces and Language Identifiers
1.5 Documentation Conventions and Terminology
2 Conceptual Framework
2.1 Overview of XSD
2.2 XSD Abstract Data Model
2.4 Conformance
2.5 Schema-validity and documents
2.6 Names and Symbol Spaces
2.7 Schema-Related Markup in Documents Being Validated 2.8 Representation of Schemas on the World Wide Web
3 Schema Component Details
3.1 Introduction
3.2 Attribute Declarations
3.3 Element Declarations
3.4 Complex Type Definitions
3.5 Attribute Uses
3.6 Attribute Group Definitions
3.7 Model Group Definitions
3.8 Model Groups
3.9 Particles
3.10 Wildcards
3.11 Identity-constraint Definitions
3.12 Type Alternatives
3.13 Assertions
3.14 Notation Declarations
3.15 Annotations
3.16 Simple Type Definitions
3.17 Schemas as a Whole
4 Schemas and Namespaces: Access and Composition
4.1 Layer 1: Summary of the Schema-validity Assessment Core
4.2 Layer 2: Schema Documents, Namespaces and Composition
5.1 Errors in Schema Construction and Structure
5.2 Assessing Schema-Validity
5.3 Missing Sub-components
5.4 Responsibilities of Schema-aware Processors
Appendices
B Outcome Tabulations (normative)
B.1 Validation Rules
B.2 Contributions to the post-schema-validation infoset
B.3 Schema Representation Constraints
B.4 Schema Component Constraints
C Terminology for implementation-defined features (normative)
C.1 Subset of the Post-schema-validation Infoset
C.2 Terminology of schema construction
D Required Information Set Items and Properties (normative)
E Checklists of implementation-defined and implementation-dependent features (normative)
E.1 Checklist of implementation-defined features
E.2 Checklist of implementation-dependent features
F Stylesheets for Composing Schema Documents (Normative)
F.1 Transformation for Chameleon Inclusion
F.2 Transformation for xs:override
G Changes since version 1.0 (non-normative)
G.1 Changes made since version 1.0
H Glossary (non-normative)
I DTD for Schemas (non-normative)
J Analysis of the Unique Particle Attribution Constraint (non-normative)
K XSD Language Identifiers (non-normative)
L References
L.1 Normative
L.2 Non-normative
M Acknowledgements (non-normative)
1 Introduction
This document sets out the structural part of the XML Schema Definition Language.
Chapter 2 presents a Conceptual Framework (§2) for XSD, including an introduction to the nature of XSD schemas and an introduction to the XSD abstract data model, along with other terminology used throughout this document.
Chapter 3, Schema Component Details (§3), specifies the precise semantics of each component of the abstract model, the representation of each component in XML, with reference to a DTD and an XSD schema for an XSD document type, along with a detailed mapping between the elements and attribute vocabulary of this representation and the components and properties of the abstract model.
Chapter 4 presents Schemas and Namespaces: Access and Composition (§4), including the connection between documents and schemas, the import, inclusion and redefinition of declarations and definitions and the foundations of schema-validity assessment.
Chapter 5 discusses Schemas and Schema-validity Assessment (§5), including the overall approach to schema-validity assessment of documents, and responsibilities of schema-aware processors.
The normative appendices include a Schema for Schema Documents (Structures) (normative) (§A) for the XML representation of schemas and Normative (§L.1).
The non-normative appendices include the DTD for Schemas (non-normative) (§I) and a Glossary (non-normative) (§H).
This document is primarily intended as a language definition reference. As such, although it contains a few examples, it is not primarily designed to serve as a motivating introduction to the design and its features, or as a tutorial for new users. Rather it presents a careful and fully explicit definition of that design, suitable for guiding implementations. For those in search of a step-by-step introduction to the design, the non-normative [XML Schema: Primer] is a much better starting point than this document.
1.1 Introduction to Version 1.1
The Working Group has three main goals for this version of W3C XML Schema:
- Significant improvements in simplicity of design and clarity of exposition without loss of backward or forward compatibility;
- Provision of support for versioning of XML languages defined using this specification, including the XML vocabulary specified here for use in schema documents.
- Provision of support for co-occurrence constraints, that is constraints which make the presence of an attribute or element, or the values allowable for it, depend on the value or presence of other attributes or elements.
These goals are in tension with one another. The Working Group's strategic guidelines for changes between versions 1.0 and 1.1 can be summarized as follows:
- Support for versioning (acknowledging that this may be slightly disruptive to the XML transfer syntax at the margins)
- Support for co-occurrence constraints (which will certainly involve additions to the XML transfer syntax, which will not be understood by 1.0 processors)
- Bug fixes (unless in specific cases we decide that the fix is too disruptive for a point release)
- Editorial changes
- Design cleanup will possibly change behavior in edge cases
- Non-disruptive changes to type hierarchy (to better support current and forthcoming international standards and W3C recommendations)
- Design cleanup will possibly change component structure (changes to functionality restricted to edge cases)
- No significant changes in existing functionality
- No changes to XML transfer syntax except those required by version control hooks, co-occurrence constraints and bug fixes
The aim with regard to compatibility is that
- All schema documents conformant to version 1.0 of this specification [XSD 1.0 2E] should also conform to version 1.1, and should have the same ·assessment· behavior across 1.0 and 1.1 implementations (except possibly in edge cases and in the details of the resulting PSVI);
- The vast majority of schema documents conformant to version 1.1 of this specification should also conform to version 1.0, leaving aside any incompatibilities arising from support for versioning or co-occurrence constraints, and when they are conformant to version 1.0 (or are made conformant by the removal of versioning information), should have the same ·assessment· behavior across 1.0 and 1.1 implementations (again except possibly in edge cases and in the details of the resulting PSVI);
1.2 Purpose
The purpose of XML Schema Definition Language: Structures is to define the nature of XSD schemas and their component parts, provide an inventory of XML markup constructs with which to represent schemas, and define the application of schemas to XML documents.
The purpose of an XSD schema is to define and describe a class of XML documents by using schema components to constrain and document the meaning, usage and relationships of their constituent parts: datatypes, elements and their content and attributes and their values. Schemas can also provide for the specification of additional document information, such as normalization and defaulting of attribute and element values. Schemas have facilities for self-documentation. Thus, XML Schema Definition Language: Structures can be used to define, describe and catalogue XML vocabularies for classes of XML documents.
Any application that consumes well-formed XML can use the formalism defined here to express syntactic, structural and value constraints applicable to its document instances. The XSD formalism allows a useful level of constraint checking to be described and implemented for a wide spectrum of XML applications. However, the language defined by this specification does not attempt to provide all the facilities that might be needed by applications. Some applications will require constraint capabilities not expressible in this language, and so will need to perform their own additional validations.
1.3 Namespaces and Language Identifiers
1.3.1.1 The Schema Namespace (xs)
1.3.1.2 The Schema Instance Namespace (xsi)
1.3.1.3 The Schema Versioning Namespace (vc)
1.3.2 Namespaces with Special Status
1.3.3 Conventional Namespace Bindings
1.3.4 Schema Language Identifiers
1.3.1 XSD Namespaces
1.3.1.1 The Schema Namespace (xs)
The XML representation of schema components uses a vocabulary
identified by the namespace name http://www.w3.org/2001/XMLSchema.
For brevity, the text and examples in this specification use
the prefix xs: to stand for this
namespace; in practice, any prefix can be used.
untyped,
untypedAtomic) which are not defined in this
specification; see the [XDM]
specification for details of those types.
Users of the namespaces defined here should be aware, as a matter of namespace policy, that more names in this namespace may be given definitions in future versions of this or other specifications.
1.3.1.2 The Schema Instance Namespace (xsi)
This specification defines
several attributes for direct use in any XML documents, as
described in Schema-Related Markup in Documents Being Validated (§2.7).
These attributes are in the namespace whose name is http://www.w3.org/2001/XMLSchema-instance.
For brevity, the text and examples in this specification use
the prefix xsi: to stand for this namespace; in
practice, any prefix can be used.
Users of the namespaces defined here should be aware, as a matter of namespace policy, that more names in this namespace may be given definitions in future versions of this or other specifications.
1.3.1.3 The Schema Versioning Namespace (vc)
The pre-processing of schema documents described in
Conditional inclusion (§4.2.2) uses
attributes in the namespace
http://www.w3.org/2007/XMLSchema-versioning.
For brevity, the text and examples in this specification use
the prefix vc: to stand for this
namespace; in practice, any prefix can be used.
Users of the namespaces defined here should be aware, as a matter of namespace policy, that more names in this namespace may be given definitions in future versions of this or other specifications.
1.3.2 Namespaces with Special Status
http://www.w3.org/XML/1998/namespacehttp://www.w3.org/2001/XMLSchemahttp://www.w3.org/2001/XMLSchema-instancehttp://www.w3.org/2007/XMLSchema-versioning
Components and source declarations must not specify
http://www.w3.org/2000/xmlns/ as their
target namespace. If they do, then the schema
and/or schema document is in ·error·.
1.3.3 Conventional Namespace Bindings
htmlbound tohttp://www.w3.org/1999/xhtmlmy(in examples) bound to the target namespace of the example schema documentrddlbound tohttp://www.rddl.org/vcbound tohttp://www.w3.org/2007/XMLSchema-versioning(defined in this and related specifications)xhtmlbound tohttp://www.w3.org/1999/xhtmlxlinkbound tohttp://www.w3.org/1999/xlinkxsbound tohttp://www.w3.org/2001/XMLSchema(defined in this and related specifications)xsibound tohttp://www.w3.org/2001/XMLSchema-instance(defined in this and related specifications)xslbound tohttp://www.w3.org/1999/XSL/Transform
In practice, any prefix bound to the appropriate namespace
name may be used (unless otherwise specified by the definition
of the namespace in question, as for xml and
xmlns).
1.3.4 Schema Language Identifiers
Sometimes other specifications or Application Programming Interfaces (APIs) need to refer to the XML Schema Definition Language in general, sometimes they need to refer to a specific version of the language, possibly even to a version defined in a superseded draft. To make such references easy and enable consistent identifiers to be used, we provide the following URIs to identify these concepts.
http://www.w3.org/XML/XMLSchemahttp://www.w3.org/XML/XMLSchema/vX.Yhttp://www.w3.org/XML/XMLSchema/v1.0 identifies
XSD version 1.0 and http://www.w3.org/XML/XMLSchema/v1.1 identifies
XSD version 1.1.
http://www.w3.org/XML/XMLSchema/vX.Y/NeX.Y of
the XSD specification. For example, http://www.w3.org/XML/XMLSchema/v1.0/2e
identifies the second edition of XSD version 1.0.
http://www.w3.org/XML/XMLSchema/vX.Y/Ne/yyyymmddX.Y of
the XSD specification published on the particular date
yyyy-mm-dd. For example,
http://www.w3.org/XML/XMLSchema/v1.0/1e/20001024
identifies the language
defined in the XSD version 1.0 Candidate
Recommendation (CR) published on 24 October 2000, and
http://www.w3.org/XML/XMLSchema/v1.0/2e/20040318
identifies the language
defined in the XSD version 1.0 Second Edition Proposed
Edited Recommendation (PER)
published on 18 March 2004.
Please see XSD Language Identifiers (non-normative) (§K) for a complete list of XML Schema Definition Language identifiers which exist to date.
1.4 Dependencies on Other Specifications
The definition of XML Schema Definition Language: Structures depends on the following specifications: [XML Infoset], [XML Namespaces 1.1], [XPath 2.0], and [XML Schema: Datatypes].
See Required Information Set Items and Properties (normative) (§D) for a tabulation of the information items and properties specified in [XML Infoset] which this specification requires as a precondition to schema-aware processing.
[XML Schema: Datatypes] defines some datatypes which depend on definitions in [XML 1.1] and [XML Namespaces 1.1]; those definitions, and therefore the datatypes based on them, vary between version 1.0 ([XML 1.0], [Namespaces in XML 1.0]) and version 1.1 ([XML 1.1], [XML Namespaces 1.1]) of those specifications. In any given schema-validity-·assessment· episode, the choice of the 1.0 or the 1.1 definition of those datatypes is ·implementation-defined·.
Conforming implementations of this specification may provide either the 1.1-based datatypes or the 1.0-based datatypes, or both. If both are supported, the choice of which datatypes to use in a particular assessment episode should be under user control.
1.5 Documentation Conventions and Terminology
The section introduces the highlighting and typography as used in this document to present technical material.
- notes
- sections explicitly marked non-normative
- examples and their commentary
- informal descriptions of the consequences of rules formally and normatively stated elsewhere (such informal descriptions are typically introduced by phrases like "Informally, ..." or "It is a consequence of ... that ...")
Special terms are defined at their point of introduction in the text. For example [Definition:] a term is something used with a special meaning. The definition is labeled as such and the term it defines is displayed in boldface. The end of the definition is not specially marked in the displayed or printed text. Uses of defined terms are links to their definitions, set off with middle dots, for instance ·term·.
Non-normative examples are set off in boxes and accompanied by a brief explanation:
<schema targetNamespace="http://www.example.com/XMLSchema/1.0/mySchema">
The definition of each kind of schema component consists of a list of its properties and their contents, followed by descriptions of the semantics of the properties:
References to properties of schema components are links to the relevant definition as exemplified above, set off with curly braces, for instance {example property}.
For a given component C, an expression of the form "C.{example property}" denotes the (value of the) property {example property} for component C. The leading "C." (or more) is sometimes omitted, if the identity of the component and any other omitted properties is understood from the context. This "dot operator" is left-associative, so "C.{p1}.{p2}" means the same as "(C.{p1}) . {p2}" and denotes the value of property {p2} within the component or ·property record· which itself is the value of C's {p1} property. White space on either side of the dot operator has no significance and is used (rarely) solely for legibility.
For components C1 and C2, an expression of the form "C1 . {example property 1} = C2 . {example property 2}" means that C1 and C2 have the same value for the property (or properties) in question. Similarly, "C1 = C2" means that C1 and C2 are identical, and "C1.{example property} = C2" that C2 is the value of C1.{example property}.
The correspondence between an element information item which is part of the XML representation of a schema and one or more schema components is presented in a tableau which illustrates the element information item(s) involved. This is followed by a tabulation of the correspondence between properties of the component and properties of the information item. Where context determines which of several different components corresponds to the source declaration, several tabulations, one per context, are given. The property correspondences are normative, as are the illustrations of the XML representation element information items.
In the XML representation, bold-face attribute names (e.g.
count below) indicate a required attribute
information item, and the rest are optional. Where an attribute
information item has an enumerated type definition, the values
are shown separated by vertical bars, as for size
below; if there is a default value, it is shown following a
colon. Where an attribute information item has a built-in simple
type definition defined in [XML Schema: Datatypes], a hyperlink
to
its definition therein is given.
The allowed content of the information item is shown as a
grammar fragment, using the Kleene operators ?,
* and +. Each element name therein is
a hyperlink to its own illustration.
example Element Information ItemReferences to elements in the text are links to the relevant illustration as exemplified above, set off with angle brackets, for instance <example>.
Unless otherwise specified, references to attribute values
are references to the ·actual value· of the attribute information
item in question, not to its ·normalized value· or to other forms
or varieties of "value" associated with it.
For a given element information item E, expressions of the
form "E has att1 = V"
are short-hand for "there is an attribute information
item named att1 among the [attributes] of E and
its ·actual value·
is V."
If the identity of E is clear from context, expressions
of the form "att1 = V"
are sometimes used.
The form "att1 ≠ V" is also used
to specify that the ·actual value· of att1 is
not V.
References to properties of information items as defined in [XML Infoset] are notated as links to the relevant section thereof, set off with square brackets, for example [children].
Properties which this specification defines for information items are introduced as follows:
- [new property]
- The value the property gets.
References to properties of information items defined in this specification are notated as links to their introduction as exemplified above, set off with square brackets, for example [new property].
The "dot operator" described above for components and their properties is also used for information items and their properties. For a given information item I, an expression of the form "I . [new property]" denotes the (value of the) property [new property] for item I.
Lists of normative constraints are typically introduced with phrase like "all of the following are true" (or "... apply"), "one of the following is true", "at least one of the following is true", "one or more of the following is true", "the appropriate case among the following is true", etc. The phrase "one of the following is true" is used in cases where the authors believe the items listed to be mutually exclusive (so that the distinction between "exactly one" and "one or more" does not arise). If the items in such a list are not in fact mutually exclusive, the phrase "one of the following" should be interpreted as meaning "one or more of the following". The phrase "the appropriate case among the following" is used only when the cases are thought by the authors to be mutually exclusive; if the cases in such a list are not in fact mutually exclusive, the first applicable case should be taken. Once a case has been encountered with a true condition, subsequent cases must not be tested.
The following highlighting is used for non-normative commentary in this document:
Within normative prose in this specification, the words may, should, must and must not are defined as follows:
These definitions describe in terms specific to this document the meanings assigned to these terms by [IETF RFC 2119]. The specific wording follows that of [XML 1.1].
Where these terms appear without special highlighting, they are used in their ordinary senses and do not express conformance requirements. Where these terms appear highlighted within non-normative material (e.g. notes), they are recapitulating rules normatively stated elsewhere.
This specification provides a further description of error and of conformant processors' responsibilities with respect to errors in Schemas and Schema-validity Assessment (§5).
2 Conceptual Framework
This chapter gives an overview of XML Schema Definition Language: Structures at the level of its abstract data model. Schema Component Details (§3) provides details on this model, including a normative representation in XML for the components of the model. Readers interested primarily in learning to write schema documents will find it most useful first to read [XML Schema: Primer] for a tutorial introduction, and only then to consult the sub-sections of Schema Component Details (§3) named XML Representation of ... for the details.
2.1 Overview of XSD
An XSD schema is a set of components such as type definitions and element declarations. These can be used to assess the validity of well-formed element and attribute information items (as defined in [XML Infoset]), and furthermore to specify additional information about those items and their descendants. These augmentations to the information set make explicit information that was implicitly present in the original document (or in the original document and the governing schema, taken together), such as normalized and/or default values for attributes and elements and the types of element and attribute information items. The input information set is also augmented with information about the validity of the item, or about other properties described in this specification. [Definition:] We refer to the augmented infoset which results from conformant processing as defined in this specification as the post-schema-validation infoset, or PSVI. Conforming processors may provide access to some or all of the PSVI, as described in Subset of the Post-schema-validation Infoset (§C.1). The mechanisms by which processors provide such access to the PSVI are neither defined nor constrained by this specification.
Throughout this specification, [Definition:] the word assessment is used to refer to the overall process of local validation, recursive determination of validation outcome, and infoset augmentation, i.e. as a short form for "·schema-validity assessment·".
In general, a valid document is a document whose contents obey the constraints expressed in a particular schema. Since a document may be validated against many different schemas, it is often clearer to speak of a document being valid against a particular schema. When this specification is used, document validity can be defined operationally in terms of the ·post-schema-validation infoset· properties on the nodes of the document (in particular [validity]). Several similar but distinct kinds of validity are usefully distinguished, for which terms are defined below in Schema-validity and documents (§2.5).
2.2 XSD Abstract Data Model
2.2.1.1 Type Definition Hierarchy
2.2.1.2 Simple Type Definition
2.2.1.3 Complex Type Definition
2.2.2 Declaration Components
2.2.2.1 Element Declaration
2.2.2.2 Element Substitution Group
2.2.2.3 Attribute Declaration
2.2.2.4 Notation Declaration
2.2.3 Model Group Components
2.2.3.1 Model Group
2.2.3.2 Particle
2.2.3.3 Attribute Use
2.2.3.4 Wildcard
2.2.4 Constraint Components
2.2.4.1 Identity-constraint Definition
2.2.4.2 Type Alternative
2.2.4.3 Assertion
2.2.4.4 Overlapping Functionality of Constraint Components
2.2.5 Group Definition Components
2.2.5.1 Model Group Definition
2.2.5.2 Attribute Group Definition
2.2.6 Annotation Components
This specification builds on [XML 1.1] and [XML Namespaces 1.1]. The concepts and definitions used herein regarding XML are framed at the abstract level of information items as defined in [XML Infoset]. By definition, this use of the infoset provides a priori guarantees of well-formedness (as defined in [XML 1.1]) and namespace conformance (as defined in [XML Namespaces 1.1]) for all candidates for ·assessment· and for all ·schema documents·.
Just as [XML 1.1] and [XML Namespaces 1.1] can be described in terms of information items, XSD schemas can be described in terms of an abstract data model. In defining schemas in terms of an abstract data model, this specification rigorously specifies the information which must be available to a conforming XSD processor. The abstract model for schemas is conceptual only, and does not mandate any particular implementation or representation of this information. To facilitate interoperation and sharing of schema information, a normative XML interchange format for schemas is provided.
[Definition:] Schema component is the generic term for the building blocks that make up the abstract data model of the schema. [Definition:] An XSD schema is a set of ·schema components·. There are several kinds of schema component, falling into three groups. The primary schema components, which may (type definitions) or must (element and attribute declarations) have names, are as follows:
- Simple type definitions
- Complex type definitions
- Attribute declarations
- Element declarations
The secondary schema components, are as follows:
- Attribute group definitions
- Identity-constraint definitions
- Type alternatives
- Assertions
- Model group definitions
- Notation declarations
Finally, the "helper" schema components provide small parts of other schema components; they are dependent on their context:
- Annotations
- Model groups
- Particles
- Wildcards
- Attribute Uses
The name [Definition:] Component covers all the different kinds of schema component defined in this specification.
During ·validation·, [Definition:] declaration components are associated by (qualified) name to information items being ·validated·.
On the other hand, [Definition:] definition components define internal schema components that can be used in other schema components.
[Definition:] Declarations and definitions may and in some cases must have and be identified by names, which are NCNames as defined by [XML Namespaces 1.1].
[Definition:] Several kinds of component have a target namespace, which is either ·absent· or a namespace name, also as defined by [XML Namespaces 1.1]. The ·target namespace· serves to identify the namespace within which the association between the component and its name exists.
An expanded name, as defined in [XML Namespaces 1.1], is a pair consisting of a namespace name, which may be ·absent·, and a local name. The expanded name of any component with both a ·target namespace· property and a ·component name· property is the pair consisting of the values of those two properties. The expanded name of a declaration is used to help determine which information items will be ·governed· by the declaration.
·Validation·, defined in detail in Schema Component Details (§3), is a relation between information items and schema components. For example, an attribute information item is ·validated· with respect to an attribute declaration, a list of element information items with respect to a content model, and so on. The following sections briefly introduce the kinds of components in the schema abstract data model, other major features of the abstract model, and how they contribute to ·validation·.
2.2.1 Type Definition Components
The abstract model provides two kinds of type definition component: simple and complex.
[Definition:] This specification uses the phrase type definition in cases where no distinction need be made between simple and complex types.
Type definitions form a hierarchy with a single root. The subsections below first describe characteristics of that hierarchy, then provide an introduction to simple and complex type definitions themselves.
2.2.1.1 Type Definition Hierarchy
[Definition:] Except for ·xs:anyType·, every ·type definition· is, by construction,
either a ·restriction· or an
·extension· of some
other type definition. The exception
·xs:anyType· is a ·restriction· of itself.
With the exception of the loop on ·xs:anyType·, the
graph of these relationships forms
a tree known as the Type Definition
Hierarchy with ·xs:anyType· as its
root.
[Definition:] The type definition used as the basis
for an ·extension· or
·restriction· is
known as the base type definition of that
definition.
[Definition:]
If a type definition D can reach a type definition B by following
its base type definition chain, then D is said to be
derived from B.
In most cases, a type definition is
derived from other type definitions. The only exception is
·xs:anyType·, which is derived from itself.
[Definition:] A type defined with the same constraints as its ·base type definition·, or with more, is said to be a restriction. The added constraints might include narrowed ranges or reduced alternatives. Given two types A and B, if the definition of A is a ·restriction· of the definition of B, then members of type A are always locally valid against type B as well.
[Definition:] A complex type definition which allows element or attribute content in addition to that allowed by another specified type definition is said to be an extension.
[Definition:] A special complex type definition, (referred to in earlier versions of this specification as 'the ur-type definition') whose name is anyType in the XSD namespace, is present in each ·XSD schema·. The definition of anyType serves as default type definition for element declarations whose XML representation does not specify one.
[Definition:] A special simple type
definition, whose name is error in the XSD
namespace, is also present in each ·XSD schema·. The
XSD error type
has no valid instances. It can be used in any place where
other types are normally used; in particular, it can be used
in conditional type assignment to cause elements which satisfy
certain conditions to be invalid.
For brevity, the text and examples in this specification often
use the qualified names xs:anyType and
xs:error for these type definitions. (In
practice, any appropriately declared prefix can be used, as
described in Schema-Related Markup in Documents Being Validated (§2.7).)
2.2.1.2 Simple Type Definition
A simple type definition is a set of constraints on strings and information about the values they encode, applicable to the ·normalized value· of an attribute information item or of an element information item with no element children. Informally, it applies to the values of attributes and the text-only content of elements.
Each simple type definition, whether built-in (that is,
defined in [XML Schema: Datatypes]) or user-defined, is a ·restriction· of its ·base type definition·.
[Definition:] A
special ·restriction· of
·xs:anyType·, whose name is
anySimpleType in the
XSD namespace, is the root of the ·Type Definition Hierarchy· for all simple type
definitions. ·xs:anySimpleType· has a lexical space containing
all sequences of characters in the Universal Character
Set (UCS) and a value space containing all
atomic values
and all finite-length lists of
atomic values.
As with ·xs:anyType·, this
specification sometimes uses the qualified name
xs:anySimpleType to designate this type
definition. The
built-in list datatypes all have ·xs:anySimpleType· as their
·base type
definition·.
[Definition:] There is a further special datatype
called anyAtomicType, a
·restriction· of
·xs:anySimpleType·, which is the ·base type definition·
of all the primitive
datatypes. This type definition is often referred
to simply as "xs:anyAtomicType".
It too is
considered to have an unconstrained lexical space. Its value
space consists of the union of the value spaces of all the
primitive datatypes.
[Definition:] Datatypes can be constructed from other datatypes by restricting the value space or lexical space of a {base type definition} using zero or more Constraining Facets, by specifying the new datatype as a list of items of some {item type definition}, or by defining it as a union of some specified sequence of {member type definitions}.
The mapping from lexical space to value space is unspecified
for items whose type definition is ·xs:anySimpleType· or ·xs:anyAtomicType·. Accordingly
this specification does not constrain processors'
behavior in areas
where this mapping is implicated, for example checking such
items against enumerations, constructing default attributes or
elements whose declared type definition is ·xs:anySimpleType·
or ·xs:anyAtomicType·,
checking identity constraints involving such items.
[XML Schema: Datatypes]
provides mechanisms for defining new simple type definitions
by ·restricting·
some primitive
or ordinary datatype. It also
provides mechanisms for constructing new simple type
definitions whose members are lists of items
themselves constrained by some other simple type definition, or
whose membership is the union of the memberships of some other
simple type definitions. Such list and union simple type
definitions are also ·restrictions· of
·xs:anySimpleType·.
For detailed information on simple type definitions, see Simple Type Definitions (§3.16) and [XML Schema: Datatypes]. The latter also defines an extensive inventory of pre-defined simple types.
2.2.1.3 Complex Type Definition
A complex type definition is a set of attribute declarations and a content type, applicable to the [attributes] and [children] of an element information item respectively. The content type may require the [children] to contain neither element nor character information items (that is, to be empty), or to be a string which belongs to a particular simple type, or to contain a sequence of element information items which conforms to a particular model group, with or without character information items as well.
xs:anyType· is
either
- a restriction of a complex ·base type definition·
- an ·extension· of a simple or complex ·base type definition·.
all-groups in ways that do not
guarantee that the new material occurs only at the end of
the content. Another
special case is extension via Open Contents in interleave
mode. For detailed information on complex type definitions, see Complex Type Definitions (§3.4).
2.2.2 Declaration Components
There are three kinds of declaration component: element, attribute, and notation. Each is described in a section below. Also included is a discussion of element substitution groups, which is a feature provided in conjunction with element declarations.
2.2.2.1 Element Declaration
An element declaration is an association of a name with a type definition, either simple or complex, an (optional) default value and a (possibly empty) set of identity-constraint definitions. The association is either global or scoped to a containing complex type definition. A top-level element declaration with name 'A' is broadly comparable to a pair of DTD declarations as follows, where the associated type definition fills in the ellipses:
<!ELEMENT A . . .> <!ATTLIST A . . .>
Element declarations contribute to ·validation· as part of model group ·validation·, when their defaults and type components are checked against an element information item with a matching name and namespace, and by triggering identity-constraint definition ·validation·.
For detailed information on element declarations, see Element Declarations (§3.3). For an overview of identity constraints, see Identity-constraint Definition (§2.2.4.1).
2.2.2.2 Element Substitution Group
[Definition:] Through the mechanism of element substitution groups, XSD provides a more powerful model than DTDs do supporting substitution of one named element for another. Any top-level element declaration can serve as the defining member, or head, for an element ·substitution group·. Other top-level element declarations, regardless of target namespace, can be designated as members of the ·substitution group· headed by this element. In a suitably enabled content model, a reference to the head ·validates· not just the head itself, but elements corresponding to any other member of the ·substitution group· as well.
All such members must have type definitions which are either the same as the head's type definition or derived from it. Therefore, although the names of elements can vary widely as new namespaces and members of the ·substitution group· are defined, the content of member elements is constrained by the type definition of the ·substitution group· head.
Note that element substitution groups are not represented as separate components. They are specified in the property values for element declarations (see Element Declarations (§3.3)).
2.2.2.3 Attribute Declaration
An attribute declaration is an association between a name and a simple type definition, together with occurrence information and (optionally) a default value. The association is either global, or local to its containing complex type definition. Attribute declarations contribute to ·validation· as part of complex type definition ·validation·, when their occurrence, defaults and type components are checked against an attribute information item with a matching name and namespace.
For detailed information on attribute declarations, see Attribute Declarations (§3.2).
2.2.2.4 Notation Declaration
A notation declaration is an association between a name and
an identifier for a notation. For an attribute or element information item to
be ·valid· with respect to a
NOTATION simple type definition, its value must
have been declared with a notation declaration.
For detailed information on notation declarations, see Notation Declarations (§3.14).
2.2.3 Model Group Components
The model group, particle, and wildcard components contribute to the portion of a complex type definition that controls an element information item's content.
2.2.3.1 Model Group
A model group is a constraint in the form of a grammar fragment that applies to lists of element information items. It consists of a list of particles, i.e. element declarations, wildcards and model groups. There are three varieties of model group:
- Sequence (the element information items match the particles in sequential order);
- Conjunction (the element information items match the particles, in any order);
- Disjunction (the element information items match one or more of the particles).
Each model group denotes a set of sequences of element information items. Regarding that set of sequences as a language, the set of sequences recognized by a group G may be written L(G). [Definition:] A model group G is said to accept or recognize the members of L(G).
For detailed information on model groups, see Model Groups (§3.8).
2.2.3.2 Particle
A particle is a term in the grammar for element content, consisting of either an element declaration, a wildcard or a model group, together with occurrence constraints. Particles contribute to ·validation· as part of complex type definition ·validation·, when they allow anywhere from zero to many element information items or sequences thereof, depending on their contents and occurrence constraints.
The name [Definition:] Term is used to refer to any of the three kinds of components which can appear in particles. All ·Terms· are themselves ·Annotated Components·. [Definition:] A basic term is an Element Declaration or a Wildcard. [Definition:] A basic particle is a Particle whose {term} is a ·basic term·.
Each content model, indeed each particle and each term, denotes a set of sequences of element information items. Regarding that set of sequences as a language, the set of sequences recognized by a particle P may be written L(P). [Definition:] A particle P is said to accept or recognize the members of L(P). Similarly, a term T accepts or recognizes the members of L(T).
If a sequence S is a member of L(P), then it is necessarily possible to trace a path through the ·basic particles· within P, with each item within S corresponding to a matching particle within P. The sequence of particles within P corresponding to S is called the ·path· of S in P.
For detailed information on particles, see Particles (§3.9).
2.2.3.3 Attribute Use
An attribute use plays a role similar to that of a particle, but for attribute declarations: an attribute declaration used by a complex type definition is embedded within an attribute use, which specifies whether the declaration requires or merely allows its attribute, and whether it has a default or fixed value.
2.2.3.4 Wildcard
A wildcard is a special kind of particle which matches element and attribute information items dependent on their namespace names and optionally on their local names.
For detailed information on wildcards, see Wildcards (§3.10).
2.2.4 Constraint Components
This section describes constructs which use [XPath 2.0] expressions to constrain the input document; using them, certain rules can be expressed conveniently which would be inconvenient or impossible to express otherwise. Identity-constraint definitions are associated with element declarations; assertions are associated with type definitions; conditional type assignment using type alternatives allows the type of an element instance to be chosen based on properties of the element instance (in particular, based on the values of its attributes).
2.2.4.1 Identity-constraint Definition
An identity-constraint definition is an association between a name and one of several varieties of identity-constraint related to uniqueness and reference. All the varieties use [XPath 2.0] expressions to pick out sets of information items relative to particular target element information items which are unique, or a key, or a ·valid· reference, within a specified scope. An element information item is only ·valid· with respect to an element declaration with identity-constraint definitions if those definitions are all satisfied for all the descendants of that element information item which they pick out.
For detailed information on identity-constraint definitions, see Identity-constraint Definitions (§3.11).
2.2.4.2 Type Alternative
A Type Alternative component (type alternative for short) associates a type definition with a predicate. Type alternatives are used in conditional type assignment, in which the choice of ·governing type definition· for elements governed by a particular element declaration depends on properties of the document instance. An element declaration may have a {type table} which contains a sequence of type alternatives; the predicates on the alternatives are tested, and when a predicate is satisfied, the type definition paired with it is chosen as the element instance's ·governing type definition·.
For detailed information on Type Alternatives, see Type Alternatives (§3.12).
2.2.4.3 Assertion
An assertion is a predicate associated with a type, which is checked for each instance of the type. If an element or attribute information item fails to satisfy an assertion associated with a given type, then that information item is not locally ·valid· with respect to that type.
For detailed information on Assertions, see Assertions (§3.13).
2.2.4.4 Overlapping Functionality of Constraint Components
Many rules that can be enforced by identity constraints and conditional type assignment can also be formulated in terms of assertions. That is, the various constructs have overlapping functionality. The three forms of constraint differ from each other in various ways which may affect the schema author's choice of formulation.
Most obviously, the ·post-schema-validation infoset· will differ somewhat, depending on which form of constraint is chosen.
Less obviously, identity constraints are associated with element declarations, while assertions are associated with type definitions. If it is desired to enforce a particular property of uniqueness or referential integrity associated with a particular element declaration E, of type T, the schema author may often choose either an identity constraint associated with E, or an assertion associated with T. One obvious difference is that elements substitutable for E are required to have types derived from T, but are not required to enforce the identity constraints (or the nillability) of E. If the constraint applicable to E should be enforced by elements substitutable for E, it is often most convenient to formulate the constraint as an assertion on T; conversely, if only some elements of type T are intended to be subject to the constraint, or if elements substitutable for E need not enforce the constraint, then it will be more convenient to formulate the rule as an identity constraint on E.
Similar considerations sometimes apply to the choice between assertions and conditional type assignment.
Because identity constraints and conditional type assignment are simpler and less variable than assertions, it may be easier for software to exploit or optimize them. Assertions have greater expressive power, which means they are often convenient. The "rule of least power" applies here; it is often preferable to use a less expressive notation in preference to a more expressive one, when either will suffice. See [Rule of Least Power].
2.2.5 Group Definition Components
There are two kinds of convenience definitions provided to enable the re-use of pieces of complex type definitions: model group definitions and attribute group definitions.
2.2.5.1 Model Group Definition
A model group definition is an association between a name and a model group, enabling re-use of the same model group in several complex type definitions.
For detailed information on model group definitions, see Model Group Definitions (§3.7).
2.2.5.2 Attribute Group Definition
An attribute group definition is an association between a name and a set of attribute declarations, enabling re-use of the same set in several complex type definitions.
For detailed information on attribute group definitions, see Attribute Group Definitions (§3.6).
2.2.6 Annotation Components
An annotation is information for human and/or mechanical consumers. The interpretation of such information is not defined in this specification.
For detailed information on annotations, see Annotations (§3.15).
2.3 Constraints and Validation Rules
The [XML 1.1] specification describes two kinds of constraints on XML documents: well-formedness and validity constraints. Informally, the well-formedness constraints are those imposed by the definition of XML itself (such as the rules for the use of the < and > characters and the rules for proper nesting of elements), while validity constraints are the further constraints on document structure provided by a particular DTD.
The preceding section focused on ·validation·, that is the constraints on information items which schema components supply. In fact however this specification provides four different kinds of normative statements about schema components, their representations in XML and their contribution to the ·validation· of information items:
The last of these, schema information set contributions, are
not as new as they might at first seem. XML validation augments the XML information set in similar
ways, for example by providing values for attributes not present
in instances, and by implicitly exploiting type information for
normalization or access. (As an example of the latter case,
consider the effect of NMTOKENS on attribute white
space, and the semantics of ID and
IDREF.) By including schema information set
contributions, this specification makes explicit some features
that XML leaves implicit.
2.4 Conformance
Within the context of this specification, conformance can be claimed for schema documents, for schemas, and for processors.
If the schema document is invalid only in consequence of invalid descendants of <annotation> elements, processors may treat the schema document as valid. It is ·implementation-defined· what effect, if any, invalid <annotation> elements have on the construction of schema components.
A schema conforms to this specification if and only if it consists of components which individually and collectively satisfy all the relevant constraints specified in this document, including but not limited to all the ·Schema Component Constraints·.
This specification distinguishes several classes of conforming processors, which are defined in terms of the following concepts.
[Definition:] A validator (or instance validator) is a processor which ·validates· an XML instance document against a conforming schema and distinguishes between valid documents and others, for one or more of the definitions of validity (·root-validity·, ·deep validity·, or ·uniform validity·) defined below in section Schema-validity and documents (§2.5). Conforming validators may additionally support other definitions of validity defined in terms of the ·post-schema-validation infoset·.
[Definition:] A schema-validity assessor (or just assessor) is a processor which performs full or partial ·schema-validity assessment· of an XML instance document, element information item, or attribute information item, with reference to a conforming schema, and provides access to the entirety of the resulting ·post-schema-validation infoset·. The means by which an ·assessor· provides access to the ·post-schema-validation infoset· is ·implementation-defined·.
[Definition:] A general-purpose processor is a ·validator· or ·assessor· which accepts schemas represented in the form of XML documents as described in Layer 2: Schema Documents, Namespaces and Composition (§4.2).
<include>) (§4.2.3).
[Definition:] A schema processor which is not a ·general-purpose· processor is a special-purpose processor.
[Definition:] Web-aware processors are network-enabled processors which are not only ·general-purpose· but which additionally must be capable of accessing schema documents from the World Wide Web as described in Representation of Schemas on the World Wide Web (§2.8) and How schema definitions are located on the Web (§4.3.2). .
Several important classes of processor can be defined in terms of the concepts just given:
A claim that a processor conforms to this specification must specify to which processor classes defined here the processor belongs.
See Checklist of implementation-defined features (§E.1) and Terminology for implementation-defined features (normative) (§C) for terminology and concepts which may be helpful in defining the behavior of conforming processors and/or claiming conformance to this specification.
2.5 Schema-validity and documents
As noted above, in general a document is valid against a particular schema if it obeys the constraints imposed by that schema. Depending on the nature of the application and on the specific invariants to be enforced, different forms of validity may be appropriately required by an application, a specification, or other users of XSD. This section defines terminology for use in describing the requirements of applications or other technologies which use XSD schema to describe constraints on XML documents.
All the terms defined below require that the document's root element be ·assessed· using either ·element-driven validation· (when the intended root element of the schema is clearly specified ) or else ·strict wildcard validation· (if several different root elements are acceptable).
2.6 Names and Symbol Spaces
As discussed in XSD Abstract Data Model (§2.2), most schema components (may) have ·names·. If all such names were assigned from the same "pool", then it would be impossible to have, for example, a simple type definition and an element declaration both with the name "title" in a given ·target namespace·.
Therefore [Definition:] this specification introduces the term symbol
space to denote a collection of names, each of which is
unique with respect to the others.
Within a given schema there are distinct symbol spaces
for each kind of named definition and declaration component identified
in XSD Abstract Data Model (§2.2), except that
simple type definitions and complex type definitions share a
symbol space. Within a given symbol space, names
must be unique;
as a consequence, each expanded name within a given
symbol space uniquely identifies a single component.
The same expanded name may however appear in more than one symbol space without
conflict. For example, assuming that the namespace prefix
my is bound to some particular namespace,
both a simple type definition and a top-level element declaration
can bear the name my:abc without conflict or
necessary relation between the two. But it is not possible
for both a simple type definition and a complex type
definition, or two distinct top-level element declarations,
to share the name my:abc.
Locally scoped attribute and element declarations are special with regard to symbol spaces. Their names are not included in the global symbol spaces for attribute and element names; each complex type definition defines its own attribute symbol space, and elements local to a complex type definition are constrained by Element Declarations Consistent (§3.8.6.3), but not by means of symbol spaces. Their names are not regarded as being in any particular symbol space. So, for example, two complex type definitions having the same target namespace can contain a local attribute declaration for the unqualified name "priority", or contain a local element declaration for the name "address", without conflict or necessary relation between the two.
2.7 Schema-Related Markup in Documents Being Validated
XML Schema Definition Language: Structures defines
several attributes for direct use in any XML documents. These
attributes are in the schema instance namespace
(http://www.w3.org/2001/XMLSchema-instance) described in The Schema Instance Namespace (xsi) (§1.3.1.2) above. All schema processors
must
have appropriate attribute declarations for these attributes
built in, see Attribute Declaration for the 'type' attribute (§3.2.7.1),
Attribute Declaration for the 'nil' attribute (§3.2.7.2), Attribute Declaration for the 'schemaLocation' attribute (§3.2.7.3) and
Attribute Declaration for the 'noNamespaceSchemaLocation' attribute (§3.2.7.4).
xsi:type",
"xsi:nil", etc. This is shorthand for
"an attribute information item whose [namespace
name] is
http://www.w3.org/2001/XMLSchema-instance and whose [local
name] is type" (or
nil, etc.).
2.7.1 xsi:type
The Simple Type Definition (§2.2.1.2) or Complex Type Definition (§2.2.1.3) used in ·validation· of an element is usually
determined by reference to the appropriate schema components. An
element information item in an instance may, however,
explicitly assert its type using the attribute
xsi:type. The value of this attribute is a ·QName·; see QName resolution (Instance) (§3.17.6.3) for the means by which the ·QName· is associated with a type
definition.
2.7.2 xsi:nil
XML Schema Definition Language: Structures introduces a mechanism for signaling that an element
must be accepted as ·valid·
when it has no content despite a content type which does not
require or even necessarily allow empty content. An element
can be ·valid·
without content if it has the attribute xsi:nil
with the value true. An element so labeled must
be empty, but can carry attributes if permitted by the
corresponding complex type.
2.7.3 xsi:schemaLocation, xsi:noNamespaceSchemaLocation
The xsi:schemaLocation and
xsi:noNamespaceSchemaLocation attributes can be
used in a document to provide hints as to the physical location
of schema documents which can be used for ·assessment·. See How schema definitions are located on the Web (§4.3.2) for details on the use of these
attributes.
xsi:schemaLocation attribute typically appears
in XML document instances being ·validated·; it is distinct from
the schemaLocation attribute defined for some
elements in schema documents (which is not always a hint
but sometimes a firm directive). 2.8 Representation of Schemas on the World Wide Web
On the World Wide Web, schemas are conventionally represented
as XML documents (preferably of MIME type
application/xml or text/xml, but see
clause 1.1 of Inclusion Constraints and Semantics (§4.2.3)),
conforming to the specifications in Layer 2: Schema Documents, Namespaces and Composition (§4.2). For
more information on the representation and use of schema
documents on the World Wide Web
see Standards for representation of schemas and retrieval of schema documents on the Web (§4.3.1) and
How schema definitions are located on the Web (§4.3.2).
3 Schema Component Details
3.1 Introduction
3.1.2 XML Representations of Components
3.1.3 The Mapping between XML Representations and Components
3.1.4 White Space Normalization during Validation
- properties: their values and significance
- XML representation and the mapping to properties
- constraints on representation
- validation rules
- ·post-schema-validation infoset· contributions
- constraints on the components themselves
3.1.1 Components and Properties
Components are defined in terms of their properties, and each property in turn is defined by giving its range, that is the values it may have. This can be understood as defining a schema as a labeled directed graph, where the root is a schema, every other vertex is a schema component or a literal (string, boolean, decimal) and every labeled edge is a property. The graph is not acyclic: multiple copies of components with the same name in the same ·symbol space· must not exist, so in some cases re-entrant chains of properties will exist.
Component properties are simply named values. Most properties have either other components or literals (that is, strings or booleans or enumerated keywords) for values, but in a few cases, where more complex values are involved, [Definition:] a property value may itself be a collection of named values, which we call a property record.
[Definition:] Throughout this specification, the term absent is used as a distinguished property value denoting absence. Again this should not be interpreted as constraining implementations, as for instance between using a null value for such properties or not representing them at all. [Definition:] A property value which is not ·absent· is present.
Any property not defined as optional is always present; optional properties which are not present are taken to have ·absent· as their value. Any property identified as a having a set, subset or list value might have an empty value unless this is explicitly ruled out: this is not the same as ·absent·. Any property value identified as a superset or subset of some set might be equal to that set, unless a proper superset or subset is explicitly called for. By 'string' in Part 1 of this specification is meant a sequence of ISO 10646 characters identified as legal XML characters in [XML 1.1].
3.1.2 XML Representations of Components
The principal purpose of XML Schema Definition Language: Structures is to define a set of schema
components that constrain the contents of instances and augment
the information sets thereof. Although no external
representation of schemas is required for this purpose, such
representations will obviously be widely used. To provide for
this in an appropriate and interoperable way, this specification
provides a normative XML representation for schemas which makes
provision for every kind of schema component. [Definition:] A document in this
form (i.e. a <schema> element information item)
is a schema document. For the schema
document as a whole, and its constituents, the sections below
define correspondences between element information items (with
declarations in
Schema for Schema Documents (Structures) (normative) (§A) and DTD for Schemas (non-normative) (§I)) and schema components. The key element information items in
the XML representation of a schema are in the XSD namespace, that
is their [namespace
name] is
http://www.w3.org/2001/XMLSchema. Although a common way of creating
the XML Infosets which are or contain ·schema documents· will be
using an XML parser, this is not required: any mechanism which
constructs conformant infosets as defined in [XML Infoset] is a possible starting
point.
- All of them allow attributes qualified with namespace names other than the XSD namespace itself: these appear as annotations in the corresponding schema component;
- All of them allow an <annotation> as their first child, for human-readable documentation and/or machine-targeted information.
A recurrent pattern in the XML
representation of schemas may also be mentioned here. In many
cases, the same element name (e.g. element or
attribute or attributeGroup), serves
both to define a particular schema component and to incorporate
it by reference. In the first case the name
attribute is required, in the second the ref
attribute is required. These
two usages are mutually exclusive, and sometimes also depend on
context.
The descriptions of the XML representation
of components, and the ·Schema Representation
Constraints·, apply to schema documents after,
not before, the
·conditional-inclusion pre-processing·
described in Conditional inclusion (§4.2.2) and the
·chameleon pre-processing·
described in Assembling a schema for a single target namespace from
multiple schema definition documents
(<include>) (§4.2.3).
3.1.3 The Mapping between XML Representations and Components
For each kind of schema component there is a corresponding normative XML representation. The sections below describe the correspondences between the properties of each kind of schema component on the one hand and the properties of information items in that XML representation on the other, together with constraints on that representation above and beyond those expressed in the Schema for Schema Documents (Structures) (normative) (§A). Neither the correspondences described nor the XML Representation Constraints apply to elements in the Schema namespace which occur as descendants of <appinfo> or <documentation>.
The language used is as if the correspondences were mappings from XML representation to schema component, but the mapping in the other direction, and therefore the correspondence in the abstract, can always be constructed therefrom.
In discussing the mapping from XML representations to schema components below, the value of a component property is often determined by the value of an attribute information item, one of the [attributes] of an element information item. Since schema documents are constrained by the Schema for Schema Documents (Structures) (normative) (§A), there is always a simple type definition associated with any such attribute information item. [Definition:] With reference to any string, interpreted as denoting an instance of a given datatype, the term actual value denotes the value to which the lexical mapping of that datatype maps the string. In the case of attributes in schema documents, the string used as the lexical representation is normally the ·normalized value· of the attribute. The associated datatype is, unless otherwise specified, the one identified in the declaration of the attribute, in the schema for schema documents; in some cases (e.g. the enumeration facet, or fixed and default values for elements and attributes) the associated datatype will be a more specific one, as specified in the appropriate XML mapping rules. The ·actual value· will often be a string, but can also be an integer, a boolean, a URI reference, etc. This term is also occasionally used with respect to element or attribute information items in a document being ·assessed·.
Many properties are identified below as having other schema components or sets of components as values. For the purposes of exposition, the definitions in this section assume that (unless the property is explicitly identified as optional) all such values are in fact present. When schema components are constructed from XML representations involving reference by name to other components, this assumption will in some cases be violated if one or more references cannot be ·resolved·. This specification addresses the matter of missing components in a uniform manner, described in Missing Sub-components (§5.3): no mention of handling missing components will be found in the individual component descriptions below.
Forward reference to named definitions and declarations is allowed, both within and between ·schema documents·. By the time the component corresponding to an XML representation which contains a forward reference is actually needed for ·validation·, it is possible that an appropriately-named component will have become available to discharge the reference: see Schemas and Namespaces: Access and Composition (§4) for details.
3.1.4 White Space Normalization during Validation
Throughout this specification, [Definition:] the initial value of some attribute information item is the value of the [normalized value] property of that item. Similarly, the initial value of an element information item is the string composed of, in order, the [character code] of each character information item in the [children] of that element information item.
The above definition means that comments and processing instructions, even in the midst of text, are ignored for most ·validation· purposes. For the exception to this rule, see the discussion of comments and processing instructions in Assertion Satisfied (§3.13.4.1).
#x9 (tab),
#xA (line feed) and #xD (carriage
return) are replaced with #x20
(space).#x20s are collapsed to a single
#x20, and initial and/or final
#x20s are deleted.When more than one pre-lexical facet applies, the whiteSpace facet is applied first; the order in which ·implementation-defined· facets are applied is ·implementation-defined·.
If the simple type definition used in an item's
·validation· is ·xs:anySimpleType·,
then the
·normalized value· must be determined
as in the preserve case above.
There are three alternative validation rules which help supply the necessary background for the above: Attribute Locally Valid (§3.2.4.1) (clause 3), Element Locally Valid (Type) (§3.3.4.4) (clause 3.1.3) or Element Locally Valid (Complex Type) (§3.4.4.2) (clause 1.2).
These three levels of normalization correspond to the processing mandated in XML for element content, CDATA attribute content and tokenized attributed content, respectively. See Attribute Value Normalization in [XML 1.1] for the precedent for replace and collapse for attributes. Extending this processing to element content is necessary to ensure consistent ·validation· semantics for simple types, regardless of whether they are applied to attributes or elements. Performing it twice in the case of attributes whose [normalized value] has already been subject to replacement or collapse on the basis of information in a DTD is necessary to ensure consistent treatment of attributes regardless of the extent to which DTD-based information has been made use of during infoset construction.
3.2 Attribute Declarations
3.2.2 XML Representation of Attribute Declaration Schema Components
3.2.2.1 Mapping Rules for Global Attribute Declarations
3.2.2.2 Mapping Rules for Local Attribute Declarations
3.2.2.3 Mapping Rules for References to Top-level Attribute Declarations
3.2.3 Constraints on XML Representations of Attribute Declarations
3.2.4 Attribute Declaration Validation Rules
3.2.4.1 Attribute Locally Valid
3.2.4.2 Governing Attribute Declaration and Governing Type Definition
3.2.4.3 Schema-Validity Assessment (Attribute)
3.2.5 Attribute Declaration Information Set Contributions
3.2.5.1 Assessment Outcome (Attribute)
3.2.5.2 Validation Failure (Attribute)
3.2.5.3 Attribute Declaration
3.2.5.4 Attribute Validated by Type
3.2.6 Constraints on Attribute Declaration Schema Components
3.2.6.1 Attribute Declaration Properties Correct
3.2.6.2 Simple Default Valid
3.2.6.3 xmlns Not Allowed
3.2.6.4 xsi: Not Allowed
3.2.7 Built-in Attribute Declarations
3.2.7.1 xsi:type
3.2.7.2 xsi:nil
3.2.7.3 xsi:schemaLocation
3.2.7.4 xsi:noNamespaceSchemaLocation
Attribute declarations provide for:
- Local ·validation· of attribute information item values using a simple type definition;
- Specifying default or fixed values for attribute information items.
<xs:attribute name="age" type="xs:positiveInteger" use="required"/>
3.2.1 The Attribute Declaration Schema Component
The attribute declaration schema component has the following properties:
The {name} property must match the local part of the names of attributes being ·validated·.
The value of each attribute validated must conform to the supplied {type definition}.
A ·non-absent· value of the {target namespace} property provides for ·validation· of namespace-qualified attribute information items (which must be explicitly prefixed in the character-level form of XML documents). ·Absent· values of {target namespace} ·validate· unqualified (unprefixed) items.
For an attribute declaration A, if A.{scope}.{variety} = global, then A is available for use throughout the schema. If A.{scope}.{variety} = local, then A is available for use only within (the Complex Type Definition or Attribute Group Definition) A.{scope}.{parent}.
The
{value constraint} property reproduces the functions of
XML default and
#FIXED attribute values. A {variety} of
default specifies that the attribute is to
appear unconditionally in the ·post-schema-validation infoset·, with {value} and {lexical form} used whenever the attribute is not
actually present; fixed indicates that the attribute
value if present must be equal or identical
to {value}, and if absent receives {value} and {lexical form} as for default. Note that
it is values that are checked, not
strings,
and that the test is for either equality or identity.
See Annotations (§3.15) for information on the role of the {annotations} property.
[XML Infoset] distinguishes attributes with names such as xmlns or xmlns:xsl from
ordinary attributes, identifying them as [namespace attributes]. Accordingly, it is unnecessary and in fact not possible for
schemas to contain attribute declarations corresponding to such
namespace declarations, see xmlns Not Allowed (§3.2.6.3). No means is provided in
this specification to supply a
default value for a namespace declaration.
3.2.2 XML Representation of Attribute Declaration Schema Components
The XML representation for an attribute declaration schema component is an <attribute> element information item. It specifies a simple type definition for an attribute either by reference or explicitly, and may provide default information. The correspondences between the properties of the information item after the appropriate ·pre-processing· and the properties of the component are given in this section.
Attribute declarations can appear at the top level of a schema
document, or within complex type definitions, either as complete
(local) declarations, or by reference to top-level declarations,
or within attribute group definitions. For complete
declarations, top-level or local, the type
attribute is used when the declaration can use a built-in or
pre-declared simple type definition. Otherwise an anonymous
<simpleType> is provided inline. When no simple type definition is
referenced or provided, the default is ·xs:anySimpleType·, which
imposes no constraints at all.
attribute Element Information Itemdefault = string
fixed = string
form = (qualified | unqualified)
id = ID
name = NCName
ref = QName
targetNamespace = anyURI
type = QName
use = (optional | prohibited | required) : optional
inheritable = boolean
{any attributes with non-schema namespace . . .}>
Content: (annotation?, simpleType?)
</attribute>
An <attribute> element maps to an attribute declaration, and allows the type definition of that declaration to be specified either by reference or by explicit inclusion.
Top-level
<attribute> elements
(i.e. those which appear
within the schema document as
children of
<schema>
elements) produce
global attribute declarations;
<attribute>s
within
<attributeGroup> or <complexType> produce
either attribute uses which contain global attribute
declarations (if there's a ref attribute) or local
declarations (otherwise). For complete declarations, top-level or local,
the type attribute is used when the declaration can use a
built-in or user-defined global type definition. Otherwise an anonymous
<simpleType> is provided inline.
<override>) (§4.2.5) for details.
Attribute information items ·validated· by a top-level
declaration must be qualified with the
{target namespace} of that
declaration. If the
{target namespace} is ·absent·, the item must be
unqualified. Control over whether attribute
information items ·validated· by a local declaration must be
similarly qualified or not is provided by the form
[attribute], whose default is provided by the
attributeFormDefault [attribute] on the enclosing
<schema>, via its determination of
{target namespace}.
The names for top-level attribute declarations are in their own ·symbol space·. The names of locally-scoped attribute declarations reside in symbol spaces local to the type definition which contains them.
- If the <attribute> element information item has <schema> as its parent, then it maps to a global Attribute Declaration as described in Mapping Rules for Global Attribute Declarations (§3.2.2.1).
- If the <attribute> element information item has <complexType> or <attributeGroup> as an ancestor, and the
ref[attribute] is absent, and theuse[attribute] is not"prohibited", then it maps both to an Attribute Declaration and to an Attribute Use component, as described in Mapping Rules for Local Attribute Declarations (§3.2.2.2).On Attribute Use components, see Attribute Uses (§3.5). - If the <attribute> element information item has <complexType> or <attributeGroup> as an ancestor, and the
ref[attribute] is ·present·, and theuse[attribute] is not"prohibited", then it maps to an Attribute Use component, as described in Mapping Rules for References to Top-level Attribute Declarations (§3.2.2.3). - If the <attribute> element information item has
use='prohibited', then it does not map to, or correspond to, any schema component at all.Note: Theuseattribute is not allowed on top-level <attribute> elements, so this can only happen with <attribute> elements appearing within a <complexType> or <attributeGroup> element.
3.2.2.1 Mapping Rules for Global Attribute Declarations
If the <attribute> element information item has <schema> as its parent, the corresponding schema component is as follows:
targetNamespace [attribute] of the parent
<schema> element information item, or ·absent· if there is none.type [attribute], if present, otherwise
·xs:anySimpleType·.default or a fixed [attribute],
then a Value Constraint as follows, otherwise ·absent·.
3.2.2.2 Mapping Rules for Local Attribute Declarations
If
the <attribute> element information item has
<complexType> or <attributeGroup> as
an ancestor and the ref [attribute] is absent,
it maps both to an attribute
declaration (see below) and
to an attribute use with properties as follows
(unless use='prohibited', in which case the item
corresponds to nothing at all):
default or a fixed [attribute],
then a Value Constraint
as follows, otherwise ·absent·.
The <attribute> element also maps to the {attribute declaration} of the attribute use, as follows:
targetNamespace is present
, then
its ·actual value·.
targetNamespace is not present and
one of the following is trueform
= qualified
form is absent and the <schema> ancestor has
attributeFormDefault =
qualified
targetNamespace
[attribute] of the ancestor <schema>
element information
item, or ·absent· if there
is none.
type [attribute], if present, otherwise
·xs:anySimpleType·.3.2.2.3 Mapping Rules for References to Top-level Attribute Declarations
If
the
<attribute> element information item has
<complexType> or <attributeGroup> as an
ancestor and the ref [attribute] is
present, it
maps to an attribute use with properties as follows
(unless use='prohibited', in which case the item
corresponds to nothing at all):
use =
required, otherwise
false.default or a fixed [attribute],
then a Value Constraint
as follows, otherwise ·absent·.
inheritable [attribute], if present, otherwise
{attribute declaration}.{inheritable}.3.2.3 Constraints on XML Representations of Attribute Declarations
default and fixed must not both be present.default and use are both present,
use must have the ·actual value· optional.ref or name is present, but not both.ref is present, then all of <simpleType>,
form and type are absent.type attribute and a
<simpleType> child element
must not both be present.fixed and use are both present,
use must not have the ·actual value· prohibited.
targetNamespace attribute
is present then
all of the following must be true:name attribute
is present.
form attribute
is absent.
targetNamespace [attribute] or its ·actual value·
is different from the ·actual value· of targetNamespace of
<attribute>, then
all of the following are true:base [attribute] of
<restriction> does not
·match· the
name of ·xs:anyType·.
3.2.4 Attribute Declaration Validation Rules
3.2.4.1 Attribute Locally Valid
Informally, an attribute in an XML
instance is locally ·valid·
against an attribute declaration if and only if (a)
the name of the attribute matches
the name of the declaration, (b) after
whitespace normalization its ·normalized value· is locally valid
against the type declared for the attribute, and
(c) the
attribute obeys any relevant value constraint. Additionally,
for xsi:type, it is required that the type named
by the attribute be present in the schema.
A logical prerequisite for checking the local validity of an
attribute against an attribute declaration is that the attribute
declaration itself and the type definition it identifies
both be present in the schema.
Local validity of attributes is tested as part of schema-validity ·assessment· of attributes (and of the elements on which they occur), and the result of the test is exposed in the [validity] property of the ·post-schema-validation infoset·.
A more formal statement is given in the following constraint.
xsi:type
(Attribute Declaration for the 'type' attribute (§3.2.7.1)), then A's ·actual value·
·resolves· to a type definition.
3.2.4.2 Governing Attribute Declaration and Governing Type Definition
xsi:type, xsi:nil,
xsi:schemaLocation, or
xsi:noNamespaceSchemaLocation are always governed by
their corresponding built-in declarations (see
Built-in Attribute Declarations (§3.2.7)).
3.2.4.3 Schema-Validity Assessment (Attribute)
Schema-validity assessment of an attribute information item involves identifying its ·governing attribute declaration· and checking its local validity against the declaration. If the ·governing type definition· is not present in the schema, then assessment is necessarily incomplete.
[Definition:] For attribute information items, there is no difference between assessment and strict assessment, so the attribute information item has been strictly assessed if and only if its schema-validity has been assessed.
3.2.5 Attribute Declaration Information Set Contributions
3.2.5.1 Assessment Outcome (Attribute)
- [validation context]
- The nearest ancestor element information item with a [schema information] property.
- [validity]
-
The appropriate case among the following:1 If it was ·strictly assessed·, then the appropriate case among the following:1.1 If it was locally ·valid· as defined by Attribute Locally Valid (§3.2.4.1), then valid;1.2 otherwise invalid.2 otherwise notKnown.
- [validation attempted]
-
The appropriate case among the following:1 If it was ·strictly assessed·, then full;2 otherwise none.
- [schema specified]
- infoset. See Attribute Default Value (§3.4.5.1) for the other possible value.
3.2.5.2 Validation Failure (Attribute)
- [schema error code]
-
The appropriate case among the following:1 If the item is ·invalid·, then a list. Applications wishing to provide information as to the reason(s) for the ·validation· failure are encouraged to record one or more error codes (see Outcome Tabulations (normative) (§B)) herein.2 otherwise ·absent·.
3.2.5.3 Attribute Declaration
- [attribute declaration]
- An ·item isomorphic· to the ·governing· declaration component itself.
- [schema default]
- If the attribute information item is ·attributed· to an Attribute Use then the {lexical form} of the ·effective value constraint·, otherwise the {lexical form} of the declaration's {value constraint}.
3.2.5.4 Attribute Validated by Type
- [schema normalized value]
- If the attribute's ·normalized value· is ·valid· with respect to the ·governing type definition·, then the ·normalized value· as ·validated·, otherwise ·absent·.
- [schema actual value]
- If the [schema normalized value] is not ·absent·, then the corresponding ·actual value·; otherwise ·absent·.
- [type definition]
- An ·item isomorphic· to the ·governing type definition· component.
- [type definition type]
- simple.
- [type definition namespace]
- The {target namespace} of the ·type definition·.
- [type definition anonymous]
- true if the {name} of the ·type definition· is ·absent·, otherwise false.
- [type definition name]
- The {name} of the ·type definition·, if the {name} is not ·absent·. If the ·type definition·'s {name} property is ·absent·, then schema processors may, but need not, provide a value which uniquely identifies this type definition among those with the same target namespace. It is ·implementation-defined· whether a processor provides a name for such a type definition. If a processor does provide a value in this situation, the choice of what value to use is ·implementation-dependent·.
- [member type definition]
- an ·item isomorphic· to the ·validating type· of the [schema actual value].
- [member type definition namespace]
- The {target namespace} of the ·validating type·.
- [member type definition anonymous]
- true if the {name} of the ·validating type· is ·absent·, otherwise false.
- [member type definition name]
- The {name} of the ·validating type·, if it is not ·absent·. If it is ·absent·, schema processors may, but need not, provide a value unique to the definition. It is ·implementation-defined· whether a processor provides a name for such a type definition. If a processor does provide a value in this situation, the choice of what value to use is ·implementation-dependent·.
- [member type definitions]
- a sequence of Simple Type Definition components, with the same length as the [schema actual value], each one an ·item isomorphic· to the ·validating type· of the corresponding item in the [schema actual value].
See also Attribute Default Value (§3.4.5.1), Match Information (§3.4.5.2) and Schema Information (§3.17.5.1), which describe other information set contributions related to attribute information items.
3.2.6 Constraints on Attribute Declaration Schema Components
All attribute declarations (see Attribute Declarations (§3.2)) must satisfy the following constraints.
3.2.6.1 Attribute Declaration Properties Correct
3.2.6.2 Simple Default Valid
3.2.6.4 xsi: Not Allowed
xsi: Not Allowedhttp://www.w3.org/2001/XMLSchema-instance
(unless it is one of the four built-in declarations given in the next section).xsi: attributes to specify default or fixed value
constraints (e.g. in a component corresponding to a schema document construct
of the form <xs:attribute ref="xsi:type" default="xs:integer"/>),
but the practice is not recommended; including such attribute uses will tend
to mislead readers of the schema document, because the attribute uses would
have no effect; see Element Locally Valid (Complex Type) (§3.4.4.2) and
Attribute Default Value (§3.4.5.1) for details.3.2.7 Built-in Attribute Declarations
There are four attribute declarations present in every schema by definition:
3.2.7.1 xsi:type
The xsi:type attribute
is used to signal use of a type other than the declared type of
an element. See xsi:type (§2.7.1).
3.2.7.2 xsi:nil
The xsi:nil attribute
is used to signal that an element's content is "nil"
(or "null"). See xsi:nil (§2.7.2).
nilhttp://www.w3.org/2001/XMLSchema-instance3.2.7.3 xsi:schemaLocation
The xsi:schemaLocation attribute
is used to signal possible locations of relevant schema documents.
See xsi:schemaLocation, xsi:noNamespaceSchemaLocation (§2.7.3).
schemaLocationhttp://www.w3.org/2001/XMLSchema-instancehttp://www.w3.org/2001/XMLSchema-instancexs:anySimpleType·3.2.7.4 xsi:noNamespaceSchemaLocation
The xsi:noNamespaceSchemaLocation attribute
is used to signal possible locations of relevant schema documents.
See xsi:schemaLocation, xsi:noNamespaceSchemaLocation (§2.7.3).
noNamespaceSchemaLocationhttp://www.w3.org/2001/XMLSchema-instance 3.3 Element Declarations
3.3.2 XML Representation of Element Declaration Schema Components
3.3.2.1 Common Mapping Rules for Element Declarations
3.3.2.2 Mapping Rules for Top-Level Element Declarations
3.3.2.3 Mapping Rules for Local Element Declarations
3.3.2.4 References to Top-Level Element Declarations
3.3.2.5 Examples of Element Declarations
3.3.3 Constraints on XML Representations of Element Declarations
3.3.4 Element Declaration Validation Rules
3.3.4.1 Selected and Instance-specified Type Definitions
3.3.4.2 Type Override and Valid Substitutability
3.3.4.3 Element Locally Valid (Element)
3.3.4.4 Element Locally Valid (Type)
3.3.4.5 Validation Root Valid (ID/IDREF)
3.3.4.6 Schema-Validity Assessment (Element)
3.3.5 Element Declaration Information Set Contributions
3.3.5.1 Assessment Outcome (Element)
3.3.5.2 Validation Failure (Element)
3.3.5.3 Element Declaration
3.3.5.4 Element Validated by Type
3.3.5.5 Element Default Value
3.3.5.6 Inherited Attributes
3.3.6 Constraints on Element Declaration Schema Components
3.3.6.1 Element Declaration Properties Correct
3.3.6.2 Element Default Valid (Immediate)
3.3.6.3 Substitution Group OK (Transitive)
3.3.6.4 Substitution Group
Element declarations provide for:
- Local ·validation· of element information item values using a type definition;
- Specifying default or fixed values for element information items;
- Establishing uniquenesses and reference constraint relationships among the values of related elements and attributes;
- Controlling the substitutability of elements through the mechanism of ·element substitution groups·.
<xs:element name="PurchaseOrder" type="PurchaseOrderType"/> <xs:element name="gift"> <xs:complexType> <xs:sequence> <xs:element name="birthday" type="xs:date"/> <xs:element ref="PurchaseOrder"/> </xs:sequence> </xs:complexType> </xs:element>
3.3.1 The Element Declaration Schema Component
The element declaration schema component has the following properties:
The {name} property must match the local part of the names of element information items being ·validated·.
For an element declaration E, if E.{scope}.{variety} = global, then E is available for use throughout the schema. If E.{scope}.{variety} = local, then E is available for use only within (the Complex Type Definition or Model Group Definition) E.{scope}.{parent}.
A ·non-absent· value of the {target namespace} property provides for ·validation· of namespace-qualified element information items. ·Absent· values of {target namespace} ·validate· unqualified items.
An element information item is normally
required to satisfy the {type definition}. For such an
item, schema information set
contributions appropriate to the {type definition} are added to the
corresponding element information
item in the ·post-schema-validation infoset·. The type
definition against which an element information item is
validated (its
·governing type definition·) can be different from the
declared {type definition}. The {type table} property of an Element Declaration, which governs conditional type assignment, and
the xsi:type attribute of an element information item
(see xsi:type (§2.7.1)) can cause the ·governing type definition· and the
declared {type definition} to be different.
If {nillable} is true, then
an element with no text or element
content can be ·valid·
despite a
{type definition}
which would otherwise require
content, if it carries the
attribute xsi:nil with the value
true (see xsi:nil (§2.7.2)).
Formal details of element ·validation· are described in
Element Locally Valid (Element) (§3.3.4.3).
xsi:nil = true. {value constraint} establishes a default or fixed value for an element. If a {value constraint} with {variety} = default is present, and if the element being ·validated· is empty, then for purposes of calculating the [schema normalized value] and other contributions to the ·post-schema-validation infoset· the element is treated as if {value constraint}.{lexical form} was used as the content of the element. If fixed is specified, then the element's content must either be empty, in which case fixed behaves as default, or its value must be equal or identical to {value constraint}.{value}.
{identity-constraint definitions} express constraints establishing uniquenesses and reference relationships among the values of related elements and attributes. See Identity-constraint Definitions (§3.11).
The {substitution group affiliations} property of an element declaration indicates which ·substitution groups·, if any, it can potentially be a member of. Potential membership is transitive but not symmetric; an element declaration is a potential member of any group named in its {substitution group affiliations}, and also of any group of which any entry in its {substitution group affiliations} is a potential member. Actual membership may be blocked by the effects of {substitution group exclusions} or {disallowed substitutions}, see below.
An empty {substitution group exclusions} allows a declaration to be named in the {substitution group affiliations} of other element declarations having the same declared {type definition} or some type ·derived· therefrom. The explicit values of {substitution group exclusions}, extension or restriction, rule out element declarations having types whose derivation from {type definition} involves any extension steps, or restriction steps, respectively.
The supplied values for {disallowed substitutions} determine whether an element declaration appearing in a ·content model· will be prevented from additionally ·validating· elements (a) with an xsi:type (§2.7.1) that identifies an extension or restriction of the type of the declared element, and/or (b) from ·validating· elements which are in the ·substitution group· headed by the declared element. If {disallowed substitutions} is empty, then all ·derived· types and ·substitution group· members are allowed.
Element declarations for which {abstract} is true can appear in content models only when substitution is allowed; such declarations must not themselves ever be used to ·validate· element content.
See Annotations (§3.15) for information on the role of the {annotations} property.
3.3.2 XML Representation of Element Declaration Schema Components
The XML representation for an element declaration schema component is an <element> element information item. It specifies a type definition for an element either by reference or explicitly, and may provide occurrence and default information. The correspondences between the properties of the information item after the appropriate ·pre-processing· and the properties of the component(s) it corresponds to are given in this section.
element Element Information Itemabstract = boolean : false
block = (#all | List of (extension | restriction | substitution))
default = string
final = (#all | List of (extension | restriction))
fixed = string
form = (qualified | unqualified)
id = ID
maxOccurs = (nonNegativeInteger | unbounded) : 1
minOccurs = nonNegativeInteger : 1
name = NCName
nillable = boolean : false
ref = QName
substitutionGroup = List of QName
targetNamespace = anyURI
type = QName
{any attributes with non-schema namespace . . .}>
Content: (annotation?, ((simpleType | complexType)?, alternative*, (unique | key | keyref)*))
</element>
An <element> element information item in a schema document maps to an element declaration and allows the type definition of that declaration to be specified either by reference or by explicit inclusion.
Top-level <element>
elements
(i.e. those which appear within
the schema document as children of
<schema>
elements)
produce
global element declarations; <element>s within <group> or <complexType> produce either particles which contain global element declarations (if there's a ref attribute) or local declarations (otherwise). For complete declarations, top-level or local, the type attribute is used when the declaration can use a
built-in or
user-defined global type definition. Otherwise an
anonymous <simpleType> or <complexType> is provided inline.
<override>) (§4.2.5) for details.
Element information items ·validated· by a top-level
declaration must be qualified with the
{target namespace} of that
declaration.
If the
{target namespace} is ·absent·,
the item must be unqualified.
Control over whether element information items ·validated· by a local declaration must be similarly qualified or not
is provided by the form [attribute], whose default is provided
by the elementFormDefault [attribute] on the enclosing <schema>, via its determination of {target namespace}.
The names for top-level element declarations are in a separate ·symbol space· from the symbol spaces for the names of type definitions, so there can (but need not be) a simple or complex type definition with the same name as a top-level element. The names of locally-scoped element declarations need not be unique and thus reside in no symbol space at all (but the element declarations are constrained by Element Declarations Consistent (§3.8.6.3)).
Note that the above allows for two levels of defaulting for unspecified
type definitions. An <element> with no referenced or included type definition will
correspond to an element declaration which has
the
same type definition as the first
substitution-group head named in the
substitutionGroup [attribute], if present,
otherwise ·xs:anyType·.
This has the important consequence that the minimum valid element declaration,
that is, one with only a name attribute and no contents,
is also (nearly) the most general, validating any combination of text and
element content and allowing any attributes, and providing for recursive
validation where possible.
See XML Representation of Identity-constraint Definition Schema Components (§3.11.2) for <key>, <unique> and <keyref>.
- If the <element> element information item has <schema> as its parent, it maps to an Element Declaration using the mappings described in Common Mapping Rules for Element Declarations (§3.3.2.1) and Mapping Rules for Top-Level Element Declarations (§3.3.2.2).
- If the <element> element information item has <complexType> or <group> as an ancestor, and the
ref[attribute] is absent, and it does not haveminOccurs=maxOccurs=0, then it maps both to a Particle, as described in Mapping Rules for Local Element Declarations (§3.3.2.3), and also to an Element Declaration, using the mappings described in Common Mapping Rules for Element Declarations (§3.3.2.1) and Mapping Rules for Local Element Declarations (§3.3.2.3). - If the <element> element information item has <complexType> or <group> as an ancestor, and the
ref[attribute] is present, and it does not haveminOccurs=maxOccurs=0, then it maps to a Particle as described in References to Top-Level Element Declarations (§3.3.2.4). - If the <element> element information item has
minOccurs=maxOccurs=0, then it maps to no component at all.Note: TheminOccursandmaxOccursattributes are not allowed on top-level <element> elements, so in valid schema documents this will happen only when the <element> element information item has <complexType> or <group> as an ancestor.
3.3.2.1 Common Mapping Rules for Element Declarations
The following mapping rules apply in all cases where an <element> element maps to an Element Declaration component.
type [attribute], if it is present.
substitutionGroup [attribute], if present.
xs:anyType·.
test [attribute].
test
[attribute], the final <alternative> maps to
the {default type definition};
if it does have a test attribute, it is covered by
the rule for {alternatives} and
the {default type definition}
is taken from the declared type of the Element Declaration.
So the value of the {default type definition}
is given by
the appropriate case among the following:test
[attribute], then a Type Alternative corresponding to the <alternative>.test) a Type Alternative with the following properties: default or a fixed [attribute],
then a Value Constraint as follows, otherwise ·absent·. [Definition:] Use the name effective simple type
definition for the declared {type definition}, if it is a
simple type definition,
or, if {type definition}.{content type}.{variety} = simple,
for {type definition}.{content type}.{simple type definition},
or else for the built-in
string simple
type definition).
substitutionGroup [attribute], if present,
otherwise the empty set.block
[attribute], if present, otherwise on the ·actual value· of the
blockDefault [attribute] of the ancestor
<schema> element information item, if present,
otherwise on the empty string. Call this the
EBV (for effective block value). Then the
value of this property is
the appropriate case among the following:#all, then {extension,
restriction,
substitution};blockDefault [attribute] of
<schema> may include values other than
extension, restriction or
substitution, those values are ignored in the
determination of {disallowed substitutions} for element
declarations (they are used elsewhere).final and finalDefault
[attributes] in place of the block and
blockDefault [attributes] and with the relevant
set being {extension,
restriction}.ref
[attribute], as defined in XML Representation of Annotation Schema Components (§3.15.2).
3.3.2.2 Mapping Rules for Top-Level Element Declarations
If the <element> element information item has <schema> as its parent, it maps to a global Element Declaration, using the mapping given in Common Mapping Rules for Element Declarations (§3.3.2.1), supplemented by the following.
targetNamespace [attribute] of the parent
<schema> element information item, or ·absent· if there is none.3.3.2.3 Mapping Rules for Local Element Declarations
If
the <element> element information
item has
<complexType> or <group> as
an ancestor,
and the ref [attribute] is absent,
and it does not have
minOccurs=maxOccurs=0,
then it maps both to a
Particle and to a local
Element Declaration which is the {term}
of that Particle. The Particle
is as follows:
maxOccurs [attribute] equals
unbounded, otherwise the ·actual value· of the
maxOccurs [attribute], if present, otherwise
1.The <element> element also maps to an element declaration using the mapping rules given in Common Mapping Rules for Element Declarations (§3.3.2.1), supplemented by those below:
targetNamespace is present
, then
its ·actual value·.
targetNamespace is not present and
one of the following is trueform
= qualified
form is absent and the <schema>
ancestor
has elementFormDefault =
qualified
targetNamespace [attribute]
of the ancestor <schema> element
information item,
or ·absent· if there is
none.
3.3.2.4 References to Top-Level Element Declarations
If the
<element> element information
item has
<complexType> or <group> as an
ancestor,
and the ref [attribute] is
present,
and it does not have
minOccurs=maxOccurs=0,
then it maps to
a Particle as follows.
maxOccurs [attribute] equals
unbounded, otherwise the ·actual value· of the
maxOccurs [attribute], if present, otherwise
1.3.3.2.5 Examples of Element Declarations
<xs:element name="unconstrained"/> <xs:element name="emptyElt"> <xs:complexType> <xs:attribute ...>. . .</xs:attribute> </xs:complexType> </xs:element> <xs:element name="contextOne"> <xs:complexType> <xs:sequence> <xs:element name="myLocalElement" type="myFirstType"/> <xs:element ref="globalElement"/> </xs:sequence> </xs:complexType> </xs:element> <xs:element name="contextTwo"> <xs:complexType> <xs:sequence> <xs:element name="myLocalElement" type="mySecondType"/> <xs:element ref="globalElement"/> </xs:sequence> </xs:complexType> </xs:element>
xs:anyType·.
The second uses an embedded anonymous complex
type definition.myLocalElement within
contextOne will be constrained by myFirstType,
while those within contextTwo will be constrained by
mySecondType. <xs:complexType name="facet">
<xs:complexContent>
<xs:extension base="xs:annotated">
<xs:attribute name="value" use="required"/>
</xs:extension>
</xs:complexContent>
</xs:complexType>
<xs:element name="facet" type="xs:facet" abstract="true"/>
<xs:element name="encoding" substitutionGroup="xs:facet">
<xs:complexType>
<xs:complexContent>
<xs:restriction base="xs:facet">
<xs:sequence>
<xs:element ref="annotation" minOccurs="0"/>
</xs:sequence>
<xs:attribute name="value" type="xs:encodings"/>
</xs:restriction>
</xs:complexContent>
</xs:complexType>
</xs:element>
<xs:element name="period" substitutionGroup="xs:facet">
<xs:complexType>
<xs:complexContent>
<xs:restriction base="xs:facet">
<xs:sequence>
<xs:element ref="annotation" minOccurs="0"/>
</xs:sequence>
<xs:attribute name="value" type="xs:duration"/>
</xs:restriction>
</xs:complexContent>
</xs:complexType>
</xs:element>
<xs:complexType name="datatype">
<xs:sequence>
<xs:element ref="facet" minOccurs="0" maxOccurs="unbounded"/>
</xs:sequence>
<xs:attribute name="name" type="xs:NCName" use="optional"/>
. . .
</xs:complexType>
facet type is defined
and the facet element is declared to use it. The facet element is abstract -- it's
only defined to stand as the head for a ·substitution group·. Two further
elements are declared, each a member of the facet ·substitution group·. Finally a type is defined which refers to facet, thereby
allowing either period or encoding (or
any other member of the group).message element will be
assigned either to type messageType or to a more
specific type derived from it.
messageType accepts any well-formed XML
or character sequence as content, and carries a kind
attribute which can be used to describe the kind or format of
the message. The value of kind is either one of a
few well known keywords or, failing that, any string.<xs:complexType name="messageType" mixed="true">
<xs:sequence>
<xs:any processContents="skip" minOccurs="0" maxOccurs="unbounded"/>
</xs:sequence>
<xs:attribute name="kind">
<xs:simpleType>
<xs:union>
<xs:simpleType>
<xs:restriction base="xs:string">
<xs:enumeration value="string"/>
<xs:enumeration value="base64"/>
<xs:enumeration value="binary"/>
<xs:enumeration value="xml"/>
<xs:enumeration value="XML"/>
</xs:restriction>
</xs:simpleType>
<xs:simpleType>
<xs:restriction base="xs:string"/>
</xs:simpleType>
</xs:union>
</xs:simpleType>
</xs:attribute>
<xs:anyAttribute processContents="skip"/>
</xs:complexType>
messageType are defined, each
corresponding to one of the three well-known formats:
messageTypeString for kind="string",
messageTypeBase64 for kind="base64"
and kind="binary", and
messageTypeXML for kind="xml" or
kind="XML".
<xs:complexType name="messageTypeString">
<xs:simpleContent>
<xs:restriction base="messageType">
<xs:simpleType>
<xs:restriction base="xs:string"/>
</xs:simpleType>
</xs:restriction>
</xs:simpleContent>
</xs:complexType>
<xs:complexType name="messageTypeBase64">
<xs:simpleContent>
<xs:restriction base="messageType">
<xs:simpleType>
<xs:restriction base="xs:base64Binary"/>
</xs:simpleType>
</xs:restriction>
</xs:simpleContent>
</xs:complexType>
<xs:complexType name="messageTypeXML">
<xs:complexContent>
<xs:restriction base="messageType">
<xs:sequence>
<xs:any processContents="strict"/>
</xs:sequence>
</xs:restriction>
</xs:complexContent>
</xs:complexType>
message element itself uses
messageType both as its declared type and
as its default type, and uses test attributes on its
<alternative> [children] to assign the appropriate
specialized message type to messages with the well known
values for the kind attribute.
Because the declared type and the default type are the same, the last
<alternative> (without the test attribute)
can be omitted.<xs:element name="message" type="messageType"> <xs:alternative test="@kind='string'" type="messageTypeString"/> <xs:alternative test="@kind='base64'" type="messageTypeBase64"/> <xs:alternative test="@kind='binary'" type="messageTypeBase64"/> <xs:alternative test="@kind='xml'" type="messageTypeXML"/> <xs:alternative test="@kind='XML'" type="messageTypeXML"/> <xs:alternative type="messageType"/> </xs:element>
3.3.3 Constraints on XML Representations of Element Declarations
default and fixed
are not
both present.ref or name is present, but not both.ref is present, then
no unqualified attributes are
present other than minOccurs, maxOccurs,
and id,
and no children in the Schema namespace (xs) other than
<annotation>.type attribute.targetNamespace is present then
all of the following are true:name is present.
form is not present.
targetNamespace [attribute] or its ·actual value·
is different from the ·actual value· of targetNamespace of
<element>, then
all of the following are true:base [attribute] of
<restriction> does not
·match· the
name of ·xs:anyType·.
test [attribute]; the last
<alternative> element may have such an [attribute].3.3.4 Element Declaration Validation Rules
When an element is ·assessed·, it is first checked against its ·governing element declaration·, if any; this in turn entails checking it against its ·governing type definition·. The second step is recursive: the element's [attributes] and [children] are ·assessed· in turn with respect to the declarations assigned to them by their parent's ·governing type definition·.
3.3.4.1 Selected and Instance-specified Type Definitions
The ·governing type definition· of an element is normally the declared {type definition} associated with the ·governing element declaration·, but this may be ·overridden· using conditional type assignment in the Element Declaration or using an ·instance-specified type definition·, or both. When the element is declared with conditional type assignment, the ·selected type definition· is used as the ·governing type definition· unless ·overridden· by an ·instance-specified type definition·.
xs:error·.3.3.4.2 Type Override and Valid Substitutability
- S and T are both complex type definitions and S is validly derived from T subject to the blocking keywords in the union of K and T. {prohibited substitutions}, as defined in Type Derivation OK (Complex) (§3.4.6.5)
- S is a complex type definition, T is a simple type definition, and S is validly ·derived· from T subject to the blocking keywords in K, as defined in Type Derivation OK (Complex) (§3.4.6.5)
- S is a simple type definition and S is validly ·derived· from T subject to the blocking keywords in K, as defined in Type Derivation OK (Simple) (§3.16.6.3).
[Definition:] If the set of keywords controlling whether a type S is ·validly substitutable· for another type T is the empty set, then S is said to be validly substitutable for T without limitation or absolutely. The phrase validly substitutable, without mention of any set of blocking keywords, means "validly substitutable without limitation".
Sometimes one type S is ·validly substitutable· for another type T only if S is derived from T by a chain of restrictions, or if T is a union type and S a member type of the union. The concept of ·valid substitutability· is appealed to often enough in such contexts that it is convenient to define a term to cover this specific case. [Definition:] A type definition S is validly substitutable as a restriction for another type T if and only if S is ·validly substitutable· for T, subject to the blocking keywords {extension, list, union}.
3.3.4.3 Element Locally Valid (Element)
The concept of local validity of an element information item against an element declaration is an important part of the schema-validity ·assessment· of elements. (The other important part is the recursive ·assessment· of attributes and descendant elements.) Local validity partially determines the element information item's [validity] property, and fully determines the [local element validity] property, in the ·post-schema-validation infoset·.
- The declaration is present in the schema and the name of the element matches the name of the declaration.
- The element is declared concrete (i.e. not abstract).
- Any
xsi:nilattribute on the element obeys the rules. The element is allowed to have anxsi:nilattribute only if the element is declared nillable, andxsi:nil = 'true'is allowed only if the element itself is empty. If the element declaration specifies a fixed value for the element,xsi:nil='true'will make the element invalid. - Any
xsi:typeattribute present names a type which is ·validly substitutable· for the element's declared {type definition}. - The element's content satisfies the appropriate constraints: If the element is empty and the declaration specifies a default value, the default is checked against the appropriate type definitions. Otherwise, the content of the element is checked against the ·governing type definition·; additionally, if the element declaration specifies a fixed value, the content is checked against that value.
- The element satisfies all the identity constraints specified on the element declaration.
- Additionally, on the ·validation root·, document-level ID and IDREF constraints are checked.
The following validation rule gives the normative formal definition of local validity of an element against an element declaration.
xsi:nil attribute.xsi:nil
attribute information item.xsi:nil = false.xsi:nil
= true
(that is, E is ·nilled·), and
all of the following are true:xsi:type attribute, the
type definition indicated by that attribute normally takes
precedence over the ·selected type definition· which would otherwise
govern the element.
If an xsi:type attribute is present
and ·resolves·
to a known type definition, but
fails to ·override· the
·selected type definition·, then E is not
locally valid against D,
since E has failed to satisfy
clause 4.
In this case
(or if xsi:type fails to
·resolve·), the ·governing type definition· of the
element is the ·selected type definition· of its
·governing element declaration·, and the element is
validated against that type as described in
clause 5.
The local validity of the element
with respect to the ·governing type definition· is recorded in the
[local type validity]
property.
The use of the ·selected type definition· when the
·instance-specified type definition· cannot be used
allows useful validation to proceed in some cases (not all) even
when the schema is incomplete. It also
helps ensure consistent typing for sub-elements
with the same name.
3.3.4.4 Element Locally Valid (Type)
The following validation rule specifies
formally what it means for an element to be locally valid
against a type definition. This concept is appealed to in the
course of checking an element's local validity against its
·governing type definition·. It
is also part of schema-validity
·assessment· of an element when the element is
·laxly assessed·, by checking its local validity
against xs:anyType.
Informally, local validity against a type requires first
that the type definition be present in the schema and not declared abstract.
For a simple type definition, the element must lack attributes
(except for namespace declarations and the special attributes
in the xsi namespace) and child elements, and must
be type-valid against that simple type definition.
For a complex type definition, the element must
be locally valid against that complex type definition.
xsi:type,
xsi:nil,
xsi:schemaLocation, or
xsi:noNamespaceSchemaLocation.3.3.4.5 Validation Root Valid (ID/IDREF)
The following validation rule specifies document-level ID/IDREF constraints checked on the ·validation root· if it is an element; this rule is not checked on other elements. Informally, the requirement is that each ID identifies a single element within the ·validation root·, and that each IDREF value matches one ID.
xs:ID provides
a unique identifier for the element's parent element, it is not useful
to have an element governed by xs:ID when the element
has no parent element or when the parent element lies outside the
scope of validation.DOC
and Y are governed by type ·xs:anyType·,
the element X and the attribute xml:id are
governed by xs:ID, and the element
Z is governed by a complex type with simple content
derived from xs:ID.- In the document
<DOC><X>abcd</X></DOC>, the ID value 'abcd' will normally be bound to theDOCelement. But if theXelement is the validation root, then 'abcd' will have no element binding, becauseDOCis outside the scope of the validation episode. So the first clause is violated and the document is invalid. - The superficially similar case
<DOC><Y xml:id="abcd"/></DOC>will, in contrast, be valid whether theDOCelement or theYelement is the validation root. The ID/IDREF table will have one entry in either case, binding 'abcd' to theYelement. - For the document
<DOC><Z xml:id="abcd">abcd</Z></DOC>, ifZis the validation root, then the ID/IDREF table for the document will have a single entry for 'abcd' and will be valid. The single binding comes from thexml:idattribute; the content ofZproduces no binding, just as the content ofXabove produces no binding.But ifDOCis the validation root, then the ID/IDREF table for the document will have two entries for 'abcd' (one, from thexml:idattribute, binding 'abcd' to theZelement, one from the content ofZbinding 'abcd' to theDOCelement) and will be invalid.
ID/IDREF functionality is imperfect in that if
the ·validation root· is not the document element of an XML
document, the results will not necessarily be the same as
those a validating parser would give were the document to have
a DTD with equivalent declarations.3.3.4.6 Schema-Validity Assessment (Element)
- Assessment begins with the identification of a ·governing element declaration· for the element and then checks that the element is locally valid against the declaration; if no ·governing element declaration· is available, a ·governing type definition· can be used instead.
- The element's attributes are to be ·assessed· recursively, unless they match a skip wildcard and are thus ·skipped·.
- The element's children are to be ·assessed· recursively, unless they match a skip wildcard and are thus ·skipped·. For each child element, the ·governing element declaration· is the one identified in the course of checking the local validity of the parent, unless that declaration is not available. If the ·governing element declaration· is not available, the element may still be ·strictly assessed· if a ·governing type definition· can be identified (e.g. via the
xsi:typeattribute), otherwise the element will be ·laxly assessed·.
xs:anyType·.
xs:anyType· as defined in
Element Locally Valid (Type) (§3.3.4.4), and the schema-validity of
E's [attributes] and [children]
is assessed as described in clause 2 and clause 3
of Schema-Validity Assessment (Element) (§3.3.4.6).3.3.5 Element Declaration Information Set Contributions
3.3.5.1 Assessment Outcome (Element)
- [validation context]
- The nearest ancestor element information item with a [schema information] property (or this element item itself if it has such a property).
- [validity]
-
The appropriate case among the following:1 If it was ·strictly assessed·, then the appropriate case among the following:1.1 If all of the following are true:then valid;1.1.1 One of the following is true:1.1.1.1 clause 1.1 of Schema-Validity Assessment (Element) (§3.3.4.6) applied and the item was locally ·valid· as defined by Element Locally Valid (Element) (§3.3.4.3);1.1.1.2 clause 1.2 of Schema-Validity Assessment (Element) (§3.3.4.6) applied and the item was locally ·valid· as defined by Element Locally Valid (Type) (§3.3.4.4).1.1.2 Neither its [children] nor its [attributes] contains an information item (element or attribute respectively) whose [validity] is invalid.1.1.3 Neither its [children] nor its [attributes] contains an information item (element or attribute respectively) which is ·attributed· to a strict ·wildcard particle· and whose [validity] is notKnown.1.2 otherwise invalid.2 otherwise notKnown.
- [validation attempted]
-
The appropriate case among the following:1 If it was ·strictly assessed· and neither its [children] nor its [attributes] contains an information item (element or attribute respectively) whose [validation attempted] is not full, then full;2 If it was not ·strictly assessed· and neither its [children] nor its [attributes] contains an information item (element or attribute respectively) whose [validation attempted] is not none, then none;3 otherwise partial.
3.3.5.2 Validation Failure (Element)
- [schema error code]
-
The appropriate case among the following:1 If the item is ·invalid·, then a list. Applications wishing to provide information as to the reason(s) for the ·validation· failure are encouraged to record one or more error codes (see Outcome Tabulations (normative) (§B)) herein.2 otherwise ·absent·.
- [subsequence-valid]
-
The appropriate case among the following:1 If the element information item is locally ·invalid·, because unexpected attributes or elements were found among its [attributes] and [children] and clause 1 of Element Locally Valid (Complex Type) (§3.4.4.2) would be satisfied, if those unexpected attributes and children (those with [match information] = none) were removed, then true2 otherwise false
- [failed identity constraints]
-
A list of Identity-Constraint Definitions that are
not satisfied
by the element information item, as defined by Identity-constraint Satisfied (§3.11.4). Note: In principle, the value of this property includes all of the Identity-Constraint Definitions which are not satisfied for this element item; in practice, some processors will expose a subset of the items in this value, rather than the full value. For example, a processor could choose not to check further identity constraints after detecting the first failure.
- [failed assertions]
-
A list of Assertions that are not
satisfied by the element information item, as defined by Assertion Satisfied (§3.13.4.1). Note: In principle, the value of this property includes all of the Assertions which are not satisfied by this element item; in practice, some processors will expose a subset of the items in this value, rather than the full value. For example, a processor could choose not to check further assertions after detecting the first failure.
3.3.5.3 Element Declaration
- [element declaration]
- an ·item isomorphic· to the ·governing· declaration component itself
- [nil]
- true if clause 3.2.3 of Element Locally Valid (Element) (§3.3.4.3) above is satisfied, otherwise false
- [expected element declaration]
- if the element information item is
·attributed· to an ·element particle·, then the {term} of that Particle, otherwise ·absent·
Note: The [element declaration] either is the same as or is in the ·substitution group· of the [expected element declaration].
- [declared type]
- an ·item isomorphic· to the declared {type definition} of the ·governing element declaration·
- [local element validity]
-
The appropriate case among the following:1 If the item was locally ·valid· as defined by Element Locally Valid (Element) (§3.3.4.3), then valid2 otherwise (the item was locally ·invalid· as defined by Element Locally Valid (Element) (§3.3.4.3)) invalid.
3.3.5.4 Element Validated by Type
- [schema normalized value]
-
The appropriate case among the following:1 If the element information item is not ·nilled· and either the ·governing type definition· is a simple type definition or its {content type} has {variety} simple, then the appropriate case among the following:1.1 If clause 5.1 of Element Locally Valid (Element) (§3.3.4.3) above has applied, then the {lexical form} of the {value constraint}1.2 If clause 5.1 of Element Locally Valid (Element) (§3.3.4.3) above has not applied and the element's ·initial value· is ·valid· with respect to the simple type definition as defined by String Valid (§3.16.4), then the ·normalized value· of the item as ·validated·1.3 otherwise ·absent·.2 otherwise ·absent·.
- [schema actual value]
- If the [schema normalized value] is not ·absent·, then the corresponding ·actual value· ; otherwise ·absent·.
- [type definition]
- An ·item isomorphic· to the ·governing type definition· component itself.
- [type definition type]
- simple or complex, depending on the [type definition].
- [type definition namespace]
- [type definition].{target namespace}.
- [type definition anonymous]
- true if [type definition].{name} is ·absent·, otherwise false.
- [type definition name]
- If [type definition].{name} is not ·absent·, then [type definition].{name}, otherwise schema processors may, but need not, provide a value unique to the definition. It is ·implementation-defined· whether a processor provides a name for such a type definition. If a processor does provide a value in this situation, the choice of what value to use is ·implementation-dependent·.
- [type fallback]
- A keyword indicating whether the expected type
definition was unavailable and the element had a fallback type
as its ·governing type definition·
- declared if the element information item has a ·governing element declaration· which has no {type table}, and also an
xsi:typeattribute which fails to ·resolve· to a type definition that ·overrides· the declared {type definition} - selected if the element information item has a ·governing element declaration· with a {type table} and also has an
xsi:typeattribute which fails to ·resolve· to a type definition that ·overrides· the ·selected type definition· - lax if the element was ·laxly assessed· using ·
xs:anyType· - none otherwise
- [type alternative]
- If the element's ·governing element declaration· does not have a {type table}, then ·absent·; otherwise the first Type Alternative that ·successfully selected· the element's ·selected type definition·, if any; otherwise the {default type definition}.
- [local type validity]
-
The appropriate case among the following:1 If the element information item was locally ·valid· as defined by Element Locally Valid (Type) (§3.3.4.4), then valid2 otherwise (the item was locally ·invalid· as defined by Element Locally Valid (Type) (§3.3.4.4)) invalid.
- [descendant validity]
-
The appropriate case among the following:1 If neither its [children] nor its [attributes] contains an information item I (element or attribute respectively) where either I's [validity] is invalid or I is ·attributed· to a strict ·wildcard particle· and I's [validity] is notKnown , then valid;2 otherwise invalid.
- [member type definition]
- An ·item isomorphic· to the ·validating type· of the [schema actual value].
- [member type definition namespace]
- The {target namespace} of the ·validating type·.
- [member type definition anonymous]
- true if the {name} of the ·validating type· is ·absent·, otherwise false.
- [member type definition name]
- The {name} of the ·validating type·, if it is not ·absent·. If it is ·absent·, schema processors may, but need not, provide a value unique to the definition. It is ·implementation-defined· whether a processor provides a name for such a type definition. If a processor does provide a value in this situation, the choice of what value to use is ·implementation-dependent·.
- [member type definitions]
- a sequence of Simple Type Definition components, with the same length as the [schema actual value], each one an ·item isomorphic· to the ·validating type· of the corresponding item in the [schema actual value].
- [schema default]
- The {lexical form} of the declaration's {value constraint}.
xs:anyType·.3.3.5.5 Element Default Value
- [schema specified]
-
The appropriate case among the following:1 If clause 5.1 of Element Locally Valid (Element) (§3.3.4.3) above applies, then schema.2 otherwise infoset.
See also Match Information (§3.4.5.2), Identity-constraint Table (§3.11.5), Validated with Notation (§3.14.5), and Schema Information (§3.17.5.1), which describe other information set contributions related to element information items.
3.3.5.6 Inherited Attributes
- [inherited attributes]
-
A list of attribute information items. An attribute information item
A is included if and only if all of the following are true:1 A is ·potentially inherited· by E.2 Let O be A's [owner element]. A does not have the same expanded name as another attribute which is also ·potentially inherited· by E and whose [owner element] is a descendant of O.
3.3.6 Constraints on Element Declaration Schema Components
All element declarations (see Element Declarations (§3.3)) must satisfy the following constraint.
3.3.6.1 Element Declaration Properties Correct
xs:error·.3.3.6.2 Element Default Valid (Immediate)
This and the following sections define relations appealed to elsewhere in this specification.
3.3.6.3 Substitution Group OK (Transitive)
3.3.6.4 Substitution Group
[Definition:] One element declaration is substitutable for another if together they satisfy constraint Substitution Group OK (Transitive) (§3.3.6.3).
[Definition:] Every element declaration (call this HEAD) in the {element declarations} of a schema defines a substitution group, a subset of those {element declarations}. An element declaration is in the substitution group of HEAD if and only if it is ·substitutable· for HEAD.
3.4 Complex Type Definitions
3.4.2 XML Representation of Complex Type Definition Schema Components
3.4.2.1 Common Mapping Rules for Complex Type Definitions
3.4.2.2 Mapping Rules for Complex Types with Simple Content
3.4.2.3 Mapping Rules for Complex Types with Complex Content
3.4.2.4 Mapping Rule for Attribute Uses Property
3.4.2.5 Mapping Rule for Attribute Wildcard Property
3.4.2.6 Examples of Complex Type Definitions
3.4.3 Constraints on XML Representations of Complex Type Definitions
3.4.4 Complex Type Definition Validation Rules
3.4.4.1 Locally Declared Type
3.4.4.2 Element Locally Valid (Complex Type)
3.4.4.3 Element Sequence Locally Valid (Complex Content)
3.4.4.4 Attribution
3.4.5 Complex Type Definition Information Set Contributions
3.4.5.1 Attribute Default Value
3.4.5.2 Match Information
3.4.6 Constraints on Complex Type Definition Schema Components
3.4.6.1 Complex Type Definition Properties Correct
3.4.6.2 Derivation Valid (Extension)
3.4.6.3 Derivation Valid (Restriction, Complex)
3.4.6.4 Content Type Restricts (Complex Content)
3.4.6.5 Type Derivation OK (Complex)
3.4.7 Built-in Complex Type Definition
Complex Type Definitions provide for:
- Constraining element information items by providing Attribute Declaration (§2.2.2.3)s governing the appearance and content of [attributes]
- Constraining element information item [children] to be empty, or to conform to a specified element-only or mixed content model, or else constraining the character information item [children] to conform to a specified simple type definition.
- Constraining elements and attributes to exist, not to exist, or to have specified values, with Assertion (§2.2.4.3)s.
- Using the mechanisms of Type Definition Hierarchy (§2.2.1.1) to ·derive· a complex type from another simple or complex type.
- Specifying ·post-schema-validation infoset contributions· for elements.
- Limiting the ability to ·derive· additional types from a given complex type.
- Controlling the permission to substitute, in an instance, elements of a ·derived· type for elements declared in a content model to be of a given complex type.
<xs:complexType name="PurchaseOrderType"> <xs:sequence> <xs:element name="shipTo" type="USAddress"/> <xs:element name="billTo" type="USAddress"/> <xs:element ref="comment" minOccurs="0"/> <xs:element name="items" type="Items"/> </xs:sequence> <xs:attribute name="orderDate" type="xs:date"/> </xs:complexType>
3.4.1 The Complex Type Definition Schema Component
A complex type definition schema component has the following properties:
Either an Element Declaration or a Complex Type Definition.
Complex type definitions are identified by their {name} and {target namespace}. Except
for anonymous complex type definitions (those with no {name}), since
type definitions (i.e. both simple and complex type definitions taken together) must be uniquely identified within an ·XSD schema·, no complex type definition can have the same name as another
simple or complex type definition. Complex type {name}s and {target namespace}s
are provided for reference from
instances (see xsi:type (§2.7.1)), and for use in the XML
representation of schema components
(specifically in <element>). See References to schema components across namespaces (<import>) (§4.2.6) for the use of component
identifiers when importing one schema into another.
As described in Type Definition Hierarchy (§2.2.1.1), each complex type is ·derived· from a {base type definition} which is itself either a Simple Type Definition (§2.2.1.2) or a Complex Type Definition (§2.2.1.3). {derivation method} specifies the means of ·derivation· as either extension or restriction (see Type Definition Hierarchy (§2.2.1.1)).
A complex type with an empty specification for {final} can be used as a
{base type definition} for other types ·derived· by either of
extension or restriction; the explicit values extension, and restriction prevent further
·derivations· by extension and restriction respectively. If all values are specified, then [Definition:] the complex type is said to be
final, because no
further ·derivations· are possible. Finality is not
inherited, that is, a type definition ·derived· by restriction from a type
definition which is final for extension is not itself, in the absence of any
explicit final attribute of its own, final for anything.
The {context} property is only relevant for anonymous type definitions, for which its value is the component in which this type definition appears as the value of a property, e.g. {type definition}.
Complex types for which {abstract} is true have no valid instances and thus cannot be used in the normal way as the {type definition} for the ·validation· of element information items (if for some reason an abstract type is identified as the ·governing type definition· of an element information item, the item will invariably be invalid). It follows that such abstract types must not be referenced from an xsi:type (§2.7.1) attribute in an instance document. Abstract complex types can be used as {base type definition}s, or even as the declared {type definition}s of element declarations, provided in every case a concrete ·derived· type definition is used for ·validation·, either via xsi:type (§2.7.1) or the operation of a ·substitution group·.
{attribute uses} are a set of attribute uses. See Element Locally Valid (Complex Type) (§3.4.4.2) and Attribute Locally Valid (§3.2.4.1) for details of attribute ·validation·.
{attribute wildcard}s provide a more flexible specification for ·validation· of attributes not explicitly included in {attribute uses}. See Element Locally Valid (Complex Type) (§3.4.4.2), The Wildcard Schema Component (§3.10.1) and Wildcard allows Expanded Name (§3.10.4.2) for formal details of attribute wildcard ·validation·.
- A {content type} with {variety} empty ·validates· elements with no character or element information item [children].
- A {content type} with {variety} simple ·validates· elements with character-only [children]using its {simple type definition}.
- A {content type} with {variety} element-only ·validates· elements with [children] that conform to the ·content model· supplied by its {particle}.
- A {content type} with {variety} mixed ·validates· elements whose element [children] (i.e. specifically ignoring other [children] such as character information items) conform to the ·content model· supplied by its {particle}.
- A {content type} with ·non-absent· {open content} ·validates· elements with some [children] conforming to the ·content model· and others conforming to the {open content}.
- as the ·governing type definition· of an element instance E, when T is the ·selected type definition· of E (often, the declared {type definition} of E's ·governing element declaration·); this can occur when E specifies a type definition using the
xsi:typeattribute; see xsi:type (§2.7.1); - as the ·selected type definition· of an element instance E, when T is the declared {type definition} of E's ·governing element declaration·; this can occur when conditional type assignment is used; see Type Alternatives (§3.12);
- as the ·governing type definition· of element instances whose ·governing element declaration· is included in a model group only ·implicitly·, by virtue of being included in the ·substitution group· of some element declaration present ·directly· ·indirectly· in the model group, whose declared {type definition} is T.
- as the {type definition} of an Element Declaration E1 where
- E1 is contained in a Complex Type Definition D
- D is derived from another Complex Type Definition B
- B contains an Element Declaration E2 that has the same expanded name as E1
- E2 has T as its {type definition}.
{assertions} constrain elements and attributes to exist, not to exist, or to have specified values. Though specified as a sequence, the order among the assertions is not significant during assessment. See Assertions (§3.13).
See Annotations (§3.15) for information on the role of the {annotations} property.
3.4.2 XML Representation of Complex Type Definition Schema Components
The XML representation for a complex type definition schema component is a <complexType> element information item.
The XML representation for complex type definitions with a {content type} with {variety} simple is significantly different from that of those with other {content type}s, and this is reflected in the presentation below, which describes the mappings for the two cases in separate subsections. Common mapping rules are factored out and given in separate sections. As always, the mapping rules given here apply after, not before, the appropriate ·pre-processing·.
complexType Element Information Itemabstract = boolean : false
block = (#all | List of (extension | restriction))
final = (#all | List of (extension | restriction))
id = ID
mixed = boolean
name = NCName
defaultAttributesApply = boolean : true
{any attributes with non-schema namespace . . .}>
Content: (annotation?, (simpleContent | complexContent | (openContent?, (group | all | choice | sequence)?, ((attribute | attributeGroup)*, anyAttribute?), assert*)))
</complexType>
<complexType name="anyThing"/> is allowed.
- If the <complexType> source declaration has a <simpleContent> element as a child, then it maps to a Complex Type Definition using the mapping rules in
- If the <complexType> source declaration has a <complexContent> element as a child, then it maps to a Complex Type Definition using the mapping rules in
- If the <complexType> source declaration has neither a <simpleContent> nor a <complexContent> element as a child, then it maps to a Complex Type Definition using the mapping rules in
Where convenient, the mapping rules are described exclusively in terms of the schema document's information set. The mappings, however, depend not only upon the source declaration but also upon the schema context. Some mappings, that is, depend on the properties of other components in the schema. In particular, several of the mapping rules given in the following sections depend upon the {base type definition} having been identified before they apply.
3.4.2.1 Common Mapping Rules for Complex Type Definitions
Whichever alternative for the content of <complexType> is chosen, the following property mappings apply. Except where otherwise specified, attributes and child elements are to be sought among the [attributes] and [children] of the <complexType> element.
targetNamespace [attribute] of the <schema> ancestor element information item if present,
otherwise ·absent·.block
[attribute], if present, otherwise to the ·actual value· of the
blockDefault [attribute] of the ancestor
<schema> element information item, if present,
otherwise on the empty string. Call this the
EBV (for effective block value). Then the
value of this property is
the appropriate case among the following:#all, then {extension,
restriction};blockDefault [attribute] of
<schema> may include values other than
restriction or extension, those values
are ignored in the determination of {prohibited substitutions} for complex type
definitions (they are used elsewhere).final and finalDefault
[attributes] in place of the block and
blockDefault [attributes].name [attribute] is present, then ·absent·, otherwise (among the ancestor element information
items there will be a nearest <element>),
the Element Declaration
corresponding to
the nearest <element>
information item among the
the ancestor element information items.
3.4.2.2 Mapping Rules for Complex Types with Simple Content
When the <complexType> source declaration has a <simpleContent> child, the following elements are relevant (as are <attribute>, <attributeGroup>, and <anyAttribute>), and the property mappings are as below, supplemented by the mappings in Common Mapping Rules for Complex Type Definitions (§3.4.2.1), Mapping Rule for Attribute Uses Property (§3.4.2.4), and Mapping Rule for Attribute Wildcard Property (§3.4.2.5). Note that either <restriction> or <extension> must appear in the content of <simpleContent>.
simpleContent Element Information Item et al.id = ID
{any attributes with non-schema namespace . . .}>
Content: (annotation?, (restriction | extension))
</simpleContent>
base = QName
id = ID
{any attributes with non-schema namespace . . .}>
Content: (annotation?, (simpleType?, (minExclusive | minInclusive | maxExclusive | maxInclusive | totalDigits | fractionDigits | length | minLength | maxLength | enumeration | whiteSpace | pattern | assertion | {any with namespace: ##other})*)?, ((attribute | attributeGroup)*, anyAttribute?), assert*)
</restriction>
base = QName
id = ID
{any attributes with non-schema namespace . . .}>
Content: (annotation?, ((attribute | attributeGroup)*, anyAttribute?), assert*)
</extension>
When the <complexType> element has a <simpleContent> child, then the <complexType> element maps to a complex type with simple content, as follows.
base [attribute]
on the
<restriction> or
<extension> element appearing as a child of
<simpleContent>
targetNamespace [attribute] of the ancestor
<schema> element information item if present,
otherwise ·absent·xs:anySimpleType·) a simple type definition which
restricts SB with a set of facet
components corresponding to the appropriate element
information items among the <restriction>'s [children] (i.e. those
which specify facets, if any), as defined in Simple Type Restriction (Facets) (§3.16.6.4);
xs:anySimpleType·), the result will be a simple type definition component
which fails to obey the constraints on simple type definitions, including
for example clause 1.1 of
Derivation Valid (Restriction, Simple) (§3.16.6.2).
xs:anySimpleType·.3.4.2.3 Mapping Rules for Complex Types with Complex Content
When the <complexType> element does not have a <simpleContent> child element, then it maps to a complex type with complex content. The following elements are relevant (as are the <attribute>, <attributeGroup>, and <anyAttribute> elements, which are described more fully in XML Representation of Attribute Declaration Schema Components (§3.2.2), Mapping Rule for Attribute Uses Property (§3.4.2.4), and XML Representation of Wildcard Schema Components (§3.10.2), respectively, and which are not repeated here), and the additional property mappings are as below, supplemented by the mappings in Common Mapping Rules for Complex Type Definitions (§3.4.2.1), Mapping Rule for Attribute Uses Property (§3.4.2.4), Mapping Rule for Attribute Wildcard Property (§3.4.2.5), Mapping Rules for Local Attribute Declarations (§3.2.2.2), and Mapping Rules for References to Top-level Attribute Declarations (§3.2.2.3). Note that either <restriction> or <extension> must appear in the content of <complexContent>, but their content models are different in this case from the case above when they occur as children of <simpleContent>.
complexContent Element Information Item et al.id = ID
mixed = boolean
{any attributes with non-schema namespace . . .}>
Content: (annotation?, (restriction | extension))
</complexContent>
base = QName
id = ID
{any attributes with non-schema namespace . . .}>
Content: (annotation?, openContent?, (group | all | choice | sequence)?, ((attribute | attributeGroup)*, anyAttribute?), assert*)
</restriction>
base = QName
id = ID
{any attributes with non-schema namespace . . .}>
Content: (annotation?, openContent?, ((group | all | choice | sequence)?, ((attribute | attributeGroup)*, anyAttribute?), assert*))
</extension>
id = ID
mode = (none | interleave | suffix) : interleave
{any attributes with non-schema namespace . . .}>
Content: (annotation?, any?)
</openContent>
Complex types with complex content can be the image of two different forms of <complexType> element: one with a <complexContent> child (discussed in Mapping Rules for Complex Types with Explicit Complex Content (§3.4.2.3.1)), and one with neither <simpleContent> nor <complexContent> as a child (discussed in Mapping Rules for Complex Types with Implicit Complex Content (§3.4.2.3.2)). The mapping of the {content type} is the same in both cases; it is described in Mapping Rules for Content Type Property of Complex Content (§3.4.2.3.3).
3.4.2.3.1 Mapping Rules for Complex Types with Explicit Complex Content
When the <complexType> source declaration has a <complexContent> child, the following mappings apply, supplemented by those specified in Mapping Rules for Content Type Property of Complex Content (§3.4.2.3.3), Common Mapping Rules for Complex Type Definitions (§3.4.2.1), Mapping Rule for Attribute Uses Property (§3.4.2.4), and Mapping Rule for Attribute Wildcard Property (§3.4.2.5).
3.4.2.3.2 Mapping Rules for Complex Types with Implicit Complex Content
When the <complexType> source declaration
has neither <simpleContent> nor
<complexContent> as a child, it is taken
as shorthand for complex content restricting
·xs:anyType·. The mapping rules specific to this
situation are as follows; the mapping rules for properties
not described here are as given in
Mapping Rules for Content Type Property of Complex Content (§3.4.2.3.3),
Common Mapping Rules for Complex Type Definitions (§3.4.2.1),
Mapping Rule for Attribute Uses Property (§3.4.2.4),
and
Mapping Rule for Attribute Wildcard Property (§3.4.2.5).
3.4.2.3.3 Mapping Rules for Content Type Property of Complex Content
For complex types with complex content, the {content type} property is calculated as follows. (For the {content type} on complex types with simple content, see Mapping Rules for Complex Types with Simple Content (§3.4.2.2).)
abc attribute is present
on the xyz element", if no xyz
element information item is present, then no
abc attribute is present on the
(non-existent) xyz element.false.minOccurs [attribute]
has the ·actual value· 0
and which has no
[children] of its own except for <annotation>;
maxOccurs
[attribute] with an ·actual value· of 0;true, then A particle whose properties are as
follows:
true, otherwise
element-onlytrue, otherwise
element-only
appliesToEmpty = true
mode = 'none'
, then
the ·explicit content type·.
mode [attribute]
of the ·wildcard element·, if present,
otherwise interleave.
3.4.2.4 Mapping Rule for Attribute Uses Property
Any <complexType> source declaration can have <attribute> and <attributeGroup> elements as children, or descendants. The <attribute> element is described in XML Representation of Attribute Declaration Schema Components (§3.2.2) and will not be repeated here.
attributeGroup Element Information Itemid = ID
ref = QName
{any attributes with non-schema namespace . . .}>
Content: (annotation?)
</attributeGroup>
The <attribute> and <attributeGroup> elements map to the {attribute uses} property of the Complex Type Definition component as described below. This mapping rule is the same for all complex type definitions.
If the
<schema> ancestor has a
defaultAttributes attribute, and the <complexType> element does not have
defaultAttributesApply =
false, then the {attribute uses}
property is
computed as if there were an
<attributeGroup> [child] with empty content
and a ref [attribute] whose ·actual value· is the
same as that of the
defaultAttributes
[attribute] appearing after any other
<attributeGroup>
[children]. Otherwise proceed as if there were no such
<attributeGroup> [child].
ref [attribute] of the <attributeGroup>
[children], if any.use =
prohibited.use attribute of an
<attribute> is in
establishing the correspondence between a complex type defined
by restriction and its XML representation. It serves to
prevent inheritance of an identically named attribute use from
the {base type definition}. Such an <attribute> does not correspond to any component, and
hence there is no interaction with either explicit or
inherited wildcards in the operation of Complex Type Definition Validation Rules (§3.4.4) or Constraints on Complex Type Definition Schema Components (§3.4.6).
It is pointless, though not an
error, for the use attribute to have the value
prohibited in other contexts (e.g. in complex type
extensions or named model group definitions), in which cases
the <attribute> element is simply ignored, provided that
it does not violate other constraints in this
specification.3.4.2.5 Mapping Rule for Attribute Wildcard Property
The {attribute wildcard} property of a Complex Type Definition depends on the <anyAttribute> element which may be present within the <complexType> element or within the attribute groups referred to within <complexType>. The <attributeGroup> element is described in the preceding section Mapping Rule for Attribute Uses Property (§3.4.2.4) and will not be repeated here.
If the <schema> ancestor has a
defaultAttributes attribute, and the
<complexType> element does not have
defaultAttributesApply = false, then the
{attribute wildcard} property is computed
as if there were an <attributeGroup>
[child] with empty content and a ref [attribute]
whose ·actual value· is the same as that of the
defaultAttributes [attribute] appearing after any
other <attributeGroup>
[children]. Otherwise proceed as if there were no such
<attributeGroup> [child].
3.4.2.6 Examples of Complex Type Definitions
The following declaration defines a type for specifications of length
by creating a complex type with simple content, with
xs:nonNegativeInteger as the type of the
content, and a unit attribute to give the
unit of measurement.
<xs:complexType name="length1"> <xs:simpleContent> <xs:extension base="xs:nonNegativeInteger"> <xs:attribute name="unit" type="xs:NMTOKEN"/> </xs:extension> </xs:simpleContent> </xs:complexType> <xs:element name="width" type="length1"/>
An instance using this type might look like this:
<width unit="cm">25</width>
A second approach to defining length uses two elements, one for size and one for the unit of measure. The definition of the type and the declaration of the element might look like this:
<xs:complexType name="length2">
<xs:complexContent>
<xs:restriction base="xs:anyType">
<xs:sequence>
<xs:element name="size" type="xs:nonNegativeInteger"/>
<xs:element name="unit" type="xs:NMTOKEN"/>
</xs:sequence>
</xs:restriction>
</xs:complexContent>
</xs:complexType>
<xs:element name="depth" type="length2"/>
An instance using this method might look like this:
<depth> <size>25</size><unit>cm</unit> </depth>
A third definition of type leaves the base type implicit; at the component level, the following declaration is equivalent to the preceding one.
<xs:complexType name="length3"> <xs:sequence> <xs:element name="size" type="xs:nonNegativeInteger"/> <xs:element name="unit" type="xs:NMTOKEN"/> </xs:sequence> </xs:complexType>
<xs:complexType name="personName">
<xs:sequence>
<xs:element name="title" minOccurs="0"/>
<xs:element name="forename" minOccurs="0" maxOccurs="unbounded"/>
<xs:element name="surname"/>
</xs:sequence>
</xs:complexType>
<xs:complexType name="extendedName">
<xs:complexContent>
<xs:extension base="personName">
<xs:sequence>
<xs:element name="generation" minOccurs="0"/>
</xs:sequence>
</xs:extension>
</xs:complexContent>
</xs:complexType>
<xs:element name="addressee" type="extendedName"/>
<addressee>
<forename>Albert</forename>
<forename>Arnold</forename>
<surname>Gore</surname>
<generation>Jr</generation>
</addressee><xs:complexType name="simpleName">
<xs:complexContent>
<xs:restriction base="personName">
<xs:sequence>
<xs:element name="forename" minOccurs="1" maxOccurs="1"/>
<xs:element name="surname"/>
</xs:sequence>
</xs:restriction>
</xs:complexContent>
</xs:complexType>
<xs:element name="who" type="simpleName"/>
<who>
<forename>Bill</forename>
<surname>Clinton</surname>
</who><xs:complexType name="paraType" mixed="true"> <xs:choice minOccurs="0" maxOccurs="unbounded"> <xs:element ref="emph"/> <xs:element ref="strong"/> </xs:choice> <xs:attribute name="version" type="xs:decimal"/> </xs:complexType>
mixed attribute appearing on complexType itself.<xs:complexType name="name">
<xs:openContent>
<xs:any namespace="##other" processContents="skip"/>
</xs:openContent>
<xs:sequence>
<xs:element name="given" type="xs:string"/>
<xs:element name="middle" type="xs:string" minOccurs="0"/>
<xs:element name="family" type="xs:string"/>
</xs:sequence>
</xs:complexType><xs:complexType name="computer">
<xs:all>
<xs:element name="CPU" type="CPUType"/>
<xs:element name="memory" type="memoryType"/>
<xs:element name="monitor" type="monitorType"/>
<xs:element name="speaker" type="speakerType"
minOccurs="0"/>
<!-- Any additional information about the computer -->
<xs:any processContents="lax"
minOccurs="0" maxOccurs="unbounded"/>
</xs:all>
</xs:complexType>
<xs:complexType name="quietComputer">
<xs:complexContent>
<xs:restriction base="computer">
<xs:all>
<xs:element name="CPU" type="CPUType"/>
<xs:element name="memory" type="memoryType"/>
<xs:element name="monitor" type="monitorType"/>
<!-- Any additional information about the computer -->
<xs:any processContents="lax" notQName="speaker"
minOccurs="0" maxOccurs="unbounded"/>
</xs:all>
</xs:restriction>
</xs:complexContent>
</xs:complexType>quietComputer has
a lax wildcard, which ·matches· any element but one with the name
speaker.notQName attribute,
the wildcard would ·match· elements named
speaker, as well. In that case, the restriction
would be valid only if there is a
top-level declaration for speaker that also has type
speakerType or a type derived from it.
Otherwise, there would be instances locally valid against the restriction
quietComputer that are not locally valid against the base type
computer.notQName attribute on the wildcard and
no top-level declaration for speaker, then the following is allowed
by quietComputer, but not by computer:
<speaker xsi:type="xs:string"/>
3.4.3 Constraints on XML Representations of Complex Type Definitions
mixed = true.
xs:enumeration,
xs:pattern, or
xs:assertion
may appear more than once
among the [children] of
<restriction>.
mode ≠ 'none',
then there
must be an <any> among the [children] of
<openContent>.
mode = 'none',
then there must not be an <any> among the [children] of
<openContent>.
mixed [attribute] is present on both
<complexType> and <complexContent>,
then ·actual values· of those [attributes]
must be the same.
3.4.4 Complex Type Definition Validation Rules
3.4.4.1 Locally Declared Type
This section defines the concept of ·locally declared type·; this concept plays a role in determining whether restrictions and extensions of complex type definitions are legitimate. The ·locally declared type· is also used to help determine the ·governing element declaration· and ·governing type definition· of an element information item.
[Definition:] Every Complex Type Definition determines a partial functional mapping from element or attribute information items (and their expanded names) to type definitions. This mapping serves as a locally declared type for elements and attributes which are allowed by the Complex Type Definition.
The attribute case is simpler and will be taken first.
The definition for elements is slightly more complex.
3.4.4.2 Element Locally Valid (Complex Type)
xsi:type, xsi:nil,
xsi:schemaLocation, or xsi:noNamespaceSchemaLocation
(see Built-in Attribute Declarations (§3.2.7)),
the appropriate case among the following is true:xsi:type and the other
attributes named in
clause 2.1; no
·attribution·
is performed for them.
3.4.4.3 Element Sequence Locally Valid (Complex Content)
[Definition:] A sequence of element information items is locally valid with respect to a Content Type if and only if it satisfies Element Sequence Locally Valid (Complex Content) (§3.4.4.3) with respect to that Content Type.
3.4.4.4 Attribution
[Definition:] During ·validation· of an element information item against its (complex) ·governing type definition·, associations between element and attribute information items among the [children] and [attributes] on the one hand, and the attribute uses, attribute wildcard, particles and open content property record on the other, are established. The element or attribute information item is attributed to the corresponding component.
When an attribute information item has the same expanded name as the {attribute declaration} of an Attribute Use, then the item is attributed to that attribute use. Otherwise, if the item matches an attribute wildcard, as described in Item Valid (Wildcard) (§3.10.4.1), then the item is attributed to that wildcard. Otherwise the item is not attributed to any component.
- S is a member of S1 × S2
- S1 is a prefix of some element sequence that is ·locally valid· with respect to CT, as defined in Element Sequence Locally Valid (Complex Content) (§3.4.4.3).
- for every element E in S2, let S3 be the longest prefix of S1 where members of S3 are before E in S, then S3 + E is not a prefix of any element sequence that is ·locally valid· with respect to CT.
<xs:sequence>
<xs:element name="a"/>
<xs:element name="b"/>
<xs:element name="c"/>
</xs:sequence>
and an input sequence
<a/><b/><d/>Then the element <a> is ·attributed· to the particle whose term is the "a" element declaration. Similarly, <b> is ·attributed· to the "b" particle.
[Definition:] During ·validation·, associations between element and attribute information items among the [children] and [attributes] on the one hand, and element and attribute declarations on the other, are also established. When an item is ·attributed· to an ·element particle·, then it is associated with the declaration which is the {term} of the particle. Similarly, when an attribute information item is ·attributed to· an Attribute Use, then the item is associated with the {attribute declaration} of that Attribute Use. Such declarations are called the context-determined declarations. See clause 2.1 (in Element Locally Valid (Complex Type) (§3.4.4.2)) for attribute declarations, clause 2 (in Element Sequence Locally Valid (Particle) (§3.9.4.2)) for element declarations.
3.4.5 Complex Type Definition Information Set Contributions
3.4.5.1 Attribute Default Value
3.4.5.2 Match Information
- [attribute attribution]
-
The appropriate case among the following:1 If the attribute information item is ·attributed· to an Attribute Use, then an ·item isomorphic· to the Attribute Use.2 If the attribute information item is ·attributed· to an {attribute wildcard}, then an ·item isomorphic· to the attribute wildcard.
- [match information]
-
A keyword indicating what kind of component the
attribute information item is ·attributed· to.
The appropriate case among the following:1 If the item is ·attributed· to an Attribute Use, then attribute2 If the item is ·attributed· to a strict {attribute wildcard}, then strict3 If the item is ·attributed· to a lax {attribute wildcard}, then lax4 If the item is ·attributed· to a skip {attribute wildcard}, then skip
- [element attribution]
-
The appropriate case among the following:1 If the element information item is ·attributed· to an ·element particle· or a ·wildcard particle·, then an ·item isomorphic· to the Particle.
- [match information]
-
A keyword indicating what kind of Particle the
item is ·attributed· to.
The appropriate case among the following:1 If the item is ·attributed· to an ·element particle·, then element2 If the item is ·attributed· to a strict ·wildcard particle·, then strict3 If the item is ·attributed· to a lax ·wildcard particle·, then lax4 If the item is ·attributed· to a skip ·wildcard particle·, then skip5 If the item is ·attributed· to an Open Content, then open
3.4.6 Constraints on Complex Type Definition Schema Components
All complex type definitions (see Complex Type Definitions (§3.4)) must satisfy the following constraints.
3.4.6.1 Complex Type Definition Properties Correct
xs:anyType·. That is, it is
possible to reach the definition of
·xs:anyType· by repeatedly following the
{base type definition}.3.4.6.2 Derivation Valid (Extension)
xs:anyType·.[Definition:] A complex type T is a valid extension of its {base type definition} if and only if T.{derivation method} = extension and T satisfies the constraint Derivation Valid (Extension) (§3.4.6.2).
3.4.6.3 Derivation Valid (Restriction, Complex)
xs:anyType·.The constraint just given, like other constraints on schemas, must be satisfied by every complex type T to which it applies.
However, under certain conditions conforming processors need not (although they may) detect some violations of this constraint. If (1) the type definition being checked has T . {content type} . {particle} . {term} . {compositor} = all and (2) an implementation is unable to determine by examination of the schema in isolation whether or not clause 2.4.2 is satisfied, then the implementation may provisionally accept the derivation. If any instance encountered in the ·assessment· episode is valid against T but not against T.{base type definition}, then the derivation of T does not satisfy this constraint, the schema does not conform to this specification, and no ·assessment· can be performed using that schema.
It is ·implementation-defined· whether a processor (a) always detects violations of clause 2.4.2 by examination of the schema in isolation, (b) detects them only when some element information item in the input document is valid against T but not against T.{base type definition}, or (c) sometimes detects such violations by examination of the schema in isolation and sometimes not. In the latter case, the circumstances in which the processor does one or the other are ·implementation-dependent·.
3.4.6.4 Content Type Restricts (Complex Content)
3.4.6.5 Type Derivation OK (Complex)
The following constraint defines a relation appealed to elsewhere in this specification.
xs:anyType·.xsi:type or
·substitution groups·), that the type used is actually ·derived· from the expected
type, and that that ·derivation· does not involve a form of ·derivation· which was
ruled out by the expected type.- When they are both top-level components with the same component type, namespace name, and local name;
- When they are necessarily the same type definition (for example, when the two type definitions in question are the type definitions associated with two attribute or element declarations, which are discovered to be the same declaration);
- When they are the same by construction (for example, when an element's type definition defaults to being the same type definition as that of its substitution-group head or when a complex type definition inherits an attribute declaration from its base type definition).
3.4.7 Built-in Complex Type Definition
There is a complex
type definition for ·xs:anyType· present in every schema
by definition. It has the following properties:
The outer particle of ·xs:anyType· contains a sequence with a single term:
The inner particle of ·xs:anyType· contains a wildcard which matches any element:
rational) and utility (e.g. array) type definitions.
In particular, there is a text type definition which is recommended for use
as the type definition in element declarations intended for general text
content, as it makes sensible provision for various aspects of
internationalization. For more details, see the schema document for the type
library at its namespace name: http://www.w3.org/2001/03/XMLSchema/TypeLibrary.xsd. 3.5 Attribute Uses
3.5.2 XML Representation of Attribute Use Schema Components
3.5.3 Constraints on XML Representations of Attribute Uses
3.5.4 Attribute Use Validation Rules
3.5.5 Attribute Use Information Set Contributions
3.5.6 Constraints on Attribute Use Schema Components
An attribute use is a utility component which controls the occurrence and defaulting behavior of attribute declarations. It plays the same role for attribute declarations in complex types that particles play for element declarations.
<xs:complexType>
. . .
<xs:attribute ref="xml:lang" use="required"/>
<xs:attribute ref="xml:space" default="preserve"/>
<xs:attribute name="version" type="xs:decimal" fixed="1.0"/>
</xs:complexType>
3.5.1 The Attribute Use Schema Component
The attribute use schema component has the following properties:
{required} determines whether this use of an attribute declaration requires an appropriate attribute information item to be present, or merely allows it.
{attribute declaration} provides the attribute declaration itself, which will in turn determine the simple type definition used.
{value constraint} allows for local specification of a default or fixed value. This must be consistent with that of the {attribute declaration}, in that if the {attribute declaration} specifies a fixed value, the only allowed {value constraint} is the same fixed value, or a value equal or identical to it.
See Annotations (§3.15) for information on the role of the {annotations} property.
3.5.2 XML Representation of Attribute Use Schema Components
Attribute uses correspond to all uses of <attribute> which
allow a use attribute. These in turn correspond to
two components in each case, an attribute use and its {attribute declaration} (although note the latter is not new when the attribute use is a reference to a top-level attribute declaration). The appropriate mapping is described in XML Representation of Attribute Declaration Schema Components (§3.2.2).
3.5.4 Attribute Use Validation Rules
[Definition:] The effective value constraint of an attribute use U is U.{value constraint}, if present, otherwise U.{attribute declaration}.{value constraint}, if present, otherwise the effective value constraint is ·absent·.
3.5.6 Constraints on Attribute Use Schema Components
All attribute uses (see Attribute Uses (§3.5)) must satisfy the following constraints.
3.6 Attribute Group Definitions
3.6.2 XML Representation of Attribute Group Definition Schema Components
3.6.2.1 XML Mapping Rule for Named Attribute Groups
3.6.2.2 Common Rules for Attribute Wildcards
3.6.3 Constraints on XML Representations of Attribute Group Definitions
3.6.4 Attribute Group Definition Validation Rules
3.6.5 Attribute Group Definition Information Set Contributions
3.6.6 Constraints on Attribute Group Definition Schema Components
A schema can name a group of attribute declarations so that they can be incorporated as a group into complex type definitions.
Attribute group definitions do not participate in ·validation· as such, but the {attribute uses} and {attribute wildcard} of one or more complex type definitions may be constructed in whole or part by reference to an attribute group. Thus, attribute group definitions provide a replacement for some uses of XML's parameter entity facility. Attribute group definitions are provided primarily for reference from the XML representation of schema components (see <complexType> and <attributeGroup>).
<xs:attributeGroup name="myAttrGroup">
<xs:attribute . . ./>
. . .
</xs:attributeGroup>
<xs:complexType name="myelement">
. . .
<xs:attributeGroup ref="myAttrGroup"/>
</xs:complexType>
The example above illustrates the pattern
mentioned in XML Representations of Components (§3.1.2): The same
element, in this case attributeGroup, serves both to
define and to incorporate by reference. In the first
attributeGroup element in the example, the
name attribute is required and the
ref attribute is forbidden; in the second the
ref attribute is required, the
name attribute is forbidden.
3.6.1 The Attribute Group Definition Schema Component
The attribute group definition schema component has the following properties:
Attribute groups are identified by their {name} and {target namespace}; attribute group identities must be unique within an ·XSD schema·. See References to schema components across namespaces (<import>) (§4.2.6) for the use of component
identifiers when importing one schema into another.
{attribute uses} is a set of attribute uses, allowing for local specification of occurrence and default or fixed values.
{attribute wildcard} provides for an attribute wildcard to be included in an attribute group. See above under Complex Type Definitions (§3.4) for the interpretation of attribute wildcards during ·validation·.
See Annotations (§3.15) for information on the role of the {annotations} property.
3.6.2 XML Representation of Attribute Group Definition Schema Components
3.6.2.1 XML Mapping Rule for Named Attribute Groups
The XML representation for an attribute group definition schema component is an <attributeGroup> element information item. It provides for naming a group of attribute declarations and an attribute wildcard for use by reference in the XML representation of complex type definitions and other attribute group definitions. The correspondences between the properties of the information item after the appropriate ·pre-processing· and the properties of the component it corresponds to are given in this section.
attributeGroup Element Information Itemid = ID
name = NCName
ref = QName
{any attributes with non-schema namespace . . .}>
Content: (annotation?, ((attribute | attributeGroup)*, anyAttribute?))
</attributeGroup>
When an <attributeGroup> appears as a child of <schema> or <redefine>, it corresponds to an attribute group definition as below. When it appears as a child of <complexType> or <attributeGroup>, it does not correspond to any component as such.
<override>) (§4.2.5) for details.
targetNamespace [attribute] of the
<schema> ancestor
element information item if present, otherwise ·absent·.ref
[attribute] of the <attributeGroup>
[children], if any.
The rules given above for
{attribute uses}
and {attribute wildcard} specify that
if an <attributeGroup> element A contains a reference
to another attribute group B (i.e. A's [children] include an
<attributeGroup> with a ref attribute pointing
at B), then A maps to an Attribute Group Definition component whose
{attribute uses} reflect not only
the <attribute> [children] of A but also those of
B and of any <attributeGroup> elements referred
to in B. The same is true for attribute groups referred to from
complex types.
Circular reference is not disallowed. That is, it is not an error if B, or some <attributeGroup> element referred to by B (directly, or indirectly at some remove) contains a reference to A. An <attributeGroup> element involved in such a reference cycle maps to a component whose {attribute uses} and {attribute wildcard} properties reflect all the <attribute> and <any> elements contained in, or referred to (directly or indirectly) by elements in the cycle.
3.6.2.2 Common Rules for Attribute Wildcards
3.6.6 Constraints on Attribute Group Definition Schema Components
All attribute group definitions (see Attribute Group Definitions (§3.6)) must satisfy the following constraint.
3.7 Model Group Definitions
3.7.2 XML Representation of Model Group Definition Schema Components
3.7.3 Constraints on XML Representations of Model Group Definitions
3.7.4 Model Group Definition Validation Rules
3.7.5 Model Group Definition Information Set Contributions
3.7.6 Constraints on Model Group Definition Schema Components
A model group definition associates a name and optional annotations with a Model Group. By reference to the name, the entire model group can be incorporated by reference into a {term}.
Model group definitions are provided primarily for reference from the XML Representation of Complex Type Definition Schema Components (§3.4.2) (see <complexType> and <group>). Thus, model group definitions provide a replacement for some uses of XML's parameter entity facility.
<xs:group name="myModelGroup"> <xs:sequence> <xs:element ref="someThing"/> . . . </xs:sequence> </xs:group> <xs:complexType name="trivial"> <xs:group ref="myModelGroup"/> <xs:attribute .../> </xs:complexType> <xs:complexType name="moreSo"> <xs:choice> <xs:element ref="anotherThing"/> <xs:group ref="myModelGroup"/> </xs:choice> <xs:attribute .../> </xs:complexType>
3.7.1 The Model Group Definition Schema Component
The model group definition schema component has the following properties:
Model group definitions are identified by their {name} and {target namespace}; model group identities must be unique within an ·XSD schema·. See References to schema components across namespaces (<import>) (§4.2.6) for the use of component
identifiers when importing one schema into another.
Model group definitions per se do not participate in ·validation·, but the {term} of a particle may correspond in whole or in part to a model group from a model group definition.
{model group} is the Model Group for which the model group definition provides a name.
See Annotations (§3.15) for information on the role of the {annotations} property.
3.7.2 XML Representation of Model Group Definition Schema Components
The XML representation for a model group definition schema component is a <group> element information item. It provides for naming a model group for use by reference in the XML representation of complex type definitions and model groups. The correspondences between the properties of the information item after the appropriate ·pre-processing· and the properties of the component it corresponds to are given in this section.
group Element Information Itemid = ID
maxOccurs = (nonNegativeInteger | unbounded) : 1
minOccurs = nonNegativeInteger : 1
name = NCName
ref = QName
{any attributes with non-schema namespace . . .}>
Content: (annotation?, (all | choice | sequence)?)
</group>
If
the item has <schema>
or <redefine>
as its parent (in which case there will be a
name [attribute],
then the item maps
to a model group definition component with properties as
follows:
name [attribute]; if it overrides
a corresponding declaration in the ·target set· of its parent, it will also (in the
overridden schema document) map to a component as described
below. See Overriding component definitions (<override>) (§4.2.5) for details.
targetNamespace [attribute] of the
<schema>
ancestor element information
item if present, otherwise ·absent·.Otherwise,
if
the item
has
a ref [attribute]
and does not have minOccurs=maxOccurs=0
, then
the <group> element maps
to a particle component with properties
as follows:
maxOccurs [attribute] equals
unbounded, otherwise the ·actual value· of the
maxOccurs [attribute], if present, otherwise
1.ref
[attribute]Otherwise, the <group>
has minOccurs=maxOccurs=0, in which
case it maps to no component at all.
ref and no
name) is not really a named model group at all, but
a reference to one. Also note that in the first (named) case
above no reference is made to minOccurs or
maxOccurs: this is because the schema for schema documents does not
allow them on the child of <group> when it is
named. This in
turn is because the {min occurs} and
{max occurs} of the particles which
refer to the definition are what count.3.7.6 Constraints on Model Group Definition Schema Components
All model group definitions (see Model Group Definitions (§3.7)) must satisfy the following constraint.
3.8 Model Groups
3.8.2 XML Representation of Model Group Schema Components
3.8.3 Constraints on XML Representations of Model Groups
3.8.4 Model Group Validation Rules
3.8.4.1 Language Recognition by Groups
3.8.4.2 Principles of Validation against Groups
3.8.4.3 Element Sequence Valid
3.8.5 Model Group Information Set Contributions
3.8.6 Constraints on Model Group Schema Components
3.8.6.1 Model Group Correct
3.8.6.2 All Group Limited
3.8.6.3 Element Declarations Consistent
3.8.6.4 Unique Particle Attribution
3.8.6.5 Effective Total Range (all and sequence)
3.8.6.6 Effective Total Range (choice)
When the [children] of element information items are not constrained to be empty or by reference to a simple type definition (Simple Type Definitions (§3.16)), the sequence of element information item [children] content may be specified in more detail with a model group. Because the {term} property of a particle can be a model group, and model groups contain particles, model groups can indirectly contain other model groups; the grammar for model groups is therefore recursive. [Definition:] A model group directly contains the particles in the value of its {particles} property. [Definition:] A model group indirectly contains the particles, groups, wildcards, and element declarations which are ·contained· by the particles it ·directly contains·. [Definition:] A model group contains the components which it either ·directly contains· or ·indirectly contains·.
<xs:group name="otherPets"> <xs:all> <xs:element name="birds"/> <xs:element name="fish"/> </xs:all> </xs:group> <xs:all> <xs:element ref="cats"/> <xs:element ref="dogs"/> <xs:group ref="otherPets"/> </xs:all> <xs:sequence> <xs:choice> <xs:element ref="left"/> <xs:element ref="right"/> </xs:choice> <xs:element ref="landmark"/> </xs:sequence>
3.8.1 The Model Group Schema Component
The model group schema component has the following properties:
- (sequence) correspond, in order, to the specified {particles};
- (choice) correspond to exactly one of the specified {particles};
- (all) correspond to the specified {particles}. The elements can occur in any order.
When two or more element declarations contained ·directly·, ·indirectly·, or ·implicitly· in the {particles} of a model group have identical names, the type definitions of those declarations must be the same.
See Annotations (§3.15) for information on the role of the {annotations} property.
3.8.2 XML Representation of Model Group Schema Components
The XML representation for a model group schema component is either an <all>, a <choice> or a <sequence> element information item. The correspondences between the properties of those information items after the appropriate ·pre-processing· and the properties of the component they correspond to are given in this section.
all Element Information Item et al.id = ID
maxOccurs = (0 | 1) : 1
minOccurs = (0 | 1) : 1
{any attributes with non-schema namespace . . .}>
Content: (annotation?, (element | any | group)*)
</all>
id = ID
maxOccurs = (nonNegativeInteger | unbounded) : 1
minOccurs = nonNegativeInteger : 1
{any attributes with non-schema namespace . . .}>
Content: (annotation?, (element | group | choice | sequence | any)*)
</choice>
id = ID
maxOccurs = (nonNegativeInteger | unbounded) : 1
minOccurs = nonNegativeInteger : 1
{any attributes with non-schema namespace . . .}>
Content: (annotation?, (element | group | choice | sequence | any)*)
</sequence>
Each of the
above items corresponds to a particle containing a model group,
with properties as follows (unless minOccurs=maxOccurs=0,
in which case the item corresponds to no component at all):
maxOccurs
[attribute] equals unbounded, otherwise the ·actual value· of the maxOccurs
[attribute], if present, otherwise 1.The particle just described has a Model Group as the value of its {term} property, as follows.
3.8.4 Model Group Validation Rules
In order to define the validation rules for model groups clearly, it will be useful to define some basic terminology; this is done in the next two sections, before the validation rules themselves are formulated.
3.8.4.1 Language Recognition by Groups
Each model group M denotes a language L(M), whose members are the sequences of element information items ·accepted· by M.
Within L(M) a smaller language V(M) can be identified, which is of particular importance for schema-validity assessment. The difference between the two languages is that V(M) enforces some constraints which are ignored in the definition of L(M). Informally L(M) is the set of sequences which are accepted by a model group if no account is taken of the schema component constraint Unique Particle Attribution (§3.8.6.4) or the related provisions in the validation rules which specify how to choose a unique ·path· in a non-deterministic model group. By contrast, V(M) takes account of those constraints and includes only the sequences which are ·locally valid· against M. For all model groups M, V(M) is a subset of L(M). L(M) and related concepts are described in this section; V(M) is described in the next section, Principles of Validation against Groups (§3.8.4.2).
[Definition:] When a sequence S of element information items is checked against a model group M, the sequence of ·basic particles· which the items of S match, in order, is a path of S in M. For a given S and M, the path of S in M is not necessarily unique. Detailed rules for the matching, and thus for the construction of paths, are given in Language Recognition by Groups (§3.8.4.1) and Principles of Validation against Particles (§3.9.4.1). Not every sequence has a path in every model group, but every sequence accepted by the model group does have a path. [Definition:] For a model group M and a sequence S in L(M), the path of S in M is a complete path; prefixes of complete paths which are themselves not complete paths are incomplete paths. For example, in the model group
<xs:sequence>
<xs:element name="a"/>
<xs:element name="b"/>
<xs:element name="c"/>
</xs:sequence>the sequences (<a/><b/><c/>)
and (<a/><b/>) have ·paths·
(the first a ·complete path· and the second
an ·incomplete path·),
but the sequences (<a/><b/><c/><d/>) and
(<a/><x/>) do not
have paths.
<xs:sequence>
<xs:element name="a"/>
<xs:element name="b"/>
<xs:choice/>
</xs:sequence>
accepts no sequences because the empty choice recognizes
no input sequences. But the sequences (<a/>)
and (<a/><b/>) have paths in the model group.The definitions of L(M) and ·paths· in M, when M is a ·basic term· or a ·basic particle·, are given in Principles of Validation against Particles (§3.9.4.1). The definitions for groups are given below.
3.8.4.1.1 Sequences
This section defines L(M), the set of ·paths· in M, and V(M), if M is a sequence group.
If M is a Model Group, and the {compositor} of M is sequence, and the {particles} of M is the sequence P1, P2, ..., Pn, then L(M) is the set of sequences S = S1 + S2 + ... + Sn (taking "+" as the concatenation operator), where Si is in L(Pi) for 0 < i ≤ n. The sequence of sequences S1, S2, ..., Sn is a ·partition· of S. Less formally, when M is a sequence of P1, P2, ... Pn, then L(M) is the set of sequences formed by taking one sequence which is accepted by P1, then one accepted by P2, and so on, up through Pn, and then concatenating them together in order.
[Definition:] A partition of a sequence is a sequence of sub-sequences, some or all of which may be empty, such that concatenating all the sub-sequences yields the original sequence.
- j ≤ n, and
- S = S1 + S2 + ... + Sj (i.e. S1, S2, ..., Sj is a ·partition· of S), and
- Si is in L(Pi) for 0 < i < j, and
- Qi is a ·path· of Si in Pi for 0 < i ≤ j.
<xs:sequence>
<xs:element name="a"/>
<xs:element name="b"/>
<xs:element name="c"/>
</xs:sequence><a/><b/>
When M is a sequence group, the set V(M) (the set of sequences ·locally valid· against M) is the set of sequences S which are in L(M) and which have a ·validation-path· in M. Informally, V(M) contains those sequences which are accepted by M and for which no element information item is ever ·attributed to· a ·wildcard particle· if it can, in context, instead be ·attributed to· an ·element particle·. There will invariably be a ·partition· of S whose members are ·locally valid· against {particles} of M.
<xs:sequence> <xs:any minOccurs="0"/> <xs:element name="a" minOccurs="0"/> </xs:sequence>then the sequence (
<a/>) has two ·paths·
in M, one containing just the ·wildcard particle· and the other
containing just the ·element particle·. It is the latter
which is a ·validation-path· and which determines which
Particle the item in the input is ·attributed to·.
<xs:sequence> <xs:any minOccurs="0"/> <xs:element name="a"/> </xs:sequence>then the sequence (
<a/><a/>) is in L(M), but not
in V(M), because the validation rules require that the first
a be ·attributed to· the ·wildcard particle·.
In a ·validation-path· the initial a will invariably be
·attributed to· the ·element particle·, and so no sequence
with an initial a can be ·locally valid· against
this model group.3.8.4.1.2 Choices
This section defines L(M), the set of ·paths· in M, and V(M), if M is a choice group.
When the {compositor} of M is choice, and the {particles} of M is the sequence P1, P2, ..., Pn, then L(M) is L(P1) ∪ L(P2) ∪ ... ∪ L(Pn), and the set of ·paths· of S in P is the set Q = Q1 ∪ Q2 ∪ ... ∪ Qn, where Qi is the set of ·paths· of S in Pi, for 0 < i ≤ n. Less formally, when M is a choice of P1, P2, ... Pn, then L(M) contains any sequence accepted by any of the particles P1, P2, ... Pn, and any ·path· of S in any of the particles P1, P2, ... Pn is a ·path· of S in P.
The set V(M) (the set of sequences ·locally valid· against M) is the set of sequences S which are in L(M) and which have a ·validation-path· in M. In effect, this means that if one of the choices in M ·attributes· an initial element information item to a ·wildcard particle·, and another ·attributes· the same item to an ·element particle·, then the latter choice is used for validation.
<xs:choice> <xs:any/> <xs:element name="a"/> </xs:choice>then the ·validation-path· for the sequence (
<a/>)
contains just the ·element particle· and it is to the
·element particle· that the input element will be
·attributed·; the alternate ·path·
containing just the ·wildcard particle· is not relevant for
validation as defined in this specification.
3.8.4.1.3 All-groups
This section defines L(M), the set of ·paths· in M, and V(M), if M is an all-group.
When the {compositor} of M is all, and the {particles} of M is the sequence P1, P2, ..., Pn, then L(M) is the set of sequences S = S1 × S2 × ... × Sn (taking "×" as the interleave operator), where for 0 < i ≤ n, Si is in L(Pi). The set of sequences {S1, S2, ..., Sn} is a ·grouping· of S. The set of ·paths· of S in P is the set of all ·paths· Q = Q1 × Q2 × ... × Qn, where Qi is a ·path· of Si in Pi, for 0 < i ≤ n.
Less formally, when M is an all-group of P1, P2, ... Pn, then L(M) is the set of sequences formed by taking one sequence which is accepted by P1, then one accepted by P2, and so on, up through Pn, and then interleaving them together. Equivalently, L(M) is the set of sequences S such that the set {S1, S2, ..., Sn} is a ·grouping· of S, and for 0 < i ≤ n, Si is in L(Pi).
[Definition:] A grouping of a sequence is a set of sub-sequences, some or all of which may be empty, such that each member of the original sequence appears once and only once in one of the sub-sequences and all members of all sub-sequences are in the original sequence.
<xs:all> <xs:element name="a" minOccurs="0" maxOccurs="5"/> <xs:element name="b" minOccurs="1" maxOccurs="1"/> <xs:element name="c" minOccurs="0" maxOccurs="5"/> </xs:all>and an input sequence S
<a/><b/><a/>where n = 3, then S1 is (
<a/><a/>),
S2 is (<b/>),
and the ·path· of
S in M is the sequence containing first the Particle
for the a element, then the Particle for the
b element, then once more the
Particle for the a element.
The set V(M) (the set of sequences ·locally valid· against M) is the set of sequences S which are in L(M) and which have a ·validation-path· in M. In effect, this means that if one of the Particles in M ·attributes· an element information item to a ·wildcard particle·, and a ·competing· Particle ·attributes· the same item to an ·element particle·, then the ·element particle· is used for validation.
<xs:all> <xs:any/> <xs:element name="a"/> </xs:all>then M accepts sequences of length two, containing one
a element and one other element.
a element. After the first a
the ·element particle· accepts no more elements
and so no longer ·competes· with the ·wildcard particle·.
So if the sequence (<a/><a/>)
is checked against M, in the ·validation-path· the
first a element will be ·attributed to·
the ·element particle· and the second to the
·wildcard particle·.
a,
use a wildcard that explicitly disallows it. That is,
<xs:all> <xs:any notQName="a"/> <xs:element name="a"/> </xs:all>Now the sequence (
<a/><a/>) is not
accepted by the particle.
3.8.4.1.4 Multiple Paths in Groups
It is possible for a given sequence of element information items to have multiple ·paths· in a given model group M; this is the case, for example, when M is ambiguous, as for example
<xs:choice>
<xs:sequence>
<xs:element ref="my:a" maxOccurs="unbounded"/>
<xs:element ref="my:b"/>
</xs:sequence>
<xs:sequence>
<xs:element ref="my:a"/>
<xs:element ref="my:b" maxOccurs="unbounded"/>
</xs:sequence>
</xs:choice>which can match the sequence (<a/><b/>)
in more than one way.
It may also be the case with unambiguous model groups, if
they do not correspond to a deterministic
expression (as it is termed in [XML 1.1])
or a "1-unambiguous" expression, as it
is defined by [Brüggemann-Klein / Wood 1998].
For example,
<xs:sequence> <xs:element name="a" minOccurs="0"/> <xs:element name="a"/> </xs:sequence>
3.8.4.2 Principles of Validation against Groups
As noted above, each model group M denotes a language L(M), whose members are sequences of element information items. Each member of L(M) has one or more ·paths· in M, as do other sequences of element information items.
By imposing conditions on ·paths· in a model group M it is possible to identify a set of ·validation-paths· in M, such that if M is a model group which obeys the Unique Particle Attribution (§3.8.6.4) constraint, then any sequence S has at most one ·validation-path· in M. The language V(M) can then be defined as the set of sequences which have ·validation-paths· in M.
[Definition:] Two Particles P1 and P2 contained in some Particle P compete with each other if and only if some sequence S of element information items has two ·paths· in P which are identical except that one path has P1 as its last item and the other has P2.
For example, in the content model
<xs:sequence>
<xs:element name="a"/>
<xs:choice>
<xs:element name="b"/>
<xs:any/>
</xs:choice>
</xs:sequence>the sequence (<a/><b/>) has two paths,
one (Q1) consisting of the Particle whose {term} is
the declaration for a followed by the
Particle whose {term} is
the declaration for b, and
a second (Q2) consisting of the Particle whose {term} is
the declaration for a followed by the
Particle whose {term} is
the wildcard. The sequences Q1 and Q2 are
identical except for their last items, and so the
two Particles which are the last items of Q1 and
Q2 are said to ·compete· with each other.
<xs:choice>
<xs:sequence>
<xs:element name="a"/>
<xs:element name="b"/>
</xs:sequence>
<xs:sequence>
<xs:element name="c"/>
<xs:any/>
</xs:sequence>
</xs:choice>
the Particles for b and the
wildcard do not ·compete·, because there is no
pair of ·paths· in P which differ only in one
having the ·element particle· for b and
the other having the ·wildcard particle·.
[Definition:] Two (or more) ·paths· of a sequence S in a Particle P are competing paths if and only if they are identical except for their final items, which differ.
[Definition:] For any sequence S of element information items and any particle P, a ·path· of S in P is a validation-path if and only if for each prefix of the ·path· which ends with a ·wildcard particle·, the corresponding prefix of S has no ·competing path· which ends with an ·element particle·.
[Definition:] A sequence S of element information items is locally valid against a particle P if and only if S has a ·validation-path· in P. The set of all such sequences is written V(P).
3.8.4.3 Element Sequence Valid
3.8.6 Constraints on Model Group Schema Components
All model groups (see Model Groups (§3.8)) must satisfy the following constraints.
3.8.6.1 Model Group Correct
3.8.6.2 All Group Limited
= 1 which is
the {particle}
of the {content type} of a complex
type definition.=
{max occurs} = 1, where
P is among the {particles} of a
Model Group whose {compositor} is
all.3.8.6.3 Element Declarations Consistent
3.8.6.4 Unique Particle Attribution
[Definition:] An element particle is a Particle whose {term} is an Element Declaration. [Definition:] A wildcard particle is a Particle whose {term} is a Wildcard. Wildcard particles may be referred to as "strict", "lax", or "skip" particles, depending on the {process contents} property of their {term}.
3.8.6.5 Effective Total Range (all and sequence)
The following constraints define relations appealed to elsewhere in this specification.
0
if there are no
{particles}).0 if there are no
{particles}).3.8.6.6 Effective Total Range (choice)
0 if there are no {particles}).0 if there are no {particles}). 3.9 Particles
3.9.2 XML Representation of Particle Schema Components
3.9.3 Constraints on XML Representations of Particles
3.9.4 Particle Validation Rules
3.9.4.1 Principles of Validation against Particles
3.9.4.2 Element Sequence Locally Valid (Particle)
3.9.4.3 Element Sequence Accepted (Particle)
3.9.5 Particle Information Set Contributions
3.9.6 Constraints on Particle Schema Components
3.9.6.1 Particle Correct
3.9.6.2 Particle Valid (Extension)
3.9.6.3 Particle Emptiable
As described in Model Groups (§3.8), particles contribute to the definition of content models.
When an element is validated against a complex type, its sequence of child elements is checked against the content model of the complex type and the children are ·attributed to· to Particles of the content model. The attribution of items to Particles determines the calculation of the items' ·context-determined declarations· and thus partially determines the ·governing element declarations· for the children: when an element information item is ·attributed to· an ·element particle·, that Particle's Element Declaration, or an Element Declaration ·substitutable· for it, becomes the item's ·context-determined declaration· and thus normally its ·governing element declaration·; when the item is ·attributed to· a ·wildcard particle·, the ·governing element declaration· depends on the {process contents} property of the wildcard and on QName resolution (Instance) (§3.17.6.3).
<xs:element ref="egg" minOccurs="12" maxOccurs="12"/>
<xs:group ref="omelette" minOccurs="0"/>
<xs:any maxOccurs="unbounded"/>
3.9.1 The Particle Schema Component
The particle schema component has the following properties:
In general, multiple element information item [children], possibly with intervening character [children] if the content type is mixed, can be ·validated· with respect to a single particle. When the {term} is an element declaration or wildcard, {min occurs} determines the minimum number of such element [children] that can occur. The number of such children must be greater than or equal to {min occurs}. If {min occurs} is 0, then occurrence of such children is optional.
Again, when the {term} is an element declaration or wildcard, the number of such element [children] must be less than or equal to any numeric specification of {max occurs}; if {max occurs} is unbounded, then there is no upper bound on the number of such children.
When the {term} is a model group, the permitted occurrence range is determined by a combination of {min occurs} and {max occurs} and the occurrence ranges of the {term}'s {particles}.
[Definition:] A particle directly contains the component which is the value of its {term} property. [Definition:] A particle indirectly contains the particles, groups, wildcards, and element declarations which are contained by the value of its {term} property. [Definition:] A particle contains the components which it either ·directly contains· or ·indirectly contains·.
See Annotations (§3.15) for information on the role of the {annotations} property.
3.9.2 XML Representation of Particle Schema Components
minOccurs and maxOccurs
attributes in the schema document:- Model groups <all>, <sequence>, and <choice>, see XML Representation of Model Group Schema Components (§3.8.2)
- Group references <group>, see XML Representation of Model Group Definition Schema Components (§3.7.2)
3.9.4 Particle Validation Rules
3.9.4.1 Principles of Validation against Particles
Every particle P ·recognizes· some language L(P). When {min occurs} and {max occurs} of P are both 1, L(P) is the language of P's {term}, as described in Validation of Basic Terms (§3.9.4.1.2). The following section (Language Recognition for Repetitions (§3.9.4.1.1)) describes how more complicated counts are handled.
3.9.4.1.1 Language Recognition for Repetitions
When P.{min occurs} = P.{max occurs} = n, and P.{term} = T, then L(P) is the set of sequences S = S1 + S2 + ... + Sn such that Si is in L(T) for 0 < i ≤ n. Less formally: L(P) is the set of sequences which have ·partitions· into n sub-sequences for which each of the n subsequences is in the language accepted by the {term} of P.
When P.{min occurs} = j and P.{max occurs} = k, and P.{term} = T, then L(P) is the set of sequences S = S1, + S2 + ... + Sn, i.e. the set of sequences which have ·partitions· into n sub-sequences such that n ≥ j and n ≤ k (or k is unbounded) and Si is in L(T) for 0 < i ≤ n.
When P.{min occurs} = 0, then L(P) also includes the empty sequence.
- If T is a model group, then the set of ·paths· of S in P is the set of all ·paths· Q such that Q = Q1 + Q2 + ... + Qn, where Qi is a ·path· of Si in T for 0 < i ≤ n. (For the definition of ·paths· in model groups, see Language Recognition by Groups (§3.8.4.1).)
- If T is a ·basic term·, then the (sole) ·path· of S in P is a sequence of n occurrences of P.
3.9.4.1.2 Validation of Basic Terms
In the preceding section (Language Recognition for Repetitions (§3.9.4.1.1)), the language L(P) ·accepted· by a Particle P is defined in terms of the language ·accepted· by P's {term}. This section defines L(T) for ·basic terms·; for the definition of L(T) when T is a group, see Language Recognition by Groups (§3.8.4.1).
[Definition:] For any Element Declaration D, the language L(D) ·accepted· by D is the set of all sequences of length 1 whose sole member is an element information item which ·matches· D.
- The local name of E is identical to N.
- Either the namespace name of E is identical to NS, or else E has no namespace name (E is an unqualified name) and NS is ·absent·.
[Definition:] For any Wildcard W, the language L(W) ·accepted· by W is the set of all sequences of length 1 whose sole member is an element information item which ·matches· W.
[Definition:] An element information item E matches a Wildcard W (or a ·wildcard particle· whose {term} is W) if and only if E is locally ·valid· with respect to W, as defined in the validation rule Item Valid (Wildcard) (§3.10.4.1).
[Definition:] Two namespace names N1 and N2 are said to match if and only if they are identical or both are ·absent·.
For principles of validation when the {term} is a model group instead of a ·basic particle·, see Language Recognition by Groups (§3.8.4.1) and Principles of Validation against Groups (§3.8.4.2).
3.9.4.2 Element Sequence Locally Valid (Particle)
3.9.4.3 Element Sequence Accepted (Particle)
3.9.6 Constraints on Particle Schema Components
3.9.6.1 Particle Correct
All particles (see Particles (§3.9)) must satisfy the following constraint.
3.9.6.2 Particle Valid (Extension)
The following constraint defines a relation appealed to elsewhere in this specification.
3.9.6.3 Particle Emptiable
The following constraint defines a relation appealed to elsewhere in this specification.
0.0. 3.10 Wildcards
3.10.2 XML Representation of Wildcard Schema Components
3.10.2.1 Mapping from <any> to a Particle
3.10.2.2 Mapping from <any> and <anyAttribute> to a Wildcard Component
3.10.3 Constraints on XML Representations of Wildcards
3.10.4 Wildcard Validation Rules
3.10.4.1 Item Valid (Wildcard)
3.10.4.2 Wildcard allows Expanded Name
3.10.4.3 Wildcard allows Namespace Name
3.10.5 Wildcard Information Set Contributions
3.10.6 Constraints on Wildcard Schema Components
3.10.6.1 Wildcard Properties Correct
3.10.6.2 Wildcard Subset
3.10.6.3 Attribute Wildcard Union
3.10.6.4 Attribute Wildcard Intersection
In order to exploit the full potential for extensibility offered by XML plus namespaces, more provision is needed than DTDs allow for targeted flexibility in content models and attribute declarations. A wildcard provides for ·validation· of attribute and element information items dependent on their namespace names and optionally on their local names.
<xs:any processContents="skip"/>
<xs:any namespace="##other" processContents="lax"/>
<xs:any namespace="http://www.w3.org/1999/XSL/Transform"
xmlns:xsl="http://www.w3.org/1999/XSL/Transform"
notQName="xsl:comment xsl:fallback"/>
<xs:any notNamespace="##targetNamespace ##local"/>
<xs:anyAttribute namespace="http://www.w3.org/XML/1998/namespace"/>3.10.1 The Wildcard Schema Component
The wildcard schema component has the following properties:
A set each of whose members is either an xs:anyURI value or the distinguished value ·absent·. Required.
- ({variety} any) have any namespace or are not namespace-qualified;
- ({variety} not and {namespaces} a set whose members are either namespace names or ·absent·) have any namespace other than the specified namespaces and/or, if ·absent· is included in the set, are namespace-qualified; (see this example, which accepts only namespace-qualified names distinct from the target namespace; the "
##local" in the schema document maps to the value ·absent· in the {namespace constraint} property) - ({variety} enumeration and {namespaces} a set whose members are either namespace names or ·absent·) have any of the specified namespaces and/or, if ·absent· is included in the set, are unqualified.
- ({disallowed names} contains the keyword defined) have any expanded name other than those matching the names of global element or attribute declarations.
- ({disallowed names} contains the keyword sibling) have any expanded name other than those matching the names of element or attribute declarations in the containing complex type definition.
xsi:type, and the
item must be ·valid· as
appropriate.See Annotations (§3.15) for information on the role of the {annotations} property.
3.10.2 XML Representation of Wildcard Schema Components
The XML representation for a wildcard schema component is an <any> or <anyAttribute> element information item.
any Element Information Itemid = ID
maxOccurs = (nonNegativeInteger | unbounded) : 1
minOccurs = nonNegativeInteger : 1
namespace = ((##any | ##other) | List of (anyURI | (##targetNamespace | ##local)) )
notNamespace = List of (anyURI | (##targetNamespace | ##local))
notQName = List of (QName | (##defined | ##definedSibling))
processContents = (lax | skip | strict) : strict
{any attributes with non-schema namespace . . .}>
Content: (annotation?)
</any>
anyAttribute Element Information Itemid = ID
namespace = ((##any | ##other) | List of (anyURI | (##targetNamespace | ##local)) )
notNamespace = List of (anyURI | (##targetNamespace | ##local))
notQName = List of (QName | ##defined)
processContents = (lax | skip | strict) : strict
{any attributes with non-schema namespace . . .}>
Content: (annotation?)
</anyAttribute>
An <any> information item
corresponds both to a wildcard component and to
a particle containing that wildcard
(unless minOccurs=maxOccurs=0, in which case the
item corresponds to no component at
all).
The mapping rules are given in the following two subsections.
As always, the mapping rules
given here apply after, not before, the appropriate
·pre-processing·.
Processors may issue a warning
if a list of xs:anyURI values in the
namespace or noNamespace
attributes includes any values beginning
with the string '##'.
##' are not
IRIs or URIS according to the definitions given in
the relevant RFCs (for references see [XML Schema: Datatypes]) and
users of this specification are discouraged from using
them as namespace names, to avoid confusion with the
keyword values defined by this specification.
3.10.2.1 Mapping from <any> to a Particle
The mapping from an <any> information item to a particle is as follows.
maxOccurs = unbounded,
otherwise the ·actual value· of the
maxOccurs [attribute], if present, otherwise
1.3.10.2.2 Mapping from <any> and <anyAttribute> to a Wildcard Component
The mapping from an <any> information item to a wildcard component is as follows. This mapping is also used for mapping <anyAttribute> information items to wildcards, although in some cases the result of the mapping is further modified, as specified in the rules for <attributeGroup> and <complexType>.
namespace [attribute] is
present, then
the appropriate case among the following:namespace
= "##any", then any;namespace
= "##other", then not;notNamespace [attribute]
is present, then
not;
namespace nor
notNamespace is present) any.namespace nor
notNamespace is present, then the empty set;namespace = "##any", then the empty set;namespace
= "##other", then a set consisting of
·absent·
and, if the targetNamespace [attribute] of
the <schema> ancestor element
information item is present, its ·actual value·;namespace or
notNamespace [attribute] (whichever is
present), except
##targetNamespace, the corresponding
member is the ·actual value· of the
targetNamespace [attribute] of the
<schema> ancestor
element information item if present, otherwise
·absent·;##local, the
corresponding member is ·absent·.notQName [attribute] is
present, then a set whose members
correspond to the items in the
·actual value· of the notQName [attribute],
as follows.
- If the item is the token "
##defined", then the keyword defined is a member of the set. - If the item is the token "
##definedSibling", then the keyword sibling is a member of the set.
notQName
[attribute] is not present, then
the empty set.
Wildcards are subject to the same ambiguity constraints (Unique Particle Attribution (§3.8.6.4)) as other content model particles: If an instance element could match one of two wildcards, within the content model of a type, that model is in error.
3.10.3 Constraints on XML Representations of Wildcards
namespace and
notNamespace attributes must not both be
present.
3.10.4 Wildcard Validation Rules
3.10.4.1 Item Valid (Wildcard)
When an element or attribute information item is ·attributed· to a wildcard and the preceding constraint (Item Valid (Wildcard) (§3.10.4.1)) is satisfied, then the item has no ·context-determined declaration·. Its ·governing· declaration, if any, is found by matching its expanded name as described in QName resolution (Instance) (§3.17.6.3). Note that QName resolution is performed only if the item is ·attributed· to a strict or lax wildcard; if the wildcard has a {process contents} property of skip, then the item has no ·governing· declaration.
[Definition:] An element or attribute information item is skipped if it is ·attributed· to a skip wildcard or if one of its ancestor elements is.
3.10.4.2 Wildcard allows Expanded Name
3.10.4.3 Wildcard allows Namespace Name
3.10.6 Constraints on Wildcard Schema Components
3.10.6.1 Wildcard Properties Correct
All wildcards (see Wildcards (§3.10)) must satisfy the following constraint.
3.10.6.2 Wildcard Subset
The following constraints define a relation appealed to elsewhere in this specification.
3.10.6.3 Attribute Wildcard Union
3.10.6.4 Attribute Wildcard Intersection
3.11 Identity-constraint Definitions
3.11.2 XML Representation of Identity-constraint Definition Schema Components
3.11.3 Constraints on XML Representations of Identity-constraint Definitions
3.11.4 Identity-constraint Definition Validation Rules
3.11.5 Identity-constraint Definition Information Set Contributions
3.11.6 Constraints on Identity-constraint Definition Schema Components
3.11.6.1 Identity-constraint Definition Properties Correct
3.11.6.2 Selector Value OK
3.11.6.3 Fields Value OK
Identity-constraint definition components provide for uniqueness and reference constraints with respect to the contents of multiple elements and attributes.
<xs:key name="fullName"> <xs:selector xpath=".//person"/> <xs:field xpath="forename"/> <xs:field xpath="surname"/> </xs:key> <xs:keyref name="personRef" refer="fullName"> <xs:selector xpath=".//personPointer"/> <xs:field xpath="@first"/> <xs:field xpath="@last"/> </xs:keyref> <xs:unique name="nearlyID"> <xs:selector xpath=".//*"/> <xs:field xpath="@id"/> </xs:unique>
3.11.1 The Identity-constraint Definition Schema Component
The identity-constraint definition schema component has the following properties:
If a value is present, its {identity-constraint category} must be key or unique.
Identity-constraint definitions are identified by their {name} and {target namespace};
identity-constraint
definition identities must be unique within an ·XSD schema·. See References to schema components across namespaces (<import>) (§4.2.6) for the use of component
identifiers when importing one schema into another.
- (unique) the identity-constraint definition asserts uniqueness, with respect to the content identified by {selector}, of the tuples resulting from evaluation of the {fields} XPath expression(s).
- (key) the identity-constraint definition asserts uniqueness as for unique. key further asserts that all selected content actually has such tuples.
- (keyref) the identity-constraint definition asserts a correspondence, with respect to the content identified by {selector}, of the tuples resulting from evaluation of the {fields} XPath expression(s), with those of the {referenced key}.
These constraints are specified alongside the specification of types for the
attributes and elements involved, i.e. something declared as of type integer
can also serve as a key. Each constraint declaration has a name, which exists in a
single symbol space for constraints. The
equality and inequality
conditions
appealed to in checking these constraints apply to the
values of
the fields selected, not their
lexical representation, so that for example 3.0 and 3
would be conflicting keys if they were both
decimal, but non-conflicting if
they were both strings, or one was a string and one a decimal.
When equality and
identity differ for the simple types involved, all three
forms of identity-constraint test for
either equality
or identity
of values.
Overall the augmentations to XML's ID/IDREF mechanism are:
- Functioning as a part of an identity-constraint is in addition to, not instead of, having a type;
- Not just attribute values, but also element content and combinations of values and content can be declared to be unique;
- Identity-constraints are specified to hold within the scope of particular elements;
- (Combinations of) attribute values and/or element content can be declared to be keys, that is, not only unique, but always present and non-nillable;
{selector} specifies a restricted XPath ([XPath 2.0]) expression relative to instances of the element being declared. This must identify a sequence of element nodes that are contained within the declared element to which the constraint applies.
{fields} specifies XPath expressions relative to each element selected by a {selector}. Each XPath expression in the {fields} property must identify a single node (element or attribute), whose content or value, which must be of a simple type, is used in the constraint. It is possible to specify an ordered list of {fields}s, to cater to multi-field keys, keyrefs, and uniqueness constraints.
In order to reduce the burden on implementers, in particular implementers of streaming processors, only restricted subsets of XPath expressions are allowed in {selector} and {fields}. The details are given in Constraints on Identity-constraint Definition Schema Components (§3.11.6).
xsl:key.See Annotations (§3.15) for information on the role of the {annotations} property.
3.11.2 XML Representation of Identity-constraint Definition Schema Components
The XML representation for an identity-constraint definition schema component is either a <key>, a <keyref> or a <unique> element information item. The correspondences between the properties of those information items after the appropriate ·pre-processing· and the properties of the component they correspond to are as follows:
unique Element Information Item et al.id = ID
name = NCName
ref = QName
{any attributes with non-schema namespace . . .}>
Content: (annotation?, (selector, field+)?)
</unique>
id = ID
name = NCName
ref = QName
{any attributes with non-schema namespace . . .}>
Content: (annotation?, (selector, field+)?)
</key>
id = ID
name = NCName
ref = QName
refer = QName
{any attributes with non-schema namespace . . .}>
Content: (annotation?, (selector, field+)?)
</keyref>
id = ID
xpath = a subset of XPath expression, see below
xpathDefaultNamespace = (anyURI | (##defaultNamespace | ##targetNamespace | ##local))
{any attributes with non-schema namespace . . .}>
Content: (annotation?)
</selector>
id = ID
xpath = a subset of XPath expression, see below
xpathDefaultNamespace = (anyURI | (##defaultNamespace | ##targetNamespace | ##local))
{any attributes with non-schema namespace . . .}>
Content: (annotation?)
</field>
If the ref [attribute] is absent,
the corresponding schema
component is as follows:
targetNamespace [attribute] of the
<schema>
ancestor
element information item if present, otherwise ·absent·.xpath as the designated
expression [attribute].
xpath as the designated expression [attribute].
refer [attribute], otherwise
·absent·.
Otherwise (the ref [attribute] is
present), the corresponding schema component is the identity-constraint definition
·resolved· to by the ·actual value· of the
ref [attribute].
<xs:element name="vehicle">
<xs:complexType>
. . .
<xs:attribute name="plateNumber" type="xs:integer"/>
<xs:attribute name="state" type="twoLetterCode"/>
</xs:complexType>
</xs:element>
<xs:element name="state">
<xs:complexType>
<xs:sequence>
<xs:element name="code" type="twoLetterCode"/>
<xs:element ref="vehicle" maxOccurs="unbounded"/>
<xs:element ref="person" maxOccurs="unbounded"/>
</xs:sequence>
</xs:complexType>
<!-- vehicles are keyed by their plate within states -->
<xs:key name="reg">
<xs:selector xpath=".//vehicle"/>
<xs:field xpath="@plateNumber"/>
</xs:key>
</xs:element>
<xs:element name="root">
<xs:complexType>
<xs:sequence>
. . .
<xs:element ref="state" maxOccurs="unbounded"/>
. . .
</xs:sequence>
</xs:complexType>
<!-- states are keyed by their code -->
<xs:key name="state">
<xs:selector xpath=".//state"/>
<xs:field xpath="code"/>
</xs:key>
<xs:keyref name="vehicleState" refer="state">
<!-- every vehicle refers to its state -->
<xs:selector xpath=".//vehicle"/>
<xs:field xpath="@state"/>
</xs:keyref>
<!-- vehicles are keyed by a pair of state and plate -->
<xs:key name="regKey">
<xs:selector xpath=".//vehicle"/>
<xs:field xpath="@state"/>
<xs:field xpath="@plateNumber"/>
</xs:key>
<!-- people's cars are a reference -->
<xs:keyref name="carRef" refer="regKey">
<xs:selector xpath=".//car"/>
<xs:field xpath="@regState"/>
<xs:field xpath="@regPlate"/>
</xs:keyref>
</xs:element>
<xs:element name="person">
<xs:complexType>
<xs:sequence>
. . .
<xs:element name="car">
<xs:complexType>
<xs:attribute name="regState" type="twoLetterCode"/>
<xs:attribute name="regPlate" type="xs:integer"/>
</xs:complexType>
</xs:element>
</xs:sequence>
</xs:complexType>
</xs:element>state element is defined, which
contains a code child and some vehicle and person
children. A vehicle in turn has a plateNumber attribute,
which is an integer, and a state attribute. State's
codes are a key for them within the document. Vehicle's
plateNumbers are a key for them within states, and
state and
plateNumber is asserted to be a key for
vehicle within the document as a whole. Furthermore, a person element has
an empty car child, with regState and
regPlate attributes, which are then asserted together to refer to
vehicles via the carRef constraint. The requirement
that a vehicle's state match its containing
state's code is not expressed here.<xs:element name="stateList">
<xs:complexType>
<xs:sequence>
. . .
<xs:element name="state" maxOccurs="unbounded">
<xs:complexType>
<xs:sequence>
. . .
<xs:element name="code" type="twoLetterCode"/>
. . .
</xs:sequence>
</xs:complexType>
</xs:element>
. . .
</xs:sequence>
</xs:complexType>
<xs:key ref="state"/> <!-- reuse the key constraint from the above example -->
</xs:element>state elements can appear as child elements
under stateList. A key constraint can be used to
ensure that there is no duplicate state code. We already
defined a key in the above example for the exact same purpose
(the key constraint is named "state"). We can reuse it
directly via the ref attribute on the key
element.3.11.3 Constraints on XML Representations of Identity-constraint Definitions
ref or name is present, but not both.
name is present, then <selector> appears in
[children].
name is present on <keyref>, then
refer is also present.
ref is present, then only id
and <annotation> are
allowed to appear together with ref.
ref is present, then the
{identity-constraint category} of the identity-constraint
definition ·resolved· to by the
·actual value· of the ref [attribute] matches the name of the
element information item.
3.11.4 Identity-constraint Definition Validation Rules
For purposes of checking identity-constraints, single atomic values are not distinguished from lists with single items. An atomic value V and a list L with a single item are treated as equal, for purposes of this specification, if V is equal to the atomic value which is the single item of L. And similarly for identity.
3.11.5 Identity-constraint Definition Information Set Contributions
- [identity-constraint table]
-
one
Identity-constraint Binding
information item for each ·eligible identity-constraint·, with
properties as follows:
PSVI Contributions for Identity-constraint Binding information items
- [definition]
- The ·eligible identity-constraint·.
- [node table]
- A ·node table· with one entry for every ·key-sequence· (call it k) and
node (call it n) such that
one of the following is trueprovided no two entries have the same ·key-sequence· but distinct nodes. Potential conflicts are resolved by not including any conflicting entries which would have owed their inclusion to clause 1 above. Note that if all the conflicting entries arose under clause 1 above, this means no entry at all will appear for the offending ·key-sequence·.1 There is an entry in one of the ·node tables· associated with the [definition] in an Identity-constraint Binding information item in at least one of the [identity-constraint table]s of the element information item [children] of the element information item whose ·key-sequence· is k and whose node is n;2 n appears with ·key-sequence· k in the ·qualified node set· for the [definition].
3.11.6 Constraints on Identity-constraint Definition Schema Components
3.11.6.1 Identity-constraint Definition Properties Correct
All identity-constraint definitions (see Identity-constraint Definitions (§3.11)) must satisfy the following constraint.
3.11.6.2 Selector Value OK
| Selector XPath expressions | ||||||||||||||||
|
child axis whose abbreviated
form is as given above.| Lexical productions | ||||||||
|
[Definition:] The subset of XPath defined in Selector Value OK (§3.11.6.2) is called the selector subset of XPath.
3.11.6.3 Fields Value OK
| Path in Field XPath expressions | ||||
|
child and/or attribute axes whose abbreviated form is
as given above.[Definition:] The subset of XPath defined in Fields Value OK (§3.11.6.3) is called the field subset of XPath.
3.12 Type Alternatives
3.12.2 XML Representation of Type Alternative Schema Components
3.12.3 Constraints on XML Representations of Type Alternatives
3.12.4 Type Alternative Validation Rules
3.12.5 Type Alternative Information Set Contributions
3.12.6 Constraints on Type Alternative Schema Components
Type Alternative components provide associations between boolean conditions (as XPath expressions) and Type Definitions. They are used in conditional type assignment.
3.12.1 The Type Alternative Schema Component
The type alternative schema component has the following properties:
Type alternatives can be used by an Element Declaration to specify a condition ({test}) under which a particular type ({type definition}) is used as the ·governing type definition· for element information items governed by that Element Declaration. Each Element Declaration may have multiple Type Alternatives in its {type table}.
3.12.2 XML Representation of Type Alternative Schema Components
The XML representation for a type alternative schema component is an <alternative> element information item. The correspondences between the properties of that information item after the appropriate ·pre-processing· and the properties of the component it corresponds to are as follows:
alternative Element Information Itemid = ID
test = an XPath expression
type = QName
xpathDefaultNamespace = (anyURI | (##defaultNamespace | ##targetNamespace | ##local))
{any attributes with non-schema namespace . . .}>
Content: (annotation?, (simpleType | complexType)?)
</alternative>
Each <alternative> element maps to a Type Alternative component as follows.
test [attribute] is not present, then ·absent·;
otherwise an XPath Expression property record, as described in
section
XML Representation of Assertion Schema Components (§3.13.2), with
<alternative> as the "host element"
and test as the designated expression [attribute].
type
[attribute], if one is present, otherwise the type definition corresponding
to the complexType or simpleType among the
[children] of the <alternative> element.
3.12.3 Constraints on XML Representations of Type Alternatives
type
attribute, or a complexType child element, or a
simpleType child element.
3.12.4 Type Alternative Validation Rules
true and A.{type definition} = T.
The {test} is evaluated in the following way:false.
3.12.6 Constraints on Type Alternative Schema Components
All type alternatives (see Type Alternatives (§3.12)) must satisfy the following constraints.
| Test XPath expressions | ||||||||||||||||||||||||||||||||||||||||||||||||||||
|
attribute axis
whose abbreviated form is as given above.
fn:not and
constructors for the built-in datatypes.
a:b('123')" has 2 paths in the grammar, by matching either
BooleanFunction or
ConstructorFunction. The rules given
here require different function names for the productions. As a result, the
ambiguity can be resolved based on the function name.
cast as" QName in the
CastExpr production)
are casts to built-in datatypes.
3.13 Assertions
3.13.2 XML Representation of Assertion Schema Components
3.13.3 Constraints on XML Representations of Assertions
3.13.4 Assertion Validation Rules
3.13.4.1 Assertion Satisfied
3.13.4.2 XPath Evaluation
3.13.5 Assertion Information Set Contributions
3.13.6 Constraints on Assertion Schema Components
3.13.6.1 Assertion Properties Correct
3.13.6.2 XPath Valid
Assertion components constrain the existence and values of related elements and attributes.
<xs:assert test="@min le @max"/>
min attribute be less than or equal to that of the
max attribute, and fails if that is not the case.
3.13.1 The Assertion Schema Component
The assertion schema component has the following properties:
To check an assertion,
an instance of the XPath 2.0 data
model ([XDM]) is constructed,
in which the element
information item being ·assessed·
is the (parentless) root node,
and
elements and attributes are assigned types and values according to
XPath 2.0 data model construction rules, with some exceptions. See
Assertion Satisfied (§3.13.4.1) for details about how the data model is
constructed.
When evaluated against this data model
instance, {test} evaluates to either
true
or false (if any other value is returned, it's converted to
either true or false as if by a call to the XPath
fn:boolean function).
See Annotations (§3.15) for information on the role of the {annotations} property.
3.13.2 XML Representation of Assertion Schema Components
The XML representation for an assertion schema component is an <assert> element information item. The correspondences between the properties of that information item after the appropriate ·pre-processing· and the properties of the component it corresponds to are as follows:
assert Element Information Itemid = ID
test = an XPath expression
xpathDefaultNamespace = (anyURI | (##defaultNamespace | ##targetNamespace | ##local))
{any attributes with non-schema namespace . . .}>
Content: (annotation?)
</assert>
The <assert> element maps to an Assertion component as follows.
test as the designated expression [attribute].
Assertions, like identity constraints and conditional type assignment, use [XPath 2.0] expressions. The expression itself is recorded, together with relevant parts of the context, in an XPath Expression property record. The mapping is as described below; in each case, the XPath expression itself is given in a designated attribute of the appropriate "host element".
xpathDefaultNamespace [attribute], if
present on the host
element, otherwise that of the
xpathDefaultNamespace [attribute] of
the <schema> ancestor. Then
the value is
the appropriate case among the following:##defaultNamespace, then the appropriate case among the following:##targetNamespace, then the appropriate case among the following:targetNamespace
[attribute] is present on the <schema>
ancestor, then its ·actual value·;##local, then ·absent·;<xs:complexType name="intRange"> <xs:attribute name="min" type="xs:int"/> <xs:attribute name="max" type="xs:int"/> <xs:assert test="@min le @max"/> </xs:complexType>
min attribute must be less than or equal to
that of the max attribute.
Note that the attributes are validated before the assertion
on the parent element is checked, so the typed values of the attributes
are available for comparison; it is not necessary to cast the values
to int or some other numeric type before comparing them.
<xs:complexType name="arrayType"> <xs:sequence> <xs:element name="entry" minOccurs="0" maxOccurs="unbounded"/> </xs:sequence> <xs:attribute name="length" type="xs:int"/> <xs:assert test="@length eq fn:count(./entry)"/> </xs:complexType>
length attribute must be the same as
the number of occurrences of entry sub-elements.3.13.4 Assertion Validation Rules
3.13.4.1 Assertion Satisfied
true (see below) without raising
any dynamic error
or type
error.
$value",
as described in
Assertion Properties Correct (§3.13.6.1).
$value" appears as a member
of the variable values in
the dynamic context. The
expanded QName of that member has no namespace URI and has
"value" as the local name.
The value of the member is determined by the appropriate case among the following:value is the
XDM representation of
E.[schema actual value]
under the {content type}
. {simple type definition}
of E's ·governing type definition·.
.", while
its content may be referred to as
"$value". Since the element node,
as a consequence of clause 1.2, will normally have the type
annotation anyType, its atomized
value will be a single atomic value of type
untypedAtomic. By contrast,
$value will be a sequence of one or more
atomic values, whose types are the most specific
(narrowest) built-in types available.value is the empty sequence.
true
or false as if by a call to the XPath
fn:boolean function.3.13.4.2 XPath Evaluation
It is ·implementation-defined· (both in this specification and in [XPath 2.0]) when type errors are detected and whether, when detected, they are treated as static or dynamic errors.
3.13.6 Constraints on Assertion Schema Components
All assertions (see Assertions (§3.13)) must satisfy the following constraints.
3.13.6.1 Assertion Properties Correct
expanded QName of that
member has no namespace URI and has value as the local
name. The (static) type of the member is
anyAtomicType*.
http://www.w3.org/2005/xpath-functions
namespace as defined in the [Functions and Operators] specification.
anyAtomicType* simply says
that for static typing purposes the variable $value
will have a value consisting of a sequence of zero or more
atomic values.3.13.6.2 XPath Valid
http://www.w3.org/2005/xpath-functions.http://www.w3.org/2005/xpath-functions/collation/codepoint)
defined by [Functions and Operators].It is ·implementation-defined· (both in this specification and in [XPath 2.0]) when type errors are detected and whether, when detected, they are treated as static or dynamic errors.
3.14 Notation Declarations
3.14.2 XML Representation of Notation Declaration Schema Components
3.14.3 Constraints on XML Representations of Notation Declarations
3.14.4 Notation Declaration Validation Rules
3.14.5 Notation Declaration Information Set Contributions
3.14.6 Constraints on Notation Declaration Schema Components
Notation declarations reconstruct XML NOTATION declarations.
<xs:notation name="jpeg" public="image/jpeg" system="viewer.exe">
3.14.1 The Notation Declaration Schema Component
The notation declaration schema component has the following properties:
Notation declarations do not participate in ·validation· as such. They are referenced in the course of ·validating· strings as members of the NOTATION simple type. An element or attribute information item with its ·governing· type definition or its ·validating type· derived from the NOTATION simple type is ·valid· only if its value was among the enumerations of such simple type. As a consequence such a value is required to be the {name} of a notation declaration.
See Annotations (§3.15) for information on the role of the {annotations} property.
3.14.2 XML Representation of Notation Declaration Schema Components
The XML representation for a notation declaration schema component is a <notation> element information item. The correspondences between the properties of that information item after the appropriate ·pre-processing· and the properties of the component it corresponds to are as follows:
notation Element Information ItemThe <notation> element maps to a Notation Declaration component as follows.
targetNamespace [attribute] of the
<schema> ancestor
element information item if present, otherwise ·absent·.<xs:notation name="jpeg"
public="image/jpeg" system="viewer.exe" />
<xs:element name="picture">
<xs:complexType>
<xs:simpleContent>
<xs:extension base="xs:hexBinary">
<xs:attribute name="pictype">
<xs:simpleType>
<xs:restriction base="xs:NOTATION">
<xs:enumeration value="jpeg"/>
<xs:enumeration value="png"/>
. . .
</xs:restriction>
</xs:simpleType>
</xs:attribute>
</xs:extension>
</xs:simpleContent>
</xs:complexType>
</xs:element>
<picture pictype="jpeg">...</picture>3.14.5 Notation Declaration Information Set Contributions
- [notation]
- An ·item isomorphic· to the notation declaration ·resolved· to by the attribute item's ·actual value·
- [notation system]
- The value of the {system identifier} of that notation declaration.
- [notation public]
- The value of the {public identifier} of that notation declaration.
3.14.6 Constraints on Notation Declaration Schema Components
All notation declarations (see Notation Declarations (§3.14)) must satisfy the following constraint.
3.15 Annotations
3.15.2 XML Representation of Annotation Schema Components
3.15.3 Constraints on XML Representations of Annotations
3.15.4 Annotation Validation Rules
3.15.5 Annotation Information Set Contributions
3.15.6 Constraints on Annotation Schema Components
Annotations provide for human- and machine-targeted annotations of schema components.
<xs:simpleType
fn:note="special"> <xs:annotation> <xs:documentation>A type for
experts only</xs:documentation> <xs:appinfo>
<fn:specialHandling>checkForPrimes</fn:specialHandling>
</xs:appinfo> </xs:annotation>
3.15.1 The Annotation Schema Component
The annotation schema component has the following properties:
{user information} is intended for
human consumption, {application information} for automatic processing. In both cases,
provision is made for an optional URI reference to supplement the
local information, as the value of the source
attribute of the respective element information items.
·validation· does not involve dereferencing these
URIs, when present. In the case of {user information}, indication should be given as
to the identity of the (human) language used in the contents,
using the xml:lang attribute.
{attributes} ensures that when schema authors take advantage of the provision for adding attributes from namespaces other than the XSD namespace to schema documents, they are available within the components corresponding to the element items where such attributes appear.
Annotations do not participate in ·validation· as such. Provided an annotation itself satisfies all relevant ·Schema Component Constraints· it cannot affect the ·validation· of element information items.
The mapping defined in this specification from XML representations to components does not apply to XML elements contained within an <annotation> element; such elements do not correspond to components, when the mapping defined here is used.
It is ·implementation-defined· what effect, if any, the invalidity of a descendant of <annotation> has on the construction of schema components from the enclosing schema document.
The name [Definition:] Annotated Component covers all the different kinds of component which may have annotations.
3.15.2 XML Representation of Annotation Schema Components
Annotation of schemas and schema components, with material for human or computer consumption, is provided for by allowing application information and human information at the beginning of most major schema elements, and anywhere at the top level of schemas. The XML representation for an annotation schema component is an <annotation> element information item. The correspondences between the properties of that information item after the appropriate ·pre-processing· and the properties of the component it corresponds to are as follows:
annotation Element Information Item et al.id = ID
{any attributes with non-schema namespace . . .}>
Content: (appinfo | documentation)*
</annotation>
source = anyURI
{any attributes with non-schema namespace . . .}>
Content: ({any})*
</appinfo>
source = anyURI
xml:lang = language
{any attributes with non-schema namespace . . .}>
Content: ({any})*
</documentation>
The <annotation> element and its descendants map to an Annotation component as follows.
The annotation component corresponding to the <annotation> element in the example above will have one element item in each of its {user information} and {application information} and one attribute item in its {attributes}.
Virtually every kind of schema component defined in this specification has an {annotations} property. When the component is described in a schema document, the mapping from the XML representation of the component to the Annotation components in the appropriate {annotations} property follows the rules described in the next paragraph.
3.15.5 Annotation Information Set Contributions
None as such: the addition of annotations to the ·post-schema-validation infoset· is covered by the ·post-schema-validation infoset· contributions of the enclosing components.
3.15.6 Constraints on Annotation Schema Components
All annotations (see Annotations (§3.15)) must satisfy the following constraint.
3.16 Simple Type Definitions
3.16.2 XML Representation of Simple Type Definition Schema Components
3.16.2.1 Common mapping rules for Simple Type Definitions
3.16.2.2 Mapping Rules for Atomic Simple Type Definitions
3.16.2.3 Mapping Rules for Lists
3.16.2.4 Mapping Rules for Unions
3.16.3 Constraints on XML Representations of Simple Type Definitions
3.16.4 Simple Type Definition Validation Rules
3.16.5 Simple Type Definition Information Set Contributions
3.16.6 Constraints on Simple Type Definition Schema Components
3.16.6.1 Simple Type Definition Properties Correct
3.16.6.2 Derivation Valid (Restriction, Simple)
3.16.6.3 Type Derivation OK (Simple)
3.16.6.4 Simple Type Restriction (Facets)
3.16.7 Built-in Simple Type Definitions
3.16.7.1 xs:anySimpleType
3.16.7.2 xs:anyAtomicType
3.16.7.3 xs:error
3.16.7.4 Built-in primitive datatypes
3.16.7.5 Other built-in datatypes
Simple type definitions provide for constraining character information item [children] of element and attribute information items.
<xs:simpleType name="celsiusWaterTemp"> <xs:restriction base="xs:decimal"> <xs:fractionDigits value="2"/> <xs:minExclusive value="0.00"/> <xs:maxExclusive value="100.00"/> </xs:restriction> </xs:simpleType>
3.16.1 The Simple Type Definition Schema Component
The simple type definition schema component has the following properties:
Either an Attribute Declaration, an Element Declaration, a Complex Type Definition, or a Simple Type Definition.
With one exception, the {base type definition} of any Simple Type Definition is a Simple Type Definition. The exception is ·xs:anySimpleType·, which has
·xs:anyType·, a
Complex Type Definition, as its {base type definition}.
xs:anySimpleType·,
in which it is ·absent·.xs:anyAtomicType·, whose
{primitive type definition} is ·absent·.
The value of this property must be a primitive or ordinary simple type definition with {variety} = atomic, or an ordinary simple type definition with {variety} = union whose basic members are all atomic; the value must not itself be a list type (have {variety} = list) or have any basic members which are list types.
Simple types are identified by their {name} and {target namespace}. Except
for anonymous simple types (those with no {name}), since
type definitions (i.e. both simple and complex type definitions taken together) must be uniquely identified within an ·XSD schema·, no simple type definition can have the same name as another
simple or complex type definition. Simple type {name}s and {target namespace}s
are provided for reference from
instances (see xsi:type (§2.7.1)), and for use in the XML
representation of schema components
(specifically in <element> and <attribute>). See References to schema components across namespaces (<import>) (§4.2.6) for the use of component
identifiers when importing one schema into another.
A simple type definition with an empty specification for {final} can be used as the {base type definition} for other types ·derived· by either of extension or restriction, or as the {item type definition} in the definition of a list, or in the {member type definitions} of a union; the explicit values extension, restriction, list and union prevent further ·derivations· by extension (to yield a complex type) and restriction (to yield a simple type) and use in ·constructing· lists and unions respectively.
{variety} determines whether the simple type corresponds to an atomic, list or union type as defined by [XML Schema: Datatypes].
As described in Type Definition Hierarchy (§2.2.1.1), every simple type definition is
a ·restriction· of some other simple
type (the {base type definition}), which is ·xs:anySimpleType· if and only if the type
definition in question is ·xs:anyAtomicType· or a list or
union type definition which is not itself ·derived· by restriction from a
list or union respectively.
A type definition
has ·xs:anyAtomicType· as its {base type definition} if and only if it is one of the primitive datatypes. Each
atomic type is ultimately a restriction of exactly one such
primitive datatype, which is its {primitive type definition}.
The {facets} property contains a set of constraining facets which are used to specify constraints on the datatype described by the simple type definition. For atomic definitions, these are restricted to those appropriate for the corresponding {primitive type definition}. Therefore, the value space and lexical space (i.e. what is ·validated· by any atomic simple type) is determined by the pair ({primitive type definition}, {facets}).
Constraining facets are defined in [XML Schema: Datatypes]. All conforming implementations of this specification must support all of the facets defined in [XML Schema: Datatypes]. It is ·implementation-defined· whether additional facets are supported; if they are, the implementation must satisfy the rules for ·implementation-defined· facets described in [XML Schema: Datatypes].
As specified in [XML Schema: Datatypes], list simple type definitions ·validate· space separated tokens, each of which conforms to a specified simple type definition, the {item type definition}. The item type specified must not itself be a list type, and must be one of the types identified in [XML Schema: Datatypes] as a suitable item type for a list simple type. In this case the {facets} apply to the list itself, and are restricted to those appropriate for lists.
A union simple type definition ·validates· strings which satisfy at least one of its {member type definitions}. As in the case of list, the {facets} apply to the union itself, and are restricted to those appropriate for unions.
·xs:anySimpleType· or ·xs:anyAtomicType·
must not be named as the {base type definition} of any user-defined
atomic simple type definitions:
as they allow no constraining facets, this
would be incoherent.
See Annotations (§3.15) for information on the role of the {annotations} property.
3.16.2 XML Representation of Simple Type Definition Schema Components
As always, the mapping rules given in this section apply after, not before, the appropriate ·pre-processing·.
simpleType Element Information Item et al.final = (#all | List of (list | union | restriction | extension))
id = ID
name = NCName
{any attributes with non-schema namespace . . .}>
Content: (annotation?, (restriction | list | union))
</simpleType>
base = QName
id = ID
{any attributes with non-schema namespace . . .}>
Content: (annotation?, (simpleType?, (minExclusive | minInclusive | maxExclusive | maxInclusive | totalDigits | fractionDigits | length | minLength | maxLength | enumeration | whiteSpace | pattern | assertion | explicitTimezone | {any with namespace: ##other})*))
</restriction>
id = ID
itemType = QName
{any attributes with non-schema namespace . . .}>
Content: (annotation?, simpleType?)
</list>
id = ID
memberTypes = List of QName
{any attributes with non-schema namespace . . .}>
Content: (annotation?, simpleType*)
</union>
The <simpleType> element and its descendants normally, when there are no errors, map to a Simple Type Definition component. The case in which an unknown facet is used in the definition of a simple type definition is handled specially: the <simpleType> in question is not in error, but it does not map to any component at all.
- If the <simpleType> element has a <restriction> element among its children, and the base type definition has {variety} = atomic, then the mapping rules in Common mapping rules for Simple Type Definitions (§3.16.2.1) and Mapping Rules for Atomic Simple Type Definitions (§3.16.2.2) apply.
- If the <simpleType> element has a <list> element among its children, or if it has a <restriction> child and the base type definition has {variety} = list, then the mapping rules in Common mapping rules for Simple Type Definitions (§3.16.2.1) and Mapping Rules for Lists (§3.16.2.3) apply.
- If the <simpleType> element has a <union> element among its children, or if it has a <restriction> child and the base type definition has {variety} = union, then the mapping rules in Common mapping rules for Simple Type Definitions (§3.16.2.1) and Mapping Rules for Unions (§3.16.2.4) apply.
3.16.2.1 Common mapping rules for Simple Type Definitions
The following rules apply to all simple type definitions.
name [attribute]
if present on the <simpleType> element,
otherwise ·absent·.targetNamespace [attribute] of
the ancestor <schema>
element information item if present,
otherwise ·absent·.base [attribute] of <restriction>, if present, otherwise the
type definition corresponding to the <simpleType> among
the [children] of <restriction>.{restriction, extension, list,
union}, determined as follows.
[Definition:] Let
FS be
the ·actual value· of the
final [attribute],
if present, otherwise the ·actual value· of the
finalDefault [attribute] of the ancestor
schema element,
if present, otherwise the empty string. Then the property value is
the appropriate case among the following:
3.16.2.2 Mapping Rules for Atomic Simple Type Definitions
The following rule applies if the {variety} is atomic
[Definition:] The ancestors of a ·type definition· are its {base type definition} and the ·ancestors· of its {base type definition}. (The ancestors of a Simple Type Definition T in the type hierarchy are themselves ·type definitions·; they are distinct from the XML elements which may be ancestors, in the XML document hierarchy, of the <simpleType> element which declares T.)
3.16.2.3 Mapping Rules for Lists
If the {variety} is list, the following additional property mapping applies:
xs:anySimpleType·, then the Simple Type Definition (a) ·resolved·
to by the
·actual value· of the itemType [attribute] of <list>,
or (b), corresponding to the <simpleType> among
the [children] of <list>, whichever is present.
itemType [attribute] or a <simpleType> [child], but not both.xs:anySimpleType·), the {item type definition} of the {base type definition}.
3.16.2.4 Mapping Rules for Unions
If the {variety} is union, the following additional property mapping applies:
xs:anySimpleType·, then the sequence of
Simple Type Definitions (a)
·resolved· to by the items in the
·actual value· of the memberTypes [attribute] of <union>,
if any, and (b)
corresponding to the <simpleType>s among
the [children] of <union>, if any, in order.
memberTypes [attribute] or one or more <simpleType> [children], or both.xs:anySimpleType·), the {member type definitions} of the {base type definition}.
3.16.3 Constraints on XML Representations of Simple Type Definitions
xs) namespace,
unless that
expanded name is one of
xs:enumeration,
xs:pattern, or
xs:assertion.
base [attribute]
or a <simpleType> among its [children], but not
both.itemType [attribute]
or a <simpleType> among its [children],
but not both.memberTypes [attribute] or it
has at least one simpleType [child].3.16.4 Simple Type Definition Validation Rules
3.16.6 Constraints on Simple Type Definition Schema Components
3.16.6.1 Simple Type Definition Properties Correct
All simple type definitions must satisfy both the following constraints.
xs:anySimpleType· (so circular
definitions are disallowed). That is, it is possible
to reach a primitive datatype or ·xs:anySimpleType· by
following the {base type definition} zero or more
times.3.16.6.2 Derivation Valid (Restriction, Simple)
xs:anyAtomicType·, or else B is an atomic simple type
definition. xs:anyAtomicType· is an exception because its
{base type definition} is ·xs:anySimpleType·, whose
{variety} is ·absent·.xs:anySimpleType·
, then
all of the following are true:xs:anySimpleType·
, then
all of the following are true:[Definition:] A simple type definition T is a valid restriction of its {base type definition} if and only if T satisfies constraint Derivation Valid (Restriction, Simple) (§3.16.6.2).
3.16.6.3 Type Derivation OK (Simple)
The following constraint defines relations appealed to elsewhere in this specification.
xs:anyType· and is validly ·derived· from B
given S,
as defined by this constraint.xs:anySimpleType·.3.16.6.4 Simple Type Restriction (Facets)
3.16.7 Built-in Simple Type Definitions
3.16.7.1 xs:anySimpleType
The Simple Type Definition of anySimpleType is present in every schema. It has the following properties:
anySimpleType'http://www.w3.org/2001/XMLSchema'The definition
of ·xs:anySimpleType· is the
root of the simple type definition
hierarchy, and as such mediates between the other simple type
definitions, which all eventually trace back to it via their
{base type definition} properties,
and
·xs:anyType·, which is
its {base type definition}.
3.16.7.2 xs:anyAtomicType
The Simple Type Definition of anyAtomicType is present in every schema. It has the following properties:
anyAtomicType'http://www.w3.org/2001/XMLSchema'3.16.7.3 xs:error
A Simple Type Definition for ·xs:error· is present in every schema
by definition. It has the following properties:
error'http://www.w3.org/2001/XMLSchema'xs:error has no valid instances
(i.e. it has an empty value space and an empty lexical space).
This is a natural consequence of its construction: a value is
a value of a union type if and only if it is a value of at
least one member of the {member type definitions} of the union. Since xs:error has
no member type definitions, there can be no values which are
values of at least one of its member types. And since the value
space is empty, the lexical space is also empty.xs:error is expected to be used
mostly in conditional type assignment. Whenever it serves as the
·governing· type definition for an attribute or element information
item, that item will be invalid.3.16.7.4 Built-in primitive datatypes
Simple type definitions corresponding to all the built-in primitive datatypes, namely string, boolean, float, double, decimal, dateTime, duration, time, date, gMonth, gMonthDay, gDay, gYear, gYearMonth, hexBinary, base64Binary, anyURI, QName and NOTATION (see the Primitive Datatypes section of [XML Schema: Datatypes]) are present by definition in every schema as follows:
http://www.w3.org/2001/XMLSchema'[as appropriate]
All conforming implementations of this specification must support all the primitive datatypes defined in [XML Schema: Datatypes]. It is ·implementation-defined· whether additional primitive datatypes are supported, and whether, if so, they are automatically incorporated in every schema or not. If ·implementation-defined· primitives are supported, the implementation must satisfy the rules for ·implementation-defined· primitive datatypes described in [XML Schema: Datatypes].
[Definition:] A type about which a processor possesses prior knowledge, and which the processor can support without any declaration of the type being supplied by the user, is said to be automatically known to the processor.
3.16.7.5 Other built-in datatypes
Similarly, simple type definitions corresponding to all the other built-in datatypes (see the Other Built-in Datatypes section of [XML Schema: Datatypes]) are present by definition in every schema, with properties as specified in [XML Schema: Datatypes] and as represented in XML in Illustrative XML representations for the built-in ordinary type definitions.
http://www.w3.org/2001/XMLSchema'All conforming implementations of this specification must support all the built-in datatypes defined in [XML Schema: Datatypes]. It is ·implementation-defined· whether additional derived types are ·automatically known· to the implementation without declaration and whether, if so, they are automatically incorporated in every schema or not.
3.17 Schemas as a Whole
3.17.2 XML Representations of Schemas
3.17.2.1 References to Schema Components
3.17.2.2 References to Schema Components from Elsewhere
3.17.3 Constraints on XML Representations of Schemas
3.17.4 Validation Rules for Schemas as a Whole
3.17.5 Schema Information Set Contributions
3.17.5.1 Schema Information
3.17.5.2 ID/IDREF Table
3.17.6 Constraints on Schemas as a Whole
3.17.6.1 Schema Properties Correct
3.17.6.2 QName resolution (Schema Document)
3.17.6.3 QName resolution (Instance)
A schema consists of a set of schema components.
<xs:schema
xmlns:xs="http://www.w3.org/2001/XMLSchema"
targetNamespace="http://www.example.com/example">
. . .
</xs:schema>3.17.1 The Schema Itself
At the abstract level, the schema itself is just a container for its components.
3.17.2 XML Representations of Schemas
A schema is represented in XML by one or more ·schema documents·, that is, one or more <schema> element information items. A ·schema document· contains representations for a collection of schema components, e.g. type definitions and element declarations, which have a common {target namespace}. A ·schema document· which has one or more <import> element information items corresponds to a schema with components with more than one {target namespace}, see Import Constraints and Semantics (§4.2.6.2).
As always, the mapping rules given in this section apply after, not before, the appropriate ·pre-processing·.
schema Element Information Item et al.attributeFormDefault = (qualified | unqualified) : unqualified
blockDefault = (#all | List of (extension | restriction | substitution)) : ''
defaultAttributes = QName
xpathDefaultNamespace = (anyURI | (##defaultNamespace | ##targetNamespace | ##local)) : ##local
elementFormDefault = (qualified | unqualified) : unqualified
finalDefault = (#all | List of (extension | restriction | list | union)) : ''
id = ID
targetNamespace = anyURI
version = token
xml:lang = language
{any attributes with non-schema namespace . . .}>
Content: ((include | import | redefine | override | annotation)*, (defaultOpenContent, annotation*)?, ((simpleType | complexType | group | attributeGroup | element | attribute | notation), annotation*)*)
</schema>
appliesToEmpty = boolean : false
id = ID
mode = (interleave | suffix) : interleave
{any attributes with non-schema namespace . . .}>
Content: (annotation?, any)
</defaultOpenContent>
The <schema> element information item maps to a Schema component as follows.
<include>) (§4.2.3)),
<override>
(see Overriding component definitions (<override>) (§4.2.5)),
<redefine>
(see Including modified component definitions (<redefine>) (§4.2.4)),
and <import>
(see References to schema components across namespaces (<import>) (§4.2.6)).
Note that none of the attribute information items displayed
above correspond directly to properties of schemas. The
blockDefault, finalDefault,
attributeFormDefault,
elementFormDefault and targetNamespace
attributes are appealed to in the sub-sections above, as they
provide global information applicable to many
representation/component correspondences. The other attributes
(id and version) are for user
convenience, and this specification defines no semantics for
them.
The definition of the schema abstract data model in XSD Abstract Data Model (§2.2) makes clear that most components have a
{target namespace}. Most components
corresponding to representations within a given <schema> element information item will have a {target namespace} which corresponds to the
targetNamespace attribute.
Since the empty string is not a legal namespace name,
supplying an empty string for targetNamespace is
incoherent, and is not the same as not specifying it
at all. The appropriate form of schema document corresponding to
a ·schema· whose components have no {target namespace} is one which has no
targetNamespace attribute specified at all.
Although the example schema at the beginning of this section might be a complete XML document, <schema> need not be the document element, but can appear within other documents. Indeed there is no requirement that a schema correspond to a (text) document at all: it could correspond to an element information item constructed 'by hand', for instance via a DOM-conformant API.
Aside from <include> and <import>, which do not correspond directly to any schema component at all, each of the element information items which may appear in the content of <schema> corresponds to a schema component, and all except <annotation> are named. The sections below present each such item in turn, setting out the components to which it corresponds.
3.17.2.1 References to Schema Components
Reference to schema components from a schema document is managed in
a uniform way, whether the component corresponds to an element
information item from the same schema document or is imported
(References to schema components across namespaces (<import>) (§4.2.6)) from an external schema
(which may, but need not, correspond to an actual schema
document). The form of all such references is a ·QName·.
[Definition:] A QName is a name with an optional namespace qualification, as defined in [XML Namespaces 1.1]. When used in connection with the XML representation of schema components or references to them, this refers to the simple type QName as defined in [XML Schema: Datatypes]. For brevity, the term ·QName· is also used to refer to ·actual values· in the value space of the QName simple type, which are expanded names with a [Definition:] local name and a [Definition:] namespace name.
[Definition:] An NCName is a name with no colon, as defined in [XML Namespaces 1.1]. When used in connection with the XML representation of schema components in this specification, this refers to the simple type NCName as defined in [XML Schema: Datatypes].
[Definition:] A ·QName· in a schema document resolves to a component in a schema if and only if in the context of that schema the QName and the component together satisfy the rule QName resolution (Schema Document) (§3.17.6.2). A ·QName· in an input document, or a pair consisting of a local name and a namespace name, resolves to a component in a schema if and only if in the context of that schema the QName (or the name + namespace pair) and the component together satisfy the rule QName resolution (Instance) (§3.17.6.3).
In each of the XML
representation expositions in the following sections, an attribute is shown as
having type QName if and only if it is
interpreted as referencing a schema component.
<xs:schema xmlns:xs="http://www.w3.org/2001/XMLSchema"
xmlns:xhtml="http://www.w3.org/1999/xhtml"
xmlns="http://www.example.com"
targetNamespace="http://www.example.com">
. . .
<xs:element name="elem1" type="Address"/>
<xs:element name="elem2" type="xhtml:blockquote"/>
<xs:attribute name="attr1"
type="xsl:quantity"/>
. . .
</xs:schema>
<import>) (§4.2.6) for a discussion of importing.3.17.2.2 References to Schema Components from Elsewhere
The names of schema components such as type definitions and element declarations are not of type ID: they are not unique within a schema, just within a symbol space. This means that simple fragment identifiers using these names will not work to reference schema components from outside the context of schema documents.
The preferred way to refer to schema components
is to use [XML Schema: Component Designators], which defines a mechanism to designate
schema components using the xscd() [XPointer]
scheme.
Alternatively, references to specific element information items in the schema document can be interpreted as to their corresponding schema documents. This can be done using mechanisms supported by [XPointer], for example, by using shorthand pointers. It is a matter for applications to specify whether they interpret these references as being to the relevant element information item (i.e. without special recognition of the relation of schema documents to schema components) or as being to the corresponding schema component.
3.17.5 Schema Information Set Contributions
3.17.5.1 Schema Information
- [schema information]
- A
set of namespace schema information information
items, one for each namespace name which appears as the {target namespace} of any schema component in the
schema used for that assessment, and one for ·absent· if any schema component in the schema
had no {target namespace}. Each
namespace schema information information item has the
following properties and values:
PSVI Contributions for namespace schema information information items
- [schema namespace]
- A namespace name or ·absent·.
- [schema components]
- A (possibly empty) set of schema component information items, each one an ·item isomorphic· to a component whose {target namespace} is the sibling [schema namespace] property above, drawn from the schema used for ·assessment·.
- [schema documents]
- A
(possibly empty) set of schema document information
items, with properties and values as follows, for each schema document
which contributed components to the schema, and whose
targetNamespacematches the sibling [schema namespace] property above (or whosetargetNamespacewas ·absent· but that contributed components to that namespace by being <include>d by a schema document with thattargetNamespaceas per Assembling a schema for a single target namespace from multiple schema definition documents (<include>) (§4.2.3)):PSVI Contributions for schema document information items- [document location]
- Either a URI reference, if available, otherwise ·absent·
- [document]
- A document information item, if available, otherwise ·absent·.
3.17.5.2 ID/IDREF Table
- [ID/IDREF table]
- A (possibly empty) set of ID/IDREF binding information items, as specified below.
- [id]
- The string identified above.
- [binding]
- A set consisting of every element information item for which
all of the following are true:1 its [validation context] is the ·validation root·;2 it has an attribute information item in its [attributes] or an element information item in its [children] whose ·actual value· is or contains the [id] of this ID/IDREF binding and the corresponding type definition is or is ·derived· from ID.
3.17.6 Constraints on Schemas as a Whole
3.17.6.1 Schema Properties Correct
All schemas (see Schemas as a Whole (§3.17)) must satisfy the following constraint.
3.17.6.2 QName resolution (Schema Document)
targetNamespace [attribute].namespace [attribute].targetNamespace [attribute] of
the <schema> element information item of the schema document containing the ·QName·.namespace [attribute] of some
<import> element information item contained in the <schema> element information item of that schema document.http://www.w3.org/2001/XMLSchema.
http://www.w3.org/2001/XMLSchema-instance.
3.17.6.3 QName resolution (Instance)
As the discussion above at Schema Component Details (§3) makes clear, at the level of schema components and ·validation·, reference to components by name is normally not involved. In a few cases, however, qualified names appearing in information items being ·validated· must be resolved to schema components by such lookup. The following constraint is appealed to in these cases.
4 Schemas and Namespaces: Access and Composition
This chapter defines the mechanisms by which this specification establishes the necessary precondition for ·assessment·, namely access to one or more schemas. This chapter also sets out in detail the relationship between schemas and namespaces, as well as mechanisms for modularization of schemas, including provision for incorporating definitions and declarations from one schema in another, possibly with modifications.
Conformance (§2.4) describes three levels of conformance for schema processors, and Schemas and Schema-validity Assessment (§5) provides a formal definition of ·assessment·. This section sets out in detail the 3-layer architecture implied by the three conformance levels. The layers are:
- The ·assessment· core, relating schema components and instance information items;
- Schema representation: the connections between XML representations and schema components, including the relationships between namespaces and schema components;
- XSD web-interoperability guidelines: connections from instance to schema (or schema document) and from schema document to schema (or schema document) for the WWW.
Layer 1 specifies the manner in which a schema composed of schema components can be applied to in the ·assessment· of an element information item. Layer 2 specifies the use of <schema> elements in XML documents as the standard XML representation for schema information in a broad range of computer systems and execution environments. To support interoperation over the World Wide Web in particular, layer 3 provides a set of conventions for schema reference on the Web. Additional details on each of the three layers are provided in the sections below.
4.1 Layer 1: Summary of the Schema-validity Assessment Core
The fundamental purpose of the ·assessment· core is to define ·assessment· for a single element information item and its descendants, with respect to a complex type definition. All processors are required to implement this core predicate in a manner which conforms exactly to this specification.
·Assessment· is defined with reference to an ·XSD schema· (note not a ·schema document·).
As specified above, each schema component is associated directly or indirectly with a target namespace, or explicitly with no namespace. In the case of multi-namespace documents, components for more than one target namespace will co-exist in a schema.
Processors have the option to assemble (and perhaps to optimize or pre-compile) the entire schema prior to the start of an ·assessment· episode, or to gather the schema lazily as individual components are required. In all cases it is required that:
- The processor succeed in locating the ·schema components· transitively required to complete an ·assessment· (note that components derived from ·schema documents· can be integrated with components obtained through other means);
- no definition or declaration changes once it has been established;
- if the processor chooses to acquire declarations and definitions dynamically, that there be no side effects of such dynamic acquisition that would cause the results of ·assessment· to differ from that which would have been obtained from the same schema components acquired in bulk.
The obligation of a schema-aware processor as far as the ·assessment· core is concerned is to implement one or more of the options for ·assessment· given below in Assessing Schema-Validity (§5.2). Neither the choice of element information item for that ·assessment·, nor which of the means of initiating ·assessment· are used, is within the scope of this specification.
Although ·assessment· is defined recursively, it is also intended to be implementable in streaming processors. Such processors may choose to incrementally assemble the schema during processing in response, for example, to encountering new namespaces. The implication of the invariants expressed above is that such incremental assembly must result in an ·assessment· outcome that is the same as would be given if ·assessment· were undertaken again with the final, fully assembled schema.
4.2 Layer 2: Schema Documents, Namespaces and Composition
4.2.2 Conditional inclusion
4.2.3 Assembling a schema for a single target namespace from multiple schema definition documents (<include>)
4.2.4 Including modified component definitions (<redefine>)
4.2.5 Overriding component definitions (<override>)
4.2.6 References to schema components across namespaces (<import>)
4.2.6.1 Licensing References to Components Across Namespaces
4.2.6.2 Providing Hints for Imported Schema Document Locations
The sub-sections of Schema Component Details (§3) define an XML representation for type definitions and element declarations and so on, specifying their target namespace and collecting them into schema documents. The following sections describe how to assemble a complete schema from multiple sources.
4.2.1 Basic concepts of schema construction and composition
When a schema is assembled from multiple sources, those sources can include both ·schema documents· and other sources of components. Several of the mechanisms described below allow a ·schema document· to refer to a schema, either by giving the target namespace of its components, or indirectly, by referring to a ·schema document· (and thus implicitly to the schema corresponding to that ·schema document·).
The sections that follow appeal often to the following concepts.
xs:override (§F.2);
also written
"override(E,D)".
<redefine>) (§4.2.4);
also written
"redefine(E,S)".
xsi:schemaLocation and
xsi:noNamespaceSchemaLocation attributes
may validly appear on elements in an XML instance
document. They are technically hints:
conforming schema-aware processors may but need not
attempt to dereference the schema documents named
in these attributes and include the components described
there in the schema used for validation.
schemaLocation attribute on the
<import> element in a schema document is
similarly a hint: a conforming schema-aware
processor may but need not attempt to dereference
the schema document named by the attribute.
schemaLocation attributes on the
<include>, <override>, and
<redefine> elements in a schema document, on the
other hand, are not hints: conforming processors must attempt
to de-reference the schema document named by the attribute.
For non-empty <redefine> elements, it is
an error for the attempt to fail; otherwise, the
attempt must be made but it is not an error for it
to fail.
4.2.2 Conditional inclusion
Whenever a conforming XSD processor reads a ·schema document· in order to include the components defined in it in a schema, it first performs on the schema document the pre-processing described in this section.
Every element in the ·schema document· is examined to
see whether any of
the attributes vc:minVersion,
vc:maxVersion,
vc:typeAvailable,
vc:typeUnavailable,
vc:facetAvailable, or
vc:facetUnavailable
appear among its [attributes].
Where they appear, the
attributes vc:minVersion
and vc:maxVersion are treated as if declared
with type xs:decimal, and their ·actual values· are compared to a decimal
value representing the version of XSD supported by the
processor (here represented as a variable V). For processors
conforming to this version of this specification, the value of
V is 1.1.
If V is less than the value of
vc:minVersion, or
if V is greater than or equal to the value of
vc:maxVersion,
then the element on which the attribute appears is
to be ignored, along with all its
attributes and
descendants.
The effect is that portions of the
schema document marked with vc:minVersion and/or
vc:maxVersion are retained if
vc:minVersion ≤ V < vc:maxVersion.
Where they appear, the attributes vc:typeAvailable
and vc:typeUnavailable are treated as if declared
with type list of xs:QName, and the items in their
·actual values· are checked to see whether they name types
·automatically known· to the processor. The attributes
vc:facetAvailable and vc:facetUnavailable
are similarly typed, and checked to see if they name facets
supported by the processor.
vc:typeAvailable= T, where any item in the ·actual value· T is not the expanded name of some type definition ·automatically known· to the processorvc:typeUnavailable= T, where every item in the ·actual value· T is the expanded name of some type definition ·automatically known· to and supported by the processorvc:facetAvailable= F, where any item in the ·actual value· F is not the expanded name of some facet known to and supported by the processorvc:facetUnavailable= F, where every item in the ·actual value· F is the expanded name of some facet known to and supported by the processor
vc:typeAvailable etc. will be
most useful in testing for ·implementation-defined· primitive datatypes
and facets, or for derived types for which the processor
supplies a definition automatically. The rules just given do
not, however, attempt to restrict their use to such tests. If
the vc:typeAvailable attribute is used with the
expanded name
associated with one of the built-in primitive datatypes, the
datatype will (in a conforming processor) always be available,
so the test is unlikely to filter out any elements, ever, from
the schema document. But such a usage is not in itself an
error.
xs:pattern for the pattern
facet.
vc:typeAvailable is the empty list
(i.e. vc:typeAvailable=""), then the corresponding element
is not ignored. (It does not list any type that is
not available.) Conversely, if the ·actual value· of
vc:typeUnavailable is the empty list, then the corresponding
element is ignored. Similar results hold for
vc:facetAvailable and vc:facetUnavailable.
The pre-processing of a schema document S1 results
in a second schema document S2, identical to S1
except that all elements and
attributes in S1 which are to be ignored
are absent from S2.
We write S2 = ci(S1).
If the <schema>
element information item in S1 is to be ignored, then S2 is identical
to S1 except that any attributes other than targetNamespace,
vc:minVersion or vc:maxVersion are removed from its
[attributes], and its [children] is the empty sequence.
It is S2, not S1, which
is required to conform to this specification.
Except where conditional-inclusion pre-processing is explicitly mentioned, references to ·schema documents· elsewhere in this specification invariably refer to the result of the pre-processing step described here, not to its input, which need not, and in the general case will not, always conform to the rules for schema documents laid out in this specification.
<xs:schema
xmlns:xs="http://www.w3.org/2001/XMLSchema"
xmlns:vc="http://www.w3.org/2007/XMLSchema-versioning">
<xs:element name="e" vc:minVersion="3.2">
<!--* declaration suitable for 3.2
* and later processors *-->
</xs:element>
<xs:element name="e"
vc:minVersion="1.1"
vc:maxVersion="3.2">
<!--* declaration suitable for processors
* supporting versions 1.1 through versions
* up to (but not including) 3.2
*-->
</xs:element>
...
</xs:schema>
e and thus
violates clause 2 of constraint
Schema Properties Correct (§3.17.6.1), the pre-processing step
described in this section filters out the first element
declaration, making it possible for the resulting schema
document to be valid and to conform to this specification.
vc:maxVersion attribute is
"exclusive". This makes it easier for schema authors to use this feature
without leaving gaps
in the numeric ranges used to select version numbers.
Suppose that a processor supports an ·implementation-defined· primitive
named xpath_expression in namespace
"http://example.org/extension_types",
and is presented with the following schema document:
<xs:schema
xmlns:xs="http://www.w3.org/2001/XMLSchema"
xmlns:vc="http://www.w3.org/2007/XMLSchema-versioning"
xmlns:tns="http://example.org/extension_types"
targetNamespace="http://example.org/extension_types" >
<xs:element vc:typeAvailable="tns:xpath_expression"
name="e" type="tns:xpath_expression" />
<xs:element vc:typeUnavailable="tns:xpath_expression"
name="e" type="string" />
</xs:schema>The effect of conditional inclusion is to include the
first declaration for e and omit the second, so
that the effective schema document, after pre-processing
for conditional inclusion, is:
<xs:schema
xmlns:xs="http://www.w3.org/2001/XMLSchema"
xmlns:vc="http://www.w3.org/2007/XMLSchema-versioning"
xmlns:tns="http://example.org/extension_types"
targetNamespace="http://example.org/extension_types" >
<xs:element vc:typeAvailable="tns:xpath_expression"
name="e" type="tns:xpath_expression" />
</xs:schema>A processor which does not support type "tns:xpath_expression",
by contrast, will use the other declaration for e:
type in the namespace in question
<xs:schema
xmlns:xs="http://www.w3.org/2001/XMLSchema"
xmlns:vc="http://www.w3.org/2007/XMLSchema-versioning"
xmlns:tns="http://example.org/extension_types"
targetNamespace="http://example.org/extension_types" >
<xs:element vc:typeUnavailable="tns:xpath_expression"
name="e" type="string" />
</xs:schema>vc:minVersion or
vc:maxVersion appears on an element information item in a
·schema document·, its ·initial value·
must
be locally ·valid·
with respect to xs:decimal as per
String Valid (§3.16.4).vc:typeAvailable,
vc:typeUnavailable,
vc:facetAvailable, or
vc:facetUnavailable,
appears on an element information item in a
·schema document·, its ·initial value·
must
be locally ·valid·
with respect to a simple type definition with
{variety} = list
and
{item type definition} =
xs:QName, as per
String Valid (§3.16.4).vc: namespace that appears
on an element information item in a
·schema document· should be one of the attributes described
elsewhere in this document (i.e. one of
vc:minVersion, vc:maxVersion, vc:typeAvailable,
vc:typeUnavailable, vc:facetAvailable, or
vc:facetUnavailable).
vc: attributes other than those named,
but it is not an error for such
attributes to appear in a ·schema document·. The rule just
given is formulated with a "should" and not
a "must" in order to preserve the ability of
future versions of this specification to add new attributes
to the schema-versioning namespace.
4.2.3 Assembling a schema for a single target namespace from
multiple schema definition documents
(<include>)
Schema components for a single target namespace can be assembled from several ·schema documents·, that is several <schema> element information items:
include Element Information Itemid = ID
schemaLocation = anyURI
{any attributes with non-schema namespace . . .}>
Content: (annotation?)
</include>
A <schema> information item may contain any
number of <include> elements. Their
schemaLocation attributes, consisting of a URI reference,
identify other ·schema documents·, that is <schema> information items.
If two <include> elements specify the same schema location (after resolving relative URI references) then they refer to the same schema document. If they specify different schema locations, then they refer to different schema documents, unless the implementation is able to determine that the two URIs are references to the same resource.
If a ·schema document· D1
contains one or more <include> elements,
then schema(D1) contains not only
immed(D1) but also all the components
of schema(D2), for each ·schema document·
D2 identified by an <include> element
child of D1.
Such included schema
documents D2
must either (a) have the same
targetNamespace as D1,
or (b) no targetNamespace at all,
in which case the
components included in schema(D1) are
not those of schema(D2) itself, but instead
those of schema(chameleon(tns(D1),D2)),
that is, the schema corresponding to the result of applying
chameleon pre-processing to D2 to convert it to
target namespace tns(D1).
schemaLocation
[attribute] successfully resolves
one or more of the following is true:application/xml or
text/xml with an XML declaration for
preference, but this is not required), which in turn
corresponds to a <schema> element
information item in a well-formed information set.targetNamespace
[attribute], and its ·actual value· is identical to the
·actual value· of the targetNamespace
[attribute] of D1 (which must have such an
[attribute]).targetNamespace [attribute].targetNamespace [attribute] (but D1
does).schemaLocation [attribute] does not
resolve successfully).targetNamespace [attribute] to D2,
whose value is the same as that of the targetNamespace
[attribute] of D1, and (b) updates all unqualified
QName references so that their namespace names become the
·actual value· of the targetNamespace [attribute].
Implementations need not use the [XSLT 2.0]
stylesheet given in Transformation for Chameleon Inclusion (§F.1),
as long as an equivalent result
is produced.
In particular, different
algorithms for generating a unique namespace
prefix may be used, even if they produce different
results.
targetNamespace
[attribute], but neither B nor
C does, then the effect is as if
A included B' and
B' included C', where
B' and C' are identical to
B and C respectively,
except that they both have a
targetNamespace [attribute] the same as
A's.
schemaLocation [attribute] to fail to resolve
at all,
in which case the corresponding inclusion must not be performed. It
is an error for it to resolve but the rest of clause 1
above to fail to be satisfied. Failure to resolve is likely
to cause less than complete ·assessment· outcomes, of course.If there is a sequence of schema documents S1, S2, ... Sn, and a sequence of <include> elements E1, E2, ... En, such that each Si contains the corresponding Ei, and each Ei (where i < n) points to schema document Si + 1, and En points to S1 (i.e. if there is a cycle in the relation defined by the <include> element), then the same schema corresponds to all of the schema documents S1, ... Sn in the cycle, and it includes the same components as the schema corresponding to S1 in the similar case where Sn has no <include> element pointing at S1.
4.2.4 Including modified component definitions (<redefine>)
In order to provide some support for evolution and versioning, it is possible to incorporate components corresponding to a schema document with modifications. The modifications have a pervasive impact, that is, only the redefined components are used, even when referenced from other incorporated components, whether redefined themselves or not.
redefine Element Information Itemid = ID
schemaLocation = anyURI
{any attributes with non-schema namespace . . .}>
Content: (annotation | (simpleType | complexType | group | attributeGroup))*
</redefine>
A <schema> information item may contain any number of <redefine> elements. Their schemaLocation attributes, consisting of a URI reference, identify other ·schema documents·, that is <schema> information items.
If a schema document D1 contains a <redefine> element E pointing to some schema document D2, then schema(D1) contains not only the components in immed(D1), but also all the components (with the exception, in most cases, of the schema-as-a-whole component) of redefine(E,schema(D2)). For any document D2 pointed at by a <redefine> element in D1, it must be the case either (a) that tns(D1) = tns(D2) or else (b) that tns(D2) is ·absent·, in which case schema(D1) includes not redefine(E,schema(D2)) itself but redefine(E,schema(chameleon(tns(D1),D2))). That is, the redefinition pre-processing is applied not to the schema corresponding to D2 but instead to the schema corresponding to the schema document chameleon(tns(D1),D2), which is the result of applying chameleon pre-processing to D2 to convert it to target namespace tns(D1).
- Type definitions must use themselves as their base type definition;
- Attribute group definitions and model group definitions must be supersets or subsets of their original definitions, either by including exactly one reference to themselves or by containing only (possibly restricted) components which appear in a corresponding way in their <redefine>d selves.
This mechanism is intended to provide a declarative and modular approach to schema modification, with functionality no different except in scope from what would be achieved by wholesale text copying and redefinition by editing. In particular redefining a type is not guaranteed to be side-effect free: it can have unexpected impacts on other type definitions which are based on the redefined one, even to the extent that some such definitions become ill-formed.
v1.xsd:
<xs:complexType name="personName">
<xs:sequence>
<xs:element name="title" minOccurs="0"/>
<xs:element name="forename" minOccurs="0" maxOccurs="unbounded"/>
</xs:sequence>
</xs:complexType>
<xs:element name="addressee" type="personName"/>
v2.xsd:
<xs:redefine schemaLocation="v1.xsd">
<xs:complexType name="personName">
<xs:complexContent>
<xs:extension base="personName">
<xs:sequence>
<xs:element name="generation" minOccurs="0"/>
</xs:sequence>
</xs:extension>
</xs:complexContent>
</xs:complexType>
</xs:redefine>
<xs:element name="author" type="personName"/>
v2.xsd has everything specified
by v1.xsd, with the personName type redefined, as
well as everything it specifies itself. According to
this schema, elements constrained
by the personName type may end with a generation
element. This includes not only the author element, but also the
addressee element.schemaLocation [attribute] must
successfully resolve.schemaLocation
[attribute] successfully resolves
one or more of the following is true:targetNamespace
[attribute], and its ·actual value· is identical to the
·actual value· of the targetNamespace
[attribute] of D1 (which must have such an
[attribute]).targetNamespace [attribute].targetNamespace [attribute] (but D1
does).restriction or extension among its
grand-[children] the ·actual value· of whose base
[attribute] must be the same as the ·actual value· of its own
name attribute plus target namespace;ref [attribute] is the same as the
·actual value· of its own name attribute plus
target namespace
and that <group> does not have an <element>
ancestor, then
all of the following are true:minOccurs and maxOccurs
[attribute] is 1 (or ·absent·).name attribute
plus target namespace successfully ·resolves· to a
model group definition in S2.ref [attribute] is the same as the
·actual value· of its own name attribute plus
target namespace, then it has exactly one such group.name attribute
plus target namespace successfully ·resolves· to an
attribute group definition in S2.name in
the <redefine>d schema document, as defined in Schema Component Details (§3), except that its {name} is ·absent· and its {context} is the redefining component, as defined in clause 1.2 below;ref [attribute] whose ·actual value· is the same as the item's name plus target namespace is
·resolved·, a component which corresponds to the top-level definition item of that name and the appropriate kind in
S2 is used.4.2.5 Overriding component definitions (<override>)
The <redefine> construct defined
in Including modified component definitions (<redefine>) (§4.2.4)
is useful in schema evolution and versioning,
when it is desirable to have some guaranteed restriction or extension
relation between the old component and the redefined component.
But there are occasions when the schema author simply wants to
replace old components with new ones without any constraint.
Also, existing XSD processors
have implemented conflicting and non-interoperable interpretations
of <redefine>, and the <redefine>
construct is ·deprecated·.
The <override> construct defined in this section
allows such unconstrained replacement.
override Element Information Itemid = ID
schemaLocation = anyURI
{any attributes with non-schema namespace . . .}>
Content: (annotation | (simpleType | complexType | group | attributeGroup | element | attribute | notation))*
</override>
A <schema> information item may contain any number of
<override> elements. Their schemaLocation
attributes, consisting of a URI reference, identify
("point to")
other ·schema documents·,
that is <schema> information items.
If a schema document Dnew contains an <override> element E pointing to some schema document Dold, then schema(Dnew) contains not only the components in immed(Dnew), but also the components in schema(override(E,Dold)). For all such schema documents Dold, it must be the case either (a) that tns(Dold) = tns(Dnew), or (b) that tns(Dold) is ·absent·, in which case schema(Dnew) contains not the components in schema(override(E,Dold)), but those in schema(override(E,chameleon(tns(Dnew),Dold))). That is, before the override pre-processsing is applied, chameleon pre-processing is applied to Dold to convert it to target namespace tns(Dnew); the override pre-processing is applied to the result, namely chameleon(tns(Dnew),Dold).
include and override
references among schema documents contains cycles. To
guarantee termination, the algorithm must detect when it has
reached closure, that is, when further computation will have no
effect on the outcome. In particular, it is useful to recognize
(a) that it is possible to terminate as soon as conflicting
components have been generated (for example, two different type
definitions with the same name), and (b) that when
override(E, D) (for some E and D) is
equivalent to D, no new schema
components will be contributed by further processing: this can
be detected either by comparing the input and output of the
override transformation using a comparator such as the
[XPath 2.0]
fn:deep-equal function, or by observing the
conditions that cause override(E, D) to be
idempotent, for example the fact that E is empty.
The children of the <override> element may override any source declarations for ·named· components which appear among the [children] of the <schema>, <redefine>, or <override> elements in the ·target set· of the <override> element information item..
schemaLocation
attribute of E.schemaLocation
attribute of any <override> element information item
in a schema document contained in the ·target set·
of E.schemaLocation
attribute of any <include> element information item
in a schema document contained in the ·target set·
of E.xs:override (§F.2)
translates both <override> and <include> elements
into <override> elements. These <override>
elements will, in turn, be handled by transforming their target schema
documents. Since every schema document in the target set of the original
<override> element is the target of either an <override>
element or of an <include> element, it follows that the
transformation described in Transformation for xs:override (§F.2) will be
applied to every schema document in the target set.
xs:override (§F.2) to D and E results in
a schema document equivalent to D (e.g. when none of the [children]
of D, or of any <redefine> and <override>
elements in D match any of the [children] of E, except
for the [children] of E themselves), then the effect is the same
as for a cyclic set of <include> references, or
as for multiple inclusions of the same document (as
described in the note at the end of
Assembling a schema for a single target namespace from
multiple schema definition documents
(<include>) (§4.2.3)).
The definitions within the <override> element itself are not required to be similar in any way to the source declarations being overridden. Not all the source declarations of the overridden schema document need be overridden.
As this mechanism is very similar to <redefine>, many similar
kinds of caution need to be taken in using <override>. Please
refer to Including modified component definitions (<redefine>) (§4.2.4) for details.
v1.xsd:
<xs:complexType name="personName">
<xs:sequence>
<xs:element name="firstName"/>
<xs:element name="lastName"/>
</xs:sequence>
</xs:complexType>
<xs:element name="addressee" type="personName"/>
v2.xsd:
<xs:override schemaLocation="v1.xsd">
<xs:complexType name="personName">
<xs:sequence>
<xs:element name="givenName"/>
<xs:element name="surname"/>
</xs:sequence>
</xs:complexType>
</xs:override>
<xs:element name="author" type="personName"/>
v1.xsd has a complex type named
personName with a sequence of firstName
and lastName children. The schema corresponding to v2.xsd
overrides personName, by providing a different sequence of
element children. All elements with the personName type are
now constrained to have the sequence of givenName and
surname. This includes not only the author
element, but also the addressee element.schemaLocation [attribute]
successfully resolves one or more of the following is true:targetNamespace [attribute], and its
·actual value· is identical to the ·actual value· of the targetNamespace
[attribute] of Dnew (which must have such an [attribute]).
targetNamespace
[attribute].
targetNamespace [attribute] (but Dnew
does).
xs:override (§F.2). Then
Dold′ corresponds to a conforming schema (call it Sold).
<include>) (§4.2.3).
xs:override (§F.2). Then
Dold′ corresponds to a conforming schema (call it S2).
<include>) (§4.2.3).
xs:override (§F.2)
is to make Dold′ identical to Dold except that some elements in
Dold are replaced
or modified, as described in
Transformation for xs:override (§F.2).
Implementations do not have to use [XSLT 2.0]
transformation, as long as the same result is produced.elementFormDefault,
attributeFormDefault, blockDefault,
finalDefault, and so on) are applied not in the
context of the document containing the <override>
(Dnew) but in the context of the document containing the
original overridden declaration or definition (Dold).
Unexpected results may be minimized if the children of an <override> are made independent of the document-level
defaults by explicitly specifying the desired values for
the properties in question.
<redefine>) (§4.2.4);
import, as defined in
References to schema components across namespaces (<import>) (§4.2.6);
and overriding, as defined in this section,
that if the same schema document is both (a) included, imported, or
redefined, and (b) non-vacuously overridden, or if the same
schema document overridden twice in
different ways, then
the resulting schema will have duplicate and conflicting versions
of some components and will not be conforming,
just as if two different schema documents had been
included, with different declarations for the same
·named· components.
4.2.6 References to schema components across namespaces (<import>)
As described in XSD Abstract Data Model (§2.2), every top-level schema component is associated with
a target namespace (or, explicitly, with none). Furthermore,
each schema document carries on its <schema> element
at most one targetNamespace attribute associating that document
with a target namespace. This section sets out
the
syntax and mechanisms by which references
may be made from within a ·schema document· to components
outside that document's target
namespace. Also included within the same syntax is an optional
facility for suggesting the URI of a
·schema document· containing
definitions and declarations for components from the foreign
target namespace.
schemaLocation attribute.
Although the function of <import> is
unchanged in this version, the presentation below has been
reorganized to clarify the two separate purposes served by
<import>, namely
(1) to license references, within a schema document, to
components in the imported namespace, and (2) to provide information
about the location of schema documents for imported namespaces.
import Element Information Itemid = ID
namespace = anyURI
schemaLocation = anyURI
{any attributes with non-schema namespace . . .}>
Content: (annotation?)
</import>
The <import> element information item identifies namespaces
used in external references, i.e. those whose
·QName· identifies them as coming from a
different namespace (or none) than the enclosing schema document's
targetNamespace.
4.2.6.1 Licensing References to Components Across Namespaces
At least two conditions must be satisfied for a
reference to be made to a foreign component: (1)
there must be a
means of addressing such foreign components,
and
(2) there must be a signal to
schema-aware processors that a schema document contains such
references. The namespace
mechanisms defined by [XML Namespaces 1.1]
satisfy the first requirement by allowing foreign components
to be addressed.
(How those components are located is governed by the
processor's strategies for locating schema components
in a given namespace, in which the schemaLocation attribute
on the <import> element can play a role;
see also
Terminology of schema construction
(§C.2).)
The <import> element information item
serves
to satisfy the second requirement, by identifying
namespaces used in external component
references, i.e. those whose
·QName· identifies them as coming
from a namespace different from that of the enclosing schema
document's targetNamespace.
By contrast, a namespace used for other purposes in a schema document
need not be imported.
<xs:import namespace="http://www.w3.org/1999/xhtml"/>(with the possible addition of a
schemaLocation attribute
and annotations). As just described, this explicit import
makes it legitimate to refer to components in the XHTML namespace,
as base type definitions, or from within content models.
The ·actual value· of
the
namespace
[attribute] indicates that the containing schema document may contain
qualified references to schema components in that namespace (via one or more
prefixes declared with namespace declarations in the normal way). If that
attribute is absent, then the import allows unqualified reference to components
with no target namespace.
It is a consequence of rules defined elsewhere that if references to components in a given namespace N appear in a schema document S, then S must contain an <import> element importing N. Otherwise, the references will fail to resolve; see clause 4 of QName resolution (Schema Document) (§3.17.6.2). References in a schema document to foreign namespaces not imported by that schema document (or otherwise accounted for by QName resolution (Schema Document) (§3.17.6.2)) are not "forward references" in the sense of The Mapping between XML Representations and Components (§3.1.3) and are not handled as if they referred to "missing components" in the sense of Missing Sub-components (§5.3).
Note that components to be imported need not be in the form of a
·schema document· and
need not in particular be declared in the particular schema document identified
by a schemaLocation attribute; the processor
is free to access or construct components using means of its own
choosing, whether or not a schemaLocation
hint is provided.
xhtml:p.
if there were no component reference, then
the import would be unnecessary; no import is needed for use of a namespace
in a <documentation>
or similar schema document element or attribute name.<xs:schema xmlns:xs="http://www.w3.org/2001/XMLSchema"
xmlns:xhtml="http://www.w3.org/1999/xhtml"
targetNamespace="uri:mywork" xmlns:my="uri:mywork">
<xs:import namespace="http://www.w3.org/1999/xhtml"/>
<xs:annotation>
<xs:documentation>
<!--* The XHTML 'p' element below requires us to
define a prefix for the XHTML namespace, but it
does NOT require us to import the XHTML
namespace into the schema. The use of XHTML
(or other) markup here is allowed by the lax
wildcard in the schema for schema documents.
*-->
<xhtml:p>[Some documentation for my schema]</xhtml:p>
</xs:documentation>
</xs:annotation>
. . .
<xs:complexType name="myType">
<xs:sequence>
<xs:element ref="xhtml:p" minOccurs="0"/>
</xs:sequence>
. . .
</xs:complexType>
<xs:element name="myElt" type="my:myType"/>
</xs:schema>
4.2.6.2 Providing Hints for Imported Schema Document Locations
The ·actual value· of the schemaLocation attribute, if present on
an <import> element, gives a hint as to where a
serialization of a ·schema document· with declarations and definitions for the
imported namespace (or none) can
possibly be found. When no schemaLocation
[attribute] is present, the schema author is leaving the
identification of that schema to the instance, application or user,
via the mechanisms described below in Layer 3: Schema Document Access and Web-interoperability (§4.3). When a
schemaLocation attribute
is present, it must contain a single URI reference which
the schema author warrants will resolve to a
serialization of a ·schema document· containing
definitions and declarations of
component(s) in the
<import>ed namespace.
Conformance profiles may further
restrict the use of the schemaLocation attribute. For example,
one profile might mandate that the hint be
honored by the schema software, perhaps calling for a
processor-dependent error should the URI fail to resolve,
or mandating that the hint agree with some expected URI value;
another profile might mandate that the hint not
be honored,
etc.
namespace and schemaLocation
[attribute] are optional, a bare <import/> information item
is allowed. This simply allows unqualified reference to foreign
components with no target namespace without giving any hints as to where to find them.namespace [attribute] is present, then its ·actual value· does not match the ·actual value· of the
enclosing <schema>'s targetNamespace [attribute].namespace [attribute] is not present, then the enclosing <schema> has a targetNamespace [attribute]schemaLocation and namespace
[attributes]
one of the following must be true:namespace [attribute], then its ·actual value· is identical to the ·actual value· of the targetNamespace [attribute] of D2.schemaLocation [attribute] is only a hint, it is open
to applications to ignore all but the first <import> for
a given namespace, regardless of the
·actual value· of schemaLocation, but such a strategy risks
missing useful information when new schemaLocations are
offered. 4.3 Layer 3: Schema Document Access and Web-interoperability
4.3.2 How schema definitions are located on the Web
Layers 1 and 2 provide a framework for ·assessment· and XML definition of schemas in a broad variety of environments. Over time, it is possible that a range of standards and conventions will evolve to support interoperability of XSD implementations on the World Wide Web. Layer 3 defines the minimum level of function required of all conformant processors operating on the Web: it is intended that, over time, future standards (e.g. XML Packages) for interoperability on the Web and in other environments can be introduced without the need to republish this specification.
4.3.1 Standards for representation of schemas and retrieval of schema documents on the Web
For interoperability, serialized ·schema documents·, like all other Web resources, should be identified by URI and retrieved using the standard mechanisms of the Web (e.g. http, https, etc.) Such documents on the Web must be part of XML documents (see clause 1.1 of Inclusion Constraints and Semantics (§4.2.3)), and are represented in the standard XML schema definition form described by layer 2 (that is as <schema> element information items).
Accept header of application/xml,
text/xml; q=0.9, */* is perhaps a reasonable starting point.4.3.2 How schema definitions are located on the Web
As described in Layer 1: Summary of the Schema-validity Assessment Core (§4.1), processors are responsible for providing the schema components (definitions and declarations) needed for ·assessment·. This section introduces a set of conventions to facilitate interoperability for instance and schema documents retrieved and processed from the Web.
- unless directed otherwise by the user, ·assessment· is undertaken on the document element information item of the instance document;
- unless directed otherwise by the user, the processor is required to construct a schema corresponding to a schema document whose
targetNamespaceis identical to the namespace name, if any, of the element information item on which ·assessment· is undertaken.
The composition of the complete schema for use in ·assessment· is discussed in Layer 2: Schema Documents, Namespaces and Composition (§4.2) above. The means used to locate appropriate schema document(s) are processor and application dependent, subject to the following requirements:
- Schemas are represented on the Web in the form specified above in Standards for representation of schemas and retrieval of schema documents on the Web (§4.3.1);
- The author of a document uses namespace declarations to indicate the intended interpretation of names appearing therein; it is possible but not guaranteed that a schema is retrievable via the namespace name. Accordingly whether a processor's default behavior is or is not to attempt such dereferencing, it must always provide for user-directed overriding of that default.Note: Experience suggests that it is not in all cases safe or desirable from a performance point of view to dereference namespace names as a matter of course. User community and/or consumer/provider agreements may establish circumstances in which such dereference is a sensible default strategy: this specification allows but does not require particular communities to establish and implement such conventions. Users are always free to supply namespace names as schema location information when dereferencing is desired: see below.
- On the other hand, in case a document author (human or not) created a document with a particular schema in view, and warrants that some or all of the document conforms to that schema, the
xsi:schemaLocationandxsi:noNamespaceSchemaLocation[attributes] are provided. The first records the author's warrant with pairs of URI references (one for the namespace name, and one for a hint as to the location of a schema document defining names for that namespace name). The second similarly provides a URI reference as a hint as to the location of a schema document with notargetNamespace[attribute].Processors may attempt to dereference each schema document location URI in the ·actual value· of suchxsi:schemaLocationandxsi:noNamespaceSchemaLocation[attributes]. Schema processors should provide an option to control whether they do so. It is not an error for such an attempt to fail, but failure may cause less than complete ·assessment· outcomes.Note: Whether schema location information in the document instance should or should not be dereferenced may vary with the purpose in view.When systems rely on an input document being schema-valid with respect to a particular agreed-upon schema, it is important that they be able to have complete control over the choice of schema used in assessment and in particular that they be able to instruct the processor not to follow anyschemaLocationhints in the input. Otherwise, the input document could circumvent the agreement and the consumer's validation of the input, by referring to an alternative schema for the same namespaces, which declares the input document schema-valid but which does not adhere to the prior agreement between the data source and the data consumer.In other cases the purpose of assessment may be not to enforce a prior agreement between data source and consumer, but to annotate the input with type definitions and other useful information from the ·post-schema-validation infoset·. In such cases it will often be better to follow theschemaLocationhints.Users who need to exert control over the choice of schema can normally be expected to be aware of the requirement; conversely, users unaware of the issue will typically be those who are not relying on the use of a particular schema to enforce a specific agreement with the data source. Casual users will often benefit from a default behavior of followingschemaLocationhints.Useful guidance on how to present this and other questions to end users may be found in the W3C's User Agent Accessibility Guidelines [UAAG 1.0], [UAAG 2.0]. - When schema location values (i.e.
schemaLocationattributes on <include>, <redefine>, <override>, and <import> in schema documents, orxsi:schemaLocationandxsi:noNamespaceSchemaLocationattributes in instance documents) are dereferenced and the values are relative references, then the [base URI] of the [owner element] must be used to resolve the relative references. - According to the rules of Layer 1: Summary of the Schema-validity Assessment Core (§4.1), the corresponding schema may be lazily assembled, but is otherwise stable throughout ·assessment·. Although schema location attributes can occur on any element, and can be processed incrementally as discovered, their effect is essentially global to the ·assessment·. Definitions and declarations remain in effect beyond the scope of the element on which the binding is declared.
<xsl:stylesheet xmlns:xsl="http://www.w3.org/1999/XSL/Transform"
xmlns:xhtml="http://www.w3.org/1999/xhtml"
xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance"
xsi:schemaLocation="http://www.w3.org/1999/XSL/Transform
http://www.w3.org/1999/XSL/Transform.xsd
http://www.w3.org/1999/xhtml
http://www.w3.org/1999/xhtml.xsd">
schemaLocation can, but need not
be identical to those actually qualifying the element within whose start tag
it is found or its other attributes. For example, as above, all
schema location information can be declared on the document element
of a document, if desired,
regardless of where the namespaces are actually used. Improved or alternative conventions for Web interoperability can be standardized in the future without reopening this specification. For example, the W3C is currently considering initiatives to standardize the packaging of resources relating to particular documents and/or namespaces: this would be an addition to the mechanisms described here for layer 3. This architecture also facilitates innovation at layer 2: for example, it would be possible in the future to define an additional standard for the representation of schema components which allowed e.g. type definitions to be specified piece by piece, rather than all at once.
5 Schemas and Schema-validity Assessment
The architecture of schema-aware processing allows for a rich characterization of XML documents: schema validity is not a binary predicate.
This specification distinguishes between errors in schema construction and structure, on the one hand, and schema validation outcomes, on the other.
5.1 Errors in Schema Construction and Structure
Before ·assessment· can be
attempted, a schema is required. Special-purpose applications are
free to determine a schema for use in ·assessment· by whatever means are
appropriate, but general purpose processors should implement
and document a strategy for assembling a schema,
exploiting at least some if not all of the non-hard-coded
methods outlined in
Terminology of schema construction
(§C.2),
starting with the namespaces declared in the document whose
·assessment· is being undertaken,
and the ·actual value·s of the xsi:schemaLocation and
xsi:noNamespaceSchemaLocation [attributes]
thereof, if any, along with any other information about schema
identity or schema document location provided by users in
application-specific ways, if any.
It is an error if a schema and all the components which are the value of any of its properties, recursively, fail to satisfy all the relevant Constraints on Schemas set out in the subsections of Schema Component Details (§3).
- It is an error if any such schema document would not be fully valid with respect to a schema corresponding to the Schema for Schema Documents (Structures) (normative) (§A), that is, following schema-validation with such a schema, the <schema> element information items would have a [validation attempted] property with value full or partial and a [validity] property with value valid.
- It is an error if any such schema document is or contains any element information items which violate any of the relevant Schema Representation Constraints set out in Schema Representation Constraints (§B.3).
The cases described above are the only types of error which this specification defines. With respect to the processes of the checking of schema structure and the construction of schemas corresponding to schema documents, this specification imposes no restrictions on processors in the presence of errors, beyond the requirement that if there are errors in a schema, or in one or more schema documents used in constructing a schema, then a conforming processor must report the fact. However, any further operations performed in the presence of errors are outside the scope of this specification and are not ·schema-validity assessment· as that term is defined here.
5.2 Assessing Schema-Validity
With a schema which satisfies the conditions expressed in Errors in Schema Construction and Structure (§5.1) above, the schema-validity of an element or attribute information item (the ·validation root·) can be assessed. Five primary approaches to this are described and given names here; conforming processors may but are not required to provide interfaces so that they can be invoked in ways consistent with any or all of these approaches.
xsi:type), then ·strict
validation· is performed. If they do
not identify any declaration or definition, then
·lax assessment
· is
performed.
xsi:type), then ·strict· validation is
performed; if they do not identify any declaration or
definition, then
·lax assessment· is performed.
[Definition:] The element or attribute information item at which ·assessment· begins is called the validation root.
The outcome of schema-validity assessment will be manifest in the [validation attempted] and [validity] properties on the ·validation root·, and if the ·validation root· is an element information item then also on its [attributes] and [children], recursively, as defined by Assessment Outcome (Element) (§3.3.5.1) and Assessment Outcome (Attribute) (§3.2.5.1). There is no requirement that input which is not schema-valid be rejected by an application. It is up to applications to decide what constitutes a successful outcome of validation.
Note that every element and attribute information item participating in the ·assessment· will also have a [validation context] property which refers back to the ·validation root·.
- ·assessment· was not attempted because of a ·validation· failure, but declarations and/or definitions are available for at least some of the [children] or [attributes];
- ·assessment· was not attempted because a named definition or declaration was missing, but after further effort the processor has retrieved it.
- ·assessment· was not attempted because it was ·skipped·, but the processor has at least some declarations and/or definitions available for at least some of the [children] or [attributes].
5.3 Missing Sub-components
At the beginning of Schema Component Details (§3), attention is drawn to the fact that most kinds of schema components have properties which are described therein as having other components, or sets of other components, as values, but that when components are constructed on the basis of their correspondence with element information items in schema documents, such properties usually correspond to QNames, and the ·resolution· of such QNames can fail, resulting in one or more values of or containing ·absent· where a component is mandated.
If at any time during ·assessment·, an element or attribute information item is being ·validated· with respect to a component of any kind any of whose properties has or contains such an ·absent· value, the ·validation· is modified, as following:
- In the case of attribute information items, the effect is as if clause 1 of Attribute Locally Valid (§3.2.4.1) had failed;
- In the case of element information items, the effect is as if clause 1 of Element Locally Valid (Element) (§3.3.4.3) had failed;
- In the case of element information items, processors must fall back to ·lax assessment·.
Because of the value specification for [validation attempted] in Assessment Outcome (Element) (§3.3.5.1), if this situation ever arises, the document as a whole cannot show a [validation attempted] of full.
References in a Simple Type Definition to unknown datatypes, or to unknown constraining facets, make the simple type definition unusable in ways similar to having ·absent· property values. Often, such references will result in component properties with ·absent· values, but not necessarily. In either case they, and likewise any types derived or constructed from them, are handled in the same way as described above for components with ·absent· property values.
5.4 Responsibilities of Schema-aware Processors
Schema-aware processors are responsible for processing XML documents, schemas and schema documents, as appropriate given the level of conformance (as defined in Conformance (§2.4)) they support, consistently with the conditions set out above.
A Schema for Schema Documents (Structures) (normative)
The XML representation of the schema for schema documents is presented here as a normative part of the specification, and as an illustrative example of how the XML Schema Definition Language can define itself using its own constructs. The names of XSD types, elements, attributes and groups defined here are evocative of their purpose, but are occasionally verbose.
There is some annotation in comments, but a fuller annotation will require the use of embedded documentation facilities or a hyperlinked external annotation for which tools are not yet readily available.
Like any other XML document, schema
documents may carry XML and document type declarations. An XML
declaration and a document type declaration are provided here for
convenience. Since this schema document describes the XSD
language, the targetNamespace attribute on the
schema element refers to the XSD namespace
itself.
Schema documents conforming to this specification may be in XML 1.0 or XML 1.1. Conforming implementations may accept input in XML 1.0 or XML 1.1 or both. See Dependencies on Other Specifications (§1.4).
Independent copies of this material are available in an undated (mutable) version at http://www.w3.org/2009/XMLSchema/XMLSchema.xsd and in a dated (immutable) version at http://www.w3.org/2012/04/XMLSchema.xsd — the mutable version will be updated with future revisions of this specification, and the immutable one will not.
<?xml version='1.0'?>
<!DOCTYPE xs:schema PUBLIC "-//W3C//DTD XSD 1.1//EN" "XMLSchema.dtd" [
<!-- provide ID type information even for parsers which only read the
internal subset -->
<!ATTLIST xs:schema id ID #IMPLIED>
<!ATTLIST xs:complexType id ID #IMPLIED>
<!ATTLIST xs:complexContent id ID #IMPLIED>
<!ATTLIST xs:simpleContent id ID #IMPLIED>
<!ATTLIST xs:extension id ID #IMPLIED>
<!ATTLIST xs:element id ID #IMPLIED>
<!ATTLIST xs:group id ID #IMPLIED>
<!ATTLIST xs:all id ID #IMPLIED>
<!ATTLIST xs:choice id ID #IMPLIED>
<!ATTLIST xs:sequence id ID #IMPLIED>
<!ATTLIST xs:any id ID #IMPLIED>
<!ATTLIST xs:anyAttribute id ID #IMPLIED>
<!ATTLIST xs:attribute id ID #IMPLIED>
<!ATTLIST xs:attributeGroup id ID #IMPLIED>
<!ATTLIST xs:unique id ID #IMPLIED>
<!ATTLIST xs:key id ID #IMPLIED>
<!ATTLIST xs:keyref id ID #IMPLIED>
<!ATTLIST xs:selector id ID #IMPLIED>
<!ATTLIST xs:field id ID #IMPLIED>
<!ATTLIST xs:assert id ID #IMPLIED>
<!ATTLIST xs:include id ID #IMPLIED>
<!ATTLIST xs:import id ID #IMPLIED>
<!ATTLIST xs:redefine id ID #IMPLIED>
<!ATTLIST xs:override id ID #IMPLIED>
<!ATTLIST xs:notation id ID #IMPLIED>
]>
<xs:schema xmlns:xs="http://www.w3.org/2001/XMLSchema"
elementFormDefault="qualified" xml:lang="EN"
targetNamespace="http://www.w3.org/2001/XMLSchema"
version="structures.xsd (rec-20120405)">
<xs:annotation>
<xs:documentation source="http://www.w3.org/TR/2012/REC-xmlschema11-1-20120405/structures.html">
The schema corresponding to this document is normative,
with respect to the syntactic constraints it expresses in the
XML Schema Definition Language. The documentation (within 'documentation' elements)
below, is not normative, but rather highlights important aspects of
the W3C Recommendation of which this is a part.
See below (at the bottom of this document) for information about
the revision and namespace-versioning policy governing this
schema document.
</xs:documentation>
</xs:annotation>
<xs:annotation>
<xs:documentation>
The simpleType element and all of its members are defined
in datatypes.xsd</xs:documentation>
</xs:annotation>
<xs:include schemaLocation="datatypes.xsd"/>
<xs:import namespace="http://www.w3.org/XML/1998/namespace"
schemaLocation="http://www.w3.org/2001/xml.xsd">
<xs:annotation>
<xs:documentation>
Get access to the xml: attribute groups for xml:lang
as declared on 'schema' and 'documentation' below
</xs:documentation>
</xs:annotation>
</xs:import>
<xs:complexType name="openAttrs">
<xs:annotation>
<xs:documentation>
This type is extended by almost all schema types
to allow attributes from other namespaces to be
added to user schemas.
</xs:documentation>
</xs:annotation>
<xs:complexContent>
<xs:restriction base="xs:anyType">
<xs:anyAttribute namespace="##other" processContents="lax"/>
</xs:restriction>
</xs:complexContent>
</xs:complexType>
<xs:complexType name="annotated">
<xs:annotation>
<xs:documentation>
This type is extended by all types which allow annotation
other than <schema> itself
</xs:documentation>
</xs:annotation>
<xs:complexContent>
<xs:extension base="xs:openAttrs">
<xs:sequence>
<xs:element ref="xs:annotation" minOccurs="0"/>
</xs:sequence>
<xs:attribute name="id" type="xs:ID"/>
</xs:extension>
</xs:complexContent>
</xs:complexType>
<xs:group name="composition">
<xs:choice>
<xs:element ref="xs:include"/>
<xs:element ref="xs:import"/>
<xs:element ref="xs:redefine"/>
<xs:element ref="xs:override"/>
<xs:element ref="xs:annotation"/>
</xs:choice>
</xs:group>
<xs:group name="schemaTop">
<xs:annotation>
<xs:documentation>
This group is for the
elements which occur freely at the top level of schemas.
All of their types are based on the "annotated" type by extension.</xs:documentation>
</xs:annotation>
<xs:choice>
<xs:group ref="xs:redefinable"/>
<xs:element ref="xs:element"/>
<xs:element ref="xs:attribute"/>
<xs:element ref="xs:notation"/>
</xs:choice>
</xs:group>
<xs:group name="redefinable">
<xs:annotation>
<xs:documentation>
This group is for the
elements which can self-redefine (see <redefine> below).</xs:documentation>
</xs:annotation>
<xs:choice>
<xs:element ref="xs:simpleType"/>
<xs:element ref="xs:complexType"/>
<xs:element ref="xs:group"/>
<xs:element ref="xs:attributeGroup"/>
</xs:choice>
</xs:group>
<xs:simpleType name="formChoice">
<xs:annotation>
<xs:documentation>
A utility type, not for public use</xs:documentation>
</xs:annotation>
<xs:restriction base="xs:NMTOKEN">
<xs:enumeration value="qualified"/>
<xs:enumeration value="unqualified"/>
</xs:restriction>
</xs:simpleType>
<xs:simpleType name="reducedDerivationControl">
<xs:annotation>
<xs:documentation>
A utility type, not for public use</xs:documentation>
</xs:annotation>
<xs:restriction base="xs:derivationControl">
<xs:enumeration value="extension"/>
<xs:enumeration value="restriction"/>
</xs:restriction>
</xs:simpleType>
<xs:simpleType name="derivationSet">
<xs:annotation>
<xs:documentation>
A utility type, not for public use</xs:documentation>
<xs:documentation>
#all or (possibly empty) subset of {extension, restriction}</xs:documentation>
</xs:annotation>
<xs:union>
<xs:simpleType>
<xs:restriction base="xs:token">
<xs:enumeration value="#all"/>
</xs:restriction>
</xs:simpleType>
<xs:simpleType>
<xs:list itemType="xs:reducedDerivationControl"/>
</xs:simpleType>
</xs:union>
</xs:simpleType>
<xs:simpleType name="typeDerivationControl">
<xs:annotation>
<xs:documentation>
A utility type, not for public use</xs:documentation>
</xs:annotation>
<xs:restriction base="xs:derivationControl">
<xs:enumeration value="extension"/>
<xs:enumeration value="restriction"/>
<xs:enumeration value="list"/>
<xs:enumeration value="union"/>
</xs:restriction>
</xs:simpleType>
<xs:simpleType name="fullDerivationSet">
<xs:annotation>
<xs:documentation>
A utility type, not for public use</xs:documentation>
<xs:documentation>
#all or (possibly empty) subset of {extension, restriction, list, union}</xs:documentation>
</xs:annotation>
<xs:union>
<xs:simpleType>
<xs:restriction base="xs:token">
<xs:enumeration value="#all"/>
</xs:restriction>
</xs:simpleType>
<xs:simpleType>
<xs:list itemType="xs:typeDerivationControl"/>
</xs:simpleType>
</xs:union>
</xs:simpleType>
<xs:element name="schema" id="schema">
<xs:annotation>
<xs:documentation
source="http://www.w3.org/TR/2012/REC-xmlschema11-1-20120405/structures.html#element-schema"/>
</xs:annotation>
<xs:complexType>
<xs:complexContent>
<xs:extension base="xs:openAttrs">
<xs:sequence>
<xs:group ref="xs:composition" minOccurs="0" maxOccurs="unbounded"/>
<xs:sequence minOccurs="0">
<xs:element ref="xs:defaultOpenContent"/>
<xs:element ref="xs:annotation" minOccurs="0"
maxOccurs="unbounded"/>
</xs:sequence>
<xs:sequence minOccurs="0" maxOccurs="unbounded">
<xs:group ref="xs:schemaTop"/>
<xs:element ref="xs:annotation" minOccurs="0"
maxOccurs="unbounded"/>
</xs:sequence>
</xs:sequence>
<xs:attribute name="targetNamespace" type="xs:anyURI"/>
<xs:attribute name="version" type="xs:token"/>
<xs:attribute name="finalDefault" type="xs:fullDerivationSet"
default="" use="optional"/>
<xs:attribute name="blockDefault" type="xs:blockSet" default=""
use="optional"/>
<xs:attribute name="attributeFormDefault" type="xs:formChoice"
default="unqualified" use="optional"/>
<xs:attribute name="elementFormDefault" type="xs:formChoice"
default="unqualified" use="optional"/>
<xs:attribute name="defaultAttributes" type="xs:QName"/>
<xs:attribute name="xpathDefaultNamespace" type="xs:xpathDefaultNamespace"
default="##local" use="optional"/>
<xs:attribute name="id" type="xs:ID"/>
<xs:attribute ref="xml:lang"/>
</xs:extension>
</xs:complexContent>
</xs:complexType>
<xs:key name="element">
<xs:selector xpath="xs:element"/>
<xs:field xpath="@name"/>
</xs:key>
<xs:key name="attribute">
<xs:selector xpath="xs:attribute"/>
<xs:field xpath="@name"/>
</xs:key>
<xs:key name="type">
<xs:selector xpath="xs:complexType|xs:simpleType"/>
<xs:field xpath="@name"/>
</xs:key>
<xs:key name="group">
<xs:selector xpath="xs:group"/>
<xs:field xpath="@name"/>
</xs:key>
<xs:key name="attributeGroup">
<xs:selector xpath="xs:attributeGroup"/>
<xs:field xpath="@name"/>
</xs:key>
<xs:key name="notation">
<xs:selector xpath="xs:notation"/>
<xs:field xpath="@name"/>
</xs:key>
<xs:key name="identityConstraint">
<xs:selector xpath=".//xs:key|.//xs:unique|.//xs:keyref"/>
<xs:field xpath="@name"/>
</xs:key>
</xs:element>
<xs:simpleType name="allNNI">
<xs:annotation>
<xs:documentation>
for maxOccurs</xs:documentation>
</xs:annotation>
<xs:union memberTypes="xs:nonNegativeInteger">
<xs:simpleType>
<xs:restriction base="xs:NMTOKEN">
<xs:enumeration value="unbounded"/>
</xs:restriction>
</xs:simpleType>
</xs:union>
</xs:simpleType>
<xs:attributeGroup name="occurs">
<xs:annotation>
<xs:documentation>
for all particles</xs:documentation>
</xs:annotation>
<xs:attribute name="minOccurs" type="xs:nonNegativeInteger" default="1"
use="optional"/>
<xs:attribute name="maxOccurs" type="xs:allNNI" default="1" use="optional"/>
</xs:attributeGroup>
<xs:attributeGroup name="defRef">
<xs:annotation>
<xs:documentation>
for element, group and attributeGroup,
which both define and reference</xs:documentation>
</xs:annotation>
<xs:attribute name="name" type="xs:NCName"/>
<xs:attribute name="ref" type="xs:QName"/>
</xs:attributeGroup>
<xs:group name="typeDefParticle">
<xs:annotation>
<xs:documentation>
'complexType' uses this</xs:documentation>
</xs:annotation>
<xs:choice>
<xs:element name="group" type="xs:groupRef"/>
<xs:element ref="xs:all"/>
<xs:element ref="xs:choice"/>
<xs:element ref="xs:sequence"/>
</xs:choice>
</xs:group>
<xs:group name="nestedParticle">
<xs:choice>
<xs:element name="element" type="xs:localElement"/>
<xs:element name="group" type="xs:groupRef"/>
<xs:element ref="xs:choice"/>
<xs:element ref="xs:sequence"/>
<xs:element ref="xs:any"/>
</xs:choice>
</xs:group>
<xs:group name="particle">
<xs:choice>
<xs:element name="element" type="xs:localElement"/>
<xs:element name="group" type="xs:groupRef"/>
<xs:element ref="xs:all"/>
<xs:element ref="xs:choice"/>
<xs:element ref="xs:sequence"/>
<xs:element ref="xs:any"/>
</xs:choice>
</xs:group>
<xs:complexType name="attribute">
<xs:complexContent>
<xs:extension base="xs:annotated">
<xs:sequence>
<xs:element name="simpleType" type="xs:localSimpleType" minOccurs="0"/>
</xs:sequence>
<xs:attributeGroup ref="xs:defRef"/>
<xs:attribute name="type" type="xs:QName"/>
<xs:attribute name="use" default="optional" use="optional">
<xs:simpleType>
<xs:restriction base="xs:NMTOKEN">
<xs:enumeration value="prohibited"/>
<xs:enumeration value="optional"/>
<xs:enumeration value="required"/>
</xs:restriction>
</xs:simpleType>
</xs:attribute>
<xs:attribute name="default" type="xs:string"/>
<xs:attribute name="fixed" type="xs:string"/>
<xs:attribute name="form" type="xs:formChoice"/>
<xs:attribute name="targetNamespace" type="xs:anyURI"/>
<xs:attribute name="inheritable" type="xs:boolean"/>
</xs:extension>
</xs:complexContent>
</xs:complexType>
<xs:complexType name="topLevelAttribute">
<xs:complexContent>
<xs:restriction base="xs:attribute">
<xs:sequence>
<xs:element ref="xs:annotation" minOccurs="0"/>
<xs:element name="simpleType" type="xs:localSimpleType" minOccurs="0"/>
</xs:sequence>
<xs:attribute name="ref" use="prohibited"/>
<xs:attribute name="form" use="prohibited"/>
<xs:attribute name="use" use="prohibited"/>
<xs:attribute name="targetNamespace" use="prohibited"/>
<xs:attribute name="name" type="xs:NCName" use="required"/>
<xs:attribute name="inheritable" type="xs:boolean"/>
<xs:anyAttribute namespace="##other" processContents="lax"/>
</xs:restriction>
</xs:complexContent>
</xs:complexType>
<xs:group name="attrDecls">
<xs:sequence>
<xs:choice minOccurs="0" maxOccurs="unbounded">
<xs:element name="attribute" type="xs:attribute"/>
<xs:element name="attributeGroup" type="xs:attributeGroupRef"/>
</xs:choice>
<xs:element ref="xs:anyAttribute" minOccurs="0"/>
</xs:sequence>
</xs:group>
<xs:element name="anyAttribute" id="anyAttribute">
<xs:annotation>
<xs:documentation
source="http://www.w3.org/TR/2012/REC-xmlschema11-1-20120405/structures.html#element-anyAttribute"/>
</xs:annotation>
<xs:complexType>
<xs:complexContent>
<xs:extension base="xs:wildcard">
<xs:attribute name="notQName" type="xs:qnameListA"
use="optional"/>
</xs:extension>
</xs:complexContent>
</xs:complexType>
</xs:element>
<xs:group name="assertions">
<xs:sequence>
<xs:element name="assert" type="xs:assertion"
minOccurs="0" maxOccurs="unbounded"/>
</xs:sequence>
</xs:group>
<xs:complexType name="assertion">
<xs:complexContent>
<xs:extension base="xs:annotated">
<xs:attribute name="test" type="xs:string"/>
<xs:attribute name="xpathDefaultNamespace" type="xs:xpathDefaultNamespace"/>
</xs:extension>
</xs:complexContent>
</xs:complexType>
<xs:group name="complexTypeModel">
<xs:choice>
<xs:element ref="xs:simpleContent"/>
<xs:element ref="xs:complexContent"/>
<xs:sequence>
<xs:annotation>
<xs:documentation>
This branch is short for
<complexContent>
<restriction base="xs:anyType">
...
</restriction>
</complexContent></xs:documentation>
</xs:annotation>
<xs:element ref="xs:openContent" minOccurs="0"/>
<xs:group ref="xs:typeDefParticle" minOccurs="0"/>
<xs:group ref="xs:attrDecls"/>
<xs:group ref="xs:assertions"/>
</xs:sequence>
</xs:choice>
</xs:group>
<xs:complexType name="complexType" abstract="true">
<xs:complexContent>
<xs:extension base="xs:annotated">
<xs:group ref="xs:complexTypeModel"/>
<xs:attribute name="name" type="xs:NCName">
<xs:annotation>
<xs:documentation>
Will be restricted to required or prohibited</xs:documentation>
</xs:annotation>
</xs:attribute>
<xs:attribute name="mixed" type="xs:boolean" use="optional">
<xs:annotation>
<xs:documentation>
Not allowed if simpleContent child is chosen.
May be overridden by setting on complexContent child.</xs:documentation>
</xs:annotation>
</xs:attribute>
<xs:attribute name="abstract" type="xs:boolean" default="false"
use="optional"/>
<xs:attribute name="final" type="xs:derivationSet"/>
<xs:attribute name="block" type="xs:derivationSet"/>
<xs:attribute name="defaultAttributesApply" type="xs:boolean"
default="true" use="optional"/>
</xs:extension>
</xs:complexContent>
</xs:complexType>
<xs:complexType name="topLevelComplexType">
<xs:complexContent>
<xs:restriction base="xs:complexType">
<xs:sequence>
<xs:element ref="xs:annotation" minOccurs="0"/>
<xs:group ref="xs:complexTypeModel"/>
</xs:sequence>
<xs:attribute name="name" type="xs:NCName" use="required"/>
<xs:anyAttribute namespace="##other" processContents="lax"/>
</xs:restriction>
</xs:complexContent>
</xs:complexType>
<xs:complexType name="localComplexType">
<xs:complexContent>
<xs:restriction base="xs:complexType">
<xs:sequence>
<xs:element ref="xs:annotation" minOccurs="0"/>
<xs:group ref="xs:complexTypeModel"/>
</xs:sequence>
<xs:attribute name="name" use="prohibited"/>
<xs:attribute name="abstract" use="prohibited"/>
<xs:attribute name="final" use="prohibited"/>
<xs:attribute name="block" use="prohibited"/>
<xs:anyAttribute namespace="##other" processContents="lax"/>
</xs:restriction>
</xs:complexContent>
</xs:complexType>
<xs:complexType name="restrictionType">
<xs:complexContent>
<xs:extension base="xs:annotated">
<xs:sequence>
<xs:choice minOccurs="0">
<xs:sequence>
<xs:element ref="xs:openContent" minOccurs="0"/>
<xs:group ref="xs:typeDefParticle"/>
</xs:sequence>
<xs:group ref="xs:simpleRestrictionModel"/>
</xs:choice>
<xs:group ref="xs:attrDecls"/>
<xs:group ref="xs:assertions"/>
</xs:sequence>
<xs:attribute name="base" type="xs:QName" use="required"/>
</xs:extension>
</xs:complexContent>
</xs:complexType>
<xs:complexType name="complexRestrictionType">
<xs:complexContent>
<xs:restriction base="xs:restrictionType">
<xs:sequence>
<xs:element ref="xs:annotation" minOccurs="0"/>
<xs:choice minOccurs="0">
<xs:annotation>
<xs:documentation>This choice is added simply to
make this a valid restriction per the REC</xs:documentation>
</xs:annotation>
<xs:sequence>
<xs:element ref="xs:openContent" minOccurs="0"/>
<xs:group ref="xs:typeDefParticle"/>
</xs:sequence>
</xs:choice>
<xs:group ref="xs:attrDecls"/>
<xs:group ref="xs:assertions"/>
</xs:sequence>
<xs:anyAttribute namespace="##other" processContents="lax"/>
</xs:restriction>
</xs:complexContent>
</xs:complexType>
<xs:complexType name="extensionType">
<xs:complexContent>
<xs:extension base="xs:annotated">
<xs:sequence>
<xs:element ref="xs:openContent" minOccurs="0"/>
<xs:group ref="xs:typeDefParticle" minOccurs="0"/>
<xs:group ref="xs:attrDecls"/>
<xs:group ref="xs:assertions"/>
</xs:sequence>
<xs:attribute name="base" type="xs:QName" use="required"/>
</xs:extension>
</xs:complexContent>
</xs:complexType>
<xs:element name="complexContent" id="complexContent">
<xs:annotation>
<xs:documentation
source="http://www.w3.org/TR/2012/REC-xmlschema11-1-20120405/structures.html#element-complexContent"/>
</xs:annotation>
<xs:complexType>
<xs:complexContent>
<xs:extension base="xs:annotated">
<xs:choice>
<xs:element name="restriction" type="xs:complexRestrictionType"/>
<xs:element name="extension" type="xs:extensionType"/>
</xs:choice>
<xs:attribute name="mixed" type="xs:boolean">
<xs:annotation>
<xs:documentation>
Overrides any setting on complexType parent.</xs:documentation>
</xs:annotation>
</xs:attribute>
</xs:extension>
</xs:complexContent>
</xs:complexType>
</xs:element>
<xs:element name="openContent" id="openContent">
<xs:annotation>
<xs:documentation
source="http://www.w3.org/TR/2012/REC-xmlschema11-1-20120405/structures.html#element-openContent"/>
</xs:annotation>
<xs:complexType>
<xs:complexContent>
<xs:extension base="xs:annotated">
<xs:sequence>
<xs:element name="any" minOccurs="0" type="xs:wildcard"/>
</xs:sequence>
<xs:attribute name="mode" default="interleave" use="optional">
<xs:simpleType>
<xs:restriction base="xs:NMTOKEN">
<xs:enumeration value="none"/>
<xs:enumeration value="interleave"/>
<xs:enumeration value="suffix"/>
</xs:restriction>
</xs:simpleType>
</xs:attribute>
</xs:extension>
</xs:complexContent>
</xs:complexType>
</xs:element>
<xs:element name="defaultOpenContent" id="defaultOpenContent">
<xs:annotation>
<xs:documentation
source="http://www.w3.org/TR/2012/REC-xmlschema11-1-20120405/structures.html#element-defaultOpenContent"/>
</xs:annotation>
<xs:complexType>
<xs:complexContent>
<xs:extension base="xs:annotated">
<xs:sequence>
<xs:element name="any" type="xs:wildcard"/>
</xs:sequence>
<xs:attribute name="appliesToEmpty" type="xs:boolean"
default="false" use="optional"/>
<xs:attribute name="mode" default="interleave" use="optional">
<xs:simpleType>
<xs:restriction base="xs:NMTOKEN">
<xs:enumeration value="interleave"/>
<xs:enumeration value="suffix"/>
</xs:restriction>
</xs:simpleType>
</xs:attribute>
</xs:extension>
</xs:complexContent>
</xs:complexType>
</xs:element>
<xs:complexType name="simpleRestrictionType">
<xs:complexContent>
<xs:restriction base="xs:restrictionType">
<xs:sequence>
<xs:element ref="xs:annotation" minOccurs="0"/>
<xs:choice minOccurs="0">
<xs:annotation>
<xs:documentation>This choice is added simply to
make this a valid restriction per the REC</xs:documentation>
</xs:annotation>
<xs:group ref="xs:simpleRestrictionModel"/>
</xs:choice>
<xs:group ref="xs:attrDecls"/>
<xs:group ref="xs:assertions"/>
</xs:sequence>
<xs:anyAttribute namespace="##other" processContents="lax"/>
</xs:restriction>
</xs:complexContent>
</xs:complexType>
<xs:complexType name="simpleExtensionType">
<xs:complexContent>
<xs:restriction base="xs:extensionType">
<xs:sequence>
<xs:annotation>
<xs:documentation>
No typeDefParticle group reference</xs:documentation>
</xs:annotation>
<xs:element ref="xs:annotation" minOccurs="0"/>
<xs:group ref="xs:attrDecls"/>
<xs:group ref="xs:assertions"/>
</xs:sequence>
<xs:anyAttribute namespace="##other" processContents="lax"/>
</xs:restriction>
</xs:complexContent>
</xs:complexType>
<xs:element name="simpleContent" id="simpleContent">
<xs:annotation>
<xs:documentation
source="http://www.w3.org/TR/2012/REC-xmlschema11-1-20120405/structures.html#element-simpleContent"/>
</xs:annotation>
<xs:complexType>
<xs:complexContent>
<xs:extension base="xs:annotated">
<xs:choice>
<xs:element name="restriction" type="xs:simpleRestrictionType"/>
<xs:element name="extension" type="xs:simpleExtensionType"/>
</xs:choice>
</xs:extension>
</xs:complexContent>
</xs:complexType>
</xs:element>
<xs:element name="complexType" type="xs:topLevelComplexType" id="complexType">
<xs:annotation>
<xs:documentation
source="http://www.w3.org/TR/2012/REC-xmlschema11-1-20120405/structures.html#element-complexType"/>
</xs:annotation>
</xs:element>
<xs:simpleType name="blockSet">
<xs:annotation>
<xs:documentation>
A utility type, not for public use</xs:documentation>
<xs:documentation>
#all or (possibly empty) subset of {substitution, extension,
restriction}</xs:documentation>
</xs:annotation>
<xs:union>
<xs:simpleType>
<xs:restriction base="xs:token">
<xs:enumeration value="#all"/>
</xs:restriction>
</xs:simpleType>
<xs:simpleType>
<xs:list>
<xs:simpleType>
<xs:restriction base="xs:derivationControl">
<xs:enumeration value="extension"/>
<xs:enumeration value="restriction"/>
<xs:enumeration value="substitution"/>
</xs:restriction>
</xs:simpleType>
</xs:list>
</xs:simpleType>
</xs:union>
</xs:simpleType>
<xs:complexType name="element" abstract="true">
<xs:annotation>
<xs:documentation>
The element element can be used either
at the top level to define an element-type binding globally,
or within a content model to either reference a globally-defined
element or type or declare an element-type binding locally.
The ref form is not allowed at the top level.</xs:documentation>
</xs:annotation>
<xs:complexContent>
<xs:extension base="xs:annotated">
<xs:sequence>
<xs:choice minOccurs="0">
<xs:element name="simpleType" type="xs:localSimpleType"/>
<xs:element name="complexType" type="xs:localComplexType"/>
</xs:choice>
<xs:element name="alternative" type="xs:altType"
minOccurs="0" maxOccurs="unbounded"/>
<xs:group ref="xs:identityConstraint" minOccurs="0"
maxOccurs="unbounded"/>
</xs:sequence>
<xs:attributeGroup ref="xs:defRef"/>
<xs:attribute name="type" type="xs:QName"/>
<xs:attribute name="substitutionGroup">
<xs:simpleType>
<xs:list itemType="xs:QName"/>
</xs:simpleType>
</xs:attribute>
<xs:attributeGroup ref="xs:occurs"/>
<xs:attribute name="default" type="xs:string"/>
<xs:attribute name="fixed" type="xs:string"/>
<xs:attribute name="nillable" type="xs:boolean" use="optional"/>
<xs:attribute name="abstract" type="xs:boolean" default="false"
use="optional"/>
<xs:attribute name="final" type="xs:derivationSet"/>
<xs:attribute name="block" type="xs:blockSet"/>
<xs:attribute name="form" type="xs:formChoice"/>
<xs:attribute name="targetNamespace" type="xs:anyURI"/>
</xs:extension>
</xs:complexContent>
</xs:complexType>
<xs:complexType name="topLevelElement">
<xs:complexContent>
<xs:restriction base="xs:element">
<xs:sequence>
<xs:element ref="xs:annotation" minOccurs="0"/>
<xs:choice minOccurs="0">
<xs:element name="simpleType" type="xs:localSimpleType"/>
<xs:element name="complexType" type="xs:localComplexType"/>
</xs:choice>
<xs:element name="alternative" type="xs:altType"
minOccurs="0" maxOccurs="unbounded"/>
<xs:group ref="xs:identityConstraint" minOccurs="0"
maxOccurs="unbounded"/>
</xs:sequence>
<xs:attribute name="ref" use="prohibited"/>
<xs:attribute name="form" use="prohibited"/>
<xs:attribute name="targetNamespace" use="prohibited"/>
<xs:attribute name="minOccurs" use="prohibited"/>
<xs:attribute name="maxOccurs" use="prohibited"/>
<xs:attribute name="name" type="xs:NCName" use="required"/>
<xs:anyAttribute namespace="##other" processContents="lax"/>
</xs:restriction>
</xs:complexContent>
</xs:complexType>
<xs:complexType name="localElement">
<xs:complexContent>
<xs:restriction base="xs:element">
<xs:sequence>
<xs:element ref="xs:annotation" minOccurs="0"/>
<xs:choice minOccurs="0">
<xs:element name="simpleType" type="xs:localSimpleType"/>
<xs:element name="complexType" type="xs:localComplexType"/>
</xs:choice>
<xs:element name="alternative" type="xs:altType"
minOccurs="0" maxOccurs="unbounded"/>
<xs:group ref="xs:identityConstraint" minOccurs="0"
maxOccurs="unbounded"/>
</xs:sequence>
<xs:attribute name="substitutionGroup" use="prohibited"/>
<xs:attribute name="final" use="prohibited"/>
<xs:attribute name="abstract" use="prohibited"/>
<xs:anyAttribute namespace="##other" processContents="lax"/>
</xs:restriction>
</xs:complexContent>
</xs:complexType>
<xs:element name="element" type="xs:topLevelElement" id="element">
<xs:annotation>
<xs:documentation
source="http://www.w3.org/TR/2012/REC-xmlschema11-1-20120405/structures.html#element-element"/>
</xs:annotation>
</xs:element>
<xs:complexType name="altType">
<xs:annotation>
<xs:documentation>
This type is used for 'alternative' elements.
</xs:documentation>
</xs:annotation>
<xs:complexContent>
<xs:extension base="xs:annotated">
<xs:choice minOccurs="0">
<xs:element name="simpleType" type="xs:localSimpleType"/>
<xs:element name="complexType" type="xs:localComplexType"/>
</xs:choice>
<xs:attribute name="test" type="xs:string" use="optional"/>
<xs:attribute name="type" type="xs:QName" use="optional"/>
<xs:attribute name="xpathDefaultNamespace" type="xs:xpathDefaultNamespace"/>
</xs:extension>
</xs:complexContent>
</xs:complexType>
<xs:complexType name="group" abstract="true">
<xs:annotation>
<xs:documentation>
group type for explicit groups, named top-level groups and
group references</xs:documentation>
</xs:annotation>
<xs:complexContent>
<xs:extension base="xs:annotated">
<xs:group ref="xs:particle" minOccurs="0" maxOccurs="unbounded"/>
<xs:attributeGroup ref="xs:defRef"/>
<xs:attributeGroup ref="xs:occurs"/>
</xs:extension>
</xs:complexContent>
</xs:complexType>
<xs:complexType name="realGroup">
<xs:complexContent>
<xs:restriction base="xs:group">
<xs:sequence>
<xs:element ref="xs:annotation" minOccurs="0"/>
<xs:choice minOccurs="0" maxOccurs="1">
<xs:element ref="xs:all"/>
<xs:element ref="xs:choice"/>
<xs:element ref="xs:sequence"/>
</xs:choice>
</xs:sequence>
<xs:anyAttribute namespace="##other" processContents="lax"/>
</xs:restriction>
</xs:complexContent>
</xs:complexType>
<xs:complexType name="namedGroup">
<xs:complexContent>
<xs:restriction base="xs:realGroup">
<xs:sequence>
<xs:element ref="xs:annotation" minOccurs="0"/>
<xs:choice minOccurs="1" maxOccurs="1">
<xs:element name="all">
<xs:complexType>
<xs:complexContent>
<xs:restriction base="xs:all">
<xs:group ref="xs:allModel"/>
<xs:attribute name="minOccurs" use="prohibited"/>
<xs:attribute name="maxOccurs" use="prohibited"/>
<xs:anyAttribute namespace="##other" processContents="lax"/>
</xs:restriction>
</xs:complexContent>
</xs:complexType>
</xs:element>
<xs:element name="choice" type="xs:simpleExplicitGroup"/>
<xs:element name="sequence" type="xs:simpleExplicitGroup"/>
</xs:choice>
</xs:sequence>
<xs:attribute name="name" type="xs:NCName" use="required"/>
<xs:attribute name="ref" use="prohibited"/>
<xs:attribute name="minOccurs" use="prohibited"/>
<xs:attribute name="maxOccurs" use="prohibited"/>
<xs:anyAttribute namespace="##other" processContents="lax"/>
</xs:restriction>
</xs:complexContent>
</xs:complexType>
<xs:complexType name="groupRef">
<xs:complexContent>
<xs:restriction base="xs:realGroup">
<xs:sequence>
<xs:element ref="xs:annotation" minOccurs="0"/>
</xs:sequence>
<xs:attribute name="ref" type="xs:QName" use="required"/>
<xs:attribute name="name" use="prohibited"/>
<xs:anyAttribute namespace="##other" processContents="lax"/>
</xs:restriction>
</xs:complexContent>
</xs:complexType>
<xs:complexType name="explicitGroup">
<xs:annotation>
<xs:documentation>
group type for the three kinds of group</xs:documentation>
</xs:annotation>
<xs:complexContent>
<xs:restriction base="xs:group">
<xs:sequence>
<xs:element ref="xs:annotation" minOccurs="0"/>
<xs:group ref="xs:nestedParticle" minOccurs="0" maxOccurs="unbounded"/>
</xs:sequence>
<xs:attribute name="name" use="prohibited"/>
<xs:attribute name="ref" use="prohibited"/>
<xs:anyAttribute namespace="##other" processContents="lax"/>
</xs:restriction>
</xs:complexContent>
</xs:complexType>
<xs:complexType name="simpleExplicitGroup">
<xs:complexContent>
<xs:restriction base="xs:explicitGroup">
<xs:sequence>
<xs:element ref="xs:annotation" minOccurs="0"/>
<xs:group ref="xs:nestedParticle" minOccurs="0" maxOccurs="unbounded"/>
</xs:sequence>
<xs:attribute name="minOccurs" use="prohibited"/>
<xs:attribute name="maxOccurs" use="prohibited"/>
<xs:anyAttribute namespace="##other" processContents="lax"/>
</xs:restriction>
</xs:complexContent>
</xs:complexType>
<xs:group name="allModel">
<xs:sequence>
<xs:element ref="xs:annotation" minOccurs="0"/>
<xs:choice minOccurs="0" maxOccurs="unbounded">
<xs:annotation>
<xs:documentation>This choice with min/max is here to
avoid a pblm with the Elt:All/Choice/Seq
Particle derivation constraint</xs:documentation>
</xs:annotation>
<xs:element name="element" type="xs:localElement"/>
<xs:element ref="xs:any"/>
<xs:element name="group">
<xs:complexType>
<xs:complexContent>
<xs:restriction base="xs:groupRef">
<xs:sequence>
<xs:element ref="xs:annotation" minOccurs="0"/>
</xs:sequence>
<xs:attribute name="minOccurs" fixed="1" type="xs:nonNegativeInteger"/>
<xs:attribute name="maxOccurs" fixed="1" type="xs:nonNegativeInteger"/>
</xs:restriction>
</xs:complexContent>
</xs:complexType>
</xs:element>
</xs:choice>
</xs:sequence>
</xs:group>
<xs:complexType name="all">
<xs:annotation>
<xs:documentation>
Only elements allowed inside</xs:documentation>
</xs:annotation>
<xs:complexContent>
<xs:restriction base="xs:explicitGroup">
<xs:group ref="xs:allModel"/>
<xs:attribute name="minOccurs" default="1" use="optional">
<xs:simpleType>
<xs:restriction base="xs:nonNegativeInteger">
<xs:enumeration value="0"/>
<xs:enumeration value="1"/>
</xs:restriction>
</xs:simpleType>
</xs:attribute>
<xs:attribute name="maxOccurs" default="1" use="optional">
<xs:simpleType>
<xs:restriction base="xs:allNNI">
<xs:enumeration value="0"/>
<xs:enumeration value="1"/>
</xs:restriction>
</xs:simpleType>
</xs:attribute>
<xs:anyAttribute namespace="##other" processContents="lax"/>
</xs:restriction>
</xs:complexContent>
</xs:complexType>
<xs:element name="all" type="xs:all" id="all">
<xs:annotation>
<xs:documentation source="http://www.w3.org/TR/2012/REC-xmlschema11-1-20120405/structures.html#element-all"/>
</xs:annotation>
</xs:element>
<xs:element name="choice" type="xs:explicitGroup" id="choice">
<xs:annotation>
<xs:documentation
source="http://www.w3.org/TR/2012/REC-xmlschema11-1-20120405/structures.html#element-choice"/>
</xs:annotation>
</xs:element>
<xs:element name="sequence" type="xs:explicitGroup" id="sequence">
<xs:annotation>
<xs:documentation
source="http://www.w3.org/TR/2012/REC-xmlschema11-1-20120405/structures.html#element-sequence"/>
</xs:annotation>
</xs:element>
<xs:element name="group" type="xs:namedGroup" id="group">
<xs:annotation>
<xs:documentation source="http://www.w3.org/TR/2012/REC-xmlschema11-1-20120405/structures.html#element-group"/>
</xs:annotation>
</xs:element>
<xs:attributeGroup name="anyAttrGroup">
<xs:attribute name="namespace" type="xs:namespaceList"
use="optional"/>
<xs:attribute name="notNamespace" use="optional">
<xs:simpleType>
<xs:restriction base="xs:basicNamespaceList">
<xs:minLength value="1"/>
</xs:restriction>
</xs:simpleType>
</xs:attribute>
<xs:attribute name="processContents" default="strict" use="optional">
<xs:simpleType>
<xs:restriction base="xs:NMTOKEN">
<xs:enumeration value="skip"/>
<xs:enumeration value="lax"/>
<xs:enumeration value="strict"/>
</xs:restriction>
</xs:simpleType>
</xs:attribute>
</xs:attributeGroup>
<xs:complexType name="wildcard">
<xs:complexContent>
<xs:extension base="xs:annotated">
<xs:attributeGroup ref="xs:anyAttrGroup"/>
</xs:extension>
</xs:complexContent>
</xs:complexType>
<xs:element name="any" id="any">
<xs:annotation>
<xs:documentation source="http://www.w3.org/TR/2012/REC-xmlschema11-1-20120405/structures.html#element-any"/>
</xs:annotation>
<xs:complexType>
<xs:complexContent>
<xs:extension base="xs:wildcard">
<xs:attribute name="notQName" type="xs:qnameList"
use="optional"/>
<xs:attributeGroup ref="xs:occurs"/>
</xs:extension>
</xs:complexContent>
</xs:complexType>
</xs:element>
<xs:annotation>
<xs:documentation>
simple type for the value of the 'namespace' attr of
'any' and 'anyAttribute'</xs:documentation>
</xs:annotation>
<xs:annotation>
<xs:documentation>
Value is
##any - - any non-conflicting WFXML/attribute at all
##other - - any non-conflicting WFXML/attribute from
namespace other than targetNS
##local - - any unqualified non-conflicting WFXML/attribute
one or - - any non-conflicting WFXML/attribute from
more URI the listed namespaces
references
(space separated)
##targetNamespace or ##local may appear in the above list, to
refer to the targetNamespace of the enclosing
schema or an absent targetNamespace respectively</xs:documentation>
</xs:annotation>
<xs:simpleType name="namespaceList">
<xs:annotation>
<xs:documentation>
A utility type, not for public use</xs:documentation>
</xs:annotation>
<xs:union memberTypes="xs:specialNamespaceList xs:basicNamespaceList" />
</xs:simpleType>
<xs:simpleType name="basicNamespaceList">
<xs:annotation>
<xs:documentation>
A utility type, not for public use</xs:documentation>
</xs:annotation>
<xs:list>
<xs:simpleType>
<xs:union memberTypes="xs:anyURI">
<xs:simpleType>
<xs:restriction base="xs:token">
<xs:enumeration value="##targetNamespace"/>
<xs:enumeration value="##local"/>
</xs:restriction>
</xs:simpleType>
</xs:union>
</xs:simpleType>
</xs:list>
</xs:simpleType>
<xs:simpleType name="specialNamespaceList">
<xs:annotation>
<xs:documentation>
A utility type, not for public use</xs:documentation>
</xs:annotation>
<xs:restriction base="xs:token">
<xs:enumeration value="##any"/>
<xs:enumeration value="##other"/>
</xs:restriction>
</xs:simpleType>
<xs:simpleType name="qnameList">
<xs:annotation>
<xs:documentation>
A utility type, not for public use
</xs:documentation>
</xs:annotation>
<xs:list>
<xs:simpleType>
<xs:union memberTypes="xs:QName">
<xs:simpleType>
<xs:restriction base="xs:token">
<xs:enumeration value="##defined"/>
<xs:enumeration value="##definedSibling"/>
</xs:restriction>
</xs:simpleType>
</xs:union>
</xs:simpleType>
</xs:list>
</xs:simpleType>
<xs:simpleType name="qnameListA">
<xs:annotation>
<xs:documentation>
A utility type, not for public use
</xs:documentation>
</xs:annotation>
<xs:list>
<xs:simpleType>
<xs:union memberTypes="xs:QName">
<xs:simpleType>
<xs:restriction base="xs:token">
<xs:enumeration value="##defined"/>
</xs:restriction>
</xs:simpleType>
</xs:union>
</xs:simpleType>
</xs:list>
</xs:simpleType>
<xs:simpleType name="xpathDefaultNamespace">
<xs:union memberTypes="xs:anyURI">
<xs:simpleType>
<xs:restriction base="xs:token">
<xs:enumeration value="##defaultNamespace"/>
<xs:enumeration value="##targetNamespace"/>
<xs:enumeration value="##local"/>
</xs:restriction>
</xs:simpleType>
</xs:union>
</xs:simpleType>
<xs:element name="attribute" type="xs:topLevelAttribute" id="attribute">
<xs:annotation>
<xs:documentation
source="http://www.w3.org/TR/2012/REC-xmlschema11-1-20120405/structures.html#element-attribute"/>
</xs:annotation>
</xs:element>
<xs:complexType name="attributeGroup" abstract="true">
<xs:complexContent>
<xs:extension base="xs:annotated">
<xs:group ref="xs:attrDecls"/>
<xs:attributeGroup ref="xs:defRef"/>
</xs:extension>
</xs:complexContent>
</xs:complexType>
<xs:complexType name="namedAttributeGroup">
<xs:complexContent>
<xs:restriction base="xs:attributeGroup">
<xs:sequence>
<xs:element ref="xs:annotation" minOccurs="0"/>
<xs:group ref="xs:attrDecls"/>
</xs:sequence>
<xs:attribute name="name" type="xs:NCName" use="required"/>
<xs:attribute name="ref" use="prohibited"/>
<xs:anyAttribute namespace="##other" processContents="lax"/>
</xs:restriction>
</xs:complexContent>
</xs:complexType>
<xs:complexType name="attributeGroupRef">
<xs:complexContent>
<xs:restriction base="xs:attributeGroup">
<xs:sequence>
<xs:element ref="xs:annotation" minOccurs="0"/>
</xs:sequence>
<xs:attribute name="ref" type="xs:QName" use="required"/>
<xs:attribute name="name" use="prohibited"/>
<xs:anyAttribute namespace="##other" processContents="lax"/>
</xs:restriction>
</xs:complexContent>
</xs:complexType>
<xs:element name="attributeGroup" type="xs:namedAttributeGroup"
id="attributeGroup">
<xs:annotation>
<xs:documentation
source="http://www.w3.org/TR/2012/REC-xmlschema11-1-20120405/structures.html#element-attributeGroup"/>
</xs:annotation>
</xs:element>
<xs:element name="include" id="include">
<xs:annotation>
<xs:documentation
source="http://www.w3.org/TR/2012/REC-xmlschema11-1-20120405/structures.html#element-include"/>
</xs:annotation>
<xs:complexType>
<xs:complexContent>
<xs:extension base="xs:annotated">
<xs:attribute name="schemaLocation" type="xs:anyURI" use="required"/>
</xs:extension>
</xs:complexContent>
</xs:complexType>
</xs:element>
<xs:element name="redefine" id="redefine">
<xs:annotation>
<xs:documentation
source="http://www.w3.org/TR/2012/REC-xmlschema11-1-20120405/structures.html#element-redefine"/>
</xs:annotation>
<xs:complexType>
<xs:complexContent>
<xs:extension base="xs:openAttrs">
<xs:choice minOccurs="0" maxOccurs="unbounded">
<xs:element ref="xs:annotation"/>
<xs:group ref="xs:redefinable"/>
</xs:choice>
<xs:attribute name="schemaLocation" type="xs:anyURI" use="required"/>
<xs:attribute name="id" type="xs:ID"/>
</xs:extension>
</xs:complexContent>
</xs:complexType>
</xs:element>
<xs:element name="override" id="override">
<xs:annotation>
<xs:documentation
source="http://www.w3.org/TR/2012/REC-xmlschema11-1-20120405/structures.html#element-override"/>
</xs:annotation>
<xs:complexType>
<xs:complexContent>
<xs:extension base="xs:openAttrs">
<xs:sequence>
<xs:element ref="xs:annotation" minOccurs="0"/>
<xs:group ref="xs:schemaTop" minOccurs="0" maxOccurs="unbounded"/>
</xs:sequence>
<xs:attribute name="schemaLocation" type="xs:anyURI" use="required"/>
<xs:attribute name="id" type="xs:ID"/>
</xs:extension>
</xs:complexContent>
</xs:complexType>
</xs:element>
<xs:element name="import" id="import">
<xs:annotation>
<xs:documentation
source="http://www.w3.org/TR/2012/REC-xmlschema11-1-20120405/structures.html#element-import"/>
</xs:annotation>
<xs:complexType>
<xs:complexContent>
<xs:extension base="xs:annotated">
<xs:attribute name="namespace" type="xs:anyURI"/>
<xs:attribute name="schemaLocation" type="xs:anyURI"/>
</xs:extension>
</xs:complexContent>
</xs:complexType>
</xs:element>
<xs:element name="selector" id="selector">
<xs:annotation>
<xs:documentation
source="http://www.w3.org/TR/2012/REC-xmlschema11-1-20120405/structures.html#element-selector"/>
</xs:annotation>
<xs:complexType>
<xs:complexContent>
<xs:extension base="xs:annotated">
<xs:attribute name="xpath" use="required">
<xs:simpleType>
<xs:annotation>
<xs:documentation>A subset of XPath expressions for use
in selectors</xs:documentation>
<xs:documentation>A utility type, not for public
use</xs:documentation>
</xs:annotation>
<xs:restriction base="xs:token"/>
</xs:simpleType>
</xs:attribute>
<xs:attribute name="xpathDefaultNamespace" type="xs:xpathDefaultNamespace"/>
</xs:extension>
</xs:complexContent>
</xs:complexType>
</xs:element>
<xs:element name="field" id="field">
<xs:annotation>
<xs:documentation source="http://www.w3.org/TR/2012/REC-xmlschema11-1-20120405/structures.html#element-field"/>
</xs:annotation>
<xs:complexType>
<xs:complexContent>
<xs:extension base="xs:annotated">
<xs:attribute name="xpath" use="required">
<xs:simpleType>
<xs:annotation>
<xs:documentation>A subset of XPath expressions for use
in fields</xs:documentation>
<xs:documentation>A utility type, not for public
use</xs:documentation>
</xs:annotation>
<xs:restriction base="xs:token"/>
</xs:simpleType>
</xs:attribute>
<xs:attribute name="xpathDefaultNamespace" type="xs:xpathDefaultNamespace"/>
</xs:extension>
</xs:complexContent>
</xs:complexType>
</xs:element>
<xs:complexType name="keybase">
<xs:complexContent>
<xs:extension base="xs:annotated">
<xs:sequence minOccurs="0">
<xs:element ref="xs:selector"/>
<xs:element ref="xs:field" minOccurs="1" maxOccurs="unbounded"/>
</xs:sequence>
<xs:attribute name="name" type="xs:NCName"/>
<xs:attribute name="ref" type="xs:QName"/>
</xs:extension>
</xs:complexContent>
</xs:complexType>
<xs:group name="identityConstraint">
<xs:annotation>
<xs:documentation>The three kinds of identity constraints, all with
type of or derived from 'keybase'.
</xs:documentation>
</xs:annotation>
<xs:choice>
<xs:element ref="xs:unique"/>
<xs:element ref="xs:key"/>
<xs:element ref="xs:keyref"/>
</xs:choice>
</xs:group>
<xs:element name="unique" type="xs:keybase" id="unique">
<xs:annotation>
<xs:documentation
source="http://www.w3.org/TR/2012/REC-xmlschema11-1-20120405/structures.html#element-unique"/>
</xs:annotation>
</xs:element>
<xs:element name="key" type="xs:keybase" id="key">
<xs:annotation>
<xs:documentation source="http://www.w3.org/TR/2012/REC-xmlschema11-1-20120405/structures.html#element-key"/>
</xs:annotation>
</xs:element>
<xs:element name="keyref" id="keyref">
<xs:annotation>
<xs:documentation
source="http://www.w3.org/TR/2012/REC-xmlschema11-1-20120405/structures.html#element-keyref"/>
</xs:annotation>
<xs:complexType>
<xs:complexContent>
<xs:extension base="xs:keybase">
<xs:attribute name="refer" type="xs:QName"/>
</xs:extension>
</xs:complexContent>
</xs:complexType>
</xs:element>
<xs:element name="notation" id="notation">
<xs:annotation>
<xs:documentation
source="http://www.w3.org/TR/2012/REC-xmlschema11-1-20120405/structures.html#element-notation"/>
</xs:annotation>
<xs:complexType>
<xs:complexContent>
<xs:extension base="xs:annotated">
<xs:attribute name="name" type="xs:NCName" use="required"/>
<xs:attribute name="public" type="xs:public"/>
<xs:attribute name="system" type="xs:anyURI"/>
</xs:extension>
</xs:complexContent>
</xs:complexType>
</xs:element>
<xs:simpleType name="public">
<xs:annotation>
<xs:documentation>
A utility type, not for public use</xs:documentation>
<xs:documentation>
A public identifier, per ISO 8879</xs:documentation>
</xs:annotation>
<xs:restriction base="xs:token"/>
</xs:simpleType>
<xs:element name="appinfo" id="appinfo">
<xs:annotation>
<xs:documentation
source="http://www.w3.org/TR/2012/REC-xmlschema11-1-20120405/structures.html#element-appinfo"/>
</xs:annotation>
<xs:complexType mixed="true">
<xs:sequence minOccurs="0" maxOccurs="unbounded">
<xs:any processContents="lax"/>
</xs:sequence>
<xs:attribute name="source" type="xs:anyURI"/>
<xs:anyAttribute namespace="##other" processContents="lax"/>
</xs:complexType>
</xs:element>
<xs:element name="documentation" id="documentation">
<xs:annotation>
<xs:documentation
source="http://www.w3.org/TR/2012/REC-xmlschema11-1-20120405/structures.html#element-documentation"/>
</xs:annotation>
<xs:complexType mixed="true">
<xs:sequence minOccurs="0" maxOccurs="unbounded">
<xs:any processContents="lax"/>
</xs:sequence>
<xs:attribute name="source" type="xs:anyURI"/>
<xs:attribute ref="xml:lang"/>
<xs:anyAttribute namespace="##other" processContents="lax"/>
</xs:complexType>
</xs:element>
<xs:element name="annotation" id="annotation">
<xs:annotation>
<xs:documentation
source="http://www.w3.org/TR/2012/REC-xmlschema11-1-20120405/structures.html#element-annotation"/>
</xs:annotation>
<xs:complexType>
<xs:complexContent>
<xs:extension base="xs:openAttrs">
<xs:choice minOccurs="0" maxOccurs="unbounded">
<xs:element ref="xs:appinfo"/>
<xs:element ref="xs:documentation"/>
</xs:choice>
<xs:attribute name="id" type="xs:ID"/>
</xs:extension>
</xs:complexContent>
</xs:complexType>
</xs:element>
<xs:annotation>
<xs:documentation>
notations for use within schema documents</xs:documentation>
</xs:annotation>
<xs:notation name="XMLSchemaStructures" public="structures"
system="http://www.w3.org/2000/08/XMLSchema.xsd"/>
<xs:notation name="XML" public="REC-xml-19980210"
system="http://www.w3.org/TR/1998/REC-xml-19980210"/>
<xs:complexType name="anyType" mixed="true">
<xs:annotation>
<xs:documentation>
Not the real urType, but as close an approximation as we can
get in the XML representation</xs:documentation>
</xs:annotation>
<xs:sequence>
<xs:any minOccurs="0" maxOccurs="unbounded" processContents="lax"/>
</xs:sequence>
<xs:anyAttribute processContents="lax"/>
</xs:complexType>
<xs:annotation>
<xs:documentation>
In keeping with the XML Schema WG's standard versioning policy,
the material in this schema document will persist at the URI
http://www.w3.org/2012/04/XMLSchema.xsd.
At the date of issue it can also be found at the URI
http://www.w3.org/2009/XMLSchema/XMLSchema.xsd.
The schema document at that URI may however change in the future,
in order to remain compatible with the latest version of XSD
and its namespace. In other words, if XSD or the XML Schema
namespace change, the version of this document at
http://www.w3.org/2009/XMLSchema/XMLSchema.xsd will change accordingly;
the version at http://www.w3.org/2012/04/XMLSchema.xsd will not change.
Previous dated (and unchanging) versions of this schema document
include:
http://www.w3.org/2012/01/XMLSchema.xsd
(XSD 1.1 Proposed Recommendation)
http://www.w3.org/2011/07/XMLSchema.xsd
(XSD 1.1 Candidate Recommendation)
http://www.w3.org/2009/04/XMLSchema.xsd
(XSD 1.1 Candidate Recommendation)
http://www.w3.org/2004/10/XMLSchema.xsd
(XSD 1.0 Recommendation, Second Edition)
http://www.w3.org/2001/05/XMLSchema.xsd
(XSD 1.0 Recommendation, First Edition)
</xs:documentation>
</xs:annotation>
</xs:schema>
B Outcome Tabulations (normative)
To facilitate consistent reporting of schema errors and ·validation·
failures, this section tabulates and provides unique names for all the
constraints listed in this document. Wherever such constraints have numbered
parts, reports should
use the name given below plus the part number, separated
by a period ('.'). Thus for example cos-ct-extends.1.2
should be
used to report a violation of the clause 1.2 of
Derivation Valid (Extension) (§3.4.6.2).
B.1 Validation Rules
- cvc-accept
- Element Sequence Accepted (Particle)
- cvc-assertion
- Assertion Satisfied
- cvc-assertions-valid
- Assertions Valid
- cvc-assess-attr
- Schema-Validity Assessment (Attribute)
- cvc-assess-elt
- Schema-Validity Assessment (Element)
- cvc-attribute
- Attribute Locally Valid
- cvc-au
- Attribute Locally Valid (Use)
- cvc-complex-content
- Element Sequence Locally Valid (Complex Content)
- cvc-complex-type
- Element Locally Valid (Complex Type)
- cvc-datatype-valid
- Datatype Valid
- cvc-elt
- Element Locally Valid (Element)
- cvc-enumeration-valid
- enumeration valid
- cvc-explicitTimezone-valid
- explicitOffset Valid
- cvc-facet-valid
- Facet Valid
- cvc-fractionDigits-valid
- fractionDigits Valid
- cvc-id
- Validation Root Valid (ID/IDREF)
- cvc-identity-constraint
- Identity-constraint Satisfied
- cvc-length-valid
- Length Valid
- cvc-maxExclusive-valid
- maxExclusive Valid
- cvc-maxInclusive-valid
- maxInclusive Valid
- cvc-maxLength-valid
- maxLength Valid
- cvc-minExclusive-valid
- minExclusive Valid
- cvc-minInclusive-valid
- minInclusive Valid
- cvc-minLength-valid
- minLength Valid
- cvc-model-group
- Element Sequence Valid
- cvc-particle
- Element Sequence Locally Valid (Particle)
- cvc-pattern-valid
- pattern valid
- cvc-resolve-instance
- QName resolution (Instance)
- cvc-simple-type
- String Valid
- cvc-totalDigits-valid
- totalDigits Valid
- cvc-type
- Element Locally Valid (Type)
- cvc-wildcard
- Item Valid (Wildcard)
- cvc-wildcard-name
- Wildcard allows Expanded Name
- cvc-wildcard-namespace
- Wildcard allows Namespace Name
- cvc-xpath
- XPath Evaluation
B.2 Contributions to the post-schema-validation infoset
- ID/IDREF binding information item properties
- [binding]
(ID/IDREF Table)
[id] (ID/IDREF Table) - Identity-constraint Binding information item properties
- [definition]
(Identity-constraint Table)
[node table] (Identity-constraint Table) - attribute information item properties
- [attribute attribution]
(Match Information)
[attribute declaration] (Attribute Declaration)
[match information] (Match Information)
[member type definition] (Attribute Validated by Type)
[member type definition anonymous] (Attribute Validated by Type)
[member type definition name] (Attribute Validated by Type)
[member type definition namespace] (Attribute Validated by Type)
[member type definitions] (Attribute Validated by Type)
[schema actual value] (Attribute Validated by Type)
[schema default] (Attribute Declaration)
[schema error code] (Validation Failure (Attribute))
[schema normalized value] (Attribute Validated by Type)
[schema specified] (Assessment Outcome (Attribute))
[type definition] (Attribute Validated by Type)
[type definition anonymous] (Attribute Validated by Type)
[type definition name] (Attribute Validated by Type)
[type definition namespace] (Attribute Validated by Type)
[type definition type] (Attribute Validated by Type)
[validation attempted] (Assessment Outcome (Attribute))
[validation context] (Assessment Outcome (Attribute))
[validity] (Assessment Outcome (Attribute)) - element information item properties
- [ID/IDREF table]
(ID/IDREF Table)
[declared type] (Element Declaration)
[descendant validity] (Element Validated by Type)
[element attribution] (Match Information)
[element declaration] (Element Declaration)
[expected element declaration] (Element Declaration)
[failed assertions] (Validation Failure (Element))
[failed identity constraints] (Validation Failure (Element))
[identity-constraint table] (Identity-constraint Table)
[inherited attributes] (Inherited Attributes)
[local element validity] (Element Declaration)
[local type validity] (Element Validated by Type)
[match information] (Match Information)
[member type definition] (Element Validated by Type)
[member type definition anonymous] (Element Validated by Type)
[member type definition name] (Element Validated by Type)
[member type definition namespace] (Element Validated by Type)
[member type definitions] (Element Validated by Type)
[nil] (Element Declaration)
[notation] (Validated with Notation)
[notation public] (Validated with Notation)
[notation system] (Validated with Notation)
[schema actual value] (Element Validated by Type)
[schema default] (Element Validated by Type)
[schema error code] (Validation Failure (Element))
[schema normalized value] (Element Validated by Type)
[schema specified] (Element Default Value)
[subsequence-valid] (Validation Failure (Element))
[type alternative] (Element Validated by Type)
[type definition] (Element Validated by Type)
[type definition type] (Element Validated by Type)
[type definition anonymous] (Element Validated by Type)
[type definition name] (Element Validated by Type)
[type definition namespace] (Element Validated by Type)
[type fallback] (Element Validated by Type)
[validation attempted] (Assessment Outcome (Element))
[validation context] (Assessment Outcome (Element))
[validity] (Assessment Outcome (Element)) - element or attribute information item properties
- [schema information]
(Schema Information)
- namespace schema information information item properties
- [schema components]
(Schema Information)
[schema documents] (Schema Information)
[schema namespace] (Schema Information) - schema document information item properties
- [document]
(Schema Information)
[document location] (Schema Information)
B.3 Schema Representation Constraints
- src-attribute
- Attribute Declaration Representation OK
- src-attribute_group
- Attribute Group Definition Representation OK
- src-cip
- Conditional Inclusion Constraints
- src-ct
- Complex Type Definition Representation OK
- src-element
- Element Declaration Representation OK
- src-enumeration-value
- Enumeration value
- src-expredef
- Individual Component Redefinition
- src-identity-constraint
- Identity-constraint Definition Representation OK
- src-import
- Import Constraints and Semantics
- src-include
- Inclusion Constraints and Semantics
- src-list-itemType-or-simpleType
- itemType attribute or simpleType child
- src-override
- Override Constraints and Semantics
- src-pattern-value
- Pattern value
- src-redefine
- Redefinition Constraints and Semantics
- src-resolve
- QName resolution (Schema Document)
- src-restriction-base-or-simpleType
- base attribute or simpleType child
- src-simple-type
- Simple Type Definition Representation OK
- src-ta
- Type Alternative Representation OK
- src-union-memberTypes-or-simpleTypes
- memberTypes attribute or simpleType children
- src-wildcard
- Wildcard Representation OK
B.4 Schema Component Constraints
- a-props-correct
- Attribute Declaration Properties Correct
- ag-props-correct
- Attribute Group Definition Properties Correct
- an-props-correct
- Annotation Correct
- as-props-correct
- Assertion Properties Correct
- au-props-correct
- Attribute Use Correct
- c-fields-xpaths
- Fields Value OK
- c-props-correct
- Identity-constraint Definition Properties Correct
- c-selector-xpath
- Selector Value OK
- cos-all-limited
- All Group Limited
- cos-applicable-facets
- Applicable Facets
- cos-assertions-restriction
- Valid restriction of assertions
- cos-aw-intersect
- Attribute Wildcard Intersection
- cos-aw-union
- Attribute Wildcard Union
- cos-choice-range
- Effective Total Range (choice)
- cos-content-act-restrict
- Content type restricts (Complex Content)
- cos-ct-derived-ok
- Type Derivation OK (Complex)
- cos-ct-extends
- Derivation Valid (Extension)
- cos-element-consistent
- Element Declarations Consistent
- cos-equiv-derived-ok-rec
- Substitution Group OK (Transitive)
- cos-group-emptiable
- Particle Emptiable
- cos-nonambig
- Unique Particle Attribution
- cos-ns-subset
- Wildcard Subset
- cos-particle-extend
- Particle Valid (Extension)
- cos-pattern-restriction
- Valid restriction of pattern
- cos-seq-range
- Effective Total Range (all and sequence)
- cos-st-derived-ok
- Type Derivation OK (Simple)
- cos-st-restricts
- Derivation Valid (Restriction, Simple)
- cos-valid-default
- Element Default Valid (Immediate)
- cos-valid-simple-default
- Simple Default Valid
- ct-props-correct
- Complex Type Definition Properties Correct
- derivation-ok-restriction
- Derivation Valid (Restriction, Complex)
- e-props-correct
- Element Declaration Properties Correct
- enumeration-required-notation
- enumeration facet value required for NOTATION
- enumeration-valid-restriction
- enumeration valid restriction
- fractionDigits-totalDigits
- fractionDigits less than or equal to totalDigits
- fractionDigits-valid-restriction
- fractionDigits valid restriction
- length-minLength-maxLength
- length and minLength or maxLength
- length-valid-restriction
- length valid restriction
- maxExclusive-valid-restriction
- maxExclusive valid restriction
- maxInclusive-maxExclusive
- maxInclusive and maxExclusive
- maxInclusive-valid-restriction
- maxInclusive valid restriction
- maxLength-valid-restriction
- maxLength valid restriction
- mg-props-correct
- Model Group Correct
- mgd-props-correct
- Model Group Definition Properties Correct
- minExclusive-less-than-equal-to-maxExclusive
- minExclusive <= maxExclusive
- minExclusive-less-than-maxInclusive
- minExclusive < maxInclusive
- minExclusive-valid-restriction
- minExclusive valid restriction
- minInclusive-less-than-equal-to-maxInclusive
- minInclusive <= maxInclusive
- minInclusive-less-than-maxExclusive
- minInclusive < maxExclusive
- minInclusive-minExclusive
- minInclusive and minExclusive
- minInclusive-valid-restriction
- minInclusive valid restriction
- minLength-less-than-equal-to-maxLength
- minLength <= maxLength
- minLength-valid-restriction
- minLength valid restriction
- n-props-correct
- Notation Declaration Correct
- no-xmlns
- xmlns Not Allowed
- no-xsi
- xsi: Not Allowed
- p-props-correct
- Particle Correct
- sch-props-correct
- Schema Properties Correct
- st-props-correct
- Simple Type Definition Properties Correct
- st-restrict-facets
- Simple Type Restriction (Facets)
- ta-props-correct
- Type Alternative Properties Correct
- timezone-valid-restriction
- timezone valid restriction
- totalDigits-valid-restriction
- totalDigits valid restriction
- w-props-correct
- Wildcard Properties Correct
- whiteSpace-valid-restriction
- whiteSpace valid restriction
- xpath-valid
- XPath Valid
C Terminology for implementation-defined features (normative)
This section defines some terms for use in describing choices made by implementations in areas where the effect of XSD features is explicitly ·implementation-defined·.
Future versions of this specification are expected to use the terminology defined here to specify conformance profiles. Conformance profiles may also be defined by other specifications without requiring any revision to this specification.
C.1 Subset of the Post-schema-validation Infoset
This specification defines a number of ways in which the information set taken as input is augmented in the course of schema-validity assessment. Conforming processors may provide access to some or all of this information; in the interests of simplifying discussion and documentation, this section defines names for several subsets of the PSVI, with the intention of simplifying short-hand descriptions of processors. These terms may be used to describe what parts of the PSVI a particular schema processor provides access to, or to specify requirements for processors, or for other purposes. A processor provides access to a particular subset of the PSVI if and only if it makes accessible some representation of the information in question, for information items to which it is applicable. (The properties labeled "if applicable" or "where applicable" below are simply the most obvious cases of properties which do not apply to every information item; the same qualification implicitly applies to all properties listed below.)
If other subsets of the PSVI prove important in practice it is expected that definitions of those subsets may be provided by other specifications or in later revisions of this one.
The definition in this section of a term denoting a particular subset of the PSVI does not constitute a requirement that conforming processors provide access to that subset.
- [schema error code], if applicable
- [member type definition] (where applicable)
- [schema normalized value] (where applicable)
- [schema actual value] (where applicable)
- [member type definition] (where applicable)
- [schema normalized value] (where applicable)
- [schema actual value] (where applicable)
- [member type definition name] (where applicable)
- [member type definition namespace] (where applicable)
- [member type definition anonymous] (where applicable)
- [member type definition name] (where applicable)
- [member type definition namespace] (where applicable)
- [member type definition anonymous] (where applicable)
- [member type definition name] (where applicable)
- [member type definition namespace] (where applicable)
- [member type definition anonymous] (where applicable)
- [schema normalized value] (where applicable)
- [schema actual value] (where applicable)
- [schema default] (where applicable)
- [schema information] some ·implementation-defined· representation (including at least the names of resources from which components were drawn)
- [member type definition name] (where applicable)
- [member type definition namespace] (where applicable)
- [member type definition anonymous] (where applicable)
- [schema actual value] (where applicable)
- [schema default] (where applicable)
- [schema specified] (where applicable)
C.2
Terminology of schema construction
C.2.2 Identifying methods of indirection
C.2.3 Identifying the key for use in indirection
C.2.4 Identifying when to stop searching
C.2.5 Identifying how to react to failure
Conforming processors may implement any combination of the following strategies for locating schema components, in any order. They may also implement other strategies.
The terminology offered here is intended to be useful in discussions of processor behavior, whether documenting existing behavior or describing required behavior.
General-purpose processors should support multiple methods for locating schema documents, and provide user control over which methods are used and how to fall back in case of failure.
C.2.1 Identifying locations where components are sought
rddl:resource
elements with the well-known property xlink:role
= "http://www.w3.org/2001/XMLSchema"
and then attempt to dereference the location(s) indicated on the
xlink:href attribute of the link.
import element,
the processor attempts to dereference those
locations.
C.2.2 Identifying methods of indirection
C.2.3 Identifying the key for use in indirection
C.2.4 Identifying when to stop searching
C.2.5 Identifying how to react to failure
C.3 Other Implementation-defined Features
This section defines terms intended to be useful in describing other implementation-defined choices.
D Required Information Set Items and Properties (normative)
This specification requires as a precondition for ·assessment· an information set as defined in [XML Infoset] which contains at least the following information items and properties:
In addition, infosets should support the [unparsed entities] property of the Document Information Item. Failure to do so will mean all items of type ENTITY or ENTITIES will fail to ·validate·. If the [unparsed entities] property is supported, the following is also required:
This specification does not require any destructive alterations to the input information set: all the information set contributions specified herein are additive.
This appendix is intended to satisfy the requirements for Conformance to the [XML Infoset] specification.
E Checklists of implementation-defined and implementation-dependent features (normative)
E.1 Checklist of implementation-defined features
[Definition:] An implementation-defined feature or behavior may vary among processors conforming to this specification; the precise behavior is not specified by this specification but must be specified by the implementor for each particular conforming implementation. (In the latter respect, ·implementation-defined· features differ from ·implementation-dependent· features.)
This appendix provides a summary of XSD features whose effect is explicitly ·implementation-defined·. Any software which claims to conform to this specification must describe how these choices have been exercised, in documentation which accompanies any conformance claim.
In describing the choices made for a given processor, it is hoped that the terminology defined in Terminology for implementation-defined features (normative) (§C) will be found useful.
E.2 Checklist of implementation-dependent features
[Definition:] An implementation-dependent feature or behavior may vary among processors conforming to this specification; the precise behavior is not specified by this or any other W3C specification and is not required to be specified by the implementor for any particular implementation. (In the latter respect, ·implementation-dependent· features differ from ·implementation-defined· features.)
This appendix provides a summary of XSD features whose effect is explicitly ·implementation-dependent·. Choices made by processors in these areas are not required to be documented.
- When a default value of type QName or NOTATION is applied to an element or attribute information item, it is ·implementation-dependent· whether ·namespace fixup· occurs to ensure that the {lexical form} maps to the {value}.
- When a default value is supplied for a defaulted attribute and more than one prefix is bound to the namespace of the attribute in the [in-scope namespaces], it is ·implementation-dependent· which prefix is used for the attribute.
- When a default value is supplied for a defaulted attribute and ·namespace fixup· is performed, it is ·implementation-dependent· what prefix is used in the new namespace information item.
- When a default value is supplied for a defaulted attribute and ·namespace fixup· is performed, it is ·implementation-dependent· whether the consistency of the information set is preserved by (a) adding the new binding to the descendants of the element on which the defaulted attribute occurred, or by (b) undeclaring the new binding on the children of that element. When [Namespaces in XML 1.0] rather than [XML Namespaces 1.1] is in use, namespace bindings cannot be undeclared, so the behavior is ·implementation-dependent· only for those implementations which do support [XML Namespaces 1.1].
- If more than one Identity-Constraint Definition fails to be satisfied, it is ·implementation-dependent· which of them are included in the [failed identity constraints] property of PSVI.
- If more than one Assertion fails to be satisfied, it is ·implementation-dependent· which of them are included in the [failed assertions] property of PSVI.
- The order of Annotation components within various components' {annotations} property is ·implementation-dependent·.
- If a name is supplied for anonymous components (for example, [type definition name] and [member type definition name] properties in the ·post-schema-validation infoset·), the choice of name is ·implementation-dependent·.
- If a processor detects some violations of clause 2.4.2 of Derivation Valid (Restriction, Complex) (§3.4.6.3) by examination of the schema in isolation, and others only when some element information item in the input document is valid against its ·governing type definition· T but not against T.{base type definition}, then the circumstances in which the processor does one or the other are ·implementation-dependent·.
F Stylesheets for Composing Schema Documents (Normative)
The transformations specified in the following sections in the form of [XSLT 2.0] stylesheets are used when assembling schemas from multiple schema documents. Implementations do not have to perform [XSLT 2.0] transformation, or use the stylesheets given here, as long as the same result is produced.
F.1 Transformation for Chameleon Inclusion
targetNamespace [attribute] is included
(Assembling a schema for a single target namespace from
multiple schema definition documents
(<include>) (§4.2.3)), redefined
(Including modified component definitions (<redefine>) (§4.2.4)), or overridden
(Overriding component definitions (<override>) (§4.2.5)) by another <schema>
D1 with a targetNamespace [attribute], the following
transformation, specified here as an
[XSLT 2.0] stylesheet, is applied to D2
before its contents are mapped to schema
components. The
transformation performs two tasks:- Add a
targetNamespace[attribute] to D2, whose value is the same as that of thetargetNamespace[attribute] of D1. - Update all QName references in D2 that do not have a namespace name so that their namespace names become the ·actual value· of the
targetNamespace[attribute].
<?xml version="1.0" encoding="UTF-8"?>
<xsl:transform xmlns:xsl="http://www.w3.org/1999/XSL/Transform"
xmlns:xs="http://www.w3.org/2001/XMLSchema"
xmlns:f="http://www.w3.org/2008/05/XMLSchema-misc"
version="2.0">
<xsl:param name="newTargetNamespace" as="xs:anyURI"
required="yes"/>
<xsl:param name="prefixForTargetNamespace" as="xs:NCName"
select="f:generateUniquePrefix(., 0)"/>
<xsl:template match="@*|node()">
<xsl:copy><xsl:apply-templates select="@*|node()"/></xsl:copy>
</xsl:template>
<xsl:template match="xs:schema">
<xsl:copy>
<xsl:namespace name="{$prefixForTargetNamespace}"
select="$newTargetNamespace"/>
<xsl:apply-templates select="@*"/>
<xsl:attribute name="targetNamespace"
select="$newTargetNamespace"/>
<xsl:apply-templates/>
</xsl:copy>
</xsl:template>
<xsl:template match="xs:*/@ref
| xs:*/@base
| xs:*/@type
| xs:schema/@defaultAttributes
| xs:keyref/@refer
| xs:list/@itemType">
<xsl:choose>
<xsl:when test="namespace-uri-from-QName(resolve-QName(string(.), ..))=''">
<xsl:attribute name="{name()}"
select="concat($prefixForTargetNamespace,
':',
local-name-from-QName(resolve-QName(string(.), ..)))"/>
</xsl:when>
<xsl:otherwise>
<xsl:copy/>
</xsl:otherwise>
</xsl:choose>
</xsl:template>
<xsl:template match="@memberTypes | @substitutionGroup">
<xsl:variable name="context" select=".."/>
<xsl:variable name="values" as="xs:string+">
<xsl:for-each select="tokenize(., '\s+')">
<xsl:variable name="oldValue"
select="resolve-QName(., $context)"
as="xs:QName"/>
<xsl:sequence
select="if (namespace-uri-from-QName($oldValue) eq '')
then concat($prefixForTargetNamespace, ':',
local-name-from-QName($oldValue))
else string(.)"/>
</xsl:for-each>
</xsl:variable>
<xsl:attribute name="{name()}" select="string-join($values, ' ')"/>
</xsl:template>
<xsl:template match="@notQName">
<xsl:variable name="context" select=".."/>
<xsl:variable name="values" as="xs:string+">
<xsl:for-each select="tokenize(., '\s+')">
<xsl:variable name="oldValue"
select="if (starts-with(.,'##'))
then ()
else resolve-QName(., $context)"
as="xs:QName?"/>
<xsl:sequence
select="if (starts-with(.,'##'))
then string(.)
else if ((namespace-uri-from-QName($oldValue) eq '')
or
empty(namespace-uri-from-QName($oldValue)))
then concat($prefixForTargetNamespace,
':',
local-name-from-QName($oldValue))
else string(.)"/>
</xsl:for-each>
</xsl:variable>
<xsl:attribute name="{name()}" select="string-join($values, ' ')"/>
</xsl:template>
<xsl:function name="f:generateUniquePrefix" as="xs:NCName">
<xsl:param name="xsd"/>
<xsl:param name="try" as="xs:integer"/>
<xsl:variable name="disallowed"
select="distinct-values($xsd//*/in-scope-prefixes(.))"/>
<xsl:variable name="candidate"
select="xs:NCName(concat('p', $try))"/>
<xsl:sequence select="if ($candidate = $disallowed) then
f:generateUniquePrefix($xsd, $try+1)
else
$candidate"/>
</xsl:function>
</xsl:transform> F.2 Transformation for xs:override
When a <schema>
information item D1 contains
<override> elements, the transformation specified in the following
[XSLT 2.0] stylesheet is performed once for
each such <override> element. It requires as
parameters (a) the <override> element in D1
(call it O1) as the overrideElement parameter
and (b)
the <schema> element of the schema document D2
identified by the schemaLocation attribute of O1
as the overriddenSchema parameter.
The transformation
produces another <schema>
element D2′,
which is equivalent
to D2 except that some elements in D2 are replaced
or modified.
The normative description of the transformation is given by the stylesheet below; the transformation can also be described (non-normatively) in prose as in the following paragraphs.
The [attributes] of D2′ (for example,
targetNamespace and defaultAttributes) are
copies of the [attributes] of D2.
name
attribute, then D2′ has a
copy of E1 in the location corresponding to E2's
place in D2.schemaLocation = E2.schemaLocation
and [children] which are copies of
those of O1.schemaLocation
= E2.schemaLocation
and [children] which are drawn from among the [children] of
E2 and O1, as specified by
the appropriate case among the following:The base URI of D2′ is the same as that of D2.
xs:override<xsl:transform version="2.0"
xmlns:xsl="http://www.w3.org/1999/XSL/Transform"
xmlns:xs="http://www.w3.org/2001/XMLSchema"
xmlns:f="http://www.w3.org/2008/05/XMLSchema-misc"
exclude-result-prefixes="f">
<xsl:template name="perform-override">
<xsl:param name="overrideElement" as="element(xs:override)"/>
<xsl:param name="overriddenSchema" as="element(xs:schema)"/>
<xsl:result-document>
<xsl:apply-templates select="$overriddenSchema">
<xsl:with-param name="overrideElement" select="$overrideElement"/>
</xsl:apply-templates>
</xsl:result-document>
</xsl:template>
<xsl:template match="xs:schema | xs:redefine"
priority="5">
<xsl:param name="overrideElement"/>
<xsl:copy>
<xsl:copy-of select="@*"/>
<xsl:apply-templates>
<xsl:with-param name="overrideElement" select="$overrideElement"/>
</xsl:apply-templates>
</xsl:copy>
</xsl:template>
<xsl:template match="xs:import" priority="5">
<xsl:copy-of select="."/>
</xsl:template>
<!--* replace children of xs:schema, xs:redefine,
* and xs:override which match children of
* $overrideElement. Retain others.
*-->
<xsl:template match="xs:schema/*
| xs:redefine/*
| xs:override/*"
priority="3">
<xsl:param name="overrideElement"/>
<xsl:variable name="original" select="."/>
<xsl:variable name="replacement"
select="$overrideElement/*
[node-name(.)
= node-name($original)
and
f:componentName(.)
= f:componentName($original)]"/>
<xsl:copy-of select="($replacement, $original)[1]"/>
</xsl:template>
<!--* replace xs:include elements with overrides
*-->
<xsl:template match="xs:include" priority="5">
<xsl:param name="overrideElement"/>
<xsl:element name="xs:override">
<xsl:copy-of
select="@schemaLocation, $overrideElement/*"/>
</xsl:element>
</xsl:template>
<!--* change xs:override elements: children which match
* children of $overrideElement are replaced, others
* are kept, and at the end all children of
* $overrideElement not already inserted are added.
*-->
<xsl:template match="xs:override"
priority="5">
<xsl:param name="overrideElement"/>
<xsl:element name="xs:override">
<xsl:attribute name="schemaLocation">
<xsl:value-of select="@schemaLocation"/>
</xsl:attribute>
<xsl:apply-templates>
<xsl:with-param name="overrideElement" select="$overrideElement"/>
</xsl:apply-templates>
<xsl:apply-templates select="$overrideElement/*"
mode="copy-unmatched">
<xsl:with-param name="overrideElement"
select="$overrideElement"/>
<xsl:with-param name="overriddenOverride"
select="."/>
</xsl:apply-templates>
</xsl:element>
</xsl:template>
<xsl:template match="*" mode="copy-unmatched">
<xsl:param name="overriddenOverride"/>
<xsl:variable name="overriding" select="."/>
<xsl:variable name="overridden"
select="$overriddenOverride/*[
node-name(.)
= node-name($overriding)
and
f:componentName(.)
= f:componentName($overriding)
]"/>
<xsl:choose>
<xsl:when test="count($overridden) > 0">
<!--* do nothing; this element already copied *-->
</xsl:when>
<xsl:when test="count($overridden) = 0">
<!--* copy this element, it isn't already there *-->
<xsl:copy-of select="."/>
</xsl:when>
</xsl:choose>
</xsl:template>
<xsl:function name="f:componentName" as="xs:QName">
<xsl:param name="component" as="element()"/>
<xsl:sequence select="
QName($component/ancestor::xs:schema/@targetNamespace,
$component/@name)"/>
</xsl:function>
</xsl:transform>G Changes since version 1.0 (non-normative)
G.1 Changes made since version 1.0
G.1.2 XSD versions
G.1.3 Changes to content models
G.1.4 Assertions and XPath
G.1.5 Derivation of complex types
G.1.6 Changes to complex type definitions
G.1.7 ID, IDREF, and related types
G.1.8 Simple type definitions
G.1.9 Element declarations
G.1.10 Attribute declarations
G.1.11 Component structure
G.1.12 The process of validation
G.1.13 The post-schema-validation infoset
G.1.14 Conformance
G.1.15 Schema composition
G.1.16 Other substantive changes
G.1.17 Clarifications and editorial changes
G.1.1 Relationship between XSD and other specifications
- Support for XML 1.1 has been added. It is now implementation defined whether datatypes dependent on definitions in XML ([XML 1.1], [XML 1.0]) and Namespaces in XML ([XML Namespaces 1.1], [Namespaces in XML 1.0]) use the definitions as found in version 1.1 or version 1.0 of those specifications.
- To reduce confusion and avert a widespread misunderstanding, the normative references to various W3C specifications now state explicitly that while the reference describes the particular edition of a specification current at the time this specification is published, conforming implementations of this specification are not required to ignore later editions of the other specification but instead may support later editions, thus allowing users of this specification to benefit from corrections to other specifications on which this one depends.
- The XPath subset for selectors and fields in section Selector Value OK (§3.11.6.2) and Fields Value OK (§3.11.6.3) has been revised to align its tokenization rules better with [XPath 2.0]; this resolves issue 8454 Tokens in XPath subset for selectors/fields.
G.1.2 XSD versions
- A conditional inclusion mechanism is defined, roughly analogous to the XSLT 2.0
use-whenattribute or to the C preprocessor#ifdefconstruct. By means of thevc:minVersionandvc:maxVersionattributes, a simple forward-processing mechanism is supplied, so that conforming XSD 1.1 processors can successfully ignore constructs introduced in future versions (if any) of XSD, and so that schema authors can define schemas which use newer constructs when available but can fall back on older constructs when the newer constructs are not available. - Identifiers for different versions of XSD are now defined in section Schema Language Identifiers (§1.3.4).
G.1.3 Changes to content models
- The Unique Particle Attribution (§3.8.6.4) constraint has been relaxed. While competition between two ·element particles· is still forbidden, as is competition between two ·wildcard particles·, competition between an ·element particle· and a ·wildcard particle· is no longer forbidden. In the course of making this substantive change, some editorial changes have also been made, in order to make the exposition clearer. (Readers familiar with version 1.0 of this specification will find that the constraint works in almost exactly the same way as it did in 1.0, except that content models in which an input item matches either a ·wildcard particle· or an ·element particle· are now allowed.)
- Content models may now use the <openContent> element to specify content models with "open content". Such content models allow elements not explicitly mentioned in the content model to appear in the document instance; it is as if wildcards were automatically inserted at appropriate points within the content model. By specifying what kind of wildcard is implicitly inserted, the schema author can adjust the degree of openness and determine what elements are accepted by the open content; the schema author can also specify that the content model should be open everywhere, or only at the end. A schema-document wide default may be set, which causes all content models to be open unless otherwise specified.
- Wildcards may now be defined which allow names in any namespace but those in a set of proscribed namespaces. (In version 1.0 of this specification, only a single namespace, the target namespace of a schema document, could be proscribed.) Also, wildcards can now be written which match any element in a set of namespaces but which exclude a particular set of qualified names from matching the wildcard. Finally, the keyword ##definedSibling can be used to exclude all elements explicitly mentioned in a content model (and all elements substitutable for those elements).
- Wildcards can now be defined which match any element (in the specified namespaces) which does not match an element declaration in the schema (so-called "not-in-schema" wildcards).
- Several of the constraints imposed by version 1.0 of this specification on all-groups have been relaxed:
- Wildcards are now allowed in all groups.
- The value of
maxOccursmay now be greater than 1 on particles in an all group. The elements which match a particular particle need not be adjacent in the input. - all groups can now be extended by adding more members to them.
- Complex types whose content models are
all-groups can now be extended; the result is anall-group (usually a larger one). - The discussion of checking content-type restriction included in an appendix in earlier drafts of this specification has now been removed, as have some references to published algorithms for the problem. Several of the papers referred to are no longer publicly accessible on the Web, and the changes made to the Unique Particle Attribution (§3.8.6.4) have in any case rendered those algorithms obsolete. These changes resolve issue 6685 Appendix I Checking content-type restriction References Not Available.
- Group references are now allowed in
<xs:all>model groups. Such references must haveminOccurs=maxOccurs=1and must refer to other<xs:all>groups. (This change resolves issue 7031 XSD 1.1 doesn't support conversion of xs:sequence to xs:all because xs:all can't contain groups references.)
G.1.4 Assertions and XPath
- Support for check clauses to implement some co-occurrence constraints has been added. Each complex type can carry a list of assertions, which are checked when the complex type is used to validate an element information item.
- The facility for assertions defined in the working draft of 31 August 2006 has been revised.
- The
reportelement described in earlier drafts has been removed. This involves no loss of functionality: the same effect can be obtained by wrapping the test expression on an <assert> element in a negation. - The XPath subset defined for assertions has been eliminated. (A somewhat smaller subset is now defined for conditional type assignment.)
- Rules are defined for the evaluation of XPath expressions (in assertions, in conditional type assignment, or in identity-constraint definitions).
- The static and dynamic contexts for XPath evaluation are explicitly specified.
- Rules are provided for constructing the [XDM] data model instance against which the XPath expressions are to be evaluated. Different rules apply in different situations:
- When assertions on a complex type are evaluated, only the subtree rooted in an element of that type is mapped into the data model instance. References to ancestor elements or other nodes outside the subtree are not illegal but will not be effective.
- For conditional type assignment, neither the ancestors nor the children of the element in question are included; the conditions for type assignment are thus effectively restricted to the attributes of the element.
- For assertions on simple types, only the value is provided; the dynamic context includes no context item.
- Rules for assigning types to the nodes of the data model instance are defined. Again, the rules differ for the different uses of XPaths:
- When assertions are evaluated, all of the elements and attributes descended from the element being validated are typed in the normal way; this has the effect that comparisons among attribute values (for example) are performed in a way consistent with the declarations of the attributes. The element node itself, however, is not typed (since it has not yet been completely validated).
- For conditional type assignment, the nodes of the data model instance are untyped.
- The conceptual overview now included in Constraint Components (§2.2.4) some discussion of the overlap in functionality among identity constraints, conditional type assignment, and assertions, and identifies some of the factors which may be relevant in choosing among them; this change resolves issue 5023 Relationship between identity constraints and assertions.
- The rules for the "available collections" and "default collection" properties of the [XPath 2.0] dynamic context have been simplified; these properties are now required to be the empty set instead of being ·implementation-defined·. This improves interoperability and resolves issue 6540 Available documents in assertions.
- The [XPath 2.0] static context used for the evaluation of assertions has been clarified; it now explicitly includes the functions in the [Functions and Operators]
fnnamespace and constructors for all built-in types. This resolves issue 6541 Assertions and in-scope functions.
G.1.5 Derivation of complex types
- The rules for checking validity of complex-type restrictions have been simplified by reformulating the constraint in terms of local validity: the set of elements or attributes accepted by a restriction as locally valid must be a subset of those accepted by its base type. The rules for attributes have also been changed.The complex rules involving matching up particles in the base type and particles in the restriction, with their complex case by case analysis, have been replaced by a statement of the constraint which is shorter and more correct.
- It is now possible to specify a target namespace for local elements and attributes which differs from the target namespace of the schema document itself, when restricting a complex type which has local elements or attributes and which itself is in another namespace. This should simplify the reuse of types from other namespaces.
- The rules for complex type restriction now allow identity constraints on local elements. To make this possible, identity constraints may now be given names and referred to from elsewhere. Corresponding changes have been made in the description of the Schema component and in the rules for ·QName resolution·.
- This draft clarifies the rule requiring that any complex type derived by extension could, in principle, be derived in three steps from ·
xs:anyType· (first a restriction step, then an extension step, then a restriction step). A misleading note about the purpose of this rule has been deleted.
G.1.6 Changes to complex type definitions
- Changes have been made to Locally Declared Type (§3.4.4.1), Element Locally Valid (Complex Type) (§3.4.4.2), and Derivation Valid (Restriction, Complex) (§3.4.6.3) to require more consistency in type assignment when elements with the same expanded name may match both a local element declaration and a wildcard in the same content model. Conceptually, these changes are related to the constraint expressed in Element Declarations Consistent (§3.8.6.3). XSD 1.0 allows such content models even if there is a discrepancy between the type assigned to elements by the local element declarations and by the top-level element declaration which will govern elements which match the wildcard. For compatibility reasons, such content models are still allowed, but any element instance which matches the wildcard is required to have a governing type definition compatible with the type assigned by the local element declarations matched by the element's expanded name.
- The elements <complexType> and <complexContent> are now forbidden to have different values for the
mixedattribute. - The constraint Element Declarations Consistent (§3.8.6.3) now takes open content into account. This change, together with the explicit exclusion of skip wildcards from the constraint, resolves issue 5940 Element Declarations Consistent.
- The rules for restriction of complex types containing local elements with conditional types have been simplified; this resolves issue 12185 Conditional Type Assignment and substitutability.
- The text has been revised to correct the terminology used to describe correct XPath expressions and to specify that it is ·implementation-defined· when type errors in XPath expressions are detected and whether they are treated as static or dynamic errors. This change resolves issue 11073 Type errors during XPath evaluation.
- The description of assertions has been revised to make it explicit that the data model instance constructed for testing assertions has a parentless element node as its root, and not an element node with a document node as its parent. This change resolves issue 12127 "Root element" in assertion testing.
G.1.7 ID, IDREF, and related types
- Certain constraints involving ID have been extended to include lists of ID and unions including ID. See e.g. Constraints on Attribute Declaration Schema Components (§3.2.6).
- An element may now have multiple attributes of type
xs:ID. Elements have always been able to have multiple children of typexs:ID, but XSD 1.0 forbad multiple attributes of this type for compatibility with XML DTDs. (Schemas intended to be translatable into DTD form should still avoid the practice.) This change should make it easier for XML vocabularies to support both existing ID attributes andxml:ID. - The validation rules for values of type
xs:IDREF,xs:ENTITY, orxs:ENTITIESare now enforced on default values. - Elements and attributes of type
xs:IDmay now have default or fixed values. XSD 1.0 had forbidden this, for compatibility with XML DTDs. - The text has been revised to ensure that the special validation rules for
xs:ID,xs:IDREF,xs:IDREFS,xs:ENTITY, andxs:ENTITIESapply not only to the built-in types themselves but also to types derived from them by restriction, list construction, union, and extension. This resolves issue 10662 Should IDREFS and ENTITIES be magic types?.
G.1.8 Simple type definitions
- A new type definition called
anyAtomicTypehas been introduced into the type hierarchy betweenanySimpleTypeand all the atomic built-in type definitions. See Built-in Simple Type Definitions (§3.16.7). - An error in version 1.0 of this specification relating to the construction of union types from other union types has been corrected. Unions may now appear as members of other unions, and all restrictions of unions are correctly enforced; the rule Type Derivation OK (Simple) (§3.16.6.3) has been modified to ensure that member types are not ·validly substitutable· for facet-restricted unions. As a result,
xsi:typemay no longer be used, as in XSD 1.0, to subvert restrictions of union types. - The requirement that a facet value be a "valid restriction" of another, in the context of simple type restriction, has been clarified.
- No union type may be a member of its own transitive membership, nor may any type derived from the union. (XSD 1.0 forbad union datatypes to be members of other unions and thus had no need to forbid this explicitly.)
- Since not all datatypes have a defined canonical representation for all of their values, appeals to the canonical forms of values have been eliminated.
- Changes have been made to ensure that the descriptions of the Simple Type Definition component and of ·
xs:anySimpleType· agree in all details with those of [XML Schema: Datatypes]. - Equality and identity of lists have been clarified.
- The fact that ·
xs:anyType· is its own base type has been clarified (addresses issue 6204 anyType/ur-Type: inconsistent whether it has a base-type). - Enumerations, value constraints, and identity constraints now accept either equal or identical values as the same. This change resolves issue 9196 Enumeration and NaN
- Changes have been made in section Constraints on XML Representations of Simple Type Definitions (§3.16.3) and section Constraints on XML Representations of Complex Type Definitions (§3.4.3) to make explicit that XML representations of extension facets (facets in namespaces other than the Schema namespace) are allowed to appear more than once in restrictions of simple types. This resolves issue 11222 src-simple-type.1 should allow duplicate elements from "##other" namespaces.
G.1.9 Element declarations
- A new form of co-occurrence constraint has now been defined, by allowing the type assigned to element instances to be conditional on properties of the instance (typically attribute values). The addition of conditional type assignment has entailed a number of changes:
- Introduction of a Type Table property on element declarations, to hold a sequence of Type Alternatives (condition - selected-type pairs) and a default type definition.
- Constraints on that table: all types named in the table (including the default) must be ·validly substitutable· for the declared {type definition}.
- Changes to the XML syntax and XML mapping rules to allow expression of conditional type bindings: the <alternative> element is added, the content model of <element> is changed.
- Validation rules for conditional types: the definition of ·governing type definition· is adjusted to account for conditional type assignment.
- Rules for evaluating the conditional typing tests (more specifically, rules for constructing a temporary infoset and then building the XDM instance and evaluating the XPath expressions as defined elsewhere; priority of tests is given by document order / component order).
- PSVI changes to reflect details of the conditional typing: a {type alternative} property is added, and the discussion of [type fallback] now refers to the ·selected type definition· rather than to either the declared {type definition} or to the ·governing type definition· of the element information item
- Introduction of some terminology for discussing conditional types (define ·selected type definition·, ·conditionally selects·, ·validly substitutable as a restriction·).
- Rules for checking type restriction in the presence of conditional types.
- Introduction of a special ·
xs:error· type for use in identifying conditionally assigned types which violate restriction rules - Miscellaneous supporting editorial changes.
- Element declarations may now specify multiple substitution-group heads.
- Abstract elements may now appear in substitution groups.
- The treatment of type tables in Element Declarations Consistent (§3.8.6.3) has been made more specific; this resolves issue 11076 Element Declarations Consistent: comparing type tables.
G.1.10 Attribute declarations
- Attribute declarations can now be marked {inheritable} (see Inherited Attributes (§3.3.5.6)) and the values of inherited attributes are accessible in the XDM data model instance constructed for conditional type assignment (see Type Alternatives (§3.12)).Among other consequences, this allows conditional type assignment to be sensitive to the inherited value of the
xml:langattribute and thus to the language of the element's contents. This change was introduced to resolve issue 5003 Applicability of <alternative> element to xml:lang, raised by the W3C Internationalization Core Working Group. - The rules for default attribute values now refer to the ·effective value constraint·, rather than to the [Value Constraint]; this resolves a bug in the handling of default values for global attribute declarations.
- The text now makes clear that it is pointless (although not illegal) for schema documents to supply default or fixed values for
xsi:typeand other attributes in the namespacehttp://www.w3.org/2001/XMLSchema-instance, since they will not be applied. - Default attribute groups are now supported. The <schema> element can carry a
defaultAttributesattribute, which identifies a named Attribute Group Definition; each complex type defined in the schema document then automatically includes that attribute group, unless this is overridden by thedefaultAttributesApplyattribute on the <complexType> element. Default attribute groups make it easier to specify attributes which should be accepted by every complex type in a schema (e.g.xml:idandxml:lang). - All wildcard unions are now expressible; this change resolves issue 6163 3.10.6.3 Attribute Wildcard Union .
- As described in XML Mapping Rule for Named Attribute Groups (§3.6.2.1), circular references from <attributeGroup> to <attributeGroup> are now allowed; all attribute groups in the cycle of references are included.
G.1.11 Component structure
- Every component now has an {annotations} property whose value is a sequence of annotation elements and out-of-band attributes. See e.g. The Complex Type Definition Schema Component (§3.4.1).Annotations are no longer allowed to vary in the part of a content model shared by a complex type and its extensions. (This was never possible in components specified using schema documents, but was possible in "born-binary" components.)
- A {context} property has been defined for the definitions of complex and of simple types; this property simplifies testing for the identity of anonymous type definitions. See e.g. The Complex Type Definition Schema Component (§3.4.1). The {context} property replaces the {scope} property found in some earlier drafts of this document.
- The Schema component has an additional {identity-constraint definitions} property containing all the identity constraints in the corresponding schema. See The Schema Itself (§3.17.1) and XML Representations of Schemas (§3.17.2).
- The underlying basis for the definition of all the different kinds of components has changed to make use of a regular and formal tabulation of their properties. This has been achieved by introducing property records wherever version 1.0 had complex property values. For example instead of describing the {scope} property as having "either global or a complex type definition" for its value, a Scope property record is called for, which in turn has its own simple properties and values. See e.g. The Element Declaration Schema Component (§3.3.1).
G.1.12 The process of validation
- When an
xsi:typeattribute appears on an element and has a QName as its value, but the QName does not resolve to a known type definition, the element is assigned a "fallback" ·governing type definition· for validation. The ·governing type definition· will be the ·selected type definition· or the declared {type definition}, if available, and ·xs:anyType· otherwise. The validation process is now explicitly defined as including the validation of the element and its descendants; processors no longer have the implicit option of skipping the element and its descendants. - Element information items which match no particle in a content model are now to be validated using their ·locally declared type·. Earlier drafts did not specify what happened in such cases.
- ·Lax assessment· is now required when an element information item to be validated has neither a ·governing element declaration· nor a ·governing type definition·; also, lax assessment now requires that the [children] and [attributes] of the element be assessed as well. In XSD 1.0 and in earlier drafts, lax assessment was optional and did not require the recursive assessment of [children] and [attributes].
- The text now specifies that if an element has an
xsi:typeattribute which does not ·resolve· to a type definition, then thexsi:typeattribute is invalid. - The terminology of assessment has been changed to avoid the suggestion that an element information item can be ·strictly assessed· without being ·assessed·.
- An anomaly in the definition of ·governing element declaration· has been corrected, to ensure that elements matching strict or lax wildcards have the appropriate global element declaration, if it exists, as their ·governing element declaration·. (Resolves issue 7913 Strange result from definition of governing element declaration.)
- The usage of the terms "·validation·" and "·assessment·" has been clarified, and definitions of various forms of document validity have been added for the convenience of users of this specification; see Schema-validity and documents (§2.5). (Resolves issues 5164 validation vs assessment and 6015 [schema11] valid (and its derivations) vs assessment as used in text.)
- The definition of Element Locally Valid (Type) (§3.3.4.4) has been changed to remove the rule that an element with an ·instance-specified type definition· cannot be locally valid against any type definition other than the one specified in the instance. This resolves issue 11764 Unresolved xsi:type should not affect validity against a type.
G.1.13 The ·post-schema-validation infoset·
- The presentation of the ·post-schema-validation infoset· has been simplified by removing the suggestion that the ·post-schema-validation infoset· varies from processor to processor. Instead, the exposition now makes clearer that the body of information available in principle after schema-validity assessment is consistent across all processors; processors may make different subsets of the ·post-schema-validation infoset· accessible to downstream applications, but when they do so the variation reflects the implementors' decisions about what information to expose, not variation in the information in the ·post-schema-validation infoset·.
- Terms have been defined to describe different subsets of the ·post-schema-validation infoset· which may be exposed by processors.
- Provision is made for exposing the ·actual values· of elements and attributes in the ·post-schema-validation infoset·, in the {schema actual value} property.
- The [element declaration] property and various other properties in the ·post-schema-validation infoset· are now described as being present in the ·post-schema-validation infoset· whenever a ·governing· declaration and/or ·governing· type definition is known for the item, instead of only when the item is valid.
- When the ·governing· type definition of an attribute or element information item is a list type whose item type is a union, the ·post-schema-validation infoset· now includes the ·validating type· for each item in the list.
- When default values are supplied for attributes with qualified names, ·namespace fixup· is performed to ensure that the [in-scope namespaces] property of the attribute's host element has an appropriate binding for the namespace name. It is ·implementation-dependent· whether ·namespace fixup· is also performed on descendants of that element so as to retain consistency of the infoset. ·Namespace fixup· may also be helpful if the defaulted value is of type QName or NOTATION; it is ·implementation-dependent· whether fixup is performed for such values.
- Annotations given in the XML form of identity-constraint declarations with
refattributes are now retained in the ·post-schema-validation infoset· form of the containing element declaration. This change resolves issue 6144 annotation on IDC with a 'ref' attribute is lost.
G.1.14 Conformance
- The set of conformance classes has been revised and clarified. Instead of "minimally conforming", "schema-document aware", and "Web-aware" processors, this specification now defines (in section Conformance (§2.4)) conformance classes for ·general-purpose validators·, ·general-purpose schema-validity assessors·, ·special-purpose validators·, and ·other special-purpose tools·, together with terminology which may be useful in describing particular processors. This change resolves issue 7695 Conformance.
- A checklist has been included listing ways in which conforming processors may vary from each other, and terminology has been provided for some of the more important properties of conforming processors, in an attempt to make it easier for implementors to describe concisely which options their processors exercise, and easier for users to describe what kinds of processor they require.
- The definition of must and ·error· have been revised to specify that conforming processors must detect and report error in the schema or schema documents. The quality and detail of the error messages are not constrained.
- Implementations are now allowed to support primitive datatypes and facets beyond those defined in [XML Schema: Datatypes].
- The validity requirements for schema documents are stated more fully and correctly.
G.1.15 Schema composition
- The <redefine> construct is ·deprecated·.
- An <override> construct has been defined; in some ways it resembles <redefine>, but imposes no constraints on the new definitions provided for components whose definitions are being overridden.
- The discussion of <include> and <override> has been revised to eliminate an ambiguity in earlier versions of this spec regarding the meaning of cyclic dependencies formed by use of <include> and <override>: such cyclic dependencies are now clearly allowed and have a well defined meaning.
- When an
xsi:schemaLocationattribute provides information about a schema document location for a particular namespace, it is no longer an error for it to be encountered after the first occurrence of an element or attribute information item in that namespace. Note, however, that if processing such anxsi:schemaLocationattribute causes new components to be added to the schema, then the new components cannot change the assessment outcome of any information items already seen before the element bearing thexsi:schemaLocationattribute. - The handling of "chameleon" inclusion and redefinition in schema documents has been simplified. The new target namespace affects any component or property which would have the target namespace if the schema document specified one. This change makes it easier to write assertions in schema documents without a namespace which are intended to be included by schema documents with varying target namespaces.
- Section Identifying how to react to failure (§C.2.5) has now been added, defining the terms error and continue for use in specifying what a processor does or should do when it seeks components for a given namespace in a given location but fails to find them there.
- Schema processors are now explicitly recommended to provide a user option to control whether the processor attempts to dereference schema locations indicated in
schemaLocationattributes in the instance document being validated; this resolves issue 5476 xsi:schemaLocation should be a hint, should be MAY not SHOULD. - The discussion of
schemaLocationinformation in How schema definitions are located on the Web (§4.3.2) has been revised to try to make clearer the motivation for recommending user control over whether schema locations specified in the document instance should or should not be dereferenced. The new text describes some circumstances in which such schema locations typically should be dereferenced and some in which they should not, and attempts to set useful expectations for users and for implementors. These changes are intended to resolve issue 6655, raised by the W3C Web Accessibility Initiative's Protocols and Formats Working Group. - The discussion of schema import in Licensing References to Components Across Namespaces (§4.2.6.1) now states more clearly that references to components in external namespaces are an error if the namespace is not imported; this change addresses issue 5779 QName resolution and xs:import.
- Some errors in the XSLT stylesheet of appendix Transformation for Chameleon Inclusion (§F.1) have been corrected (resolving issues 8573 F.1 Stylesheet for chameleons invalid and 8574 F.1 Stylesheet for chameleons incomplete).
- The sections on the XML representation of components have been revised to say explicitly that the constraints and mapping rules defined there apply after, not before, pre-processing. This change resolves issues 11179 minor editorial improvement : parent schema components of a named model group and 11354 Mentions of "override" outside of the override section
G.1.16 Other substantive changes
- The discussion of schema-validity assessment and the invocation of conforming processors has been revised; additional invocation patterns have been identified, and names have been given to the different methods of invoking a processor.
- When an element cannot be strictly validated because no element declaration or type definition is available for it, fallback to lax validation (validating the element against the built-in type ·
xs:anyType·) is now required; in earlier drafts of this document, fallback to lax validation was optional. - The XML Representation Constraints no longer refer to the component level; this makes it possible to test a schema document in isolation to determine whether it conforms or fails to conform to these rules.
- The constraints on the XML representation of schemas have been reformulated to allow them to be checked on schema documents in isolation, rather than requiring knowledge of the rest of the schema into which they will be embedded. The consequence is that some errors are caught not in the XML representation constraints but by having the XML mapping rules generate faulty components so that the error can be detected at the component level. These changes resolve issue 6235 Restriction from xs:anySimpleType.
- The <schema> element is now declared with open content in the schema for schema documents. This change addresses issue 5930 defaultOpenContent in the S4SD.
- The setting
blockDefault="#all"has been removed from the schema for schema documents; this change resolves issue 6120 Reconsider blockDefault=#all. - Namespace fixup is now explicitly required in some places where it is needed but was not mentioned before; these changes resolve issue 6445 Namespace fixup and default namespace and issue 6465 Namespace fixup and inherited attributes.
- In the DTD for schema documents (DTD for Schemas (non-normative) (§I)), an error has been corrected in the declaration of the
inheritableattribute of thexs:attributeelement (resolving issue 11070 DTD for schema documents: inheritable declared as %URIref). - In the schema for schema documents, an error in the declaration of
xs:groupwithin the named model groupxs:allModelhas been corrected to make the type ofxs:alla legal restriction of its base type and make the schema for schema documents conformant to this specification. This resolves issue 11092 Error in S4SD: complexType name="all" is not a valid restriction.
G.1.17 Clarifications and editorial changes
- Each named constraint is now given in a separate section, to simplify reference to them.
- The XML mapping rules have been reorganized to make them more perspicuous.
- The keywords defined by [IETF RFC 2119] to designate different levels of requirement have been marked up to distinguish more consistently between cases where their normative meaning is intended (e.g. "must") and cases where the words are used in its everyday sense without conformance implications (e.g. "must"). See Documentation Conventions and Terminology (§1.5).
- A note has been added, warning that the replace and collapse values for whitespace handling are not a reliable means of neutralizing the effects of word-wrapping and pretty-printing of natural-language data and should not be used for that purpose.
- Several minor corrections and clarifications have been made. The usage of some technical terminology has been clarified, normalized, and aligned where appropriate with the usage in [XML Schema: Datatypes]. Conditionals using "if" have been rephrased to use "if and only if" where appropriate.
- The title of the specification has been changed, and the language defined here is referred to as XSD, not using the name "XML Schema". This may help reduce confusion between the language defined here and the broader class of XML schema languages in general.
- Conformance-related language has been reviewed to avoid confusion between the conformance-related usage of the verbs may, must, and should, and other usages.
- Various new terms have been defined, and some existing terms have been redefined, to reduce confusion and improve legibility. In some cases, existing terms which were felt insufficiently informative have been replaced by new terms which may be more useful.
- Following the example of XQuery 1.0 and XSLT 2.0, the terms "·implementation-defined·" and "·implementation-dependent·" have been defined and the two concepts distinguished. The appendix contains lists both of ·implementation-defined· and of ·implementation-dependent· features.
- The term "context-determined-declaration" has been replaced with the term ·locally declared type·; this resolves issue 4690 Editorial: 'context-determined declarations' needs more work.
- The namespace prefixes used to refer to well known namespaces have been changed and are now more consistent; this resolves issue 4316 Make sure namespace prefixes are used appropriately throughout structures.
- Numerous small changes were made in the interests of clarity, completeness, consistency, and precision, and to correct typographical errors. These changes resolve a number of issues, including: 5140 small editorial changes section 3.3; 5148 inconsistent target ns description; 5639 when is value V a valid restriction of value Y?; 5800 Possibly revise list of required infoset properties; 5916 Obsolete editorial note; 5917 Typo in 3.1.1; 5934 Typo concerning <simpleContent mixed="true">; 6011 [schema11] base URI comments; 6156 Typo in 3.4.2; 6162 <anyAttribute> allows ##definedSibling; 6165 Constraints on XML representation of anyAttribute; 6166 Schema Component Model for Wildcards; 6167 Attribute Wildcard Intersection; 6170 Wildcards and defaultAttributes; 6175 Wildcard overlap; 6227 Type Derivation OK (simple); and 6233 Wrong pointer for [nil] PSVI property.
- Discussions of global components now take <redefine> into account (addresses issue 5918 Top level declarations).
- The usage of "·validation·", "·assessment·", and related terms has been clarified and made more consistent.
- The text concerning
xsi:typeattributes and their effect has been clarified in Element Locally Valid (Element) (§3.3.4.3). In particular, the revisions attempt to make clearer just what happens in cases where thexsi:typeattribute in the document instance cannot be used (because the type named is unknown, or otherwise not usable). This resolves issue 11219 Editorial revision of Element Locally Valid (Element). - The text has been revised to make clearer that declarations enclosed in an
xs:overrideelement are handled using theelementFormDefaultand other schema-document-level defaults from the schema document being overridden, not the schema document containing thexs:overrideelement. This resolves issue 10652 xs:override and document-level defaults. - The constraints forbidding the use of special types as members of unions and item types for lists have been reformulated as part of the definition of the simple type definition component. This resolves issue 11103 Note in section 2.4.1 (Special datatypes as members of a union).
- The treatment of elements in the Schema namespace occurring within <annotation> elements has been clarified:
- Such elements do not participate in the mapping from XML representations to components as defined in this specification (The Mapping between XML Representations and Components (§3.1.3), The Annotation Schema Component (§3.15.1)).
- Such elements are not required to be valid or to satisfy the XML Representation rules as a condition of conformance for a schema document (Conformance (§2.4), The Annotation Schema Component (§3.15.1)).
- If such elements are invalid, the effect on schema component construction is ·implementation-defined· (The Annotation Schema Component (§3.15.1), Checklist of implementation-defined features (§E.1)).
- A note has been added to the discussion of <override> elements to make it easier to see how processors are expected to handle cycles in references from one schema document to another. This change resolves issue 12184 Circularity in xs:override.
G.2 Issues not resolved
It may be useful to mention some points where possible changes to the specification have been discussed, but on which no changes have, in the end, been made. In some cases, this resulted from the XML Schema Working Group's determination that no change was desirable; in other cases, there was no consensus on the desirability of change, or no consensus on what change should be made.
- As noted above, some restrictions on all groups have been relaxed; all groups, however, must still be top-level groups; they are not allowed to appear within sequences or choice groups.
- The namespace-related properties of the basic infoset are ·fixed up· when attributes with qualified names are assigned default values.Other kinds of infoset fixup, however, are still not performed. Attributes of type
ID,IDREF,IDREFS, andNOTATIONdo not have the same effect on the base infoset as they do if declared in a DTD. (An infoset-to-infoset transformation can be used to migrate the appropriate information into the base infoset.) - Some existing implementations (and specifications) assume that elements of type
xs:IDuniquely identify themselves, instead of uniquely identifying their parent. This version of this specification reaffirms the existing rule, which is that elements and attributes of typexs:IDuniquely identify the parent element of the ID attribute or element. - The identity of components is still underspecified (although a number of points have been clarified, e.g. by the specification of the {scope} property), with the result that some schemas can be interpreted either as conformant or as non-conformant, depending on the interpretation of the specification's appeals to component identity.
- The constraint Element Declarations Consistent (§3.8.6.3) has been recast, but not at the higher level of abstraction originally required and expected.
- The account of schema composition given here has not eliminated all the uncertainties present in XSD 1.0; edge cases remain which different conformant implementations will treat differently.
- A systematic tabulation of error conditions and definition of a new system of error codes was originally foreseen for XSD 1.1, but has not been completed for inclusion here. No further work in this area is currently anticipated.
H Glossary (non-normative)
The listing below is for the benefit of readers of a printed version of this document: it collects together all the definitions which appear in the document above.
- L(D)
- For any Element Declaration D, the language L(D) ·accepted· by D is the set of all sequences of length 1 whose sole member is an element information item which ·matches· D.
- L(W)
- For any Wildcard W, the language L(W) ·accepted· by W is the set of all sequences of length 1 whose sole member is an element information item which ·matches· W.
- NCName
- An NCName is a name with no colon, as defined in [XML Namespaces 1.1]. When used in connection with the XML representation of schema components in this specification, this refers to the simple type NCName as defined in [XML Schema: Datatypes]
- QName
- A QName is a name with an optional namespace qualification, as defined in [XML Namespaces 1.1]. When used in connection with the XML representation of schema components or references to them, this refers to the simple type QName as defined in [XML Schema: Datatypes]
- Schema Component Constraint
- Constraints on the schema components themselves, i.e. conditions components must satisfy to be components at all. They are located in the sixth sub-section of the per-component sections of Schema Component Details (§3) and tabulated in Schema Component Constraints (§B.4)
- Schema Information Set Contribution
- Augmentations to ·post-schema-validation infoset·s expressed by schema components, which follow as a consequence of ·assessment·. They are located in the fifth sub-section of the per-component sections of Schema Component Details (§3) and tabulated in Contributions to the post-schema-validation infoset (§B.2)
- Schema Representation Constraint
- Constraints on the representation of schema components in XML beyond those which are expressed in Schema for Schema Documents (Structures) (normative) (§A). They are located in the third sub-section of the per-component sections of Schema Component Details (§3) and tabulated in Schema Representation Constraints (§B.3)
- Type Definition Hierarchy
- Except for ·
xs:anyType·, every ·type definition· is, by construction, either a ·restriction· or an ·extension· of some other type definition. The exception ·xs:anyType· is a ·restriction· of itself. With the exception of the loop on ·xs:anyType·, the graph of these relationships forms a tree known as the Type Definition Hierarchy with ·xs:anyType· as its root - Validation Rules
- Contributions to ·validation· associated with schema components. They are located in the fourth sub-section of the per-component sections of Schema Component Details (§3) and tabulated in Validation Rules (§B.1)
- Web-aware
- Web-aware processors are network-enabled processors which are not only ·general-purpose· but which additionally must be capable of accessing schema documents from the World Wide Web as described in Representation of Schemas on the World Wide Web (§2.8) and How schema definitions are located on the Web (§4.3.2).
- XSD schema
- An XSD schema is a set of ·schema components·
- absent
- Throughout this specification, the term absent is used as a distinguished property value denoting absence
- accept
- A model group G is said to accept or recognize the members of L(G).
- accept
- A particle P is said to accept or recognize the members of L(P). Similarly, a term T accepts or recognizes the members of L(T).
- actual value
- With reference to any string, interpreted as denoting an instance of a given datatype, the term actual value denotes the value to which the lexical mapping of that datatype maps the string.
- ancestor
- The ancestors of a ·type definition· are its {base type definition} and the ·ancestors· of its {base type definition}.
- annotation mapping
- The annotation
mapping of a set of element information items ES
is a sequence of annotations AS, with the following properties:
1 For every <annotation> element information item among the [children] of any element information item in ES, there is a corresponding Annotation component in AS.Note: As noted above, the {attributes} property of each Annotation component includes all the attribute information items on the <annotation> element itself, on the XML element which represents (and maps to) the component being annotated, and on any intervening XML elements, if those attribute information items have [namespace name]s different from the XSD namespace.2 If any element information item E in ES has any attribute information items A such that all of the following are true:then for each such E, an Annotation component C will appear in AS, with C.{application information} and C.{user information} each being the empty sequence and C.{attributes} containing all and only those attribute information items A among E.[attributes].2.1 A is in E.[attributes].2.2 A.[namespace name] is present and not the XSD namespace.2.3 A is not included in the [attributes] property of any annotation component described in clause 1.3 AS contains no other Annotation components.
- annotation mapping
- The annotation mapping of a single element information item is the ·annotation mapping· of the singleton set containing that element.
- anyAtomicType
- There is a further special datatype
called anyAtomicType, a
·restriction· of
·
xs:anySimpleType·, which is the ·base type definition· of all the primitive datatypes. - anySimpleType
- A
special ·restriction· of
·
xs:anyType·, whose name is anySimpleType in the XSD namespace, is the root of the ·Type Definition Hierarchy· for all simple type definitions. ·xs:anySimpleType· has a lexical space containing all sequences of characters in the Universal Character Set (UCS) and a value space containing all atomic values and all finite-length lists of atomic values. - assessment
- the word assessment is used to refer to the overall process of local validation, recursive determination of validation outcome, and infoset augmentation, i.e. as a short form for "·schema-validity assessment·"
- assessor
- A schema-validity assessor (or just assessor) is a processor which performs full or partial ·schema-validity assessment· of an XML instance document, element information item, or attribute information item, with reference to a conforming schema, and provides access to the entirety of the resulting ·post-schema-validation infoset·. The means by which an ·assessor· provides access to the ·post-schema-validation infoset· is ·implementation-defined·.
- attributed to
- During ·validation· of an element information item against its (complex) ·governing type definition·, associations between element and attribute information items among the [children] and [attributes] on the one hand, and the attribute uses, attribute wildcard, particles and open content property record on the other, are established. The element or attribute information item is attributed to the corresponding component.
- automatically known
- A type about which a processor possesses prior knowledge, and which the processor can support without any declaration of the type being supplied by the user, is said to be automatically known to the processor.
- base particle
- Let the base particle be the particle of the {content type} of the {base type definition}.
- base information set properties
- By base information set properties are meant the properties listed in Required Information Set Items and Properties (normative) (§D).
- base type definition
- The type definition used as the basis for an ·extension· or ·restriction· is known as the base type definition of that definition
- basic particle
- A basic particle is a Particle whose {term} is a ·basic term·.
- basic term
- A basic term is an Element Declaration or a Wildcard.
- compete
- Two Particles P1 and P2 contained in some Particle P compete with each other if and only if some sequence S of element information items has two ·paths· in P which are identical except that one path has P1 as its last item and the other has P2.
- competing paths
- Two (or more) ·paths· of a sequence S in a Particle P are competing paths if and only if they are identical except for their final items, which differ.
- complete path
- For a model group M and a sequence S in L(M), the path of S in M is a complete path; prefixes of complete paths which are themselves not complete paths are incomplete paths.
- component name
- Declarations and definitions may and in some cases must have and be identified by names, which are NCNames as defined by [XML Namespaces 1.1]
- conditionally selects
- Given a Type Table T and an element
information item E, T conditionally selects a
type S for E in
the following way. The {test}
expressions in T's {alternatives} are evaluated, in order,
until one of the Type Alternatives ·successfully selects· a type definition for E, or until
all have been tried without success. If any
Type Alternative ·successfully selects· a type definition, none of the following
Type Alternatives are tried. Then the type S conditionally
selected for E by T is
as described in
the appropriate case among the following:1 If at least one Type Alternative in T.{alternatives} ·successfully selects· a type definition for E, then S is the type definition selected by the first such Type Alternative.2 If no Type Alternative in T.{alternatives} ·successfully selects· a type definition, then S is T.{default type definition}.{type definition}.
- constructed
- Datatypes can be constructed from other datatypes by restricting the value space or lexical space of a {base type definition} using zero or more Constraining Facets, by specifying the new datatype as a list of items of some {item type definition}, or by defining it as a union of some specified sequence of {member type definitions}.
- contains
- A model group contains the components which it either ·directly contains· or ·indirectly contains·.
- contains
- A particle contains the components which it either ·directly contains· or ·indirectly contains·.
- content model
- A particle can be used in a complex type definition to constrain the ·validation· of the [children] of an element information item; such a particle is called a content model
- context-determined declaration
- During ·validation·, associations between element and attribute information items among the [children] and [attributes] on the one hand, and element and attribute declarations on the other, are also established. When an item is ·attributed· to an ·element particle·, then it is associated with the declaration which is the {term} of the particle. Similarly, when an attribute information item is ·attributed to· an Attribute Use, then the item is associated with the {attribute declaration} of that Attribute Use. Such declarations are called the context-determined declarations.
- declaration
- declaration components are associated by (qualified) name to information items being ·validated·
- declared entity name
- A string is a declared entity name if and only if it is equal to the [name] of some unparsed entity information item in the value of the [unparsedEntities] property of the document information item at the root of the infoset containing the element or attribute information item whose ·normalized value· the string is.
- default binding
-
When a sequence of element information items ES
is ·locally valid·
with respect to a
Content Type CT
or when a set of attribute information items
AS satisfies clause 2 and clause 3
of Element Locally Valid (Complex Type) (§3.4.4.2) with respect to a Complex Type Definition,
there is a (partial) functional mapping from
the element information items E in the sequence ES
or the attribute information items in
AS
to a default binding for the item,
where the default binding is
an Element Declaration,
an Attribute Use,
or one
of the keywords strict, lax, or skip,
as follows:
1 When the item has a ·governing element declaration·, the default binding is that Element Declaration.2 When the item has a ·governing attribute declaration· and it is ·attributed· to an Attribute Use, the default binding is that Attribute Use.3 When the item has a ·governing attribute declaration· and it is ·attributed· to an attribute wildcard, the default binding is an Attribute Use whose {attribute declaration} is the ·governing attribute declaration·, whose {value constraint} is ·absent·, and whose {inheritable} is the ·governing attribute declaration·'s {inheritable} (the other properties in the Attribute Use are not relevant).4 When the item is ·attributed· to a strict ·wildcard particle· or attribute wildcard or an Open Content with a strict Wildcard and it does not have a ·governing element declaration· or a ·governing attribute declaration·, then the default binding is the keyword strict.5 When the item is ·attributed· to a lax ·wildcard particle· or attribute wildcard or an Open Content with a lax Wildcard and it does not have a ·governing element declaration· or a ·governing attribute declaration·, then the default binding is the keyword lax.6 When the item is ·attributed· to a skip ·wildcard particle· or attribute wildcard or an Open Content with a skip Wildcard then the default binding is the keyword skip.
- defaulted attribute
- A
defaulted attribute
belonging to an element information item E
·governed by· a complex type T
is any Attribute Use
U
for which
all of the following are true:1 U is a member of T.{attribute uses}.2 U.{required} = false.3 U's ·effective value constraint· is not ·absent·.4 U.{attribute declaration} is not one of the Attribute Declarations from Built-in Attribute Declarations (§3.2.7).5 U.{attribute declaration} does not match any of the attribute information items in E.[attributes] as per clause 2.1 of Element Locally Valid (Complex Type) (§3.4.4.2) above.
- definition
- definition components define internal schema components that can be used in other schema components
- definition of anyType
- A special complex type definition, (referred to in earlier versions of this specification as 'the ur-type definition') whose name is anyType in the XSD namespace, is present in each ·XSD schema·. The definition of anyType serves as default type definition for element declarations whose XML representation does not specify one
- derived
- If a type definition D can reach a type definition B by following its base type definition chain, then D is said to be derived from B.
- directly contains
- A model group directly contains the particles in the value of its {particles} property.
- directly contains
- A particle directly contains the component which is the value of its {term} property.
- effective value constraint
- The effective value constraint of an attribute use U is U.{value constraint}, if present, otherwise U.{attribute declaration}.{value constraint}, if present, otherwise the effective value constraint is ·absent·.
- element particle
- An element particle is a Particle whose {term} is an Element Declaration.
- element substitution group
- Through the mechanism of element substitution groups, XSD provides a more powerful model than DTDs do supporting substitution of one named element for another
- equivalent type alternative
-
Any Type Alternative is equivalent to itself.
Otherwise, any Type Alternative T1 is equivalent
to a different Type Alternative
T2 if and only if
T1.{test} and
T2.{test} are true for the same
set of input element information items
and
T1.{type definition} and
T2.{type definition} accept
the same set of input information items as valid.
In the general case, equivalence and non-equivalence
can be difficult to establish.
It is ·implementation-defined· under just what conditions a
processor detects that two type
alternatives are equivalent, but all
processors must detect T1 and T2 as
equivalent if
all of the following are true:A processor may treat two type alternatives as non-equivalent if they do not satisfy the conditions just given and the processor does not detect that they are nonetheless equivalent.1 T1.{test}.{namespace bindings} and T2.{test}.{namespace bindings} have the same number of Namespace Bindings, and for each entry in T1.{test}.{namespace bindings} there is a corresponding entry in T2.{test}.{namespace bindings} with the same {prefix} and {namespace}.2 T1.{test}.{default namespace} and T2.{test}.{default namespace} either are both ·absent· or have the same value.3 T1.{test}.{base URI} and T2.{test}.{base URI} either are both ·absent· or have the same value.4 T1.{test}.{expression} and T2.{test}.{expression} have the same value.5 T1.{type definition} and T2.{type definition} are the same type definition.
- equivalent type table
-
A Type Table T1 is equivalent to a Type Table T2
if and only if all of the following are true:1 T1.{alternatives} has the same length as T2.{alternatives} and their corresponding entries are ·equivalent·.2 T1.{default type definition} and T2.{default type definition} are ·equivalent·.
- extension
- A complex type definition which allows element or attribute content in addition to that allowed by another specified type definition is said to be an extension
- field subset of XPath
- The subset of XPath defined in Fields Value OK (§3.11.6.3) is called the field subset of XPath.
- final
- the complex type is said to be final, because no further ·derivations· are possible
- full instance subset
- The full instance subset of the PSVI includes almost all properties defined by this specification as applying to element and attribute information items, but excludes schema components. It consists of the ·instance-validity subset·, plus the following properties for elements:
- general-purpose
- A general-purpose processor is a ·validator· or ·assessor· which accepts schemas represented in the form of XML documents as described in Layer 2: Schema Documents, Namespaces and Composition (§4.2).
- governing
- The declaration associated with an information item, if any, and with respect to which its validity is ·assessed· in a given assessment episode is said to govern the item, or to be its governing element or attribute declaration. Similarly the type definition with respect to which the type-validity of an item is assessed is its governing type definition.
- governing attribute declaration
-
In a given schema-validity ·assessment· episode,
the ·governing· declaration of an attribute
(its governing attribute declaration)
is the first of
the following which applies:
If none of these applies, the attribute has no ·governing attribute declaration· (or, in equivalent words, the ·governing attribute declaration· is ·absent·).1 A declaration which was stipulated by the processor (see Assessing Schema-Validity (§5.2)).3 A declaration ·resolved· to by its [local name] and [namespace name], provided the attribute is not ·skipped· and the processor has not stipulated a type definition at the start of ·assessment·.
- governing element declaration
- The governing element declaration of
an element information item E,
in a given schema-validity
·assessment· episode, is the first of the following
which applies:
If none of these applies, E has no ·governing element declaration· (or, in equivalent words, E's ·governing element declaration· is ·absent·).1 A declaration stipulated by the processor (see Assessing Schema-Validity (§5.2)).3 A declaration ·resolved· to by E's [local name] and [namespace name], provided that E is ·attributed· either to a strict ·wildcard particle· or to a lax ·wildcard particle·.4 A declaration ·resolved· to by E's [local name] and [namespace name], provided that none of the following is true:4.1 E is ·skipped·4.2 the processor has stipulated a type definition for E4.3 a ·non-absent· ·locally declared type· exists for E
- governing type definition
- The governing type definition of an
element information item E,
in a given schema-validity ·assessment· episode, is the first of the following which
applies: If none of these applies, there is no ·governing type definition· (or, in equivalent words, it is ·absent·).1 An ·instance-specified type definition· which ·overrides· a type definition stipulated by the processor (see Assessing Schema-Validity (§5.2)).2 A type definition stipulated by the processor (see Assessing Schema-Validity (§5.2)).3 An ·instance-specified type definition· which ·overrides· the ·selected type definition· of E.4 The ·selected type definition· of E.6 An ·instance-specified type definition· which ·overrides· the ·locally declared type·.7 The ·locally declared type·.
- governing type definition
-
The governing type definition of an
attribute, in a given schema-validity ·assessment· episode, is
the first of the following which applies:
If neither of these applies, there is no ·governing type definition· (or, in equivalent words, it is ·absent·).1 A type definition stipulated by the processor (see Assessing Schema-Validity (§5.2)).2 The {type definition} of the ·governing attribute declaration·.
- grouping
- A grouping of a sequence is a set of sub-sequences, some or all of which may be empty, such that each member of the original sequence appears once and only once in one of the sub-sequences and all members of all sub-sequences are in the original sequence.
- implementation-defined
- An implementation-defined feature or behavior may vary among processors conforming to this specification; the precise behavior is not specified by this specification but must be specified by the implementor for each particular conforming implementation.
- implementation-dependent
- An implementation-dependent feature or behavior may vary among processors conforming to this specification; the precise behavior is not specified by this or any other W3C specification and is not required to be specified by the implementor for any particular implementation.
- implicitly contains
- A list of particles implicitly contains an element declaration if and only if a member of the list contains that element declaration in its ·substitution group·
- indirectly contains
- A model group indirectly contains the particles, groups, wildcards, and element declarations which are ·contained· by the particles it ·directly contains·.
- indirectly contains
- A particle indirectly contains the particles, groups, wildcards, and element declarations which are contained by the value of its {term} property.
- initial value
- the initial value of some attribute information item is the value of the [normalized value] property of that item. Similarly, the initial value of an element information item is the string composed of, in order, the [character code] of each character information item in the [children] of that element information item
- instance-specified type definition
- An instance-specified type definition
is a type definition associated with an element information
item in the following way: 2 The ·normalized value· of that attribute information item is a qualified name ·valid· with respect to the built-in QName simple type, as defined by String Valid (§3.16.4).3 The ·actual value· (a ·QName·) ·resolves· to a type definition. It is this type definition which is the instance-specified type definition.
- instance-validity subset
- The instance-validity subset of the PSVI consists of the ·root-validity subset·, plus the following properties on elements, wherever applicable:
- item isomorphic to a component
- by an item isomorphic to a component is meant an information item whose type is equivalent to the component's, with one property per property of the component, with the same name, and value either the same atomic value, or an information item corresponding in the same way to its component value, recursively, as necessary
- laxly assessed
- The schema validity of an element information item E is
said to be laxly assessed if and only if
both of the following are true:1 E has neither a ·governing element declaration· nor a ·governing type definition·.2 E is locally ·validated· with respect to ·
xs:anyType· as defined in Element Locally Valid (Type) (§3.3.4.4), and the schema-validity of E's [attributes] and [children] is assessed as described in clause 2 and clause 3 of Schema-Validity Assessment (Element) (§3.3.4.6). - locally declared type
- Every Complex Type Definition determines a partial functional mapping from element or attribute information items (and their expanded names) to type definitions. This mapping serves as a locally declared type for elements and attributes which are allowed by the Complex Type Definition.
- locally declared type
-
For a given Complex Type Definition CTD and a given attribute
information item A, the
·locally declared type· of
A within CTD is
the appropriate case among the following:2 If A has the same expanded name as some attribute declaration D which is the {attribute declaration} of some Attribute Use contained by CTD's {attribute uses} , then the {type definition} of D.3 otherwise the ·locally declared type· of A within CTD.{base type definition}.
- locally declared type
-
For a given Complex Type Definition
CTD and a given element information item E, the
·locally declared type· of
E within CTD is
the appropriate case among the following:2 If E has the same expanded name as some element declaration D which is ·contained· by CTD's content model, whether ·directly·, ·indirectly·, or ·implicitly· , then the declared {type definition} of D.3 otherwise the ·locally declared type· of E within CTD.{base type definition}.
- locally valid
- A sequence of element information items is locally valid with respect to a Content Type if and only if it satisfies Element Sequence Locally Valid (Complex Content) (§3.4.4.3) with respect to that Content Type.
- locally valid
- A sequence S of element information items is locally valid against a particle P if and only if S has a ·validation-path· in P. The set of all such sequences is written V(P).
- match
-
An element information item E matches an Element Declaration D if and only if
one of the following is true:1 E and D have the same expanded name,2 The expanded name of E ·resolves· to an element declaration D2 which is ·substitutable· for D.
- match
- An
expanded name E matches an
·NCName· N and
a namespace name NS (or, equivalently, N and NS
match E)
if and only if all of the following
are true:
- The local name of E is identical to N.
- Either the namespace name of E is identical to NS, or else E has no namespace name (E is an unqualified name) and NS is ·absent·.
- match
- An element information item E matches a Wildcard W (or a ·wildcard particle· whose {term} is W) if and only if E is locally ·valid· with respect to W, as defined in the validation rule Item Valid (Wildcard) (§3.10.4.1).
- match
- Two namespace names N1 and N2 are said to match if and only if they are identical or both are ·absent·.
- namespace fixup
- When
default values are supplied for attributes, namespace fixup
may be required, to ensure that the ·post-schema-validation infoset· includes
the namespace bindings needed and maintains the consistency
of the namespace information in the infoset. To perform
namespace fixup on an element information item E for
a namespace N:
1 If the [in-scope namespaces] of E binds a prefix to N, no namespace fixup is needed; the properties of E are not changed.2 Otherwise, first select some prefix P which is not bound by the [in-scope namespaces] of E (the choice of prefix is ·implementation-dependent·).3 Add an entry to the [in-scope namespaces] of E binding P to N.4 Add a namespace attribute to the [namespace attributes] of E.5 Maintain the consistency of the information set by adjusting the namespace bindings on the descendants of E. This may be done in either of two ways:5.1 Add the binding of P to N to the [in-scope namespaces] of all descendants of E, except where that binding is overridden by another binding for P.5.2 Add to the [namespace attributes] of each child of E a namespace attribute which undeclares the binding for P (i.e. a namespace attribute for prefix P whose ·normalized value· is the empty string), unless that child already has a namespace declaration for prefix P. Note that this approach is possible only if [XML Namespaces 1.1] is in use, rather than [Namespaces in XML 1.0].The choice between the two methods of maintaining consistency in the information set is ·implementation-dependent·.
- nilled
- An
element information item E is nilled
with respect to some element declaration D if and only if
all of the following are true:1 E has
xsi:nil= true.2 D.{nillable} = true. - normalized value
- The
normalized value of an element or attribute
information item is an ·initial value· which has been normalized
according to the value of the whiteSpace facet, and the values of any other pre-lexical facets, associated with the simple type definition used
in its ·validation·. The keywords for
whitespace normalization have the following meanings:
Similarly, the normalized value of any string with respect to a given simple type definition is the string resulting from normalization using the whiteSpace facet and any other pre-lexical facets, associated with that simple type definition.preserveNo normalization is done, the whitespace-normalized value is the ·initial value·replaceAll occurrences of
#x9(tab),#xA(line feed) and#xD(carriage return) are replaced with#x20(space).collapseSubsequent to the replacements specified above under replace, contiguous sequences of#x20s are collapsed to a single#x20, and initial and/or final#x20s are deleted. - overlay
- Given two sets of facets B and S, the result of overlaying B with S is the set of facets R for which all of the following are true:
- override
- An ·instance-specified type definition· S is said to
override another type definition T if and only
if all of the following are true: 1 S is the ·instance-specified type definition· on some element information item E. A ·governing element declaration· may or may not be known for E.2 S is ·validly substitutable· for T, subject to the blocking keywords of the {disallowed substitutions} of E's ·governing element declaration·, if any, or ·validly substitutable without limitation· for T (if no ·governing element declaration· is known).Note: Typically, T would be the ·governing type definition· for E if it were not overridden. (This will be the case if T was stipulated by the processor, as described in Assessing Schema-Validity (§5.2), or E has a ·governing element declaration· and T is its declared type, or T is the ·locally declared type· of E.)
- partition
- A partition of a sequence is a sequence of sub-sequences, some or all of which may be empty, such that concatenating all the sub-sequences yields the original sequence
- path
- When a sequence S of element information items is checked against a model group M, the sequence of ·basic particles· which the items of S match, in order, is a path of S in M. For a given S and M, the path of S in M is not necessarily unique. Detailed rules for the matching, and thus for the construction of paths, are given in Language Recognition by Groups (§3.8.4.1) and Principles of Validation against Particles (§3.9.4.1).
- post-schema-validation infoset
- We refer to the augmented infoset which results from conformant processing as defined in this specification as the post-schema-validation infoset, or PSVI
- potentially inherited
- An attribute
information item A, whether explicitly specified in the input
information set or defaulted as described in
Attribute Default Value (§3.4.5.1), is potentially inherited by
an element information item E if and only if
all of the following are true:1 A is among the [attributes] of one of E's ancestors.2 A and E have the same [validation context].3 One of the following is true:3.1 A is ·attributed to· an Attribute Use whose {inheritable} = true.3.2 A is not ·attributed to· any Attribute Use but A has a ·governing attribute declaration· whose {inheritable} = true.
- present
- A property value which is not ·absent· is present.
- property record
- a property value may itself be a collection of named values, which we call a property record
- resolve
- A ·QName· in a schema document resolves to a component in a schema if and only if in the context of that schema the QName and the component together satisfy the rule QName resolution (Schema Document) (§3.17.6.2). A ·QName· in an input document, or a pair consisting of a local name and a namespace name, resolves to a component in a schema if and only if in the context of that schema the QName (or the name + namespace pair) and the component together satisfy the rule QName resolution (Instance) (§3.17.6.3).
- restriction
- A type defined with the same constraints as its ·base type definition·, or with more, is said to be a restriction.
- root-validity subset
- The root-validity subset of the PSVI consists of the following properties of the ·validation root·:
- schema component
- Schema component is the generic term for the building blocks that make up the abstract data model of the schema.
- schema document
- A document in this form (i.e. a <schema> element information item) is a schema document
- schema-validity assessment
- As it is used in this specification, the
term schema-validity assessment has three aspects: 1 Determining local schema-validity, that is whether an element or attribute information item satisfies the constraints embodied in the relevant components of an XSD schema (specifically the ·governing· element or attribute declaration and/or ·governing· type definition);2 Determining an overall validation outcome for the item by combining local schema-validity with the results of schema-validity assessments of its descendants, if any; and3 Determining the appropriate augmentations to the infoset (and, if desired, exposing them to downstream applications in some way, to record this outcome).
- selected type definition
- The selected type
definition S of an element information item E is a
type definition associated with E in the following way. Let
D be the ·governing element declaration· of E. Then: If E has no ·governing element declaration·, then E has no selected type definition.1 If D has a {type table}, then S is the type ·conditionally selected· for E by D.{type table}.2 If D has no {type table}, then S is D.{type definition}.
- selector subset of XPath
- The subset of XPath defined in Selector Value OK (§3.11.6.2) is called the selector subset of XPath.
- skipped
- An element or attribute information item is skipped if it is ·attributed· to a skip wildcard or if one of its ancestor elements is.
- special-purpose
- A schema processor which is not a ·general-purpose· processor is a special-purpose processor.
- strictly assessed
- An element
information item E is said to be strictly assessed
if and only if
all of the following are true:1 One of the following is true:1.1 All of the following are true:1.1.1 A ·non-absent· element declaration is known for E, namely its ·governing· declaration.1.1.2 E's local ·validity· with respect to that declaration has been evaluated as per Element Locally Valid (Element) (§3.3.4.3).1.1.3 If that evaluation involved the evaluation of Element Locally Valid (Type) (§3.3.4.4), clause 1 thereof is satisfied.1.2 All of the following are true:1.2.1 E does not have a ·governing element declaration·.1.2.2 A ·non-absent· type definition is known for E, namely its ·governing type definition·1.2.3 The local ·validity· of E with respect to its ·governing type definition· has been evaluated as per Element Locally Valid (Type) (§3.3.4.4).2 For each of the attribute information items among E.[attributes], the appropriate case among the following is true:2.1 If the attribute has a ·governing attribute declaration· , then its schema-validity is assessed with respect to that declaration, as defined in Schema-Validity Assessment (Attribute) (§3.2.4.3).2.2 otherwise its schema-validity is not assessed.3 For each of the element information items among its [children], the appropriate case among the following is true:3.1 If the child has a ·governing element declaration· or a ·governing type definition· , then its schema-validity is assessed with respect to that declaration or type definition, as defined in Schema-Validity Assessment (Element) (§3.3.4.6).3.2 If the child is ·attributed to· a skip Wildcard , then its schema-validity is not assessed.3.3 otherwise its schema-validity is ·laxly assessed· with respect to ·
xs:anyType·. - substitutable
- One element declaration is substitutable for another if together they satisfy constraint Substitution Group OK (Transitive) (§3.3.6.3).
- substitution group
- Every element declaration (call this HEAD) in the {element declarations} of a schema defines a substitution group, a subset of those {element declarations}. An element declaration is in the substitution group of HEAD if and only if it is ·substitutable· for HEAD.
- successfully selects
- A Type Alternative A
successfully selects a Type Definition T for an
element information item E if and only if A.{test} evaluates to
trueand A.{type definition} = T. - symbol space
- this specification introduces the term symbol space to denote a collection of names, each of which is unique with respect to the others
- target namespace
- Several kinds of component have a target namespace, which is either ·absent· or a namespace name, also as defined by [XML Namespaces 1.1]
- target set
- The
target set of an <override> element information
item E contains all of the following:The target set of E contains no other schema documents.1 The schema document identified by the
schemaLocationattribute of E.2 The schema document identified by theschemaLocationattribute of any <override> element information item in a schema document contained in the ·target set· of E.3 The schema document identified by theschemaLocationattribute of any <include> element information item in a schema document contained in the ·target set· of E. - type definition
- This specification uses the phrase type definition in cases where no distinction need be made between simple and complex types
- type-aware subset
- The type-aware subset of the PSVI consists of the ·instance-validity subset·, plus the following items and properties.
- type-aware subset
- The lightweight type-aware subset of the PSVI provides the same information as the ·type-aware subset·, except that instead of providing direct access to schema components, it provides only their names and related information.
- typed value
- When the ·validating type· of an ·actual value· is or is ·derived· from a simple type definition T, the value is also referred to as a T value.
- user option
- A choice left under the control of the user of a processor, rather than being fixed for all users or uses of the processor.Statements in this specification that "Processors may at user option" behave in a certain way mean that processors may provide mechanisms to allow users (i.e. invokers of the processor) to enable or disable the behavior indicated. Processors which do not provide such user-operable controls must not behave in the way indicated. Processors which do provide such user-operable controls must make it possible for the user to disable the optional behavior.Note: The normal expectation is that the default setting for such options will be to disable the optional behavior in question, enabling it only when the user explicitly requests it. This is not, however, a requirement of conformance: if the processor's documentation makes clear that the user can disable the optional behavior, then invoking the processor without requesting that it be disabled can be taken as equivalent to a request that it be enabled. It is required, however, that it in fact be possible for the user to disable the optional behavior.Note: Nothing in this specification constrains the manner in which processors allow users to control user options. Command-line options, menu choices in a graphical user interface, environment variables, alternative call patterns in an application programming interface, and other mechanisms may all be taken as providing user options.
- valid
- Validation is the process of determining whether an XML document, an element information item, or an attribute information item obeys the constraints expressed in a schema; in the context of XSD, this amounts to calculating the value of the appropriate item's [validity] property.
- valid extension
- A complex type T is a valid extension of its {base type definition} if and only if T.{derivation method} = extension and T satisfies the constraint Derivation Valid (Extension) (§3.4.6.2)
- valid restriction
- A complex type definition with {derivation method} = restriction is a valid restriction of its {base type definition} if and only if the constraint Derivation Valid (Restriction, Complex) (§3.4.6.3) is satisfied
- valid restriction
- A simple type definition T is a valid restriction of its {base type definition} if and only if T satisfies constraint Derivation Valid (Restriction, Simple) (§3.16.6.2)
- validating type
-
When a string N is schema-valid with respect to a simple type definition
T as defined by Datatype
Valid with the corresponding ·actual value· V,
1 The validating type of V is T if T is not a union type, otherwise the validating type is the basic member of T's transitive membership which actually ·validated· N.2 If the ·validating type· of V is a list type L and the {item type definition} of L is I, then the validating type of an (atomic) item value A occurring in V is I if I is not a union type, otherwise the validating type is the basic member of I's transitive membership which actually ·validated· the substring in N that corresponds to A.
- validation root
- The element or attribute information item at which ·assessment· begins is called the validation root.
- validation-path
- For any sequence S of element information items and any particle P, a ·path· of S in P is a validation-path if and only if for each prefix of the ·path· which ends with a ·wildcard particle·, the corresponding prefix of S has no ·competing path· which ends with an ·element particle·.
- validator
- A validator (or instance validator) is a processor which ·validates· an XML instance document against a conforming schema and distinguishes between valid documents and others, for one or more of the definitions of validity (·root-validity·, ·deep validity·, or ·uniform validity·) defined below in section Schema-validity and documents (§2.5). Conforming validators may additionally support other definitions of validity defined in terms of the ·post-schema-validation infoset·.
- validly substitutable
- A type definition S is
validly substitutable for another type T,
subject to a
set of blocking keywords K (typically drawn from the set
{substitution, extension,
restriction, list, union} used in
the {disallowed substitutions} and
{prohibited substitutions} of
element declarations and type definitions), if and
only if either
- S and T are both complex type definitions and S is validly derived from T subject to the blocking keywords in the union of K and T. {prohibited substitutions}, as defined in Type Derivation OK (Complex) (§3.4.6.5)
- S is a complex type definition, T is a simple type definition, and S is validly ·derived· from T subject to the blocking keywords in K, as defined in Type Derivation OK (Complex) (§3.4.6.5)
- S is a simple type definition and S is validly ·derived· from T subject to the blocking keywords in K, as defined in Type Derivation OK (Simple) (§3.16.6.3).
- validly substitutable without limitation
- If the set of keywords controlling whether a type S is ·validly substitutable· for another type T is the empty set, then S is said to be validly substitutable for T without limitation or absolutely. The phrase validly substitutable, without mention of any set of blocking keywords, means "validly substitutable without limitation".
- validly substitutable as a restriction
- A type definition S is validly substitutable as a restriction for another type T if and only if S is ·validly substitutable· for T, subject to the blocking keywords {extension, list, union}.
- wildcard particle
- A wildcard particle is a Particle whose {term} is a Wildcard. Wildcard particles may be referred to as "strict", "lax", or "skip" particles, depending on the {process contents} property of their {term}.
- xs:error
- A special simple type
definition, whose name is error in the XSD
namespace, is also present in each ·XSD schema·. The
XSD
errortype has no valid instances. It can be used in any place where other types are normally used; in particular, it can be used in conditional type assignment to cause elements which satisfy certain conditions to be invalid.
I DTD for Schemas (non-normative)
The DTD for schema documents is given below. Note there is no
implication here that schema must be the root element of a
document.
Independent copies of this material are available in an undated (mutable) version at http://www.w3.org/2009/XMLSchema/XMLSchema.dtd and in a dated (immutable) version at http://www.w3.org/2012/04/XMLSchema.dtd — the mutable version will be updated with future revisions of this specification, and the immutable one will not.
Although this DTD is non-normative, any XML document which is not valid per this DTD, given redefinitions in its internal subset of the 'p' and 's' parameter entities below appropriate to its namespace declaration of the XSD namespace, is almost certainly not a valid schema document, with the exception of documents with multiple namespace prefixes for the XSD namespace itself. Accordingly authoring ·schema documents· using this DTD and DTD-based authoring tools, and specifying it as the DOCTYPE of documents intended to be ·schema documents· and validating them with a validating XML parser, are sensible development strategies which users are encouraged to adopt until XSD-based authoring tools and validators are more widely available.
<!-- DTD for XML Schema Definition Language Part 1: Structures
Public Identifier: "-//W3C//DTD XSD 1.1//EN"
Official Location: http://www.w3.org/2009/XMLSchema/XMLSchema.dtd -->
<!-- Id: structures.dtd,v 1.1 2003/08/28 13:30:52 ht Exp -->
<!-- With the exception of cases with multiple namespace
prefixes for the XSD namespace, any XML document which is
not valid per this DTD given redefinitions in its internal subset of the
'p' and 's' parameter entities below appropriate to its namespace
declaration of the XSD namespace is almost certainly not
a valid schema document. -->
<!-- See below (at the bottom of this document) for information about
the revision and namespace-versioning policy governing this DTD. -->
<!-- The simpleType element and its constituent parts
are defined in XML Schema Definition Language Part 2: Datatypes -->
<!ENTITY % xs-datatypes PUBLIC '-//W3C//DTD XSD 1.1 Datatypes//EN' 'datatypes.dtd' >
<!ENTITY % p 'xs:'> <!-- can be overridden in the internal subset of a
schema document to establish a different
namespace prefix -->
<!ENTITY % s ':xs'> <!-- if %p is defined (e.g. as foo:) then you must
also define %s as the suffix for the appropriate
namespace declaration (e.g. :foo) -->
<!ENTITY % nds 'xmlns%s;'>
<!-- Define all the element names, with optional prefix -->
<!ENTITY % schema "%p;schema">
<!ENTITY % defaultOpenContent "%p;defaultOpenContent">
<!ENTITY % complexType "%p;complexType">
<!ENTITY % complexContent "%p;complexContent">
<!ENTITY % openContent "%p;openContent">
<!ENTITY % simpleContent "%p;simpleContent">
<!ENTITY % extension "%p;extension">
<!ENTITY % element "%p;element">
<!ENTITY % alternative "%p;alternative">
<!ENTITY % unique "%p;unique">
<!ENTITY % key "%p;key">
<!ENTITY % keyref "%p;keyref">
<!ENTITY % selector "%p;selector">
<!ENTITY % field "%p;field">
<!ENTITY % group "%p;group">
<!ENTITY % all "%p;all">
<!ENTITY % choice "%p;choice">
<!ENTITY % sequence "%p;sequence">
<!ENTITY % any "%p;any">
<!ENTITY % anyAttribute "%p;anyAttribute">
<!ENTITY % attribute "%p;attribute">
<!ENTITY % attributeGroup "%p;attributeGroup">
<!ENTITY % include "%p;include">
<!ENTITY % import "%p;import">
<!ENTITY % redefine "%p;redefine">
<!ENTITY % override "%p;override">
<!ENTITY % notation "%p;notation">
<!ENTITY % assert "%p;assert">
<!-- annotation elements -->
<!ENTITY % annotation "%p;annotation">
<!ENTITY % appinfo "%p;appinfo">
<!ENTITY % documentation "%p;documentation">
<!-- Customisation entities for the ATTLIST of each element type.
Define one of these if your schema takes advantage of the
anyAttribute='##other' in the
schema for schema documents -->
<!ENTITY % schemaAttrs ''>
<!ENTITY % defaultOpenContentAttrs ''>
<!ENTITY % complexTypeAttrs ''>
<!ENTITY % complexContentAttrs ''>
<!ENTITY % openContentAttrs ''>
<!ENTITY % simpleContentAttrs ''>
<!ENTITY % extensionAttrs ''>
<!ENTITY % elementAttrs ''>
<!ENTITY % groupAttrs ''>
<!ENTITY % allAttrs ''>
<!ENTITY % choiceAttrs ''>
<!ENTITY % sequenceAttrs ''>
<!ENTITY % anyAttrs ''>
<!ENTITY % anyAttributeAttrs ''>
<!ENTITY % attributeAttrs ''>
<!ENTITY % attributeGroupAttrs ''>
<!ENTITY % uniqueAttrs ''>
<!ENTITY % keyAttrs ''>
<!ENTITY % keyrefAttrs ''>
<!ENTITY % selectorAttrs ''>
<!ENTITY % fieldAttrs ''>
<!ENTITY % assertAttrs ''>
<!ENTITY % includeAttrs ''>
<!ENTITY % importAttrs ''>
<!ENTITY % redefineAttrs ''>
<!ENTITY % overrideAttrs ''>
<!ENTITY % notationAttrs ''>
<!ENTITY % annotationAttrs ''>
<!ENTITY % appinfoAttrs ''>
<!ENTITY % documentationAttrs ''>
<!ENTITY % complexDerivationSet "CDATA">
<!-- #all or space-separated list drawn from derivationChoice -->
<!ENTITY % blockSet "CDATA">
<!-- #all or space-separated list drawn from
derivationChoice + 'substitution' -->
<!ENTITY % composition '%include; | %import; | %override; | %redefine;'>
<!ENTITY % mgs '%all; | %choice; | %sequence;'>
<!ENTITY % cs '%choice; | %sequence;'>
<!ENTITY % formValues '(qualified|unqualified)'>
<!ENTITY % attrDecls '((%attribute;| %attributeGroup;)*,(%anyAttribute;)?)'>
<!ENTITY % assertions '(%assert;)*'>
<!ENTITY % particleAndAttrs '(%openContent;?, (%mgs; | %group;)?,
%attrDecls;, %assertions;)'>
<!-- This is used in part2 -->
<!ENTITY % restriction1 '(%openContent;?, (%mgs; | %group;)?)'>
%xs-datatypes;
<!-- the duplication below is to produce an unambiguous content model
which allows annotation everywhere -->
<!ELEMENT %schema; ((%composition; | %annotation;)*,
(%defaultOpenContent;, (%annotation;)*)?,
((%simpleType; | %complexType;
| %element; | %attribute;
| %attributeGroup; | %group;
| %notation; ),
(%annotation;)*)* )>
<!ATTLIST %schema;
targetNamespace %URIref; #IMPLIED
version CDATA #IMPLIED
%nds; %URIref; #FIXED 'http://www.w3.org/2001/XMLSchema'
xmlns CDATA #IMPLIED
finalDefault %complexDerivationSet; ''
blockDefault %blockSet; ''
id ID #IMPLIED
elementFormDefault %formValues; 'unqualified'
attributeFormDefault %formValues; 'unqualified'
defaultAttributes CDATA #IMPLIED
xpathDefaultNamespace CDATA '##local'
xml:lang CDATA #IMPLIED
%schemaAttrs;>
<!-- Note the xmlns declaration is NOT in the
schema for schema documents,
because at the Infoset level where schemas operate,
xmlns(:prefix) is NOT an attribute! -->
<!-- The declaration of xmlns is a convenience for schema authors -->
<!-- The id attribute here and below is for use in external references
from non-schemas using simple fragment identifiers.
It is NOT used for schema-to-schema reference, internal or
external. -->
<!ELEMENT %defaultOpenContent; ((%annotation;)?, %any;)>
<!ATTLIST %defaultOpenContent;
appliesToEmpty (true|false) 'false'
mode (interleave|suffix) 'interleave'
id ID #IMPLIED
%defaultOpenContentAttrs;>
<!-- a type is a named content type specification which allows attribute
declarations-->
<!-- -->
<!ELEMENT %complexType; ((%annotation;)?,
(%simpleContent;|%complexContent;|
%particleAndAttrs;))>
<!ATTLIST %complexType;
name %NCName; #IMPLIED
id ID #IMPLIED
abstract %boolean; #IMPLIED
final %complexDerivationSet; #IMPLIED
block %complexDerivationSet; #IMPLIED
mixed (true|false) 'false'
defaultAttributesApply %boolean; 'true'
%complexTypeAttrs;>
<!-- particleAndAttrs is shorthand for a root type -->
<!-- mixed is disallowed if simpleContent, overridden if complexContent has one too. -->
<!-- If anyAttribute appears in one or more referenced attributeGroups
and/or explicitly, the intersection of the permissions is used -->
<!ELEMENT %complexContent; ((%annotation;)?, (%restriction;|%extension;))>
<!ATTLIST %complexContent;
mixed (true|false) #IMPLIED
id ID #IMPLIED
%complexContentAttrs;>
<!ELEMENT %openContent; ((%annotation;)?, (%any;)?)>
<!ATTLIST %openContent;
mode (none|interleave|suffix) 'interleave'
id ID #IMPLIED
%openContentAttrs;>
<!-- restriction should use the branch defined above, not the simple
one from part2; extension should use the full model -->
<!ELEMENT %simpleContent; ((%annotation;)?, (%restriction;|%extension;))>
<!ATTLIST %simpleContent;
id ID #IMPLIED
%simpleContentAttrs;>
<!-- restriction should use the simple branch from part2, not the
one defined above; extension should have no particle -->
<!ELEMENT %extension; ((%annotation;)?, (%particleAndAttrs;))>
<!ATTLIST %extension;
base %QName; #REQUIRED
id ID #IMPLIED
%extensionAttrs;>
<!-- an element is declared by either:
a name and a type (either nested or referenced via the type attribute)
or a ref to an existing element declaration -->
<!ELEMENT %element; ((%annotation;)?, (%complexType;| %simpleType;)?,
(%alternative;)*,
(%unique; | %key; | %keyref;)*)>
<!-- simpleType or complexType only if no type|ref attribute -->
<!-- ref not allowed at top level -->
<!ATTLIST %element;
name %NCName; #IMPLIED
id ID #IMPLIED
ref %QName; #IMPLIED
type %QName; #IMPLIED
minOccurs %nonNegativeInteger; #IMPLIED
maxOccurs CDATA #IMPLIED
nillable %boolean; #IMPLIED
substitutionGroup %QName; #IMPLIED
abstract %boolean; #IMPLIED
final %complexDerivationSet; #IMPLIED
block %blockSet; #IMPLIED
default CDATA #IMPLIED
fixed CDATA #IMPLIED
form %formValues; #IMPLIED
targetNamespace %URIref; #IMPLIED
%elementAttrs;>
<!-- type and ref are mutually exclusive.
name and ref are mutually exclusive, one is required -->
<!-- In the absence of type AND ref, type defaults to type of
substitutionGroup, if any, else xs:anyType, i.e. unconstrained -->
<!-- default and fixed are mutually exclusive -->
<!ELEMENT %alternative; ((%annotation;)?,
(%simpleType; | %complexType;)?) >
<!ATTLIST %alternative;
test CDATA #IMPLIED
type %QName; #IMPLIED
xpathDefaultNamespace CDATA #IMPLIED
id ID #IMPLIED >
<!ELEMENT %group; ((%annotation;)?,(%mgs;)?)>
<!ATTLIST %group;
name %NCName; #IMPLIED
ref %QName; #IMPLIED
minOccurs %nonNegativeInteger; #IMPLIED
maxOccurs CDATA #IMPLIED
id ID #IMPLIED
%groupAttrs;>
<!ELEMENT %all; ((%annotation;)?, (%element;| %group;| %any;)*)>
<!ATTLIST %all;
minOccurs (0 | 1) #IMPLIED
maxOccurs (0 | 1) #IMPLIED
id ID #IMPLIED
%allAttrs;>
<!ELEMENT %choice; ((%annotation;)?, (%element;| %group;| %cs; | %any;)*)>
<!ATTLIST %choice;
minOccurs %nonNegativeInteger; #IMPLIED
maxOccurs CDATA #IMPLIED
id ID #IMPLIED
%choiceAttrs;>
<!ELEMENT %sequence; ((%annotation;)?, (%element;| %group;| %cs; | %any;)*)>
<!ATTLIST %sequence;
minOccurs %nonNegativeInteger; #IMPLIED
maxOccurs CDATA #IMPLIED
id ID #IMPLIED
%sequenceAttrs;>
<!-- an anonymous grouping in a model, or
a top-level named group definition, or a reference to same -->
<!ELEMENT %any; (%annotation;)?>
<!ATTLIST %any;
namespace CDATA #IMPLIED
notNamespace CDATA #IMPLIED
notQName CDATA ''
processContents (skip|lax|strict) 'strict'
minOccurs %nonNegativeInteger; '1'
maxOccurs CDATA '1'
id ID #IMPLIED
%anyAttrs;>
<!-- namespace is interpreted as follows:
##any - - any non-conflicting WFXML at all
##other - - any non-conflicting WFXML from namespace other
than targetNamespace
##local - - any unqualified non-conflicting WFXML/attribute
one or - - any non-conflicting WFXML from
more URI the listed namespaces
references
##targetNamespace ##local may appear in the above list,
with the obvious meaning -->
<!-- notNamespace is interpreted as follows:
##local - - any unqualified non-conflicting WFXML/attribute
one or - - any non-conflicting WFXML from
more URI the listed namespaces
references
##targetNamespace ##local may appear in the above list,
with the obvious meaning -->
<!ELEMENT %anyAttribute; (%annotation;)?>
<!ATTLIST %anyAttribute;
namespace CDATA #IMPLIED
notNamespace CDATA #IMPLIED
notQName CDATA ''
processContents (skip|lax|strict) 'strict'
id ID #IMPLIED
%anyAttributeAttrs;>
<!-- namespace and notNamespace are interpreted as for 'any' above -->
<!-- simpleType only if no type|ref attribute -->
<!-- ref not allowed at top level, name iff at top level -->
<!ELEMENT %attribute; ((%annotation;)?, (%simpleType;)?)>
<!ATTLIST %attribute;
name %NCName; #IMPLIED
id ID #IMPLIED
ref %QName; #IMPLIED
type %QName; #IMPLIED
use (prohibited|optional|required) #IMPLIED
default CDATA #IMPLIED
fixed CDATA #IMPLIED
form %formValues; #IMPLIED
targetNamespace %URIref; #IMPLIED
inheritable %boolean; #IMPLIED
%attributeAttrs;>
<!-- type and ref are mutually exclusive.
name and ref are mutually exclusive, one is required -->
<!-- default for use is optional when nested, none otherwise -->
<!-- default and fixed are mutually exclusive -->
<!-- type attr and simpleType content are mutually exclusive -->
<!-- an attributeGroup is a named collection of attribute decls, or a
reference thereto -->
<!ELEMENT %attributeGroup; ((%annotation;)?,
(%attribute; | %attributeGroup;)*,
(%anyAttribute;)?) >
<!ATTLIST %attributeGroup;
name %NCName; #IMPLIED
id ID #IMPLIED
ref %QName; #IMPLIED
%attributeGroupAttrs;>
<!-- ref iff no content, no name. ref iff not top level -->
<!-- better reference mechanisms -->
<!ELEMENT %unique; ((%annotation;)?, %selector;, (%field;)+)>
<!ATTLIST %unique;
name %NCName; #IMPLIED
ref %QName; #IMPLIED
id ID #IMPLIED
%uniqueAttrs;>
<!ELEMENT %key; ((%annotation;)?, %selector;, (%field;)+)>
<!ATTLIST %key;
name %NCName; #IMPLIED
ref %QName; #IMPLIED
id ID #IMPLIED
%keyAttrs;>
<!ELEMENT %keyref; ((%annotation;)?, %selector;, (%field;)+)>
<!ATTLIST %keyref;
name %NCName; #IMPLIED
ref %QName; #IMPLIED
refer %QName; #IMPLIED
id ID #IMPLIED
%keyrefAttrs;>
<!ELEMENT %selector; ((%annotation;)?)>
<!ATTLIST %selector;
xpath %XPathExpr; #REQUIRED
xpathDefaultNamespace CDATA #IMPLIED
id ID #IMPLIED
%selectorAttrs;>
<!ELEMENT %field; ((%annotation;)?)>
<!ATTLIST %field;
xpath %XPathExpr; #REQUIRED
xpathDefaultNamespace CDATA #IMPLIED
id ID #IMPLIED
%fieldAttrs;>
<!-- co-constraint assertions -->
<!ELEMENT %assert; ((%annotation;)?)>
<!ATTLIST %assert;
test %XPathExpr; #REQUIRED
id ID #IMPLIED
xpathDefaultNamespace CDATA #IMPLIED
%assertAttrs;>
<!-- Schema combination mechanisms -->
<!ELEMENT %include; (%annotation;)?>
<!ATTLIST %include;
schemaLocation %URIref; #REQUIRED
id ID #IMPLIED
%includeAttrs;>
<!ELEMENT %import; (%annotation;)?>
<!ATTLIST %import;
namespace %URIref; #IMPLIED
schemaLocation %URIref; #IMPLIED
id ID #IMPLIED
%importAttrs;>
<!ELEMENT %redefine; (%annotation; | %simpleType; | %complexType; |
%attributeGroup; | %group;)*>
<!ATTLIST %redefine;
schemaLocation %URIref; #REQUIRED
id ID #IMPLIED
%redefineAttrs;>
<!ELEMENT %override; ((%annotation;)?,
((%simpleType; | %complexType; | %group; | %attributeGroup;) |
%element; | %attribute; | %notation;)*)>
<!ATTLIST %override;
schemaLocation %URIref; #REQUIRED
id ID #IMPLIED
%overrideAttrs;>
<!ELEMENT %notation; (%annotation;)?>
<!ATTLIST %notation;
name %NCName; #REQUIRED
id ID #IMPLIED
public CDATA #REQUIRED
system %URIref; #IMPLIED
%notationAttrs;>
<!-- Annotation is either application information or documentation -->
<!-- By having these here they are available for datatypes as well
as all the structures elements -->
<!ELEMENT %annotation; (%appinfo; | %documentation;)*>
<!ATTLIST %annotation; %annotationAttrs;>
<!-- User must define annotation elements in internal subset for this
to work -->
<!ELEMENT %appinfo; ANY> <!-- too restrictive -->
<!ATTLIST %appinfo;
source %URIref; #IMPLIED
id ID #IMPLIED
%appinfoAttrs;>
<!ELEMENT %documentation; ANY> <!-- too restrictive -->
<!ATTLIST %documentation;
source %URIref; #IMPLIED
id ID #IMPLIED
xml:lang CDATA #IMPLIED
%documentationAttrs;>
<!NOTATION XMLSchemaStructures PUBLIC
'structures' 'http://www.w3.org/2001/XMLSchema.xsd' >
<!NOTATION XML PUBLIC
'REC-xml-1998-0210' 'http://www.w3.org/TR/1998/REC-xml-19980210' >
<!--
In keeping with the XML Schema WG's standard versioning policy,
this DTD will persist at the URI
http://www.w3.org/2012/04/XMLSchema.dtd.
At the date of issue it can also be found at the URI
http://www.w3.org/2009/XMLSchema/XMLSchema.dtd.
The schema document at that URI may however change in the future,
in order to remain compatible with the latest version of XSD
and its namespace. In other words, if XSD or the XML Schema
namespace change, the version of this document at
http://www.w3.org/2009/XMLSchema/XMLSchema.dtd will change accordingly;
the version at http://www.w3.org/2012/04/XMLSchema.dtd
will not change.
Previous dated (and unchanging) versions of this DTD include:
http://www.w3.org/2012/01/XMLSchema.dtd
(XSD 1.1 Proposed Recommendation)
http://www.w3.org/2011/07/XMLSchema.dtd
(XSD 1.1 Candidate Recommendation)
http://www.w3.org/2009/04/XMLSchema.dtd
(XSD 1.1 Candidate Recommendation)
http://www.w3.org/2004/10/XMLSchema.dtd
(XSD 1.0 Recommendation, Second Edition)
http://www.w3.org/2001/05/XMLSchema.dtd
(XSD 1.0 Recommendation, First Edition)
-->
J Analysis of the Unique Particle Attribution Constraint (non-normative)
A specification of the import of Unique Particle Attribution (§3.8.6.4) which does not appeal to a processing model is difficult. What follows is intended as guidance, without claiming to be complete.
- They are both element declaration particles whose declarations have the same expanded name.
- They are both element declaration particles and one of them has the same expanded name as an element declaration in the other's ·substitution group·.
- They are both global element declaration particles and their ·substitution groups· contain the same element declaration.
- They are both wildcards, and any one of the following is true of the wildcard intersection of their {namespace constraint}s as defined in Attribute Wildcard Intersection (§3.10.6.4):
- It has {variety} = any.
- It has {variety} = not.
- It has {variety} = enumeration and {namespaces} ≠ the empty set.
- are both in the {particles} of a choice or all group
Two particles may ·validate· adjacent information items if they are separated by at most epsilon transitions in the most obvious transcription of a content model into a finite-state automaton.
A precise formulation of this constraint can also be offered in terms of operations on finite-state automaton: transcribe the content model into an automaton in the usual way using epsilon transitions for optionality and unbounded maxOccurs, unfolding other numeric occurrence ranges and treating the heads of ·substitution groups· as if they were choices over all elements in the group, but using not element QNames as transition labels, but rather pairs of element QNames and positions in the model. Determinize this automaton, treating wildcard transitions as if they were distinct from all other edge labels for the purposes of the determinization. Now replace all QName+position transition labels with the element QNames alone. If the result has any states with two or more identical-QName-labeled transitions from it, or two wildcard transitions whose intentional intersection is non-empty, the model does not satisfy the Unique Attribution constraint.
K XSD Language Identifiers (non-normative)
This section defines identifiers for various versions of XSD, including versions defined in superseded drafts, to enable precise reference to versions when such reference is necessary.
http://www.w3.org/XML/XMLSchemahttp://www.w3.org/XML/XMLSchema/v1.0http://www.w3.org/XML/XMLSchema/v1.1http://www.w3.org/XML/XMLSchema/v1.0/1ehttp://www.w3.org/XML/XMLSchema/v1.0/2ehttp://www.w3.org/XML/XMLSchema/v1.1/1ehttp://www.w3.org/XML/XMLSchema/v1.0/1e/19990506http://www.w3.org/XML/XMLSchema/v1.0/1e/19990924http://www.w3.org/XML/XMLSchema/v1.0/1e/19991105http://www.w3.org/XML/XMLSchema/v1.0/1e/19991217http://www.w3.org/XML/XMLSchema/v1.0/1e/20000225http://www.w3.org/XML/XMLSchema/v1.0/1e/20000407http://www.w3.org/XML/XMLSchema/v1.0/1e/20000922http://www.w3.org/XML/XMLSchema/v1.0/1e/20001024http://www.w3.org/XML/XMLSchema/v1.0/1e/20010316http://www.w3.org/XML/XMLSchema/v1.0/1e/20010330http://www.w3.org/XML/XMLSchema/v1.0/1e/20010502http://www.w3.org/XML/XMLSchema/v1.0/2e/20040318http://www.w3.org/XML/XMLSchema/v1.0/2e/20041028http://www.w3.org/XML/XMLSchema/v1.1/1e/20040716http://www.w3.org/XML/XMLSchema/v1.1/1e/20050224http://www.w3.org/XML/XMLSchema/v1.1/1e/20060116http://www.w3.org/XML/XMLSchema/v1.1/1e/20060217http://www.w3.org/XML/XMLSchema/v1.1/1e/20060330http://www.w3.org/XML/XMLSchema/v1.1/1e/20060831http://www.w3.org/XML/XMLSchema/v1.1/1e/20070830http://www.w3.org/XML/XMLSchema/v1.1/1e/20080620http://www.w3.org/XML/XMLSchema/v1.1/1e/20090130http://www.w3.org/XML/XMLSchema/v1.1/1e/20090430http://www.w3.org/XML/XMLSchema/v1.1/1e/20091203http://www.w3.org/XML/XMLSchema/v1.1/1e/20110721http://www.w3.org/XML/XMLSchema/v1.1/1e/20120119http://www.w3.org/XML/XMLSchema/v1.1/1e/20120405L References
L.1 Normative
The following documents, in whole or in part, contain provisions which must be consulted in order to understand fully or to implement some of the normative provisions of this specification.
- Functions and Operators
- World Wide Web Consortium. XQuery 1.0 and XPath 2.0 Functions and Operators (Second Edition), ed. Ashok Malhotra, Jim Melton, and Norman Walsh. W3C Recommendation 14 December 2010. See http://www.w3.org/TR/xpath-functions/ The edition cited is the one current at the date of publication of this specification. Implementations may follow the edition cited and/or any later edition(s); it is implementation-defined which.
- IETF RFC 2119
- Bradner, Scott. RFC 2119: Key words for use in RFCs to Indicate Requirement Levels. IETF (Internet Engineering Task Force), 1997. See http://www.ietf.org/rfc/rfc2119.txt.
- Namespaces in XML 1.0
- World Wide Web Consortium. Namespaces in XML 1.0 (Third Edition), ed. Tim Bray et al. W3C Recommendation 8 December 2009. See http://www.w3.org/TR/xml-names/ The edition cited is the one current at the date of publication of this specification. Implementations may follow the edition cited and/or any later edition(s); it is implementation-defined which. For details of the dependency of this specification on Namespaces in XML 1.0, see Dependencies on Other Specifications (§1.4).
- XDM
- World Wide Web Consortium. XQuery 1.0 and XPath 2.0 Data Model (XDM) (Second Edition), ed. Mary Fernández et al. W3C Recommendation 14 December 2010. See http://www.w3.org/TR/xpath-datamodel/ The edition cited is the one current at the date of publication of this specification. Implementations may follow the edition cited and/or any later edition(s); it is implementation-defined which.
- XML 1.0
- World Wide Web Consortium. Extensible Markup Language (XML) 1.0 (Fifth Edition), ed. Tim Bray et al. W3C Recommendation 26 November 2008. Available at http://www.w3.org/TR/xml/ The edition cited is the one current at the date of publication of this specification. Implementations may follow the edition cited and/or any later edition(s); it is implementation-defined which. For details of the dependency of this specification on XML 1.1, see Dependencies on Other Specifications (§1.4).
- XML 1.1
- World Wide Web Consortium. Extensible Markup Language (XML) 1.1 (Second Edition), ed. Tim Bray et al. W3C Recommendation 16 August 2006, edited in place 29 September 2006. Available at http://www.w3.org/TR/xml11/ The edition cited is the one current at the date of publication of this specification. Implementations may follow the edition cited and/or any later edition(s); it is implementation-defined which. For details of the dependency of this specification on XML 1.1, see Dependencies on Other Specifications (§1.4).
- XML Infoset
- World Wide Web Consortium. XML Information Set (Second Edition), ed. John Cowan and Richard Tobin W3C Recommendation 4 February 2004. Available at http://www.w3.org/TR/xml-infoset/ The edition cited is the one current at the date of publication of this specification. Implementations may follow the edition cited and/or any later edition(s); it is implementation-defined which.
- XML Namespaces 1.1
- World Wide Web Consortium. Namespaces in XML 1.1 (Second Edition), ed. Tim Bray et al. W3C Recommendation 16 August 2006. Available at: http://www.w3.org/TR/xml-names11/ The edition cited is the one current at the date of publication of this specification. Implementations may follow the edition cited and/or any later edition(s); it is implementation-defined which. For details of the dependency of this specification on Namespaces in XML 1.1, see Dependencies on Other Specifications (§1.4).
- XML Schema: Datatypes
- World Wide Web Consortium. XML Schema Version 1.1 Part 2: Datatypes, ed. Dave Peterson, Paul V. Biron and Ashok Malhotra, and C. M. Sperberg-McQueen W3C Recommendation 5 April 2012. See http://www.w3.org/TR/2012/REC-xmlschema11-2-20120405/datatypes.html The edition cited is the one current at the date of publication of this specification. Implementations may follow the edition cited and/or any later edition(s); it is implementation-defined which.
- XPath 2.0
- World Wide Web Consortium. XML Path Language 2.0 (Second Edition), ed. Anders Berglund et al. W3C Recommendation 14 December 2010 (Link errors corrected 3 January 2011). See http://www.w3.org/TR/xpath20/ The edition cited is the one current at the date of publication of this specification. Implementations may follow the edition cited and/or any later edition(s); it is implementation-defined which.
- XSLT 2.0
- World Wide Web Consortium. XSL Transformations (XSLT) Version 2.0, ed. Michael Kay. W3C Recommendation 23 January 2007. See http://www.w3.org/TR/xslt20/ The edition cited is the one current at the date of publication of this specification. Implementations may follow the edition cited and/or any later edition(s); it is implementation-defined which.
L.2 Non-normative
- Brüggemann-Klein / Wood 1998
- Brüggemann-Klein, Anne, and Derick Wood. One-Unambiguous Regular Languages. Information and Computation 140 (1998): 229-253. Also appears as 142 (1998): 182-206.
- DCD
- Bray, Tim, Charles Frankston, and Ashok Malhotra, ed., Document Content Description for XML (DCD). Submission to the World Wide Web Consortium 31-July-1998. [A submission to W3C from International Business Machines Corporation and Microsoft Corporation.] See http://www.w3.org/TR/1998/NOTE-dcd-19980731
- DDML
- Bourret, Ronald, et al., ed., Document Definition Markup Language (DDML) Specification, Version 1.0. W3C Note, 19-Jan-1999. [A submission to W3C from GMD - Forschungszentrum Informationstechnik GmbH.] See http://www.w3.org/TR/1999/NOTE-ddml-19990119
- Requirements for XML Schema 1.1
- World Wide Web Consortium. Requirements for XML Schema 1.1, ed. Charles Campbell, Ashok Malhotra, and Priscilla Walmsley. W3C, 21 January 2003. See http://www.w3.org/TR/xmlschema-11-req/
- Rule of Least Power
- The Rule of Least Power, ed. Tim Berners-Lee and Noah Mendelsohn. W3C TAG Finding 23 February 2006. See http://www.w3.org/2001/tag/doc/leastPower.html.
- SOX
- Fuchs, Matthew, Murray Maloney, and Alex Milowski. Schema for Object-oriented XML. Submitted to W3C 19980915. [A submission to W3C by Veo Systems Inc.] See http://www.w3.org/TR/1998/NOTE-SOX-19980930/
- SOX-2
- Davidson, Andrew, et al. Schema for Object-oriented XML 2.0. See http://www.w3.org/TR/NOTE-SOX/
- SchemaPath
- Marinelli, Paolo, Claudio Sacerdoti Coen, and Fabio Vitali. SchemaPath, a Minimal Extension to XML Schema for Conditional Constraints. In Proceedings of the Thirteenth International World Wide Web Conference, New York: ACM Press, 2004, pp. 164-174. Available on the Web in the ACM Digital Library; citation at http://dl.acm.org/citation.cfm?doid=988672.988695.
- UAAG 1.0
- World Wide Web Consortium. User Agent Accessibility Guidelines 1.0, ed. Ian Jacobs, Jon Gunderson, and Eric Hansen. W3C Recommendation 17 December 2002. See http://www.w3.org/TR/UAAG10/.
- UAAG 2.0
- World Wide Web Consortium. User Agent Accessibility Guidelines (UAAG) 2.0, ed. James Allan, Kelly Ford, and Jeanne Spellman. W3C Working Draft 19 July 2011. See http://www.w3.org/TR/UAAG20/.
- XDR
- Frankston, Charles, and Henry S. Thompson. XML-Data Reduced, 3 July 1998. ["This note is a refinement of the January 1998 XML-Data submission http://www.w3.org/TR/1998/NOTE-XML-data-0105/."] See http://www.ltg.ed.ac.uk/~ht/XMLData-Reduced.htm
- XML Schema Requirements
- World Wide Web Consortium. XML Schema Requirements , ed. Ashok Malhotra and Murray Maloney W3C Note 15 February 1999. See http://www.w3.org/TR/NOTE-xml-schema-req
- XML Schema: Component Designators
- World Wide Web Consortium. XML Schema: Component Designators, ed. Mary Holstege and Asir Vedamuthu. W3C Candidate Recommendation 19 January 2010. See http://www.w3.org/TR/xmlschema-ref/.
- XML Schema: Primer
- World Wide Web Consortium. XML Schema Part 0: Primer Second Edition, ed. Priscilla Walmsley and and David C. Fallside.W3C Recommendation 28 October 2004. See http://www.w3.org/TR/xmlschema-0/
- XML-Data
- Layman, Andrew, et al. XML-Data. W3C Note 05 Jan 1998. [A submission to W3C by Microsoft, ArborText, DataChannel, and Inso.] See http://www.w3.org/TR/1998/NOTE-XML-data-0105/
- XPath 1.0
- World Wide Web Consortium. XML Path Language, ed. James Clark and Steve DeRose W3C Recommendation 16 November 1999. See http://www.w3.org/TR/xpath/
- XPointer
- World Wide Web Consortium. XPointer Framework, ed. Paul Grosso et al. W3C Recommendation 25 March 2003. See http://www.w3.org/TR/xptr-framework/
- XSD 1.0 2E
- World Wide Web Consortium. XML Schema Part 1: Structures Second Edition, ed. Henry S. Thompson et al. W3C Recommendation 28 October 2004. See http://www.w3.org/TR/xmlschema-1/.
M Acknowledgements (non-normative)
The following contributed material to version 1.0 of this specification:
David Fallside, IBM
Scott Lawrence, Agranat Systems
Andrew Layman, Microsoft
Eve L. Maler, Sun Microsystems
Asir S. Vedamuthu, webMethods, Inc
The Working Group thanks the members of other W3C Working Groups and industry experts in other forums who have contributed directly or indirectly to the creation of this document and its predecessor.
Since version 1.0 of this specification was completed, David Beech and Noah Mendelsohn have retired from the corporations which supported their work as editors. The email addresses given for them are those known at the time this document was published.
The work of C. M. Sperberg-McQueen as a co-editor of this specification was supported by the World Wide Web Consortium through January 2009 and again from June 2010 through May 2011, and from February 2009 to the present by Black Mesa Technologies LLC.
At the time this document is published, the members in good standing of the XML Schema Working Group are:
- David Ezell, National Association of Convenience Stores (NACS) (chair)
- Shudi (Sandy) Gao 高殊镝, IBM
- Mary Holstege, Mark Logic
- Sam Idicula, Oracle Corporation
- Michael Kay, Invited expert
- Jim Melton, Oracle Corporation
- Dave Peterson, Invited expert
- Liam Quin, W3C (staff contact)
- C. M. Sperberg-McQueen, invited expert
- Henry S. Thompson, University of Edinburgh
- Kongyi Zhou, Oracle Corporation
The XML Schema Working Group has benefited in its work from the participation and contributions of a number of people who are no longer members of the Working Group in good standing at the time of publication of this Working Draft. Their names are given below. In particular we note with sadness the accidental death of Mario Jeckle shortly before publication of the first Working Draft of XML Schema 1.1. Affiliations given are (among) those current at the time of the individuals' work with the WG.
- Paula Angerstein, Vignette Corporation
- Leonid Arbouzov, Sun Microsystems
- Jim Barnette, Defense Information Systems Agency (DISA)
- David Beech, Oracle Corp.
- Gabe Beged-Dov, Rogue Wave Software
- Laila Benhlima, Ecole Mohammadia d'Ingenieurs Rabat (EMI)
- Doris Bernardini, Defense Information Systems Agency (DISA)
- Paul V. Biron, HL7; Invited expert
- Don Box, DevelopMentor
- Allen Brown, Microsoft
- Lee Buck, TIBCO Extensibility
- Greg Bumgardner, Rogue Wave Software
- Dean Burson, Lotus Development Corporation
- Charles E. Campbell, Invited expert
- Oriol Carbo, University of Edinburgh
- Wayne Carr, Intel
- Peter Chen, Bootstrap Alliance and LSU
- Tyng-Ruey Chuang, Academia Sinica
- Tony Cincotta, NIST
- David Cleary, Progress Software
- Mike Cokus, MITRE
- Dan Connolly, W3C (staff contact)
- Ugo Corda, Xerox
- Roger L. Costello, MITRE
- Joey Coyle, Health Level Seven
- Haavard Danielson, Progress Software
- Josef Dietl, Mozquito Technologies
- Kenneth Dolson, Defense Information Systems Agency (DISA)
- Andrew Eisenberg, Progress Software
- Rob Ellman, Calico Commerce
- Tim Ewald, Developmentor
- Alexander Falk, Altova GmbH
- David Fallside, IBM
- George Feinberg, Object Design
- Dan Fox, Defense Logistics Information Service (DLIS)
- Charles Frankston, Microsoft
- Matthew Fuchs, Commerce One
- Andrew Goodchild, Distributed Systems Technology Centre (DSTC Pty Ltd)
- Xan Gregg, TIBCO Extensibility
- Paul Grosso, Arbortext, Inc
- Martin Gudgin, DevelopMentor
- Ernesto Guerrieri, Inso
- Dave Hollander, Hewlett-Packard Company (co-chair)
- Nelson Hung, Corel
- Jane Hunter, Distributed Systems Technology Centre (DSTC Pty Ltd)
- Michael Hyman, Microsoft
- Renato Iannella, Distributed Systems Technology Centre (DSTC Pty Ltd)
- Mario Jeckle, DaimlerChrysler
- Rick Jelliffe, Academia Sinica
- Marcel Jemio, Data Interchange Standards Association
- Simon Johnston, Rational Software
- Kohsuke Kawaguchi, Sun Microsystems
- Dianne Kennedy, Graphic Communications Association
- Janet Koenig, Sun Microsystems
- Setrag Khoshafian, Technology Deployment International (TDI)
- Melanie Kudela, Uniform Code Council
- Ara Kullukian, Technology Deployment International (TDI)
- Andrew Layman, Microsoft
- Dmitry Lenkov, Hewlett-Packard Company
- Bob Lojek, Mozquito Technologies
- John McCarthy, Lawrence Berkeley National Laboratory
- Matthew MacKenzie, XML Global
- Nan Ma, China Electronics Standardization Institute
- Eve Maler, Sun Microsystems
- Ashok Malhotra, IBM; Microsoft; Oracle
- Murray Maloney, Muzmo Communication, acting for Commerce One
- Paolo Marinelli, University of Bologna
- Lisa Martin, IBM
- Noah Mendelsohn, Lotus, IBM, invited expert
- Adrian Michel, Commerce One
- Alex Milowski, Invited expert
- Don Mullen, TIBCO Extensibility
- Ravi Murthy, Oracle
- Murata Makoto, Xerox
- Chris Olds, Wall Data
- Frank Olken, Lawrence Berkeley National Laboratory
- David Orchard, BEA Systems, Inc.
- Paul Pedersen, Mark Logic Corporation
- Shriram Revankar, Xerox
- Mark Reinhold, Sun Microsystems
- Jonathan Robie, Software AG
- Cliff Schmidt, Microsoft
- John C. Schneider, MITRE
- Eric Sedlar, Oracle Corp.
- Lew Shannon, NCR
- Anli Shundi, TIBCO Extensibility
- William Shea, Merrill Lynch
- Jerry L. Smith, Defense Information Systems Agency (DISA)
- John Stanton, Defense Information Systems Agency (DISA)
- Tony Stewart, Rivcom
- Bob Streich, Calico Commerce
- William K. Stumbo, Xerox
- Hoylen Sue, Distributed Systems Technology Centre (DSTC Pty Ltd)
- Ralph Swick, W3C
- John Tebbutt, NIST
- Ross Thompson, Contivo
- Matt Timmermans, Microstar
- Jim Trezzo, Oracle Corp.
- Steph Tryphonas, Microstar
- Scott Tsao, The Boeing Company
- Mark Tucker, Health Level Seven
- Asir S. Vedamuthu, webMethods, Inc
- Fabio Vitali, University of Bologna
- Scott Vorthmann, TIBCO Extensibility
- Priscilla Walmsley, XMLSolutions
- Norm Walsh, Sun Microsystems
- Cherry Washington, Defense Information Systems Agency (DISA)
- Aki Yoshida, SAP AG
- Stefano Zacchiroli, University of Bologna
- Mohamed Zergaoui, Innovimax