Copyright © 2002 W3C® (MIT, INRIA, Keio), All Rights Reserved. W3C liability, trademark, document use, and software licensing rules apply.
This document defines the formal semantics of XQuery 1.0 [XQuery 1.0: A Query Language for XML] and XPath 2.0 [XML Path Language (XPath) 2.0].
This is a public W3C Working Draft for review by W3C Members and other interested parties. This section describes the status of this document at the time of its publication. It is a draft document and may be updated, replaced, or obsoleted by other documents at any time. It is inappropriate to use W3C Working Drafts as reference material or to cite them as other than "work in progress." A list of current public W3C technical reports can be found at http://www.w3.org/TR/.
This document is a work in progress. It contains many open issues, and should not be considered to be fully stable. Vendors who wish to create preview implementations based on this document do so at their own risk. While this document reflects the general consensus of the working groups, there are still controversial areas that may be subject to change.
Among the most important changes from the previous version of this document are:
The addition of the semantics of XPath 2.0 (notably changes in Section [5.2 Path Expressions]).
A new type system aligned with [XML Schema] (see Section [3 The XQuery Type System] and the new Section [8 Importing Schemas]).
The semantics of constructors (see Section [5.7 Constructors]).
An improved presentation (notably revisions to Section [2 Preliminaries]).
A complete list of issues is maintained in [C Issues]. The following are identified as high priority issues.
This document is not aligned with the other XQuery and XPath documents that include information about error handling and conformance levels. See [Issue-0094: Static type errors and warnings], [Issue-0098: Implementation of and conformance levels for static type checking], [Issue-0171: Raising errors], and [Issue-0169: Conformance Levels].
The semantics of sort by are still under discussion. See [Issue-0109: Semantics of sortby].
The current semantics does not completely cover all functions. Some functions used in the Formal Semantics, or some functions from the [XQuery 1.0 and XPath 2.0 Functions and Operators] document need additional semantics specification. See [Issue-0135: Semantics of special functions].
Public comments on this document and its open issues are welcome. Comments should be sent to the W3C XPath/XQuery mailing list, public-qt-comments@w3.org (archived at http://lists.w3.org/Archives/Public/public-qt-comments/).
XQuery 1.0, XPath 2.0, and their formal semantics has been defined jointly by the XML Query Working Group (part of the XML Activity) and the XSL Working Group (part of the Style Activity).
Patent disclosures relevant to this specification may be found on the XML Query Working Group's patent disclosure page at http://www.w3.org/2002/08/xmlquery-IPR-statements and the XSL Working Group's patent disclosure page at http://www.w3.org/Style/XSL/Disclosures.
1 Introduction
2 Preliminaries
2.1 Processing model
2.2 Namespaces
2.3 Data Model
2.3.1 Data model overview
2.3.2 Node identity
2.3.3 Document order and sequence order
2.3.4 Type annotations
2.4 Schemas and types
2.4.1 The elements of a (statically) typed language
2.4.2 XML Schema and the XQuery type system
2.4.3 Structural and named typing
2.4.4 Subtyping
2.4.4.1 Type substitutability
2.4.4.2 Subtyping and XML Schema derivation
2.5 Functions
2.5.1 Functions and operators
2.5.2 Functions and static typing
2.5.3 The error function
2.5.4 Data Model Accessors and XPath Axes
2.5.5 Other Formal Semantics functions
2.6 Notations
2.6.1 Grammar productions
2.6.2 Judgments
2.6.3 Inference rules
2.6.4 Environments
2.6.5 Putting it together
2.7 The Formal Semantics
2.7.1 Normalization
2.7.2 Static type inference
2.7.3 Dynamic Evaluation
3 The XQuery Type System
3.1 Values and Types
3.1.1 Values
3.1.2 Types
3.1.3 Top level definitions
3.1.4 Built-in type declarations
3.1.5 Syntactic constraints on types
3.1.6 Example
3.2 Auxiliary judgments
3.2.1 Derivation and substitution
3.2.1.1 Derives
3.2.1.2 Substitutes
3.2.2 Extension
3.2.3 Mixed content
3.2.4 Adjusts
3.2.5 Resolution
3.2.6 Derives
3.2.7 Lookup
3.2.8 Interleaving
3.2.9 Filtering
3.3 Matching
3.3.1 Nil-matches
3.3.2 Matches
3.3.3 Optimized matching
3.4 Erase and Annotate
3.4.1 Erasure
3.4.1.1 Simply erases
3.4.1.2 Erases
3.4.2 Annotate
3.4.2.1 Simply annotate
3.4.2.2 Nil-annotate
3.4.2.3 Annotate
3.5 Subtyping
3.5.1 Subtype
3.5.2 Type equivalence
3.6 Auxiliary typing judgments for for,
unordered, and sortby
expressions
3.6.1 Prime types
3.6.2 Computing Prime Types and Occurrence Indicators
3.7 Auxiliary typing judgments for typeswitch
expressions
3.7.1 Computing common types and occurrence in typeswitch
3.7.2 Computing Common Prime Types and Occurrence
Indicators
3.8 Major type issues
4 Basics
4.1 Expression Context
4.1.1 Static Context
4.1.2 Evaluation Context
4.2 Input Functions
4.3 Expression Processing
4.4 Types
4.4.1 Type Checking
4.4.2 SequenceType
4.4.3 Type Conversions
4.4.3.1 Atomization
4.4.3.2 Effective Boolean Value
4.4.3.3 Fallback Conversion
4.5 Errors and Conformance
5 Expressions
5.1 Primary Expressions
5.1.1 Literals
5.1.2 Variables
5.1.3 Parenthesized Expressions
5.1.4 Function Calls
5.1.5 Comments
5.2 Path Expressions
5.2.1 Steps
5.2.1.1 Axes
5.2.1.2 Node Tests
5.2.2 Predicates
5.2.3 Unabbreviated Syntax
5.2.4 Abbreviated Syntax
5.3 Sequence Expressions
5.3.1 Constructing Sequences
5.3.2 Combining Sequences
5.4 Arithmetic Expressions
5.5 Comparison Expressions
5.5.1 Value Comparisons
5.5.2 General Comparisons
5.5.3 Node Comparisons
5.5.4 Order Comparisons
5.6 Logical Expressions
5.7 Constructors
5.7.1 Element Constructors
5.7.2 Computed Element and Attribute Constructors
5.7.2.1 Computed Element Nodes
5.7.2.2 Constructed Attribute Nodes
5.7.3 Whitespace in Constructors
5.7.4 Other Constructors and Comments
5.8 [For/FLWR] Expressions
5.8.1 FLWR expressions
5.8.2 For expression
5.8.3 Let Expression
5.9 Order-Related Expressions
5.9.1 Sorting Expressions
5.9.2 Unordered Expressions
5.10 Conditional Expressions
5.11 Quantified Expressions
5.12 Expressions on SequenceTypes
5.12.1 Instance Of
5.12.2 Typeswitch
5.12.3 Cast and Treat
5.12.3.1 Cast as
5.12.3.2 Treat as
5.13 Validate Expressions
6 The Query Prolog
6.1 Namespace Declarations
6.2 Schema Imports
6.3 Xmlspace Declaration
6.4 Default Collation
6.5 Function Definitions
7 Additional Semantics of Functions
7.1 Formal Semantics Functions
7.1.1 The fs:characters-to-string function
7.1.2 The fs:distinct-doc-order function
7.1.3 The fs:item-sequence-to-node-sequence function
7.1.4 The fs:item-sequence-to-string function
7.2 Functions with specific typing rules
7.2.1 The xf:error function
7.2.2 The xf:distinct-nodes, and
xf:distinct-values functions
7.2.3 The op:union, op:intersect and
op:except operators
7.2.4 The op:to operator
7.2.5 The xf:data function
8 Importing Schemas
8.1 Introduction
8.1.1 Features
8.1.2 Organization
8.1.3 Main mapping rules
8.1.4 Special attributes
8.1.4.1 use
8.1.4.2 minOccurs and maxOccurs
8.1.4.3 mixed
8.1.4.4 nillable
8.1.4.5 substitutionGroup
8.2 Attribute Declarations
8.2.1 Global attributes declarations
8.2.2 Local attribute declarations
8.3 Element Declarations
8.3.1 Global element declarations
8.3.2 Local element declarations
8.4 Complex Type Definitions
8.4.1 Global complex type
8.4.2 Local complex type
8.4.3 Complex type with simple content
8.4.4 Complex type with complex content
8.5 Attribute Uses
8.6 Attribute Group Definitions
8.6.1 Attribute group definitions
8.6.2 Attribute group reference
8.7 Model Group Definitions
8.8 Model Groups
8.8.1 All groups
8.8.2 Choice groups
8.8.3 Sequence groups
8.9 Particles
8.9.1 Element reference
8.9.2 Group reference
8.10 Wildcards
8.10.1 Attribute wildcards
8.10.2 Element wildcards
8.11 Identity-constraint Definitions
8.12 Notation Declarations
8.13 Annotation
8.14 Simple Type Definitions
8.14.1 Global simple type definition
8.14.2 Local simple type definition
8.14.3 Simple type content
8.15 Schemas as a whole
8.15.1 Schema
8.15.2 Include
8.15.3 Redefine
8.15.4 Import
A Normalized core grammar
A.1 Core lexical structure
A.1.1 Syntactic Constructs
A.2 Core BNF
B References
B.1 Normative References
B.2 Non-normative References
B.3 Background References
C Issues
C.1 Introduction
C.2 Issues list
C.3 Alphabetic list of issues
C.3.1 Open Issues
C.3.2 Resolved (or redundant) Issues
C.4 Delegated Issues
C.4.1 XPath 2.0
C.4.2 XQuery
C.4.3 Operators
This document defines the formal semantics of XQuery 1.0 and XPath 2.0. The present document is part of a set of documents that together define the XQuery 1.0 and XPath 2.0 languages:
[XQuery 1.0: A Query Language for XML] introduces the XQuery 1.0 language, defines its capabilities from a user-centric view, and defines the language syntax.
[XML Path Language (XPath) 2.0] introduces the XPath 2.0 language, defines its capabilities from a user-centric view, and defines the language syntax.
[XQuery 1.0 and XPath 2.0 Data Model] formally specifies the data model used by [XPath/XQuery] to represent the content of XML documents. The [XPath/XQuery] language is formally defined by operations on this data model.
[XQuery 1.0 and XPath 2.0 Functions and Operators] lists the functions and operators defined for the [XPath/XQuery] language and specifies to which arguments they can be applied and what the result should be.
Ed. Note: [Kristoffer/XSL] The role of the formal semantics document could be clarified: does it supplement or subsume the language specification in case of conflict?
The scope and goals for the [XPath/XQuery] language are discussed in the charter of the W3C [XSL/XML Query] Working Group and in the [XPath/XQuery] requirements [XML Query 1.0 Requirements].
[XPath/XQuery] is a powerful language, capable of selecting and extracting complex patterns from XML documents , reformulating them into results in arbitrary ways, and computing expressions over the result. This document defines the semantics of [XPath/XQuery] by giving a precise formal meaning to each of the constructions of the [XPath/XQuery] specification in terms of the [XPath/XQuery] data model. This document assumes that the reader is already familiar with the [XPath/XQuery] language.
Two important design aspects of [XPath/XQuery] are that it is functional and that it is typed. These two aspects play an important role in the [XPath/XQuery] Formal Semantics.
[XPath/XQuery] is a functional language. It is built from expressions, rather than statements. Every construct in the language (except for the query prolog) is an expression and expressions can be composed arbitrarily. The result of one expression can be used as the input to any other expression, as long as the type of the result of the former expression is compatible with the input type of the latter expression with which it is composed. Another aspect of the functional approach is that variables are always passed by value and their value cannot be modified through side-effects.
[XPath/XQuery] is a typed language. Types can be imported from
one or more XML Schemas describing the documents that will be
processed, and the [XPath/XQuery] language can then perform operations
based on these types (e.g., using a treat as
operation). In addition, [XPath/XQuery] also supports a level of
static type analysis. This means that the system can
perform infer the type of a [expression/query], based on the type of its
inputs. Static typing allows early error detection, and can be used
as the basis for certain forms of optimization. The type system of
[XPath/XQuery] is based on [XML Schema]. The [XPath/XQuery] type system
models most of the features of [XML Schema Part 1], including global and
local element and attribute declarations, complex and simple type
definitions, named and anonymous types, derivation by restriction,
extension, list and union, substitution groups, and wildcard
types. It does not model uniqueness constraints and facet
constraints on simple types. The main issues with respect to the
[XPath/XQuery] type system are discussed in [3.8 Major type issues].
The [XPath/XQuery] formal semantics builds on long-standing traditions in the database and in the programming languages communities. In particular, the [XPath/XQuery] formal semantics has been inspired by works on SQL [SQL], OQL [ODMG], [BKD90], [CM93], and nested relational algebra (NRA) [BNTW95], [Col90], [LW97], [LMW96]. Other references include Quilt [Quilt], UnQL [BFS00], XDuce [HP2000], XML-QL [XMLQL99], XPath 1.0 [XML Path Language (XPath) : Version 1.0], XQL [XQL99], XSLT [XSLT 99], and YATL [YAT99]. Additional related work can be found in the bibliography [B References].
This document is organized as follows. [2 Preliminaries] introduces notations used to define the [XPath/XQuery] formal semantics. [3 The XQuery Type System] describes the [XPath/XQuery] type system, operations on the [XPath/XQuery] type system, and explains the relationship between the [XPath/XQuery] type system and XML Schema. [4 Basics] describes semantics for basic [XPath/XQuery] concepts, and [5 Expressions], describes the dynamic and static semantics of [XPath/XQuery] expressions. [6 The Query Prolog] describes the semantics of the [XPath/XQuery] prolog. [7 Additional Semantics of Functions] describes any additional semantics required for [XPath/XQuery] functions. Finally, [8 Importing Schemas], specifies how XML Schemas are imported into the [XPath/XQuery] type system.
This section provides the background necessary to understand the [XPath/XQuery] Formal Semantics and introduces the notations that are used.
First, a processing model for [expression/query] evaluation is defined. This processing model is not intended to describe an actual implementation, although a naive implementation might be based upon it. It does not prescribe an implementation technique, but any implementation should produce the same results as obtained by following this processing model and applying the rest of the Formal Semantics specification.
The processing model consists of five phases; each phase consumes the result of the previous phase and generates output for the next phase. For each processing phase, we furthermore point to the relevant notations introduced later in the document.
Parsing. The grammar for the [XPath/XQuery] syntax is defined in [XQuery 1.0: A Query Language for XML]. Parsing may generate syntax errors. If no error occurs, an internal representation of the parsed syntax tree corresponding to the query is created: this ensures that we can unambiguously specify the following phases by a case per syntax production.
Context Processing. The semantics of [expression/query] depends on the input context. The input context needs to be generated before the [expression/query] can be processed. In XQuery, the input context is described in the Query Prolog (See [6 The Query Prolog]). In XPath, the input context is generated by the processing environment. The input context is split in a static and a dynamic part (denoted statEnv and dynEnv, respectively).
Normalization. To
simplify the semantics specification, some normalization
must first be performed over the [expression/query]. The
[XPath/XQuery] language provides many powerful features that
make [expression/query]s simpler to write and use, but are also
redundant. For instance, a complex for
expression might be rewritten as a composition of several
simple for
expressions. The language composed
of these simpler [expression/query] is called the [XPath/XQuery]
Core language and is a subset of the complete
[XPath/XQuery] language. The grammar of the [XPath/XQuery] Core
language is given in [A Normalized core grammar].
During the normalization phase, each [XPath/XQuery] [expression/query] is mapped into its equivalent [expression/query] in the core. (Note that this has nothing to do with Unicode Normalization, which works on character strings.) Normalization works by bottom-up application of normalization rules over expressions, starting with normalization of literals.
Specifically the normalization phase is defined in terms of the static part of the context (statEnv) and a [expression/query] (Expr) abstract syntax tree. Formal notations for the normalization phase are introduced in [2.7.1 Normalization].
After normalization, the full semantics can be obtained just by giving a semantics to the normalized Core [expression/query]. This is done during the last two phases.
Static type analysis. Static type analysis checks whether each [expression/query] is type safe, and if so, determines its static type. Static type analysis is defined only for Core [expression/query]. Static type analysis works by bottom-up application of type inference rules over expressions, taking the type of literals and the known types of input documents into account.
If the [expression/query] is not type-safe, static type analysis can result in a static error. For instance, a comparison between an integer value and a string value might be detected as an error during the static type analysis. If static type analysis succeeds, it results in a syntax tree where each sub-expression is "decorated" with its static type, and in an output type for the result of the [expression/query].
More precisely the static analysis phase is defined in terms of the static context (statEnv) and a core [expression/query] (CoreExpr). Formal notations for the static analysis phase are introduced in [2.7.2 Static type inference].
Static typing does not imply that the content of XML documents must be rigidly fixed or even known in advance. The [XPath/XQuery] type system accommodates "flexible" types, such as elements that can contain any content. Schema-less documents are handled in [XPath/XQuery] by associating a standard type with the document, such that it may include any legal XML content.
Dynamic Evaluation. This is the phase in which the result of the [expression/query] is computed. The semantics of evaluation is defined only for Core [expression/query] terms. Evaluation works by bottom-up application of evaluation rules over expressions, starting with evaluation of literals. This guarantees that every expression can be unambiguously reduced to a value, which is the final result of the [expression/query].
The dynamic evaluation phase is defined in terms of the static context (statEnv) and evaluation context (), and a core [expression/query] (CoreExpr). Formal notations for the dynamic evaluation phase are introduced in [2.7.3 Dynamic Evaluation].
Ed. Note: Issue:[Kristoffer/XSL] The distinction between errors manifest by not being able to prove a judgment and special error values is not clear. Also the processing model does not allow for skipping static typing. See [Issue-0094: Static type errors and warnings], [Issue-0171: Raising errors], and [Issue-0169: Conformance Levels].
The first four phases above are "analysis-time" (sometimes also called "compile-time") steps, which is to say that they can be performed on a [expression/query] before examining any input document. Indeed, analysis-time processing can be performed before such document even exists. Analysis-time processing can detect many errors early-on, e.g., syntax errors or type errors. If no error occurs, the result of analysis-time processing could be some compiled form of [expression/query], suitable for execution by a compiled-[expression/query] processor. The last phase is an "execution-time" (sometimes also called "run-time") step, which is to say that the query is evaluated on actual input document(s).
Static analysis catches only certain classes of errors. For
instance, it can detect a comparison operation applied between
incompatible types (e.g., xs:int
and
xs:date
). Some other classes of errors cannot be
detected by the static analysis and are only detected at execution
time. For instance, whether an arithmetic expression on 32 bits
integers (xs:int
) yields an out-of-bound value can
only be detected at run-time by looking at the data.
While implementations may be free to employ different processing models, the [XPath/XQuery] static semantics relies on the existence of a static type analysis phase that precedes any access to the input data. Statically typed implementations are required to find and report static type errors, as specified in this document. It is still an open issue (See [Issue-0098: Implementation of and conformance levels for static type checking]) whether to make the static type analysis phase optional to allow implementations to return a result for a type-invalid [expression/query] in special cases where the [expression/query] happens to perform correctly on a particular instance of input data. (Note that this is not the same as merely permitting that the static type error is emitted at evaluation time as is done below.)
Notice that the separation of logical processing into phases is not meant to imply that implementations must separate analysis-time from evaluation-time processing: [expression/query] processors may choose to perform all phases simultaneously at evaluation-time and may even mix the phases in their internal implementations. The processing model defines only what the final result.
The above processing phases are all internal to the [expression/query] processor. They do not deal with how the [expression/query] processor interacts with the outside world, notably how it accesses actual documents and types. A typical [expression/query] engine would support at least three other important processing phases:
XML Schema import phase. The [XPath/XQuery] type system is based on XML Schema. In order to perform static type analysis, the [XPath/XQuery] processor needs to build type descriptions that correspond to the schema(s) of the input documents. This phase is achieved by mapping all schemas required by the [expression/query] into the [XPath/XQuery] type system. The XML Schema import phase is described in [8 Importing Schemas].
XML loading phase. Expressions are evaluated on values in the [XQuery 1.0 and XPath 2.0 Data Model]. XML documents must be loaded into the [XQuery 1.0 and XPath 2.0 Data Model] before the evaluation phase. This is described in the [XQuery 1.0 and XPath 2.0 Data Model] and is not discussed further here.
Serialization phase. Once the [expression/query] is evaluated, processors might want to serialize the result of the [expression/query] as actual XML documents. Serialization of data model instances is still an open issue (See [Issue-0116: Serialization]) and is not discussed further here.
The parsing phase is not specified formally; the formal semantics does not define a formal model for the syntax trees, but uses the [XPath/XQuery] concrete syntax directly. More details about parsing for XQuery 1.0 can be found in the [XQuery 1.0: A Query Language for XML] document and more details about parsing for XPath 2.0 can be found in the [XML Path Language (XPath) 2.0] document. No further discussion of parsing is included here.
For the other three phases (normalization, static type analysis and evaluation), instead or giving an algorithm in pseudo-code, the semantics is described formally by means of inference rules. Inference rules provide a notation to describe how the semantics of an expression derives from the semantics of its sub-expressions. Hence, they provide a concise and precise way for specifying bottom-up algorithms, as required by the normalization, static type analysis, and evaluation phases.
The Formal Semantics uses the following namespace prefixes.
xf:
and op:
for functions and
operators from the [XQuery 1.0 and XPath 2.0 Functions and Operators] document.dm:
for constructors and accessors of the
[XQuery 1.0 and XPath 2.0 Data Model].xs:
for XML Schema components, and built-in
types.fs:
for Formal Semantics specific
components.All these prefixes are assumed to be bound to the appropriate URIs.
Ed. Note: [Kristoffer/XSL] The fs: prefix URI should be defined here.
This section gives an overview of the main data model features that are relevant to the Formal Semantics. The reader is referred to the [XQuery 1.0 and XPath 2.0 Data Model] document for more details.
An atomic value is a value in the value space of one of the [XML Schema Part 2] atomic types (that is, a primitive simple type that is not derived by list or union).
A node is one of the following kinds: document, element, attribute, namespace, comment, processing-instruction and text. The [XPath/XQuery] Formal Semantics does not currently discuss namespace, comment, and processing-instruction nodes (See [Issue-0105: Types for nodes in the data model.]). Components of nodes can be typed values, string values, names, type annotations, or other nodes.
XML documents and their contents are represented in the data model as trees composed of nodes and atomic values. [XQuery 1.0 and XPath 2.0 Data Model] defines a mapping from the PSVI (Post Schema Validation Information Set) to such trees.
[XQuery 1.0 and XPath 2.0 Data Model] defines constructors, which are functions that construct nodes and atomic values, and accessors, which are functions that access a value's properties or components.
For instance, the children function returns all the child nodes of an element node. The typed value of a node is a sequence of zero or more atomic values. The string value of a node is an instance of the type xs:string. The name of a node is an instance of the type xs:QName.
An item is either an atomic value or a node.
Every value in the data model is a sequence. A sequence is an ordered collection of zero or more items. Sequences are represented by items separated by commas, enclosed in parentheses.
A sequence containing exactly one item is called a singleton sequence. An item is identical to a singleton sequence containing that item. Sequences are never nested--for example, combining the values 1, (2, 3), and () into a single sequence results in the sequence (1, 2, 3). A sequence containing zero items is called an empty sequence.
The data model annotates element nodes, attribute nodes, and atomic values with type names. This type annotation is the type name given to the element, attribute, or value through the validation process.
The remainder of the section is devoted to several related features that merit special attention: node identity, order, and type annotations.
In the [XQuery 1.0 and XPath 2.0 Data Model], nodes have
identity. Node identity follows from the unique
location of the node within exactly one XML document (or document fragment, in the case of XML being
constructed within the [expression/query] itself). It is
possible for two expressions to return not only the same value,
but also the identical node. On the other hand, two expressions
could return results with the same document structure, but
different identities. [XPath/XQuery] supports comparison of
nodes using either "node equality" (equality by
identity) or "value equality" (equality by
value), for instance by using the operators
is
or =
.
Atomic values do not have an associated identity and are therefore always compared by value.
The difference between node equality and value equality is illustrated by the following example:
let $a1 := <book><author>Suciu</author></book>, $a2 := <author>Suciu</author>, $a3 := $a1/author return ($a1/author is $a3), {-- true, they refer to the same node --} ($a1/author = $a2), {-- true, they have the same value --} ($a1/author is $a2) {-- false, they are not the same node --}
All [XPath/XQuery]'s operators preserve node identity with the
exception of explicit copy operations, node
(element, attribute, etc.) constructors and validate
expressions. An element constructor always creates a deep copy
of its attributes and child nodes. Other operators, such as
sequence constructors or path expressions, do not result in
copies of the corresponding nodes. So, for example, ($a3,
$a2)
creates a new sequence of nodes, the first of which
has the same identity as $a1/author
.
There are two kinds of order in [XPath/XQuery]: sequence order and document order.
Sequence order. Sequences of items in the [XPath/XQuery] data model are ordered. Sequence order refers to the order of items within a given sequence.
Document order. Document order refers to the total order among all nodes in a given document. It is defined as the order of appearance of the nodes when performing a pre-order, depth-first traversal of a tree. For elements, this corresponds to the order of appearance of their opening tags in the corresponding XML serialization. Document order is equivalent to the definition used in [XML Path Language (XPath) : Version 1.0].
Depending on the context, it may be possible to talk about two different notions of order for the same (set of) nodes. For example:
let $e := <list> <item id="1"/> <item id="2"/> </list>, $s := ($e/item[@id='2'], $e/item[@id='1']) ...
The item "1" is before item "2" in document order, but the
same two nodes are in the opposite order in the sequence
$s
.
The order between nodes from distinct documents is implementation defined but must be stable. That is, it must not change for the duration of query evaluation.
A type annotation indicates the type name for each element and attribute node, which results from the validation process or is assigned by default (depending on the way the data was built). In the case of anonymous types, the data model annotates element and attributes with xs:anyType and xs:anySimpleType respectively.
For instance, consider the document fragment
<fact>The cat weighs <weight>12</weight> pounds.</fact>
and the associated schema
<xs:element name="fact" type="FactType"/> <xs:complexType name="FactType" mixed="true"> <xs:sequence> <xs:element name="weight" type="xs:integer"> </xs:sequence> </xs:complexType>
Before validation, the two elements fact
and
weight
in the document are annotated by
xs:anyType.
After validation, the element fact
is annotated
with the type name FactType
and the element
weight
is annotated with the type name
xs:integer
.
Type annotations are taken into account during [expression/query] evaluation and have an impact on the semantics of [XPath/XQuery].
For instance, consider the following function declaration
define function convert_weight(element of type FactType $x) { ... }
This function only accepts as input an element annotated with
the type FactType
, or with one of the types derived
from it. Therefore, the previous document fragment is only
accepted by the function after it has been validated against the
given schema.
[3 The XQuery Type System] gives a formal description of data model values with type annotations and explain how type annotations are taken into account when matching a value against a given type.
This section presents an introduction to (statically) typed languages in general, and a conceptual overview of the [XPath/XQuery] type system in particular. The [XPath/XQuery] type system is discussed formally in [3 The XQuery Type System].
A type system relates values, types, and expressions in the language.
The main constituent parts of a typed system are:
A universe of possible types. Type are composed of other types, starting with primitive types, and can be built using type constructors.
In [XPath/XQuery], the primitive types are the primitive atomic types of [XML Schema Part 2]. Type constructors are also based on schema, and can be used to build types for attributes and elements, sequence and choice groups, etc. The [XPath/XQuery] type system is defined in [3.1 Values and Types].
A notation for specifying types.
In [XPath/XQuery], types are imported from XML Schema, and can be used in expressions using the SequenceType syntax. In order to model and reason about types in [XPath/XQuery], this document introduces its own notation for types. This notation is defined in [3.1 Values and Types].
A relationship between values and types. Formally, the semantics of a type is defined to be the (usually infinite) set of instance values which match that type.
For example, the type xs:integer consists of the set of
all integer values, and the type element address {
xs:string }
consists of all elements named
"address" whose contents are a single string value, etc.
Matching a [XPath/XQuery] value against a type is defined in [3.3 Matching].
A notion of subtyping. Subtyping is a relationship between types that plays an important role in a statically typed language. Notably, it is used to determine whether function calls are legal or not.
Subtyping in [XPath/XQuery] is defined in [3.5.1 Subtype].
For a statically typed language one also needs to define:
Rules that relate expressions to types. Static type analysis infers a type for each expression in the language. The most important property for a static type system is that the type inferred statically must be such that for all valid inputs, evaluating the expression returns a result that matches the inferred type. If this property holds, then the static typing provides guarantees that certain kinds of errors can not occur at run-time.
The static typing rules for [XPath/XQuery] are defined for all [XPath/XQuery] expressions in [5 Expressions], [6 The Query Prolog] and [7 Additional Semantics of Functions].
Finally, types can also be used during language evaluation if the language provides:
Expressions on types. A language can support operations that take types into account, such as casting, type matching, etc.
[XPath/XQuery] provide several such expressions: "typeswitch", "cast as", "treat as", and "validate as". [XPath/XQuery] also support a "validate" expression, which performs XML Schema validation. Validation is related to matching in that if validation succeeds, it returns a value which matches the type used for validation. Expressions on types are defined in [5.12 Expressions on SequenceTypes]. The validate expression is defined in [3.4 Erase and Annotate].
The remainder of the section is devoted to several related features that merit special attention: the relationship between the [XPath/XQuery] type system and XML Schema, structural and named typing, and subtyping.
The [XPath/XQuery] type system is based on [XML Schema]. An introduction to XML Schema can be found in [XML Schema Part 0].
The [XPath/XQuery] type system captures a large subset of XML Schema. This section gives a summary of which features are captured and in some cases deviations from XML Schema.
The following components and features of XML Schema are captured exactly in the [XPath/XQuery] type system:
Element and attribute declarations;
Simple and complex type definitions;
Local attributes and elements;
Named and anonymous types;
the type name hierarchy;
Sequence, choice and all groups;
Wildcards;
Derivation by extension, list and union;
Substitution groups.
The following components or features of XML Schema are not represented in the [XPath/XQuery] type system.
Simple type facets;
Identity-constraint definitions;
Notations and annotations.
The following components or features of XML Schema are represented partially or differently in the [XPath/XQuery] type system.
The [XPath/XQuery] type system only captures an approximation
of minOccurs and maxOccurs. Like DTDs, the [XPath/XQuery]
type system only supports *, +, and ? which correspond to
[minOccurs="0" maxOccurs="unbounded"
],
[minOccurs="1" maxOccurs="unbounded"
], and
[minOccurs="0" maxOccurs="1"
] respectively.
The [XPath/XQuery] type system generalizes the notion of derivation by restriction for the needs of static type analysis. Derivation by restriction in XML Schema relies on a syntactic relationship between content models. The [XPath/XQuery] type system uses a generalization of this relationship based on the notion of inclusion between types -- also called structural subtyping.
At compile time, the [XPath/XQuery] environment imports XML Schema declarations, and loads them as declarations in the [XPath/XQuery] type system. This loading process is specified by a mapping from XML Schema to the [XPath/XQuery] type system, given in [8 Importing Schemas].
XML Schema is a powerful schema language for XML. XML Schema can describe both structural constraints as well as type annotations that apply to XML documents. These aspects are referred to as structural typing and named typing respectively.
Structural typing. An important notion underlying XML Schema is the concept of regular expressions, and their tree counterparts, regular tree grammars. An introduction to regular (tree) languages can be found in [Languages] or in [TATA].
Tree grammars can be used to capture the structural constraints imposed by an XML Schema. Automata are the traditional way of implementing tree grammars and can be used to implement part of the XML Schema validation process.
For instance, consider the following element declaration:
<xs:element name="root"> <xs:complexType> <xs:sequence maxOccurs="unbounded"> <xs:choice minOccurs="0" maxOccurs="unbounded"> <xs:element ref="a"/> <xs:element ref="b" minOccurs="0"/> </xs:choice> <xs:element ref="c"/> </xs:sequence> </xs:complexType> </xs:element>
The structural constraints imposed by the definition of
the content of element root
can be described by
the following regular expression (written here in
DTD notation): ((a|b?)*,c)+
. Such a constraint can be
checked using a finite state automaton applied on the
children of the element root
in the instance
document.
Named typing. In addition, XML Schema provides the ability to associate names with type definitions and to declare relationships between type names.
For instance, consider the following two element declarations:
<xs:element name="person"> <xs:complexType name="Person"> <xs:sequence> <xs:element ref="ssn"> <xs:choice> <xs:sequence> <xs:element ref="major" minOccurs="0"/> <xs:element ref="minors" maxOccurs="unbounded"/> </xs:sequence> <xs:element ref="job_desc"/> </xs:choice> </xs:sequence> </xs:complexType> </xs:element> <xs:element name="student"> <xs:complexType name="Student"> <xs:complexContent> <xs:restriction base="Person"> <xs:sequence> <xs:element ref="ssn"> <xs:element ref="major" minOccurs="0"/> <xs:element ref="minors" maxOccurs="unbounded"/> </xs:sequence> </xs:restriction> </xs:complexType> </xs:complexContent> </xs:element>
The type Student
of the element
student
is derived by restriction from the type
Person
. Such a declaration not only defines a
new type, but also creates a relationship between the type
names Person
and Student
which
needs to be taken into account when doing validation and
matching against a given type. For instance, the following
function
define function salary(element of type Person $x) { .... }
accepts as parameters elements of type Person as well as
elements with types derived by restriction from Person, but does not
accept elements with the same content model as the element
person
but a type which does not derive
from the type Person
.
A type is a subtype of another type if every value matching the first type also matches the second type. Since matching takes both type structure and type names into account, so is subtyping.
Here is a simple example of subtyping on two regular expressions:
( xs:double )* ( xs:integer | xs:double )*
The first type is a subtype of the second, because any sequence that contains only doubles is also an example of a sequence that contains either integers or doubles. This example only illustrates the structural subtyping.
Type1 <: Type2 indicates that type Type1 is a subtype of Type2. Note that the notation <: is used when defining the [XPath/XQuery] semantics, but is not part of the [XPath/XQuery] syntax.
Subtyping plays a crucial role in the semantics of function application since all functions have an associated signature that declares the types of input parameters and the type of the result of the function.
Intuitively, one can call a function not only by passing an argument of the declared type, but also any argument whose type is a subtype of the declared type. This property is called type substitutability.
Ed. Note: [Kristoffer/XSL] Type substitutability should really be true for any subexpression, not just function arguments (it just happens that in functional languages, where type substitutability is usually defined, the situations are equivalent). Specifically type substitutability does not apply to any subexpression of [XPath/XQuery]:
typeswitch
violates it. In particular this means that while one may replace a function argument with one whose type is a subtype this does not guarantee that the resulting value is the same even if the value is the same (but cast to a subtype).
Subtyping in [XPath/XQuery] is related to, but not identical to, "derivation by restriction" in XML Schema. A type derived by restriction is always a subtype of its base type, but the opposite is not true. For instance, consider the following types:
( xs:double )+ xs:double, ( xs:integer | xs:double )*
The first type is a subtype of the second, because any sequence that contains one or more doubles is also an example of a sequence containing a double followed by a sequence of zero or more integers or doubles. But the first type cannot be derived from the second type using derivation by restriction as defined in XML Schema.
The [XQuery 1.0 and XPath 2.0 Functions and Operators] document provides a number of useful basic functions over the components of the [XPath/XQuery] data model (atomic values, nodes, sequences, etc). A number of these functions are used in the course of describing the [XPath/XQuery] semantics. Here is the list of functions from the [XQuery 1.0 and XPath 2.0 Functions and Operators] document that are used in the [XPath/XQuery] Formal Semantics:
op:numeric-add
op:numeric-subtract
op:numeric-multiply
op:numeric-divide
op:numeric-mod
op:numeric-unary-plus
op:numeric-unary-minus
op:numeric-equal
op:numeric-less-than
op:numeric-greater-than
op:boolean-equal
op:boolean-less-than
op:boolean-greater-than
op:yearMonthDuration-equal
op:yearMonthDuration-less-than
op:yearMonthDuration-greater-than
op:dayTimeDuration-equal
op:dayTimeDuration-less-than
op:dayTimeDuration-greater-than
op:dateTime-equal
op:dateTime-less-than
op:dateTime-greater-than
op:add-yearMonthDurations
op:subtract-yearMonthDurations
op:multiply-yearMonthDuration
op:divide-yearMonthDuration
op:add-dayTimeDurations
op:subtract-dayTimeDurations
op:multiply-dayTimeDuration
op:divide-dayTimeDuration
op:add-yearMonthDuration-to-dateTime
op:add-dayTimeDuration-to-dateTime
op:subtract-yearMonthDuration-from-dateTime
op:subtract-dayTimeDuration-from-dateTime
op:add-yearMonthDuration-to-date
op:add-dayTimeDuration-to-date
op:subtract-yearMonthDuration-from-date
op:subtract-dayTimeDuration-from-date
op:add-dayTimeDuration-to-time
op:subtract-dayTimeDuration-from-time
op:QName-equal
op:anyURI-equal
op:hex-binary-equal
op:base64-binary-equal
op:NOTATION-equal
op:node-equal
op:node-before
op:node-after
op:node-precedes
op:node-follows
op:to
op:concatenate
op:item-at
op:union
op:intersect
op:except
op:operation
xf:false
xf:true
xf:count
xf:boolean
xf:get-namespace-uri
xf:get-local-name
xf:round
xf:compare
xf:not
xf:empty
xf:root
xf:error
Many functions in the [XQuery 1.0 and XPath 2.0 Functions and Operators] document are
generic: they perform operations on arbitrary
components of the data model, e.g., any kind of node, or any
sequence of items. For instance, the
xf:distinct-nodes
function removes duplicates in
any sequence of nodes. As a result, the signature given in the
[XQuery 1.0 and XPath 2.0 Functions and Operators] document is also generic. For instance, the
signature of the xf:distinct-nodes
function is:
define function xf:distinct-nodes(node*) returns node*
If applied as is, this signature would result in poor static
type information. In general, it would be preferable if some of
these function signatures could take the type of input
parameters into account. For instance, if the function
xf:distinct-nodes
is applied on a parameter of type
element a*, element b
, one can easily deduce that
the resulting sequence is a collection of either a
or b
elements.
In order to provide better static typing, some specific typing rules are specified for some of the functions in [XQuery 1.0 and XPath 2.0 Functions and Operators]. These additional typing rules are given in [7 Additional Semantics of Functions]. Here is the list of functions that are given specific typing rules.
xf:error
xf:distinct-nodes
xf:distinct-values
op:union
op:intersect
op:except
op:to
xf:data
Ed. Note: There might be other functions that need specific typing rules. See [Issue-0135: Semantics of special functions].
Some queries result in an error. Errors that are detected at
compile-time, like parse errors or type errors, are reported to
the user by the system. Dynamic errors are raised using the
xf:error()
function. General handling of errors in
the Formal Semantics is still an open issue (See [Issue-0094:
Static type errors and warnings], [Issue-0098:
Implementation of and conformance levels for static type
checking], [Issue-0171:
Raising errors], and [Issue-0169:
Conformance Levels]).
The [XPath/XQuery] Data Model provides operations to construct or
access components of the Data Model, some of which are used in
the course of defining the [XPath/XQuery] semantics. The Formal
Semantics uses the namespace prefix dm:
for those
functions to distinguish them from other functions in the
[XQuery 1.0 and XPath 2.0 Functions and Operators] document.
Here is a list of data model constructors or accessors used for Formal Semantics specification.
dm:atomic-value
dm:children
dm:attributes
dm:parent
dm:name
dm:node-kind
dm:dereference
dm:empty-sequence
dm:namespaces
dm:type
dm:typed-value
dm:attribute-node-atomic
dm:element-node-atomic
dm:text-node
XPath axes are used to describe tree navigation in instances of the [XPath/XQuery] data model. The semantics of axis navigation is described in terms of data model functions. Some of the XPath axes are directly supported through existing data model accessors. Some axes (e.g., ancestor) are defined as a simple recursive application of a data model accessor and others (e.g., following) require more complex computation on top of existing data model accessors. The correspondence between XPath axis and data model accessors is specified in section [5.2.1.1 Axes]
In a few cases, the Formal Semantics makes use of
functions that are not currently in the [XQuery 1.0 and XPath 2.0 Functions and Operators] document.
The namespace prefix fs:
is used for those functions, to distinguish them from functions
in the [XQuery 1.0 and XPath 2.0 Functions and Operators] document.
Here is a list of additional functions used for Formal Semantics specification.
fs:characters-to-string
fs:distinct-doc-order
fs:item-sequence-to-node-sequence
fs:item-sequence-to-string
In order to make the specification of the semantics both concise and precise, formal notations in the form of judgments and inference rules are used. This section, introduces the notations for judgments, inference rules and mapping rules, as well as the notion of an environment.
This section is intended for the reader who may not be familiar with these notations. The reader familiar with these notations can skip this section and go directly to [2.7 The Formal Semantics].
Grammar productions are used in this document to describe "objects" (values, types, [XPath/XQuery] expressions, etc.) manipulated by the Formal Semantics. The Formal Semantics makes use of several kinds of grammar productions.
XQuery grammar productions describe the XQuery language and expressions. XQuery productions are identified by a number, which corresponds to the number in the [XQuery 1.0: A Query Language for XML] document, and are annotated with "(XQuery)". For instance, the following production describes FLWR expressions in XQuery.
[10 (XQuery)] | FLWRExpr | ::= |
For the purpose of this document, the differences between the XQuery 1.0 and the XPath 2.0 grammars are mostly irrelevant. By default, this document uses XQuery 1.0 grammar productions. Whenever the grammar for XPath 2.0 differs from the one for XQuery 1.0, the corresponding XPath 2.0 productions are also given. XPath productions are identified by a number, which corresponds to the number in the document, and are annotated with "(Path)". For instance, the following production describes for expressions in XPath.
[13 (XPath)] | ForExpr | ::= |
XQuery Core grammar productions describe the XQuery Core. The complete XQuery Core grammar is given in [A Normalized core grammar]. XQuery Core productions are identified by a number, which corresponds to the number in [A Normalized core grammar], and are annotated by "(Core)". For instance, the following production describes the simpler form of "for" expressions present in the XQuery Core.
[8 (Core)] | ForExpr | ::= |
The Formal Semantics sometimes needs to manipulate "objects" (values, types, expressions, etc.) for which there is no existing grammar production in the [XQuery 1.0: A Query Language for XML] document. In these cases, specific grammar productions are introduced. Notably, additional productions are used to describe the [XPath/XQuery] type system. XQuery Formal Semantics productions are identified by a number, and are annotated by "(Formal)". For instance, the following production describes global type definitions in the [XPath/XQuery] type system.
[27 (Formal)] | Definition | ::= |
Note that grammar productions which are specific to the Formal Semantics (i.e., with the "(Formal)" annotation) are not part of [XPath/XQuery]. They are not accessible to the user and are only used in the course of defining the language's semantics.
The basic building block of the formal specification is called a judgment. A judgment expresses whether a property holds or not.
For example:
Notation
The judgment
holds if the painting Painting is beautiful.
Or more relevant, here are two example of judgments that are used extensively in the rest of this document.
Notation
The judgment
holds if the expression Expr yields (or evaluates to) the value Value.
Notation
The judgment
holds when the expression Expr has type Type.
A judgment can contain symbols and patterns.
Symbols are purely syntactic and are used to write the judgment itself. In general, symbols in a judgment are chosen to reflect its meaning. For example, 'is beautiful', '=>' and ':' are symbols, the second and third of which should be read "yields", and "has type" respectively.
Patterns are written with italicized words. The name of a pattern is significant: each pattern name corresponds to an "object" (a value, a type, an expression, etc.) that can be substituted legally for the pattern. By convention, all patterns in the Formal Semantics correspond to grammar non-terminals, and are used to represent entities that can be constructed through application of the corresponding grammar production. For example, Expr can be used to represent any [XPath/XQuery] expression, Value can be used to represent any value in the [XPath/XQuery] data model.
When applying the judgment, each pattern must be instantiated to an appropriate sort of "object" (value, type, expression, etc). For example, '3 => 3' and '$x+0 => 3' are both instances of the judgment 'Expr => Value'. Note that in the first judgment, '3' corresponds to both the expression '3' (on the left-hand side of the => symbol) and to the the value '3' (on the right-hand side of the => symbol).
Patterns may appear with subscripts (e.g. Expr1, Expr2), which simply name different instances of the same sort of pattern. Each distinct pattern must be instantiated to a single "object" (value, type, expression, etc.). If the same pattern occurs twice in a judgment description then it should be instantiated with the same "object". For example, '3 => 3' is an instance of the judgment 'Expr1 => Expr1' but '$x+0 => 3' is not since the two expressions '$x+0' and '3' cannot be both instance of the pattern Expr1. On the contrary, '$x+0 => 3' is an instance of the judgment 'Expr1 => Expr2'.
In a few cases, patterns may have a name which is not exactly the name of a grammar production but is based on it. For instance, a BaseTypeName is a pattern which stands for a type name, as would TypeName, or TypeName2. This usage is limited, and only occurs to improve the readability of some of the inference rules.
Whether a judgments holds or not is specified by means of inference rules. Inference rules express the logical relation between judgments and describe how complex judgments can be concluded from simpler premise judgments. (As explained in [2.1 Processing model], this approach lends itself well to bottom-up algorithms.)
A logical inference rule is written as a collection of premises and a conclusion, respectively written above and below a dividing line:
premise1 ... premisen |
|
conclusion |
All premises and the conclusion are judgments. The interpretation of an inference rule is: if all the premise judgments above the line hold, then the conclusion judgment below the line must also hold.
Here is a simple example of inference rule, which uses the example judgment 'Expr => Value' from above:
$x => 0 3 => 3 |
|
$x + 3 => 3 |
This inference rule expresses the following property of the judgment 'Expr => Value': if the variable expression '$x' yields the value '0', and the literal expression '3' yields the value '3', then the expression '$x + 3' yields the value '3'.
It is also possible for an inference rule to have no premises above the line to have no judgments at all; this simply means that the expression below the line always holds:
|
3 => 3 |
This inference rule expresses the following property of the judgment 'Expr => Value': evaluating the literal expression '3' always yields the value '3'.
The two above rules are expressed in terms of specific variables and values, but usually rules are more abstract. That is, the judgments they relate contain patterns. For example, here is a rule that says that for any variable Variable that yields the integer value Integer, adding '0' yields the same integer value:
Variable => Integer |
|
Variable + 0 => Integer |
As in a judgment, each pattern in a particular inference rule must be instantiated to the same "object" within the entire rule. This means that one can talk about "the value of Variable" instead of the more precise "what Variable is instantiated to in (this particular instantiation of) the inference rule".
Logical inference rules use environments to record information computed during static type analysis or dynamic evaluation so that this information can be used by other logical inference rules. For example, the type signature of a user-defined function in a [expression/query] prolog can be recorded in an environment and used by subsequent rules. Similarly, the value assigned to a variable within a "let" statement can be captured in an environment and used for further evaluations.
An environment is a dictionary that maps a symbol (e.g., a function name or a variable name) to an "object" (e.g., a function body, a type, a value). One can either access existing information from an environment, or update the environment.
If "env" is an environment, then "env(symbol)" denotes the "object" to which symbol is mapped to. The notation is intentionally akin to function application as an environment can be seen as a "function" from the argument symbol to the "object" that the symbol is mapped to.
This specification uses environment groups that group related environments. If "env" is an environment group with the member "mem", then that environment is denoted "env.mem" and the value that it maps symbol to is denoted "env.mem(symbol)".
Updating is only defined on environment groups:
"env [ mem(symbol |-> object) ]" denotes the a new environment group which is identical to env except that the mem environment has been updated to map symbol to object. The notation symbol |-> object indicates that symbol is mapped to object in the new environment.
If the "object" is a type then the following conventional variant notation is used: "env [ mem(symbol : object) ]".
The following shorthand is also allowed: "env [ mem( symbol1 |-> object1 ; ... ; symboln |-> objectn ) ]" in which each symbol is mapped to a corresponding object in the new environment.
This notation is equivalent to nested simple updates, as in " (...(env[mem(symbol1 |-> object1)]) ... [mem(symboln |-> objectn)])".
Note that updating the environment overrides any previous binding that might exist for the same name. Updating the environment is used to capture the scope of variables, namespaces, etc. Also, note that there are no operations to remove entries from environments: the need never arises because the environment group from "before" the update remains accessible concurrently with the updated version.
Environments are typically used as part of a judgment, to capture some of the context in which the judgment is computed. Indeed, most judgments are computed assuming that some environment is given. This assumption is denoted by prefixing the judgment with "env |-". The "|-" symbol is called a "turnstile" and is ubiquitous in inference rules.
For instance, the judgment
should be read: assuming the dynamic environment dynEnv, the expression Expr yields the value Value.
The two main environments used in the Formal Semantics are: a dynamic environment (dynEnv), which captures the [XPath/XQuery]'s dynamic context, and a static environment (statEnv), which captures the [XPath/XQuery]'s static context. Both are defined in [4.1 Expression Context].
Putting the above notations together, here is an example of an inference rule that occurs later in this document:
This rule is read as follows: if two expressions Expr1 and Expr2 have already been statically inferred to have types Type1 and Type2 (the two premises above the line), then it is the case that the expression below the line "Expr1 , Expr2" must have the type "Type1, Type2", which is the sequence of types Type1 and Type2.
The above inference rule, does not modify the (static) environment. The following rule defines the static semantics of a "let/return" expression. The binding of the new variable is captured by an update to the varType component of the original static environment.
statEnv |- Expr1 : Type1 statEnv [ varType(QName : Type1) ] |- Expr2 : Type2 |
|
statEnv |-
let
$ QName := Expr1
return
Expr2 : Type2
|
This rule should be read as follows. First, the type Type1 for the "let" input expression Expr1 is computed. Second the "let" variable is added into the varType member of the static environment group statEnv, with type Type1. Finally, the type Type2 of Expr2 is computed in that new environment.
Ed. Note: Jonathan suggests that we should explain 'chain' inference rules. I.e., how several inference rules are applied recursively.
Finally, this section introduces the top-level notations defining the processing model phases described above. These notations are used to define the normalization, static type analysis, and dynamic evaluation processing phases.
Normalization is specified using mapping rules which describe how a [XPath/XQuery] expression is rewritten into another expression in the [XPath/XQuery] Core. Note that mapping rules are also used in [8 Importing Schemas] to specify how XML Schemas are imported into the [XPath/XQuery] Type System.
Notation
Mapping rules are written using a square bracket notation, as follows:
[Object]Subscript |
== |
Mapped Object |
The original "object" is written above the == sign. The rewritten "object" is written beneath the == sign. The subscript is used to indicate what kind of "object" is mapped, and sometimes to pass some information between mapping rules.
(Since normalization is always done in the context of the static context the above is really a shorthand for
but we shall stay with the shorthand because statEnv will always be implied.)
The static environment is used in certain cases (e.g. for normalization of function calls) during normalization. To keep the notation simpler, the static environment is not written in the normalization rules, but it is assumed to be available.
Ed. Note: [Kristoffer/XSL] We should decide whether to use a shorthand notation as suggested or modify the mapping rules throughout.
Specifically the normalization rule that is used to map "top-level" expressions in the [XPath/XQuery] syntax into expressions in the [XPath/XQuery] Core is
[Expr]Expr |
== |
CoreExpr |
which indicates that the expression Expr is normalized to the expression CoreExpr in the [XPath/XQuery] core (with the implied statEnv).
Example
For instance, the following [expression/query]
for $i in (1, 2), $j in (3, 4) return element pair { ($i,$j) }
is normalized to the core expression
for $i in (1, 2) return for $j in (3, 4) return return element pair { ($i,$j) }
in which the complex "FWLR" expression is mapped into a composition of two simpler "for" expressions.
The static semantics is specified using type inference rules, which relate [XPath/XQuery] expressions to types and specify under what conditions an expression is well typed.
Notation
The judgment
holds when, assuming the static environment statEnv is given, the expression Expr has type Type.
Example
The result of static type inference is to associate a static type with every [expression/query], such that any evaluation of that [expression/query] is guaranteed to yield a value that belongs to that type.
For instance, the following expression.
let $v := 3 return $v+5
has type xs:integer. This can be inferred as follows: the input literals '3' and '5' have type integer, so the variable $v also has type integer. Since the sum of two integers is an integer, the complete expression has type integer.
Note
The type of an expression is computed by inference. Static type inference rules are given to describe, for each kind of expression, how to compute the type of the expression given the types of its sub-expressions. Here is a simple example of such a rule:
statEnv |- Expr1 : xs:boolean statEnv |- Expr2 : Type2 statEnv |- Expr3 : Type3 |
|
statEnv |-
if Expr1
then Expr2
else Expr3
: ( Type2 | Type3 )
|
This rule states that if the conditional expression of an "if" expression has type boolean, then the type of the entire expression is one of the two types of its "then" and "else" clauses. Note that the resulting type is represented as a choice: '(Type2|Type3)'.
The "left half" of the expression below the line (the part before the :) corresponds to some phrase in a [expression/query], for which a type is computed. If the [expression/query] has been parsed into an internal parse tree, this usually corresponds to some node in that tree. The expression usually has patterns in it (here Expr1, Expr2, and Expr3) that need to be matched against the children of the node in the parse tree. The expressions above the line indicate things that need to be computed to use this rule; in this case, the types of the two sub-expressions of the "," operator. Once those types are computed (by further applying static inference rules recursively to the expressions on each side), then the type of the expression below the line can be computed. This illustrates a general feature of the type system: the type of an expression depends only on the type of its sub-expressions. The overall static type inference algorithm is recursive, following the parse structure of the [expression/query]. At each point in the recursion, an appropriate matching inference rule is sought; if at any point there is no applicable rule, then static type inference has failed and the [expression/query] is not type-safe.
The dynamic, or operational, semantics is specified using value inference rules, which relate [XPath/XQuery] expressions to values, and in some cases specify the order in which an [XPath/XQuery] expression is evaluated.
Notation
The judgment
holds when, assuming the static environment statEnv and dynamic environment dynEnv are given, the expression Expr yields the value Value.
The static environment is used in certain cases (e.g. for type matching) during evaluation. To keep the notation simpler, the static environment is not written in the dynamic inference rules, but it is assumed to be available.
Example
For instance, the following expression.
let $v := 3 return $v+5
yields the integer value 8. This can be inferred as follows: the input literals '3' and '5' denote the values 3 and 5, respectively, so the variable $v has the value 3. Since the sum of 3 and 5 is 8, the complete expression has the value 8.
Note
As with static type inference, logical inference rules are used to determine the value of each expression, given the dynamic environment and the values of its sub-expressions. [XPath/XQuery]'s dynamic semantics is modeled on the dynamic semantics presented in [Milner].
The inference rules used for dynamic evaluation, like those for static type inference, follow a top-down recursive structure, computing the value of expressions from the values of their sub-expressions.
Ed. Note: Status:This section has been extensively revised to improve the alignment between the [XPath/XQuery] type system and XML Schema. It now incorporates "named typing". Feedback on the new design is solicited.
The [XPath/XQuery] type system is used for the specification of both the dynamic and the static semantics of [XPath/XQuery]. It is used to describe the semantics of expressions on sequence types and in type conversion rules. It is also the basis for the static semantics of [XPath/XQuery].
This section defines formal values and types, four main operations on types. Three operations (match, erase, and annotate) are used for the dynamic semantics. The last operation (subtyping) is used for the static semantics.
The "match" operation takes as input a value and a type and either succeeds or fails. Type matching checks that the value given as input verifies the name and structural constraints given by the type. It is used in matching parameters against function signatures, and matching values against cases in "typeswitch". An informal description of type matching is given in [2.4.2 SequenceType] in [XQuery 1.0: A Query Language for XML].
The match operation is one the most important operation on types and is the basis for the semantics of typeswitch, treat and assert as, and is used in function calls to check dynamically that the parameter(s) of a function verifies the function signature.
The "erase" operation takes a value and removes all type information from it.
The "annotate" operation takes an untyped value and a type and either succeeds or fails. Type annotation models part of the semantics of XML Schema validation. From the untyped value, it verifies the constraints described by the type, and annotates the value with type names, and adds atomic values. If it succeeds it returns a new value.
The "erase" and "annotate" operations model aspects of the validate as in [XPath/XQuery]. Note that the validate operation in [XPath/XQuery] needs to operate on possibly already typed data model instances, hence the need to erase type information before applying standard XML Schema validation.
The "subtyping" operation takes two types and succeeds if the first type is smaller than the second.
This section introduces formal notations for describing XQuery types and values. Those notations are used extensively throughout this document to represent values and types in inference rules. We use formal notations for values and types because they are more compact, and are easier to manipulate within the inference rules. The formal notations for values and types introduced here are not exposed to the XQuery user.
The following grammar introduces formal notations for values. This notation is used to formally represent values in the the [XQuery 1.0 and XPath 2.0 Data Model].
A value is a sequence of zero or more items. An item is
either a node or an atomic value. A node is either an element,
an attribute, a document node, or a text node. Text nodes always
contain string values of type xs:anySimpleType
. Elements,
attributes, and atomic values have a type annotation, which is
the QName of a type.
Elements may be annotated with any type, and attributes may be annotated with any simple type.
A atomic value encapsulates an XML Schema atomic type (which
is its type annotation) and a corresponding value of that
type. An XML Schema atomic type [XML Schema Part 2] may be primitive
or derived, or xs:anySimpleType
. The corresponding atomic type
value may be a value in the value space of one of the 19
primitive XML Schema types.
Type annotations are always present. Untyped elements or
attributes (e.g., from well-formed documents before validation
has been performed) are annotated with xs:anyType
and attributes
and atomic values with no other type information are annotated
with xs:anySimpleType
.
A value is called a simple value if it consists of a sequence of zero or more atomic values.
[1 (Formal)] | Value | ::= | |
[2 (Formal)] | SimpleValue | ::= | |
[3 (Formal)] | ElementValue | ::= | |
[4 (Formal)] | AttributeValue | ::= | |
[5 (Formal)] | DocumentValue | ::= | |
[6 (Formal)] | TextValue | ::= | |
[7 (Formal)] | NodeValue | ::= | |
[8 (Formal)] | Item | ::= | |
[9 (Formal)] | AtomicValue | ::= | |
[10 (Formal)] | AtomicTypeValue | ::= | |
[11 (Formal)] | TypeAnnotation | ::= | |
[12 (Formal)] | ElementName | ::= | |
[13 (Formal)] | AttributeName | ::= | |
[14 (Formal)] | TypeName | ::= |
Notation
In the above grammar, the atomic type names are used to
represents the value space of the corresponding XML Schema
atomic type. For instance, "String" indicates the
value space of xs:string
, and
"Decimal" indicates the value space of
xs:decimal
.
Note that the same rule about constructing sequences apply to
the values described by that grammar. Notably sequences cannot
be nested. For instance, the sequence (10, (1, 2), (), (3,
4))
is equivalent to the sequence (10, 1, 2, 3,
4)
.
Ed. Note: Issue: Although the XQuery data model describes an error value, this error value is not represented formally here. Formal treatment of errors is deferred to a future version of that document.
Ed. Note: Issue: The formal semantics does not represent comments and process-instructions (See [Issue-0143: Support for PI, comment and namespace nodes]).
Ed. Note: Issue: This formal notation for values only represents either text nodes or values. (See [Issue-0144: Representation of text nodes in formal values])
Example
Example (1):
<fact>The cat weighs <weight units="lbs">12</weight> pounds.</fact>
In the absence of a Schema, this document is represented as
element fact of type xs:anyType { text { "The cat weighs " }, element weight of type xs:anyType { attribute units of type xs:anySimpleType { "lbs" of type xs:anySimpleType } text { "12" } }, text { " pounds." } }
Example (2):
<weight xsi:type="xs:integer">42</weight>
The formal model can represent values before and after validation. Before validation, this element is represented as:
element weight of type xs:anyType { attribute xsi:type of type xs:anySimpleType { "xs:integer" of type xs:anySimpleType }, text { "42" } }
After validation, this element is represented as:
element weight of type xs:integer { attribute xsi:type of type xs:QName { "xs:integer" of type xs:QName }, 42 of type xs:integer }
Note that the typing rules must permit attributes with name xsi:type and xsi:nil to appear on any element.
Example (3):
<sizes>1 2 3</sizes>
Before validation, this element is represented as:
element sizes of type xs:anyType { text { "1 2 3" } }
Assume the following Schema.
<xs:element name="sizes" type="sizesType"/> <xs:simpleType name="sizesType"> <xs:list itemType="sizeType"/> </xs:simpleType> <xs:simpleType name="sizeType"> <xs:restriction base="xs:integer"/> </xs:simpleType>
After validation against this Schema, the element is represented as:
element sizes of type sizesType { 1 of type sizeType, 2 of type sizeType, 3 of type sizeType }
Example (4): Example with an anonymous type.
<sizes>1 2 3</sizes>
Before validation, this element is represented as:
element sizes of type xs:anyType { text { "1 2 3" } }
Assume the following Schema.
<xs:element name="sizes"> <xs:simpleType> <xs:list itemType="xs:integer"/> </xs:simpleType> </xs:element>
After validation against this Schema, the element is represented as:
element sizes of type xs:anySimpleType { 1 of type xs:integer, 2 of type xs:integer, 3 of type xs:integer }
Example (5): Example with a union type.
<sizes>1 two 3 four</sizes>
Before validation, this element is represented as:
element sizes of type xs:anyType { text { "1 two 3 four" } }
Assume the following Schema:
<xs:element name="sizes" type="sizesType"/> <xs:simpleType name="sizesType"> <xs:list itemType="sizeType"/> </xs:simpleType> <xs:simpleType name="sizeType"> <xs:union memberType="xs:integer xs:string"/> </xs:simpleType>
After validation against this Schema, the element is represented as:
element sizes of type sizesType { 1 of type xs:integer, "two" of type xs:string, 3 of type xs:integer, "four" of type xs:string }
As they are in DTDs, types in [XPath/XQuery] are based on regular expressions. A type is composed from item types by optional, one or more, zero or more, all group, sequence, choice, empty sequence, or empty choice (written none).
The type none matches no values. It is called the empty choice because it is the identity for choice, that is (Type | none) = Type)). The type none appears in the definition of [3.6.1 Prime types], and is the type for [2.5.3 The error function].
[15 (Formal)] | Type | ::= | |
[16 (Formal)] | Occurrence | ::= |
An item type is an element or attribute type, a document node type, a text node type, the untyped type (i.e., which is the type of untyped text values), or an atomic type.
[17 (Formal)] | ItemType | ::= | |
[18 (Formal)] | AtomicTypeName | ::= |
An element or attribute type gives an optional name and an optional type specifier. A name with a type specifier is a local declaration. A type specifier alone is a local declaration that matches any name. A name alone refers to a global declaration. The word "element" or "attribute" alone refers to any element or any attribute.
[19 (Formal)] | ElementType | ::= | |
[20 (Formal)] | AttributeType | ::= | |
[21 (Formal)] | Nillable | ::= |
A type specifier either references a global type, or specifies an anonymous type. An anonymous type is described by naming the base type it derives from and giving the type, optionally with a flag indicating a mixed content.
[22 (Formal)] | TypeSpecifier | ::= | |
[23 (Formal)] | TypeDerivation | ::= | |
[24 (Formal)] | TypeReference | ::= | |
[25 (Formal)] | Derivation | ::= | |
[26 (Formal)] | Mixed | ::= |
Example
Example (1).
element
matches any element.
Example (2).
element of type xs:integer
matches any element of type xs:integer, such as:
element size of type xs:integer { 2 of type xs:integer }
Example (3).
element restricts xs:anyType { xs:integer* }
matches any element of any type that contains a sequence of integers, such as:
element numbers of type xs:integer { 1 of type xs:integer, 2 of type xs:integer, 3 of type xs:integer }
Example (4).
element sizes
refers to the global declaration for element "sizes".
Example (5).
element trouble of type xs:anyType { ( xs:float | xs:string )* }
describes an element with a simple type derived by union. This type matches the following instance:
validate as trouble { <trouble>this is not 1 string</trouble> } => element trouble of type xs:anyType {"this", "is", "not", 1, "string" }
Empty content can be indicated with the explicit empty sequence, or omitted, as in:
element bib { () } element bib { }
If the content model is omitted, then the element, (resp. attribute or type) name must be a proper QName, and refers to the global element (resp. attribute or type) with that name, which must be defined (by importation from a schema or through a type definition expression).
The type system includes three operators on types: ",", "|" and "&", corresponding respectively to sequence, choice and all groups in Schema.
The "," operator builds the "sequence" of two types. For example,
element title of type xs:string, element year of type xs:integer
means a sequence of an element title of type string followed by an element year of type integer.
The "|" operator builds a "choice" between two types. For example,
element editor of type xs:string | element bib:author*
means either an element editor of type string, or a
sequence of bib:author
elements.
The "&" operator builds the "interleaved
product" of two types. The type t1
&
t2 matches any sequence that is
an interleaving of a sequence that matches t1 and a
sequence that matches t2. For example,
(element a , element b) & xs:string = element a, element b, xs:string | element a, xs:string, element b | xs:string, element a, element b
In each case, the order of element a
and
element b
is unchanged, but the xs:string can
be interleaved in any position.
The interleaved product is used to represent all groups in XML Schema. The xs:all construct in XML Schema may only consist of global or local element declarations with lower bound 0 or 1, and upper bound 1.
At the top level, one can define elements, attributes, and types.
[27 (Formal)] | Definition | ::= | |
[28 (Formal)] | Substitution | ::= |
Global element and attribute declarations, like local element and attribute declarations, contain a type specifier. In addition, a global element declaration may declare the substitution group for the element and whether the element is nillable. A global type declaration specifies both the derivation and the declared type.
Ed. Note: Issue: The formal semantics provide support for substitution group. Support for substitution group is still an open issue in the [XPath/XQuery] document. (See [Issue-0144: Representation of text nodes in formal values])
The following type definitions capture the primitive types from Schema.
define type xs:string restricts xs:anySimpleType { xs:string } define type xs:decimal restricts xs:anySimpleType { xs:decimal } ...
In the above definitions, each name (such as xs:string) appears twice. The first appearance is used for named typing (xs:string is derived by restriction from xs:anySimpleType), and the second for structural typing (the value space of xs:string is given by xs:string -- the apparent circularity here is broken in the rule for matching in [3.3 Matching], which defines matching against xs:string directly).
The following type definition captures the Ur simple type from Schema.
define type xs:anySimpleType restricts xs:anyType { ( xs:string | xs:decimal | ... )* }
The name of the Ur simple type is
xs:anySimpleType
, and its structural definition
is given by the union of all simple type.
Note that there is no separate "value space"
for the type xs:anySimpleType
, it's value space
being the same as xs:string
. The following
example shows the distinction between a value of type string
containing "Database" and an untyped value containing
"Database": both are using string values as content with
different type names.
"Databases" of type xs:string "Databases" of type xs:anySimpleType }
The following type definition captures the Ur type from Schema.
define type xs:anyType restricts xs:anyType { attribute*, ( xs:anySimpleType | ( element* & text* ) ) }
Schema defines four built-in attributes that can appear on any element in the document without being explicitly declared in the schema. Those four attributes need to be added inside content models when doing matching. The four built-in attributes of Schema are declared as follows.
define attribute xsi:type of type xs:QName define attribute xsi:nil of type xs:boolean define attribute xsi:schemaLocation of type xs:anySimpleType { xs:anyURI* } define attribute xsi:noNamespaceSchemaLocation of type xs:anyURI
For convenience, a type that is an all group of the four built-in XML Schema attributes is defined.
BuiltInAttributes = attribute xsi:type ? & attribute xsi:nil ? & attribute xsi:schemaLocation ? & attribute xsi:noNamespaceSchemaLocation ?
The type system given in [3.1.2 Types] gives a simple but overly general definition of types. For instance, the above type grammar allows types to describe sequences of attributes and elements in any order. For example, the following type, describing a sequence of zero or more elements or attributes with name "year", is allowed.
(element year of type string | attribute year of type string)*
There are two reasons for this approach. First, it makes the grammar for types simpler. Second, it allows to describe types for heterogeneous sequences, that can result from [XPath/XQuery] expressions but cannot be represented as an XML Schema. For example, the above type is inferred for the following query.
for $b in //book return if ($b/publisher = "Springer") then element year { $b/year/text() } else attribute year { $b/year/text() }
When constructing elements, or attributes, some additional constraints on type need to be imposed, for which this grammar is too general. This section gives auxiliary grammar productions which impose additional constraints on the content of elements and attributes.
First, a grammar for simple types is defined. This grammar is a subset of the grammar for types. A simple type is composed from atomic types by optional, one or more, zero or more, choice, or empty choice.
[29 (Formal)] | SimpleType | ::= |
An all group contains only attributes or only elements; attributes or elements in an all group may be optional but not repeated; attributes always precede other content of an element.
[30 (Formal)] | AttributeAll | ::= | |
[31 (Formal)] | ElementAll | ::= | |
[32 (Formal)] | ElementNoAll | ::= | |
[130 (Formal)] | ElementContent | ::= | "ElementContent" |
[33 (Formal)] | ElementBody | ::= |
The type in an element type should always match the grammar
for ElementBody given above. (Note that in case the element type
is omitted altogether, e.g., like in element a { }
,
the type is implicitely matching the empty sequence.)
Those auxiliary productions is be used when matching the type content of elements or attributes within inference rules.
Here is a schema describing purchase orders, taken from the XML Schema Primer, followed by its mapping into the [XPath/XQuery] type system. The complete mapping from XML Schema into the [XPath/XQuery] type system is given in [8 Importing Schemas].
<xsd:schema xmlns:xsd="http://www.w3.org/2001/XMLSchema"> <xsd:annotation> <xsd:documentation xml:lang="en"> Purchase order schema for Example.com. Copyright 2000 Example.com. All rights reserved. </xsd:documentation> </xsd:annotation> <xsd:element name="purchaseOrder" type="PurchaseOrderType"/> <xsd:element name="comment" type="xsd:string"/> <xsd:complexType name="PurchaseOrderType"> <xsd:sequence> <xsd:element name="shipTo" type="USAddress"/> <xsd:element name="billTo" type="USAddress"/> <xsd:element ref="comment" minOccurs="0"/> <xsd:element name="items" type="Items"/> </xsd:sequence> <xsd:attribute name="orderDate" type="xsd:date"/> </xsd:complexType> <xsd:complexType name="USAddress"> <xsd:sequence> <xsd:element name="name" type="xsd:string"/> <xsd:element name="street" type="xsd:string"/> <xsd:element name="city" type="xsd:string"/> <xsd:element name="state" type="xsd:string"/> <xsd:element name="zip" type="xsd:decimal"/> </xsd:sequence> <xsd:attribute name="country" type="xsd:NMTOKEN" fixed="US"/> </xsd:complexType> <xsd:complexType name="Items"> <xsd:sequence> <xsd:element name="item" minOccurs="0" maxOccurs="unbounded"> <xsd:complexType> <xsd:sequence> <xsd:element name="productName" type="xsd:string"/> <xsd:element name="quantity"> <xsd:simpleType> <xsd:restriction base="xsd:positiveInteger"> <xsd:maxExclusive value="100"/> </xsd:restriction> </xsd:simpleType> </xsd:element> <xsd:element name="USPrice" type="xsd:decimal"/> <xsd:element ref="comment" minOccurs="0"/> <xsd:element name="shipDate" type="xsd:date" minOccurs="0"/> </xsd:sequence> <xsd:attribute name="partNum" type="SKU" use="required"/> </xsd:complexType> </xsd:element> </xsd:sequence> </xsd:complexType> <!-- Stock Keeping Unit, a code for identifying products --> <xsd:simpleType name="SKU"> <xsd:restriction base="xsd:string"> <xsd:pattern value="\d{3}-[A-Z]{2}"/> </xsd:restriction> </xsd:simpleType> </xsd:schema>
namespace xsd = "http://www.w3.org/2001/XMLSchema" define element purchaseOrder of type ipo:PurchaseOrderType define element comment of type xsd:string define type PurchaseOrderType { attribute orderDate of type xsd:date?, element shipTo of type USAddress, element billTo of type USAddress, element ipo:comment?, element items of type Items } define type USAddress { attribute country of type xsd:NMTOKEN?, element name of type xsd:string, element street of type xsd:string, element city of type xsd:string, element state of type xsd:string, element zip of type xsd:decimal } define type Items { attribute partNum of type SKU, element item { element productName of type xsd:string, element quantity restricts xsd:positiveInteger { xsd:positiveInteger }, element USPrice of type xsd:decimal, element comment?, element shipDate of type xsd:date? }* } define type SKU restrict xsd:string { xsd:string }
A number of auxiliary judgment that specify part of the semantics of Schema are defined. Those judgments are used in the rest of the section, but are not used directly used from other parts of the formal semantics.
The following judgements capture the relationship between names, obtained from derivation and substitution groups in a given XML Schema.
Notation
The judgment
holds when the first type name derives from the second type name.
Note
Derivation is a partial order. It is reflexive and transitive by the definition below. It is asymmetric because no cycles are allowed in derivation by restriction or extension.
Semantics
This judgment is specified by the following rules.
Some rules have hypotheses that simply list a type, element, or attribute declaration.
Every type name derives from itself.
|
statEnv |- TypeName derives from TypeName |
Every type name derives from the type it is declared to derive from by restriction or extension.
statEnv.typeDefn(TypeName) => define type TypeName extends BaseTypeName Mixed? { Type? } |
|
statEnv |- TypeName derives from BaseTypeName |
statEnv.typeDefn(TypeName) => define type TypeName restricts BaseTypeName Mixed? { Type? } |
|
statEnv |- TypeName derives from BaseTypeName |
Derivation is transitive.
statEnv |- TypeName1 derives from TypeName2 statEnv |- TypeName2 derives from TypeName3 |
|
statEnv |- TypeName1 derives from TypeName3 |
Notation
The judgment
holds when the first element name substitutes for the second element name.
Note
Substitution is a partial order. It is reflexive and transitive by the definition below. It is asymmetric because no cycles are allowed in substitution groups.
Semantics
This judgment is specified by the following rules.
Every element name substitutes for itself.
|
statEnv |- ElementName substitutes for ElementName |
Every element name substitutes for the element it is declared to substitute for.
statEnv.elemDecl(ElementName) => define element ElementName substitutes for BaseElementName Nillable? TypeSpecifier |
|
statEnv |- ElementName substitutes for BaseElementName |
Substitution is transitive.
statEnv |- ElementName1 substitutes for ElementName2 statEnv |- ElementName1 substitutes for ElementName3 |
|
statEnv |- ElementName1 substitutes for ElementName3 |
Notation
The judgment
holds when the result of extending Type1 by Type2 is Type.
Semantics
This judgment is specified by the following rules.
statEnv |- Type1 = AttributeAll1 , ElementContent1 statEnv |- Type2 = AttributeAll2 , ElementContent2 |
|
statEnv |- Type1 extended by Type2 is (AttributeAll1 & AttributeAll2) , ElementContent1 , ElementContent2 |
Notation
The judgment
holds when the result of creating a mixed content from Type1 is Type2.
Semantics
This judgment is specified by the following rules.
An element may optionally include the four built-in attributes xsi:type, xsi:nil, xsi:schemaLocation, or xsi:noNamespaceSchemaLocation.
Notation
The judgment
holds when the second type is the same as the first, with the four built-in attributes added, and with text nodes added if the type is mixed.
Semantics
This judgment is specified by the following rules.
If the type is flagged as mixed, then mix the type and extend it by the built-in attributes.
|
|||
|
|||
statEnv |- mixed Type adjusts to Type'' |
Otherwise, just extend the type by the built-in attributes.
statEnv |- Type extended by BuiltInAttributes is Type' |
|
statEnv |- Type adjusts to Type' |
The definition of BuiltInAttributes appears in [3.1.4 Built-in type declarations].
Notation
The judgment
holds when an element matches the type declaration if the element has a type annotation that derives from the type name, and a content that matches the type.
Semantics
This judgment is specified by the following rules.
If the type is omitted, it is resolved as the empty sequence type.
statEnv |- Derivation? Mixed? { () } resolves to TypeName { Type } |
|
statEnv |- Derivation? Mixed? { } resolves to TypeName { Type } |
If the type specifier names a global type, then the type name is the name of that type, and the type is taken by resolving the type specifier of the global type.
|
|||
|
|||
statEnv |- of type TypeName resolves to TypeName { Type } |
In the above inference rule, note that BaseTypeName is the base type of the type referred to. So this is indeed the original type name, TypeName, which must be returned, and eventually used to annotated the corresponding element or attribute. However, the type specifier needs to be obtained through a second application of the judgment.
If the type specifier is a restriction, then the type name is the name of the base type, and the type is taken from the type specifier.
statEnv |- Mixed? Type adjusts to AdjustedType |
|
statEnv |- restricts TypeName Mixed? { Type } resolves to TypeName { AdjustedType } |
If the type specifier is an extension, then the type name is the name of the base type, and the type is the base type extended by the type in the type specifier.
|
||||
|
||||
statEnv |- extends TypeName Mixed? { Type } resolves to TypeName { AdjustedType } |
Notation
The judgment
holds if the first type is derived from the second type. This corresponds to [Type Derivation OK] in [XML Schema Part 1].
Semantics
This judgment is specified by the following rules.
A type specifier validly derives from a type reference if the type specifier resolves to a type name that derives from the referenced type.
statEnv |- TypeSpecifier resolves to TypeName { Type } statEnv |- TypeName derives from TypeName' |
|
statEnv |- TypeSpecifier derives from of type TypeName' |
There is no rule if the type specifier not a type reference, because it is not possible for a local type to derive from another local type.
Notation
The judgment
holds when matching an element with the given element name against the given element type requires that the element be nillable as indicated and matches the type specifier.
Semantics
This judgment is specified by the following rules.
If the element type is a reference to a global element, then lookup yields the type specifier in the element declaration for the given element name. The given element name must be in the substitution group of the global element.
|
|||
|
|||
statEnv |- ElementName lookup element ElementName' yields Nillable? TypeSpecifier |
If the given element name matches the element name in the element type, and the element type contains a type specifier, then lookup yields that type specifier.
|
statEnv |- ElementName lookup element ElementName Nillable? TypeSpecifier yields Nillable? TypeSpecifier |
If the element type has no element name but contains a type specifier, then lookup yields the type specifier.
If the element type has no element name and no type
specifier, then lookup yields xs:anyType
.
|
statEnv |-
ElementName lookup element
yields of type xs:anyType
|
Notation
The judgment
holds when matching an attribute with the given attribute name against the given attribute type matches the type specifier.
Semantics
This judgment is specified by the following rules.
If the attribute type is a reference to a global attribute, then lookup yields the type specifier in the attribute declaration for the given attribute name.
|
||
|
||
statEnv |- AttributeName lookup attribute AttributeName yields TypeSpecifier |
If the given attribute name matches the attribute name in the attribute type, and the attribute type contains a type specifier, then lookup yields that type specifier.
If the attribute type has no attribute name but contains a type specifier, then lookup yields the type specifier.
If the attribute type has no attribute name and no type
specifier, then lookup yields xs:anySimpleType
.
|
statEnv |-
AttributeName lookup
attribute yields of type
xs:anySimpleType
|
Notation
The judgment
holds if some interleaving of Value1 and Value2 yields Value. Interleaving is non-deterministic; it is used for processing all groups.
Semantics
This judgment is specified by the following rules.
Interleaving two empty sequences yields the empty sequence.
|
statEnv |- () interleave () yields () |
Otherwise, pick an item from the head of one of the sequences, and recursively interleave the remainder.
statEnv |- Value1 interleave Value2 yields Value |
|
statEnv |- Item,Value1 interleave Value2 yields Item,Value |
statEnv |- Value1 interleave Value2 yields Value |
|
statEnv |- Value1 interleave Item,Value2 yields Item,Value |
Notation
The judgment
holds if there are no occurrences of the attribute QName in Value. The judgment
holds if there is one occurrence of the attribute QName in Value, and the value of that attribute is SimpleValue. The judgment
holds if either of the previous two judgments hold.
Semantics
These judgments are defined using the auxiliary judgments
and
which are defined in [5.2.1 Steps].
The filter judgments are defined as follows.
Introduction
The semantics of a type is given by the notion of matching, I.e., the set of all values which match that type. A tree in the [XQuery 1.0 and XPath 2.0 Data Model] matches a type in the [XPath/XQuery] type system, if and only if:
It verifies the structural constraints described by the type. For instance, the data model value:
element bib:pubdate { 1954, 1966, 1974, 1986 }
matches the following type:
element { attribute country { xs:string }?, xs:integer* }
because the element name "bib:pubdate" matches the wildcard element in the type (in which the name is omitted), the attribute "country" is optional, and the content of that element is indeed a sequence of integers.
It verifies the name constraints described by the type. For instance, the data model value:
element bib:pubdate of type xs:anyType { 1954, 1966, 1974, 1986 }
does not match the following type:
element of type PublicationInfo define type PublicationInfo { attribute country { xs:string }?, xs:integer* }
because the element in the data model is annotated with
the type name xs:anyType
while the schema expects an element
annotated with the type name PublicationInfo.
Notation
The judgment
holds when the given value matches the given nillable type.
Semantics
This judgment is specified by the following rules.
If the type is not nillable, then the xsi:nil attribute must not appear in the value, and the value must match the type.
|
|||
|
|||
statEnv |- Value nil-matches Type |
If the type is nillable, and the xsi:nil attribute does not appear or is false, then the value must match the type.
|
|||
|
|||
statEnv |- Value nil-matches nillable Type |
If the type is nillable, and the xsi:nil attribute is true, then the value must match the attributes in the type. The element content of the type is ignored.
Notation
The judgment
holds when the given value matches the given type.
Semantics
This judgment is specified by the following rules.
The empty sequence matches the empty sequence type.
If two values match two types, then their sequence matches the corresponding sequence type.
|
|||
|
|||
statEnv |- Value1,Value2 matches Type1,Type2 |
If a value matches a type, then it also matches a choice type where that type is one of the choices.
If two values match two types, then their interleaving matches the corresponding all group.
|
||||
|
||||
statEnv |- Value matches Type1 & Type2 |
An optional type matches a value of that type or the empty sequence.
The following rules are used to match a value against a sequence of zero (or one) or more types.
statEnv |- Value1 matches Type statEnv |- Value2 matches Type* |
|
statEnv |- Value1, Value2 matches Type* |
statEnv |- Value1 matches Type statEnv |- Value2 matches Type* |
|
statEnv |- Value1, Value2 matches Type+ |
An element matches an element type if the element type resolves to another element type, and the type annotation is derived from the type annotation of the resolved type, and the element value matches the enclosed type of the resolved type.
|
|||||
|
|||||
statEnv |- element ElementName of type TypeName { Value } matches ElementType |
The rule for attributes is similar.
|
|||||
|
|||||
statEnv |- attribute AttributeName of type TypeName { Value } matches AttributeType |
A document node matches the corresponding document type.
A text node matches text.
An atomic value matches an atomic type if its type annotation derives from the atomic type. The value itself is ignored -- this is checked as part of validation.
statEnv |- AtomicType derives from AtomicType' |
|
statEnv |- AtomicValue of type AtomicType matches AtomicType' |
An atomic value matches "untyped" only if it is annotated
with xs:anySimpleType
.
|
statEnv |-
AtomicValue of type xs:anySimpleType
matches untyped
|
Note
The above definition of matching, although complete and precise, does not give a simple means to compute the structural matching. Notably, some of the above rules can be non-deterministic (e.g., the rule for matching of choice or repetition).
The structural component of the [XPath/XQuery] type system can be modeled by tree grammars. Computing structural matching can be done by computing if a given tree grammar recognizes the given data model value.
This document does not provide a complete algorithm to recognize a given tree by a tree grammar. The interested reader can consult the relevant literature, for instance [Languages], or [TATA].
Ed. Note: A future version of this document should include a more complete description of algorithms to compute type matching.
Recall the rule for matching an element against an element type.
|
|||||
|
|||||
statEnv |- element ElementName of type TypeName { Value } matches ElementType |
This rule simplifies greatly in the case that the type specifier is a reference to a global type.
|
||||
|
||||
statEnv |- element ElementName of type TypeName { Value } matches ElementType |
In this case, it is not necessary to do resolution or to check that the value matches the type, because this is guaranteed by the way in which elements are labeled with types. Note that the optimization applies only if xsi:nil is not true.
A similar optimization applies to attributes.
Erase and annotate define the core of XML Schema validation. They are used to define (partially) the semantics of the validate operation in [XPath/XQuery].
Notation
To define erasure, an auxiliary judgment is needed. The judgment
holds when SimpleValue erases to the string String.
Semantics
This judgment is specified by the following rules.
The empty sequence erases to the empty string.
|
statEnv |- () simply erases to "" |
The concatenation of two non-empty sequences of values erases to the concatenation of their erasures with a separating space.
|
|||
|
|||
statEnv |- SimpleValue1,SimpleValue2 simply erases to xf:concat(String1," ",String2) |
An atomic value erases to its string representation.
|
statEnv |-
AtomicValue of type AtomicType
simply erases to
dm:string-value (AtomicValue)
|
Notation
The judgment
holds when the erasure of Value is Value'.
Semantics
This judgment is specified by the following rules.
The empty sequence erases to itself.
The erasure of the concatenation of two values is the concatenation of their erasure, so long as neither of the two original values is simple.
|
|||
|
|||
statEnv |- Value1,Value2 erases to Value1',Value2' |
The erasure of an element is an element that has the same
name and the type xs:anyType
and the erasure of the original
content.
|
||
|
||
statEnv |-
element ElementName of type
TypeName { Value } erases to element
ElementName of type xs:anyType { Value'
}
|
The erasure of an attribute is an attribute that has the
same name and the type xs:anySimpleType
and the simple erasure
of the original content labeled with xs:anySimpleType
.
|
||
|
||
statEnv |-
attribute AttributeName of type
TypeName { Value } erases to attribute
AttributeName of type xs:anySimpleType { String
of type xs:anySimpleType }
|
The erasure of a document is a document with the erasure of the original content.
The erasure of a text node is itself.
The erasure of a simple value is the corresponding text node.
|
||
|
||
statEnv |- SimpleValue erases to text { String } |
Notation
The judgment
holds if the result of casting the SimpleValue to SimpleType is SimpleValue'.
Ed. Note: Issue: The simply annotate judgment is used to describe the behavior of validation of simple values. This operation is essentially similar to casting from string to an atomic value. It is not clear if this actually aligns to the behavior of casting as specified by the [XQuery 1.0 and XPath 2.0 Functions and Operators]. See [Issue-0156: Casting and validation].
Semantics
This judgment is specified by the following rules.
Simply annotating a simple value to a union type yields the result of simply annotating the simple value to either the first or second type in the union. Note that simply annotating to the second type is attempted only if simply annotating to the first type fails.
|
||
|
||
statEnv |- simply annotate as SimpleType1|SimpleType2 (SimpleValue) => SimpleValue' |
|
|||
|
|||
statEnv |- simply annotate as SimpleType1|SimpleType2 (SimpleValue) => SimpleValue' |
The simple annotation rules for ?, +, *, and none are similar.
|
statEnv |- simply annotate as SimpleType1? ( () ) => () |
|
||
|
||
statEnv |- simply annotate as SimpleType? (SimpleValue) => SimpleValue' |
|
statEnv |- simply annotate as SimpleType* ( () ) => () |
|
||
|
||
statEnv |- simply annotate as SimpleType* (SimpleValue1,SimpleValue2) => SimpleValue1',SimpleValue2' |
|
||
|
||
statEnv |- simply annotate as SimpleType+ (SimpleValue1,SimpleValue2) => SimpleValue1',SimpleValue2' |
Simply annotating an atomic value to xs:string yields its string representation.
|
statEnv |- simply annotate as xs:string (AtomicValue) => dm:string-value(AtomicValue) |
Simply annotating an atomic value to xs:decimal yields the decimal that results from parsing its string representation.
|
statEnv |-
simply annotate as xs:decimal (AtomicValue)
=>
xs:decimal(dm:string-value (AtomicValue))
|
Similar rules are assumed for the rest of the 19 XML Schema primitive types.
Notation
The judgment
holds if it is possible to annotate value Value as if it had the nillable type Type and Value' is the corresponding annotated value.
Semantics
This judgment is specified by the following rules.
If the type is not nillable, then the xsi:nil attribute must not appear in the value, and it must be possible to annotate value Value as if it had the type Type.
|
|||
|
|||
statEnv |- nil-annotate as Type ( Value ) => Value' |
If the type is nillable, and the xsi:nil attribute does not appear or is false, then it must be possible to annotate value Value as if it had the type Type.
|
|||
|
|||
statEnv |- nil-annotate as nillable Type ( Value ) => Value' |
If the type is nillable, and the xsi:nil attribute is true, then it must be possible to annotate value Value as if it had a type where the attributes in the type are kept and the element content of the type is ignored.
|
|||
|
|||
statEnv |- nil-annotate as nillable (AttributeAll, ElementContent) ( Value ) => Value' |
Notation
The judgment
holds if it is possible to annotate value Value as if it had type Type and Value' is the corresponding annotated value.
Note
Assume an XML Infoset instance X is validated against an XML Schema S, yielding PSVI instance X'. Then if X corresponds to Value and S corresponds to Type and X' corresponds to Value', the following should hold: annotate as Type ( Value ) => Value'.
Semantics
This judgment is specified by the following rules.
Annotating the empty sequence as the empty type yields the empty sequence.
|
statEnv |- annotate as () (()) => () |
Annotating a concatenation of values as a concatenation of types yields the concatenation of the annotated values.
|
|||
|
|||
statEnv |- annotate as Type1,Type2 (Value1,Value2) => Value1',Value2' |
Annotating a value as a choice type yields the result of annotating the value as either the first or second type in the choice.
statEnv |- annotate as Type1 (Value) => Value' |
|
statEnv |- annotate as Type1|Type2 (Value) => Value' |
statEnv |- annotate as Type2 (Value) => Value' |
|
statEnv |- annotate as Type1|Type2 (Value) => Value' |
Annotating a value as an all group uses interleaving to decompose the original value and recompose the annotated value.
Ed. Note: Jerome and Phil: Note that this may reorder the original sequence. Perhaps we should disallow such reordering. Specifying that formally is not as easy as we would like.
|
|||||
|
|||||
statEnv |- annotate as Type1 & Type2 ( Value ) => Value' |
The annotation rules for ?, +, *, none are similar.
statEnv |- annotate as (Type | ())(Value) => Value' |
|
statEnv |- annotate as Type? (Value) => Value' |
statEnv |- annotate as Type (Value1) => Value1' statEnv |- annotate as Type* (Value2) => Value2' |
|
statEnv |- annotate as Type+ (Value1,Value2) => (Value1',Value2') |
|
statEnv |- annotate as Type* ( () ) => () |
statEnv |- annotate as Type (Value1) => Value1' statEnv |- annotate as Type* (Value2) => Value2' |
|
statEnv |- annotate as Type* (Value1,Value2) => (Value1',Value2') |
To annotate an element with no xsi:type attribute, first look up the the element type, next resolve the resulting type specifier, then annotate the value against the resolved type, and finally return a new element with the name of the original element, the resolved type name, and the annotated value.
|
|||||
|
|||||
statEnv |-
annotate as ElementType ( element
ElementName of type xs:anyType { Value } )
=> element ElementName of type
TypeName { Value' }
|
To annotate an element with an xsi:type attribute, define a type specifier corresponding to the xsi:type. Look up the element type, yielding a type specifier, and check that the xsi:type specifier derives from this type specifier. Resolve the xsi:type specifier, then annotate the value against the resolved type, and finally return a new element with the name of the original element, the resolved type name, and the annotated value.
|
|||||||
|
|||||||
statEnv |-
annotate as ElementType ( element
ElementName of type xs:anyType { Value } )
=> element ElementName of type
TypeName { Value' }
|
Ed. Note: Issue: the treatment of xsi:type in the [XQuery 1.0: A Query Language for XML] document and in the formal semantics document still differ. See [Issue-0142: Treatment of xsi:type in validation].
The rule for attributes is similar to the first rule for elements.
|
||||
|
||||
statEnv |-
annotate as AttributeType (
attribute AttributeName of type xs:anySimpleType {
Value } ) => attribute
AttributeName of type TypeName { Value'
}
|
Annotating a document node yields a document with the annotation of its contents.
statEnv |- annotate as Type (Value) => Value' |
|
statEnv |- annotate as document { Type } ( document { Value } ) => document { Value' } |
Annotating a text node as text yields itself.
|
statEnv |- annotate as text (text { String }) => text { String } |
Annotating a text nodes as a simple type is identical to casting.
statEnv |-
simply annotate as SimpleType ( String
as xs:anySimpleType ) =>
SimpleValue'
|
|
statEnv |- annotate as SimpleType ( text { String } ) => SimpleValue' |
Annotating a simple value as a simple type is identical to casting.
statEnv |- simply annotate as SimpleType ( SimpleValue ) => SimpleValue' |
|
statEnv |- annotate as SimpleType ( SimpleValue ) => SimpleValue' |
Introduction
This section defines the semantics of subtyping in [XPath/XQuery]. Subtyping is used during the static type analysis, in typeswitch expressions, treat and assert expressions, and to check the correctness of function applications.
Notation
The judgment
holds if the first type is a subtype of the second.
Semantics
This judgment is true if and only if, for every value Value, then Value matches Type implies Value matches Type'.
Note
It is easy to see that the subtype relation <: is a partial order, i.e. it is reflexive:
statEnv |- Type <: Typeand it is transitive: if,
statEnv |- Type1 <: Type2and,
statEnv |- Type2 <: Type3then,
statEnv |- Type1 <: Type3The above definition although complete and precise, does not give a simple means to compute subtyping.
The structural component of the [XPath/XQuery] type system can be modeled by tree grammars. Computing subtyping between two types can be done by computing if inclusion holds between their corresponding tree grammars.
This document does not provide a complete algorithm to compute inclusion between tree grammar. The interested reader can consult the relevant literature on tree grammars, for instance [Languages], or [TATA].
Ed. Note: A future version of this document should include a more complete description of algorithms to compute subtyping.
In a few cases, equivalence between two types (i.e., that they define exactly the same domain over data model instances) is used.
Notation
The judgment
holds if the Type1 is equivalent to the Type2.
Semantics
By definition, Type1 = Type2 if and only if, Type1<:Type2 and Type2<: Type1.
This section defines the notion of Prime Type, and operations on prime types. Prime types play an important role in defining the static semantics of [XPath/XQuery], and are used notably in the semantics of "for", "unordered", and "sortby" expressions.
Some expressions must operate on sequences where all items have the same type -- this type possibly being a choice of item types. These include FLWR expressions, sortby, and distinct. For example, let's assume the document
<paper> <author>Buneman</author> <author>Davidson</author> <author>Fernandez</author> <author>Suciu</author> <title>Adding structure to unstructured data</title> <editor>Afrati</editor> <editor>Kolaitis</editor> </paper>
is of type
element paper { element author {xs:string}+, element title {xs:string}, element editor {xs:string}* }
The following query extracts a sequence of authors followed by editors and sorts them by their content.
(/paper/author,/paper/editor) sortby (.)
This results in a sequence of authors and editors.
<editor>Afrati</editor> <author>Buneman</author> <author>Davidson</author> <author>Fernandez</author> <editor>Kolaitis</editor> <author>Suciu</author>
Based on the content model for the paper
element, the type inferred for the expression
(/paper/author,/paper/editor)
is simply
element author {xs:string}+, element
editor{xs:string}*
. This type indicates that there should
be a sequence of one or more authors, followed by zero or more
editors. Due to the sortby expression, the original order of
elements within the type can then be changed in an arbitrary
way. As a result, the regular expression which describes the
type cannot preserve any information which relates to order. The
type infered for the complete expression reflects the arbitrary
order by repeating a choice of author and editor elements.
(element author {xs:string} | element editor {xs:string})+
Intuitively, sorting expressions, as well as iteration with for expressions, always operate on sequences of items of the same type, this type possibly being a choice. A choice of items is called a Prime type, and can be described by the following grammar production.
[34 (Formal)] | PrimeType | ::= |
When inferring the type of a for or a sortby expression, the system needs to compute such a prime type.
It also needs to compute the appropriate occurrence indicator for the sequence type. For instance, note that the type in the above example ends in a plus rather than a star, since there must be at least one author element in the sequence.
The rest of this section defines operations related to prime types and occurrence indicators, which are used during static type analysis.
Notation
Two auxiliary functions on types are used.
The type function prime(Type) extracts all item types from the type Type, and combines them into a choice.
The function quantifier(Type)
approximates the possible number of items in Type with
the occurrence indicators supported by the [XPath/XQuery] type
system (?, +, *
).
For interim results, the following auxiliary occurrence
indicators are used: 1
for exactly one
occurrence, and 0
for exactly zero occurrences,
i.e., the occurrence indicator of the empty list.
Types and occurrence can be combined with the · operation, as follows.
Type · 0 | = | () |
Type · 1 | = | Type |
Type · ? | = | Type? |
Type · + | = | Type+ |
Type · * | = | Type* |
Example
For instance, here are the result of applying prime and quantifier on a few simple types.
prime(element a+) = element a prime(element a | ()) = element a prime(element a?,element b?) = element a | element b prime(element a | element b+, element c*) = element a | element b | element c quantifier(element a+) = + quantifier(element a | ()) = ? quantifier(element a?,element b?) = * quantifier(element a | element b+, element d*) = +
Note that the last occurrence indicator should be '+', since the regular expression is such that there must be at least one element in the sequence (this element being an 'a' element or a 'b' element).
Note
Note that both prime and quantifier functions are only used within type inference rules; they are not part of the [XPath/XQuery] syntax.
Semantics
The prime function is defined by induction as follows.
prime(ItemType) | = | ItemType |
prime(()) | = | none |
prime(none) | = | none |
prime(Type1 , Type2) | = | prime(Type1) | prime(Type2) |
prime(Type1 & Type2) | = | prime(Type1) | prime(Type2) |
prime(Type1 | Type2) | = | prime(Type1) | prime(Type2) |
prime(Type?) | = | prime(Type) |
prime(Type*) | = | prime(Type) |
prime(Type+) | = | prime(Type) |
Semantics
The quantifier function is defined by induction as follows.
quantifier(ItemType) | = | 1 |
quantifier(()) | = | 0 |
quantifier(none) | = | 0 |
quantifier(Type1 , Type2) | = | quantifier(Type1) , quantifier(Type2) |
quantifier(Type1 & Type2) | = | quantifier(Type1) , quantifier(Type2) |
quantifier(Type1 | Type2) | = | quantifier(Type1) | quantifier(Type2) |
quantifier(Type?) | = | quantifier(Type) · ? |
quantifier(Type*) | = | quantifier(Type) · * |
quantifier(Type+) | = | quantifier(Type) · + |
This definition uses the sum (Occurrence1 , Occurrence2), the choice (Occurrence1 | Occurrence2), and the product (Occurrence1 · Occurrence2) of two occurrence indicators Occurrence1, Occurrence2, which are defined by the following tables.
|
|
|
Using these two newly defined functions, the result type of a SortExpr can be computed as follows. If Expr has type Type then Expr sortby SortSpecList has type prime(Type) · quantifier(Type). For the formal type inference rule see [5.9.1 Sorting Expressions]. Similar rules are applied to type iteration over sequences using for, as well as other operations that destroy sequence order - union, intersect, except, distinct-node, distinct-value, and unordered.
Note
Note that prime(Type) · quantifier(Type) is always a super type of the original type Type and therefore, can be used as an approximation for it. More formally, the following property always holds: Type <: prime(Type) · quantifier(Type). This property is important for the soundness of the static type analysis.
Static type analysis for the "typeswitch" expression has to compute the choice of all the common items between two types, and the corresponding occurrence indicators.
For instance, consider the following typeswitch expression, applied on the result of the previous query.
let $persons := (/paper/author,/paper/editor) sortby (.) return typeswitch $person case element author return <single-author> { $person } </single-author> case element author* return <authors-only> { $person } </authors-only> default return <authors-and-editors> { $person } </authors-and-editors>
Static type analysis needs to compute the type of the
variable $person
within each case clause. In the
first case, the variable is of type element
author
. In the second case, the variable is of type
element author+
. The '+' occurrence indicator can
be infered since the input type guarantees the input sequence
has at least one author.
Notation
The two following auxiliary functions on types are used.
The function common-prime(PrimeType1, PrimeType2) computes the type for all the items common between the prime types PrimeType1 and PrimeType2, and combines them into a new prime type.
The function common-occurrence(Occurrence1, Occurrence2) computes the occurrence indicator which approximates the possible number of items that can result from the constraints described by both Occurrence1, and Occurrence2.
Example
For instance, here are the result of applying common-prime and common-occurrence on a few simple prime types.
common-prime((element a),(element a)) = element a common-prime((element a),(element b)) = none common-prime((element a | element b | element c), (element c | element a)) = element a | element c common-occurrence(+,+) = + common-occurrence(*,+) = + common-occurrence(?,+) = 1
Note that the last occurrence indicator should be '1', since the first input occurrence indicator '?' specifies that there should be at most one item, while the second '+' specifies that there should be at least one.
Semantics
The common-prime function is defined by induction as follows.
The common-prime for two arbitrary prime types, is defined as the choice containing the results of the function common-prime applied between all possible pairs of items in each input prime types.
|
|||||
|
|||||
statEnv |- common-prime( ( ItemType1 | ··· | ItemTypen ), ( ItemType1' | ··· | ItemTyper' ) ) = ItemType(1,1) | ··· | ItemType(n,r) |
The common-prime function between any pair of item types return either a new item type or the empty choice (none); remember that none is the unit for choice.
If one of the item type is a subtype of the other, then the function returns the smaller item type.
statEnv |- ItemType1 <: ItemType2 |
|
statEnv |- common-prime(ItemType1, ItemType2) = ItemType1 |
statEnv |- ItemType2 <: ItemType1 |
|
statEnv |- common-prime(ItemType1, ItemType2) = ItemType2 |
Ed. Note: Issue: The above rule does not deal with cases where the two item types might have some intersection (i.e., there exist values which match both types), but subtyping does not hold between them. See [Issue-0155: Common primes for incomparable types].
In all the other cases, common-prime returns none. I.e., otherwise:
Semantics
The common-occurrence function is defined by the following table.
common-occurrence | 0 | 1 | ? | + | * |
0 | 0 | 0 | 0 | 0 | 0 |
1 | 0 | 1 | 1 | 1 | 1 |
? | 0 | 1 | ? | 1 | ? |
+ | 0 | 1 | 1 | + | + |
* | 0 | 1 | ? | + | * |
Example
The above definition relies on subtyping which covers complex cases (involving derivation, substitution groups, etc.) appropriately. For instance, consider the following type declarations.
define element person of type Person define type Person { element name of type xs:string } define element student substitutes for person of type Student define type Student extends Person { element promotion of type Promotion, element grade of type Grade } define type Promotion restricts xs:integer { xs:integer } define type Grade restricts xs:integer { xs:integer }
Here are some more complex examples of the application of the common-prime type function involving that schema.
common-prime(Promotion, xs:integer) = Promotion common-prime(Promotion, Grade) = none common-prime(element of type Person, element of type Student) = element of type Student common-prime(element person, element student) = element student
Ed. Note: Alignment between [XPath/XQuery], the [XQuery 1.0 and XPath 2.0 Data Model], and the [XPath/XQuery] formal semantics. There are some known discrepancies between the type models in the Data Model document, the [XPath/XQuery] document and this document. Currently the [XPath/XQuery] grammar does not contain comments, processing-instructions or schema-components. Currently this document does not deal with PI and comment nodes, which are present in the Data Model. See issues [Issue-0068: Document Collections], [Issue-0105: Types for nodes in the data model.].
Ed. Note: Complexity of type operations. There are concerns about the complexity of type inference, notably about type subsumption used during type inference, and validation used during evaluation of some of the type operations (e.g., typeswitch). Additionally, there are many language features for which it is possible to define special type inference rules that would give tighter bounds. The question is, which features, which rules, and how do they interact with the complexity of type inference and subtype computation. See [Issue-0080: Typing of parent], [Issue-0083: Expressive power and complexity of typeswitch expression], [Issue-0091: Attribute expression].
The organization of this section parallels the organization of Section 2 of the [XPath/XQuery] document.
Introduction
The expression context for a given expression consists of all the information that can affect the result of the expression. This information is organized into the static context and the evaluation context. This section specifies the environments that represent the context information used by [XPath/XQuery] expressions.
The [XPath/XQuery] static inference rules use the environment group statEnv containing the environments built during static type checking and used during both static type checking and dynamic evaluation.
The following environments are maintained in the static environment group:
statEnv.namespace |
The namespace environment maps namespace prefixes (NCNames) onto namespace URIs (URIs). The namespace environment captures in-scope namespaces in the [XPath/XQuery] static context. | ||
statEnv.default_namespace |
The default namespace environment maps "element", and "function" to a namespace URI (a URI), as determined by the appropriate namespace declaration. The default namespace environment captures the default namespace for element and type names and Default namespace for function names in the [XPath/XQuery] static context. | ||
statEnv.typeDefn |
The type definition environment maps type names (TypeNames) onto their global type definitions (Definitions). The type definition environment captures in-scope schema definitions in the [XPath/XQuery] static context. | ||
statEnv.elemDecl |
The element declaration environment maps element names (ElementNames) onto their global element declarations (Definitions). The element declaration environment does not have a counterpart in the [XPath/XQuery] static context. See [Issue-0159: Element and attribute declarations in the static context]. | ||
statEnv.attrDecl |
The attribute declaration environment maps attribute names (AttributeNames) onto their global attribute declarations (Definitions). The attribute declaration environment does not have a counterpart in the [XPath/XQuery] static context. See [Issue-0159: Element and attribute declarations in the static context]. | ||
statEnv.varType |
The variable static type environment maps variable names (Variables) to their static types (Types). The variable static type environment captures in-scope variables in the [XPath/XQuery] static context. | ||
statEnv.funcType |
The function declaration environment
stores the static type signatures of functions. Because
[XPath/XQuery] allows multiple functions with the same name
differing only in the number of arguments, this
environment maps function name/arity (QName, integer)
pairs to function type signatures The function declaration environment captures in-scope functions in the [XPath/XQuery] static context. | ||
statEnv.base_uri |
The base uri environment contains a unique namespace URI (a URI). The base uri environment captures the base URI in the [XPath/XQuery] static context. |
Ed. Note: Issue: The static environment does not represent collations. See [Issue-0160: Collations in the static environment]
Environments have an initial state when [expression/query] processing begins, containing, for example, the function signatures of all built-in functions.
A common use of the static environment is to expand QNames by looking up namespace prefixes in the statEnv.namespace environment.
The helper function expand
is
used to expand QNames by looking up the namespace prefix in
statEnv.namespace. This function is defined as follows:
statEnv |-
expand
(QName) = qname(URI,
ncname)
or
statEnv |-
expand
(QName) = qname(ncname)
the right hand side is a QName value (not a QName expression).
The helper expand
function is defined as
follows:
If QName matches
NCName1:
NCName2, and if
statEnv.namespace(NCName1) = URI, then the expression
yields qname(URI,NCName2). If the namespace
prefix NCName1 is not found in statEnv.namespace, then the
expression does not apply (that is, the inference rule will
not match).
If QName matches NCName, NCName is an element or type name, and statEnv.default_namespace("element") = URI, then the expression yields qname(URI,NCName), where URI is the default namespace in effect.
If QName matches NCName, NCName is a function name, and statEnv.default_namespace("function") = URI, then the expression yields qname(URI,NCName), where URI is the default namespace in effect.
Ed. Note: The above rules could be given as proper inference rules defining the
expand
judgment.
Here is an example that shows how the static environment is modified in response to a namespace definition.
This rule reads as follows: "the phrase on the bottom (a namespace declaration followed by a sequence of expressions) is well-typed (accepted by the static type inference rules) within an environment statEnv if the sequence of expressions above the line is well-typed in the environment obtained from statEnv by adding the namespace declaration".
This is the common idiom for passing new information in an environment using sub-expressions. In the case where the environment must be updated with a completely new component, the following notation is used:
statEnv [ namespace = (NewEnvironment) ]dynEnv denotes the group of environments built and used only during dynamic evaluation.
The following environments are dynamic:
dynEnv.funcDefn |
The dynamic function environment maps a function name to a function definition. The function definition consists of an expression, which is the function's body, and a list of variables, which are the function's formal parameters. As with statEnv.funcType, dynEnv.funcDefn requires a function name and a parameter count: it maps a (QName, integer) pair to a value list of the form (Expr , Variable1, ..., Variablen). | ||
dynEnv.varValue |
The dynamic value environment maps a variable name (QName) onto the variable's current value (Value). |
Ed. Note: DD: this still does not account for those functions that are genuinely overloaded, as some of the built-in functions are. Probably this will be handled by special rules for those functions in the main semantics section of the document. See [Issue-0122: Overloaded functions]
Finally, dynamic environments have an initial state when [expression/query] processing begins, containing, for example, the function declarations of all built-in functions.
Ed. Note: Somewhere an exact definition of what is in the initial environments is needed. Notice that for XPath this is partially defined by the containing language. See [Issue-0115: What is in the default context?].
The following Formal Semantics built-in variables represent the context item, context position , and context size properties of the evaluation context:
Built-in Variable | Represents: |
$fs:dot | context item |
$fs:position | context position |
$fs:last | context size |
$fs:implicitTimezone | implicit timezone |
Variables with the "fs" namespace prefix are reserved for use in the definition of the Formal Semantics. It is a static error to define a variable in the "fs" namespace.
Ed. Note: "fs" is actually a namespace prefix and should be replaced with a proper namespace URI unique to this spec. See [Issue-0100: Namespace resolution].
Values of $fs:dot, $fs:position and $fs:last can be
obtained by invoking the xf:context-item(),
xf:position()
and xf:last()
functions,
respectively. The context document, can be
obtained by application of the xf:root()
function.
The variable $fs:implicitTimezone is used to represent the implicit timezone, and is used by the timezone related functions in [XQuery 1.0 and XPath 2.0 Functions and Operators].
Ed. Note: The Formal Semantics does not yet model the semantics of semantics of timezone related functions.
Ed. Note: The following dynamic contexts have no formal representation yet: current-date, current-time and current-dateTime. See [Issue-0114: Dynamic context for current date and time]
[XPath/XQuery] has three functions that provide access to input
data: input
, collection
, and
document
. The dynamic semantics of these three input
functions are described in more detail in [XQuery 1.0 and XPath 2.0 Functions and Operators]. The static typing for these
function is still an open issue (See [Issue-0137:
Typing of input functions]).
This section gives background material about the [XPath/XQuery] data model. More information on the [XPath/XQuery] data model can be found in [2.3 Data Model].
This section gives background material about [XPath/XQuery] type checking. More information on the [XPath/XQuery] type system can be found in [2.4 Schemas and types] and [3 The XQuery Type System].
Introduction
SequenceTypes can be used in [XPath/XQuery] to refer to a type imported from a schema (see [6 The Query Prolog]). SequenceTypes are used to declare the types of function parameters and in several kinds of [XPath/XQuery] expressions.
The syntax of SequenceTypes is described by the following grammar productions.
The semantics of SequenceTypes is defined by means of normalization rules from SequenceTypes to the [XPath/XQuery] type system (see [3 The XQuery Type System]).
Core Grammar
The core grammar productions for sequence types are:
Ed. Note: Note that normalization on SequenceTypes does not occur during the normalization phase but whenever a dynamic or static rule requires it. The reason for this deviation from the processing model is that the result of SequenceType normalization is not part of the [XPath/XQuery] syntax (See issue [Issue-0089: Syntax for types in XQuery]). SequenceType normalization is the only occurrence of such a deviation in the formal semantics.
Notation
To define the semantics of SequenceTypes, the following auxiliary mapping rule is used.
[SequenceType]sequencetype |
== |
Type |
specifies that SequenceType is mapped to Type, in the XQuery type system.
OccurenceIndicators are left unchanged when normalizing SequenceTypes into [XPath/XQuery] types. Each kind of SequenceType component is normalized separately into the [XPath/XQuery] type system.
[ItemType OccurrenceIndicator]sequencetype |
== |
[ItemType]sequencetype OccurrenceIndicator |
The "empty" sequence type is mapped to the empty sequence type in the [XPath/XQuery] type system.
[empty]sequencetype |
== |
[()]sequencetype |
The SequenceType component with type SchemaType is mapped directly into the [XPath/XQuery] type system.
[element SchemaType]sequencetype |
== |
element SchemaType |
[attribute SchemaType]sequencetype |
== |
attribute SchemaType |
The mapping still does not handle SequenceTypes using SchemaContext (See [Issue-0138: Semantics of Schema Context]). The two following rules map references to a global element or attribute, without taking the schema context into account.
[element QName]sequencetype |
== |
element QName |
[attribute QName]sequencetype |
== |
attribute QName |
Document nodes, text nodes, untyped and atomic types are left unchanged.
[text]sequencetype |
== |
text |
[document]sequencetype |
== |
document |
[untyped]sequencetype |
== |
untyped |
[AtomicType]sequencetype |
== |
AtomicType |
Processing instruction and comment types are ignored. See [Issue-0105: Types for nodes in the data model.].
[comment]sequencetype |
== |
[processing-instruction]sequencetype |
== |
The SequenceType components "node",
"item", and "atomic value" correspond to
wildcard types. node
indicates that any node is
allowed, "atomic value" indicates that any atomic (not list)
value is allowed, and item
indicates that any node or atomic
value is allowed. The following mapping rules make use of the corresponding
wildcard types.
[node]sequencetype |
== |
(element | attribute | text | document) |
[item]sequencetype |
== |
(element | attribute | text | document | xs:string | xs:decimal | ... ) |
[atomic value]sequencetype |
== |
(xs:string | xs:decimal | ... ) |
Ed. Note: Jerome: The Formal Semantics makes use of fs:numeric which is not in XML Schema. This is necessary for the specification of some of XPath type conversion rules. See [Issue-0127: Datatype limitations].
During processing of a query, it is sometimes necessary to determine whether a given value matches a type that was declared using the SequenceType syntax. This process is known as SequenceType matching, and is formally specified in [3.3 Matching].
Introduction
Some expressions do not require their operands to exactly match the expected type. For example, function parameters and returns expect a value of a particular type, but automatically perform certain type conversions, such as extraction of atomic values from nodes, promotion of numeric values, and implicit casting of untyped values. The conversion rules for function parameters and returns are discussed in [5.1.4 Function Calls]. Other operators that provide special conversion rules include arithmetic operators, which are discussed in [5.4 Arithmetic Expressions], and value comparisons, which are discussed in [5.5.1 Value Comparisons].
Some special conversion rules: atomization, effective boolean value, and fallback conversions, are used in several places in the language.
Notation
There are two variants of the normalization function []Atomize.
The first variant, []Atomize is not parameterized by the required type of the expression.
The second variant, []Atomize(Type), is parameterized by the required type.
Both functions convert an expression into an expression that returns an optional atomic value and is used in the normalization of expressions whose required type is an optional atomic value.
A node is converted to an optional atomic value by extracting its typed content.
[Expr]Atomize | |||||||
== | |||||||
|
In the parameterized variant, an atomic value with type untyped is always cast to the required type:
[Expr]Atomize(Type) | |||||||||
== | |||||||||
|
Ed. Note: Issue:Don Chamberlin indicates that this rule should do type promotion. See [Issue-0161: Type promotion in Atomization].
Notation
The following normalization rule implements type exceptions: []Type_Exception(Type).
There are two definitions for each of these functions.
The definition here implements the strict
type
exception policy. The strict policy always raises an
error:
[Expr]Type_Exception(Type) |
== |
xf:error() |
The flexible
type exception policy is defined
in [4.4.3.3 Fallback Conversion].
Notation
The function []Effective_Boolean_Value takes an expression and normalizes it into an effective boolean value.
The effective boolean value is obtained through the following normalization rule. Note that the default clause returns true is at least one item in the sequence is a node, otherwise, it raises a type exception.
[Expr]Effective_Boolean_Value | ||||
== | ||||
|
The following rules define the "fallback conversions" that support the "flexible" type-exception policy. These rules depend on the required type for the expression that is being normalized.
In the first rule, the required type is xs:boolean. The conditional expression in the "default return" clause below guarantees that in an arbitrary sequence of items, if at least one value is a node, then the boolean expression evaluates to true.
[Expr]Type_Exception(xs:boolean) | |||||
== | |||||
|
Ed. Note: MFF: The rule above requires that $v/self::node() on an atomic value returns () rather than raise an error.
In the next rule, the required type is "node". The conditional expression in the "default return" clause below guarantees that, if the first item is a node, then it returns the node, otherwise it returns an error.
[Expr]Type_Exception(node) | ||||||
== | ||||||
|
Ed. Note: MFF: All the remaining rules in the fallback conversions table must be specified. See [Issue-0113: Incomplete specification of type conversions]
This section describes error handling and conformance levels.
Ed. Note: Issue: Error handling is not formally specified. See [Issue-0094: Static type errors and warnings]
Ed. Note: Issue: Conformance levels are not formally specified. See [Issue-0169: Conformance Levels]
This section gives the semantics of all the [XPath/XQuery] expressions. The organization of this section parallels the organization of Section 3 of the [XPath/XQuery] document.
[5 (XQuery)] | Expr | ::= | |
[10 (XPath)] | Expr | ::= |
For each expression, a short description and the relevant grammar productions are given. The semantics of an expression includes the normalization, static analysis, and dynamic evaluation phases. Recall that normalization rules translate [XPath/XQuery] syntax into core [XPath/XQuery] syntax. In the sections that contain normalization rules, the Core grammar productions into which the expression is normalized are also provided. After normalization, sections on static type inference and dynamic evaluation define the static type and dynamic value for the core expression.
Core Grammar
The core grammar production for expressions is:
[5 (Core)] | Expr | ::= |
Primary expressions are the basic primitives of the language.They include literals, variables, function calls, and the use of parentheses to control precedence of operators.
[39 (XQuery)] | PrimaryExpr | ::= | |
[227 (XQuery)] | VarName | ::= |
Core Grammar
The core grammar productions for primary expressions are:
[24 (Core)] | PrimaryExpr | ::= | |
[169 (Core)] | VarName | ::= |
Introduction
A literal is a direct syntactic representation of an atomic value. [XPath/XQuery] supports two kinds of literals: string literals and numeric literals.
[56 (XQuery)] | Literal | ::= | |
[55 (XQuery)] | NumericLiteral | ::= | |
[193 (XQuery)] | IntegerLiteral | ::= | |
[194 (XQuery)] | DecimalLiteral | ::= | |
[195 (XQuery)] | DoubleLiteral | ::= | |
[214 (XQuery)] | StringLiteral | ::= |
All literals are core expressions, therefore no normalization rules are required for literals.
Core Grammar
The core grammar productions for literals are:
[38 (Core)] | Literal | ::= | |
[37 (Core)] | NumericLiteral | ::= | |
[138 (Core)] | IntegerLiteral | ::= | |
[139 (Core)] | DecimalLiteral | ::= | |
[140 (Core)] | DoubleLiteral | ::= | |
[158 (Core)] | StringLiteral | ::= |
In the static semantics, the type of an integer literal is simply xs:integer:
|
||
|
In the dynamic semantics, an integer literal is evaluated by constructing an atomic value in the data model, which consists of the literal value and its type:
The formal definitions of decimal, double, and string literals are analogous to those for integer.
|
||
|
|
||
|
|
||
|
|
||
|
|
||
|
Ed. Note: MFF: Phil has noted that the data model should support primitive literals in their lexical form, in which case no explicit dynamic semantic rule would be necessary. See [Issue-0118: Data model syntax and literal values].
Introduction
A variable evaluates to the value to which the variable's QName is bound in the evaluation context.
A variable is a core expression, therefore no normalization rule is required for a variable.
In the static semantics, the type of a variable is simply its type in the static type environment statEnv.varType:
If the variable is not bound in the environment, the system raises an error.
In the dynamic semantics, a variable is evaluated by "looking up" its value in dynEnv.varValue:
If the variable is not bound in the environment, the system raises an error.
[57 (XQuery)] | ParenthesizedExpr | ::= |
The formal definition of parenthesized expressions is in [5.3 Sequence Expressions].
Core Grammar
The core grammar production for parenthesized expressions is:
[39 (Core)] | ParenthesizedExpr | ::= |
Introduction
A function call consists of a QName followed by a parenthesized list of zero or more expressions.
[58 (XQuery)] | FunctionCall | ::= |
Because [XPath/XQuery] perform implicit operations when doing function calls, a normalization step is required.
Notation
Normalization of function calls uses an auxiliary mapping rule, []FormalArgument, used to map the formal arguments of a function call.
There are three variants of this mapping rule. If the required type of the formal argument is an optional atomic type, the following rule is applied: (Type is the required atomic type.)
[Expr]FormalArgument |
== |
[Expr]Atomize(Type) |
If the required type of the formal argument is a sequence of atomic types, the following rule is applied: (Type is the atomic type of the sequence.)
[Expr]FormalArgument | ||||
== | ||||
|
Ed. Note: Jerome: it is not clear whether the above rule is correct. At least type promotion seems to be implied by the corresponding description in the [XPath/XQuery] document. See .
If the required type of the formal argument is neither an optional atomic type or a sequence of atomic types, the expression is simply mapped to its corresponding core expression:
[Expr]FormalArgument |
== |
[Expr]Expr |
First, each argument in a function call is normalized to its corresponding core expression by applying []FormalArgument.
[ QName (Expr1, ..., Exprn) ]Expr |
== |
[[QName] ( [[Expr1 ]Expr]FormalArgument, ..., [[ Exprn ]Expr]FormalArgument)]FormalArgument |
Note that this normalization rule depends on the static environment containing function signatures and is the only place where we exploit the implicit presence of statEnv.
Core Grammar
The core grammar production for function calls is:
[40 (Core)] | FunctionCall | ::= |
Based on the function's name and number of arguments (and in the case of built-in functions based also on the type of its arguments), the function signature is retrieved from the static environment. If the function is not present in the environment, an error is raised. The type of each actual argument to the function must be a subtype of the corresponding formal argument to the function, i.e., it is not necessary that the actual and formal types be the same.
Ed. Note: Issue: Michael Rys points out there is a dependency between normalization (which requires the function signature) and the fact that built-in functions may be overloaded for various types. See [Issue-0140: Dependency in normalization and function resolution]
|
||||||
|
||||||
|
Based on the function's name and the number of arguments (and in the case of built-in functions based also based on the type of its arguments), the function body is retrieved from the dynamic environment. If the function is not present in the environment, an error is raised. The rule first evaluates each function argument, then extends dynEnv.varValue by binding each formal variable to its corresponding value, and then evaluates the body of the function in the new environment. The resulting value is the value of the function call.
|
||||||||
|
||||||||
|
Note that the function body is evaluated in the default environment. Note also that input values and output values are matched against the types declared for the function. If static analysis was performed, all these checks are guaranteed to be true and may be omitted.
Ed. Note: This only describes the semantics of user defined functions. The semantics of built-in functions is still an open issue. See [Issue-0122: Overloaded functions] and [Issue-0162: How to describe the semantics of built-in functions].
[94 (XQuery)] | ExprComment | ::= |
Comments are lexical constructs only, and have no meaning within the query and therefore have no Formal Semantics.
Introduction
Path expressions are used to locate nodes within a tree. There are two kinds of path expressions, absolute path expressions and relative path expressions. An absolute path expression is a rooted relative path expression. A relative path expression is composed of a sequence of steps.
[23 (XQuery)] | PathExpr | ::= | |
[24 (XQuery)] | RelativePathExpr | ::= |
Core Grammar
The core grammars productions for path expressions are:
[13 (Core)] | PathExpr | ::= | |
[14 (Core)] | RelativePathExpr | ::= |
Notation
To define the semantics of relative path expressions, the auxiliary mapping rule is used: [RelativePathExpr]Path.
Absolute path expressions are path expressions starting with
the /
symbol, indicating that the expression must be
applied on the root node in the current context. Remember that the
root node in the current context is the topmost ancestor of the
context node. The following two rules are used to normalize
absolute path expressions to relative ones, and rely on the use of
the xf:root()
function, which computes the document
node from the context node.
["/"]Expr |
== |
xf:root( $fs:dot ) |
["/" RelativePathExpr]Expr |
== |
fs:distinct-doc-order( [xf:root( $fs:dot ) "/" RelativePathExpr]Path ) |
Ed. Note: Some of the semantics of the root expression
'/'
are still undefined. For instance, what should the semantics of'/'
be in case of a document fragment (e.g., created using XQuery element constructor). See [Issue-0123: Semantics of /].
Ed. Note: [Kristoffer/XSL] Also the context node and document order are not defined when it is a context item).
In general, a path expression always returns a sequence in document order. The complete normalization of a Path expression is obtained by applying the Path normalization and then sorting the result in document order and removing duplicates.
Ed. Note: Jerome: the restriction that XPath expressions operate on nodes here seems too strict and is still an open issue. See [Issue-0125: Operations on node only in XPath].
A composite relative path expression (using /
)
is normalized into a for
expression by
concatenating the sequences obtained by mapping each node of the
left-hand side in document order to the sequence it generates on
the right-hand side; the encapsulating call of the
fs:distinct-doc-order function then ensures that the result is
in document order without duplicates. The evaluation context is
carefully set up (using two bindings of the
$fs:last semantic variable).
[StepExpr "/" RelativePathExpr ]Path | |||||
== | |||||
|
Ed. Note: [Kristoffer/XSL] We have defined normalization over a right recursive variant of the syntax production -- this should perhaps be explained more elaborately.
Introduction
[25 (XQuery)] | StepExpr | ::= | |
[50 (XQuery)] | ForwardStep | ::= | |
[51 (XQuery)] | ReverseStep | ::= | |
[54 (XQuery)] | Predicates | ::= |
Core Grammar
The core grammars productions for XPath steps are:
[15 (Core)] | StepExpr | ::= | |
[35 (Core)] | ForwardStep | ::= | |
[36 (Core)] | ReverseStep | ::= |
Notation
Step expressions can be followed by predicates. Normalization of predicates uses the following auxiliary mapping rule: []Predicates.
Normalization of predicates need to distinguish between forward and reverse axes.
As explained in the [XPath/XQuery] document, applying a step in
XPath changes the focus (or context). The change of focus is
made explicit by the normalization rule below, which binds the
variable $fs:dot
to the node currently being
processed, and the variable $fs:position
to the
position (i.e., the position within the input sequence) of that
node. Notice that the expression does not reorder the sequences
obtained by evaluating the subexpressions: if they are
RelativePathExprs then the contained path normalization will
insert fs:distinct-doc-order appropriately.
[ForwardStep Predicates "[" Expr "]"]Path | |||||
== | |||||
|
[ReverseStep Predicates "[" Expr "]"]Path | |||||
== | |||||
|
The []Predicates function is specified in [5.2.2 Predicates].
Ed. Note: Issue:These rules use the function xf:index-of to bind the position of a node in a sequence. This works since path expressions only work on nodes. See [Issue-0125: Operations on node only in XPath]. Still, it might be preferable to be able to bind both the current node and its position through a single processing of the collection within the for expression. The FS editors have made several syntax proposals for such an operation. For instance:
for $v at $i in E1 return E2
. See [Issue-0124: Binding position in FLWR expressions].
Ed. Note: Issue:The semantics of Predicates applied on primary expression is not specified. See [Issue-0163: Normalization of XPath predicates]
Introduction
[40 (XQuery)] | ForwardAxis | ::= | |
[41 (XQuery)] | ReverseAxis | ::= | |
[36 (XPath)] | ForwardAxis | ::= | |
[37 (XPath)] | ReverseAxis | ::= |
Core Grammar
The core grammars productions for XPath axis are:
[25 (Core)] | ForwardAxis | ::= | |
[26 (Core)] | ReverseAxis | ::= |
Notation
Some auxiliary grammar productions and judgments are introduced to structure the semantic rules for axes and node tests. The first is used to capture the principal node kind associated with each axis:
[51 (Formal)] | PrincipalNodeKind | ::= | |
[49 (Formal)] | Axis | ::= |
Notation
The principal node kind for each axis is specified using the following judgment.
Notation
The following auxiliary grammar production defines Filters, which denote either an axis, or a principal node kind in the context of a principal node kind. An Axis merely combines the forward and reverse axes to allow judgments that range over both.
[49 (Formal)] | Axis | ::= | |
[50 (Formal)] | Filter | ::= |
Notation
The semantics of filters is defined with three auxiliary judgments. The first judgment defines the effect of a filter on a value, and is used in the dynamic semantics. This judgment should be read as follows: in the current context (i.e., with respect to the dynamic environment dynEnv.varValue), applying the Filter on Value1 yields Value2:
The second judgment is defining the
effect of a filter (either an axis or a nodetest) on a type and
is used in the static semantics. This judgment should be read as
follows: in the current context, (i.e., with respect to the the
static environment statEnv.varType), applying the filter
Filter
on type Type1
yields the
type Type2
The last judgment allows an additional type environment, localTypeEnv. This "local" type environment maps variables to types (in the same way as statEnv.varType), and is used when computing the static type of the descendant axis.
These judgments will be defined separately for axes and node tests below.
Ed. Note: Explain the judgments in detail, maybe similarly to in section 3.2.
The static semantics of an Axis NodeTest pair is obtained by retrieving the type of the context node, and applying the two filters (the Axis, and then the NodeTest with a PrincipalNodeKind) on the result.
|
|||||
|
|||||
statEnv |- Axis NodeTest : Type3 |
Here are the common set of inference rules defining the static semantics of filters. Essentially, these rules are used to process complex types through a filter, breaking the types down to the type of a node or of a value. The semantics of a filter applied to a node or value type is then specific to each Axis and NodeTest.
|
statEnv |- Filter on () : () |
|
statEnv |- Filter on none : none |
|
|||
|
|||
statEnv |- Filter on Type1,Type2 : Type3,Type4 |
|
|||
|
|||
statEnv |- Filter on Type1|Type2 : Type3|Type4 |
|
|||
|
|||
statEnv |- Filter on Type1&Type2 : Type3&Type4 |
The cases for specific axis and node test filters are given in the axis and node test sections below.
The dynamic semantics of an Axis NodeTest pair is obtained by retrieving the context node, and applying the two filters (Axis, then NodeTest) on the result. The application of each filter is expressed through the filter judgment as follows.
|
|||||
|
|||||
dynEnv |- Axis NodeTest => Value3 |
Here are the common set of inference rules defining the dynamic semantics of filters. These rules apply filters to a sequence, by breaking the sequence down to a node or value.
|
dynEnv |- Filter on () => () |
|
|||
|
|||
dynEnv |- Filter on Value1,Value2 => Value3,Value4 |
Ed. Note: Jerome: These rules fetaure a notational abuse! Value1,Value2 indicates the concatenation of Value1 and Value2, and is used for both constructing a new sequence and deconstructing it. When doing the construction, it is equivalent to applying the
op:concatenate
operator. The Formal Semantics specification should use more consistent notation for data model constructions and deconstruction. See also [Issue-0118: Data model syntax and literal values].
The semantics of a filter applied to a specific axis or nodetest is given in the appropriate section below.
The semantics of the following(-sibling) and preceding(-sibling) axes are expressed by mapping them to core expressions, all other axes are part of core [XPath/XQuery] and therefore are left unchanged through normalization.
[following-sibling::
NodeTest]Path
|
|||||
== | |||||
|
Ed. Note: Should all mappings be unfolded all the way to the core language like the above one?
[following:: NodeTest]Path
|
== |
[ancestor-or-self::node()/following-sibling::node()/descendant-or-self:: NodeTest]Path
|
Otherwise, the forward axis is part of the core [XPath/XQuery] and handled by the Axis/NodeTest semantics below:
[child:: NodeTest]Path
|
== |
child:: NodeTest
|
[attribute:: NodeTest]Path
|
== |
attribute:: NodeTest
|
[self:: NodeTest]Path
|
== |
self:: NodeTest
|
[descendant:: NodeTest]Path
|
== |
descendant:: NodeTest
|
[descendant-or-self:: NodeTest]Path
|
== |
descendant-or-self:: NodeTest
|
[namespace:: NodeTest]Path
|
== |
namespace:: NodeTest
|
Reverse axes:
[preceding-sibling:: NodeTest]Path
|
||
== | ||
|
[preceding:: NodeTest]Path
|
== |
[ancestor-or-self::node()/preceding-sibling::node()/descendant-or-self:: NodeTest]Path
|
Otherwise, the reverse axis is part of the core [XPath/XQuery] and is handled by the Axis/NodeTest semantics below.
[parent:: NodeTest]Path
|
== |
parent:: NodeTest
|
[ancestor:: NodeTest]Path
|
== |
ancestor:: NodeTest
|
[ancestor-or-self:: NodeTest]Path
|
== |
ancestor-or-self:: NodeTest
|
Finally, the principal node kind of each axis is enumerated by the following rules (given here because they are used both by the static and dynamic semantic rules).
|
attribute:: principal attribute
|
|
namespace:: principal namespace
|
Axis != attribute::
Axis != namespace::
|
|
Axis principal element |
The following rules define the static semantics of the filter judgment when applied to an Axis.
The type for the self axis is the same type as the type of the context node.
In case of elements, the type of the child axis is obtained by extracting the children types out of the content model describing the type of the context node.
Ed. Note: [Kristoffer/XSL] Need to add filters for all cases.
The type of the attribute axis is obtained by extracting the attribute types out of the content model describing the type of the context node.
Ed. Note: [Kristoffer/XSL] Need to add filters for all cases.
The type for the parent axis is either an element, a document (for document elements), or empty.
Ed. Note: Better typing for the parent axis is still an open issue. See [Issue-0080: Typing of parent].
The type for the namespace axis is always empty.
Ed. Note: Jerome: The type of namespace nodes is still an open issue. See [Issue-0105: Types for nodes in the data model.].
The types for the descendant, and descendant-or-self, ancestor, and ancestor-or-self axis are implemented through recursive application of the children and parent filters. The corresponding inference rules use the auxiliary filter judgment with a local type environment. This local type environment is used to keep track of the visited elements in order to deal with recursive types.
The following two rules are used to deal with global elements. Global elements need careful treatment here in order to deal with possible recursion. Notably, if the global element has been seen before, then the rule terminates and returns the union of all types already visited in the local environment.
|
|||
|
|||
statEnv |-
descendant:: on
element qname :
(Type1|Type2|...)*
|
|
|||||
|
|||||
statEnv localTypeEnv |-
descendant:: on
element qname Type'
|
Ed. Note: Peter: I need yet to figure out, whether this works, there still appear a few glitches. See [Issue-0132: Typing for descendant].
In all other cases, the following rule applies
|
|||
|
|||
statEnv |-
descendant:: on
NodeType :
Type1,Type2
|
|
|||
|
|||
statEnv |-
descendant-or-self::
on NodeType
:
Type1,Type2
|
The type for the ancestor axis is the
element*,document?
type indicating that it
includes elements and possibly a document element.
|
|||
|
|||
statEnv |-
ancestor-or-self:: on
NodeType :
Type1,
Type2
|
In all the other cases, the filter application results in an empty type.
Ed. Note: KHR: "otherwise" rules should be avoided and specify the cases exhaustively.
The inference rules below indicate for each axis whether a particular node should be considered further or whether the node should be left out. Therefore, each rule either returns the input node, or returns the empty sequence. The overall result is obtained by putting together all of the remaining nodes, following the generic semantics for filters.
The self axis just returns the context node.
The child, parent, attribute and namespace axis are implemented through their corresponding accessors in the [XQuery 1.0 and XPath 2.0 Data Model].
The descendant, descendant-or-self, ancestor, and ancestor-or-self axis are implemented through recursive application of the children and parent filters.
|
|||
|
|||
dynEnv |-
descendant:: on NodeValue
=>
fs:distinct-doc-order(op:concatenate(Value1, Value2))
|
|
|||
|
|||
dynEnv |-
descendant-or-self:: on NodeValue
=>
op:concatenate(Value1, Value2)
|
|
|||
|
|||
dynEnv |-
ancestor:: on NodeValue
=>
op:concatenate(Value1, Value2)
|
|
|||
|
|||
dynEnv |-
ancestor-or-self:: on NodeValue
=>
op:concatenate(Value1, Value2)
|
In all the other cases, the filter application results in an empty sequence.
Ed. Note: Peter: Generally steps may operate on nodes and values alike; the axis rules only can operate on nodes (NodeValue). Is it a dynamic error to apply an axis rule on a value? See [Issue-0125: Operations on node only in XPath].
Introduction
A node test is a condition applied on the nodes selected by an axis step. Possible node tests are described by the following grammar productions.
Core Grammar
The core grammars productions for XPath node tests are:
[27 (Core)] | NodeTest | ::= | |
[28 (Core)] | NameTest | ::= | |
[29 (Core)] | Wildcard | ::= | |
[30 (Core)] | KindTest | ::= | |
[31 (Core)] | ProcessingInstructionTest | ::= | |
[32 (Core)] | CommentTest | ::= | |
[33 (Core)] | TextTest | ::= | |
[34 (Core)] | AnyKindTest | ::= |
The following typing rules apply to filters that are node tests in the context of a principal node kind.
Node tests on elements and attributes always accomplish the
most specific type possible. For example, if $v
is
bound to an element with a computed name, the type of
$v
is element { Type }. The static type computed
for the expression $v/self::foo
is element
foo
{Type}, which makes use of the nametest
foo
to arrive at a more specific type. Also note
that each case of name matching restricts the principal node
kind to the appropriate one.
Ed. Note: [Kristoffer/XSL] Perhaps use statEnv |- expand(QName) = qname(URI, ncname) instead of qname = prefix:local? Also The ElemOrAttrType doesn't allow wildcard in the ElementName or AttributeName, so either the rules can be removed or the definition should be updated.
|
||||
|
||||
statEnv |- element, QName2 on element QName1 {Type} : element QName1 {Type} |
|
|||
|
|||
statEnv |-
element, QName2
on element
*: LocalPart1 {Type}
: element
QName2 {Type}
|
|
|||
|
|||
statEnv |-
element, QName2
on element
Prefix1:* {Type}
: element
Prefix1: LocalPart2{Type}
|
xf:get-local-name( QName1 ) = LocalPart2 |
|
statEnv |-
element, *: LocalPart2
on element
QName1 {Type}
: element
QName1 {Type}
|
LocalPart1 = LocalPart2 |
|
statEnv |-
element, *: LocalPart2
on element
*: LocalPart1 {Type}
: element
*: LocalPart2 {Type}
|
|
statEnv |-
element, *: LocalPart2
on element { Type }
: element
*: LocalPart2 {Type}
|
xf:get-namespace-uri( QName1) = statEnv.namespace(Prefix2) |
|
statEnv |- element, Prefix2:* on element QName1 {Type} : element QName1 {Type} |
statEnv.namespace(Prefix1) = statEnv.namespace(Prefix2) |
|
statEnv |-
element, Prefix2:*
onelement
Prefix1:* {Type}
: element
Prefix1:* {Type}
|
Very similar typing rules apply to attributes:
|
||||
|
||||
statEnv |- attribute, QName2 on attribute QName1 {Type} : attribute QName1 {Type} |
|
|||
|
|||
statEnv |-
attribute, QName2
on attribute
*: LocalPart1 {Type}
: attribute
QName2 {Type}
|
|
|||
|
|||
statEnv |-
attribute, QName2
on attribute
Prefix1:* {Type}
: attribute
Prefix1: LocalPart2{Type}
|
xf:get-local-name( QName1 ) = LocalPart2 |
|
statEnv |-
attribute, *: LocalPart2
on attribute
QName1 {Type}
: attribute
QName1 {Type}
|
LocalPart1 = LocalPart2 |
|
statEnv |-
attribute, *: LocalPart2
on attribute
*: LocalPart1 {Type}
: attribute
*: LocalPart2 {Type}
|
|
statEnv |-
attribute, *: LocalPart2
on attribute
Prefix1:* {Type}
: attribute
Prefix1:LocalPart2{Type}
|
xf:get-namespace-uri( QName1) = statEnv.namespace(Prefix2) |
|
statEnv |-
attribute, Prefix2:*
on attribute
QName1 {Type}
: attribute
QName1 {Type}
|
|
statEnv |-
attribute, Prefix2:*
on attribute
*: LocalPart1 {Type}
: attribute
Prefix2: LocalPart1
{Type}
|
statEnv.namespace(Prefix1) = statEnv.namespace(Prefix2) |
|
statEnv |-
attribute, Prefix2:*
on attribute
Prefix1:* {Type}
: attribute
Prefix1:* {Type}
|
Comments, processing instructions, and text:
|
statEnv |-
PrincipalNodeKind, processing-instruction()
on processing-instruction
: processing-instruction
|
|
statEnv |-
PrincipalNodeKind, processing-instruction( String)
on processing-instruction
: processing-instruction
|
If none of the above rules apply, then the node test returns the empty sequence and the following dynamic rule is applied:
Ed. Note: Peter: Except for
self::
, all axes guarantee that the NodeType is not the generic type node. However, when the type node is encountered, it has to be interpreted as element | attribute | text | comment | processing-instruction for these typing rules to work.
The dynamic semantics indicates for each node test whether a node is retained.
|
||||||
|
||||||
dynEnv |- PrincipalNodeKind, QName2 on NodeValue => NodeValue |
|
|||
|
|||
dynEnv |-
PrincipalNodeKind, * on NodeValue
=> NodeValue
|
|
||||
|
||||
dynEnv |-
PrincipalNodeKind, prefix:* on NodeValue => NodeValue
|
|
||||
|
||||
dynEnv |-
PrincipalNodeKind, *: local on NodeValue => NodeValue
|
|
||
|
||
dynEnv |-
PrincipalNodeKind, processing-instruction() on NodeValue => NodeValue
|
|
||||
|
||||
dynEnv |-
PrincipalNodeKind, processing-instruction( String ) on NodeValue => NodeValue
|
Ed. Note: Note the use of the
xf:get-local-name
function to extract the local name out of the name of the node.
|
||
|
||
dynEnv |-
PrincipalNodeKind, comment() on NodeValue => NodeValue
|
The node()
node test is true for all nodes. Therefore,
the following rule does not have any precondition (remember that an
empty upper part in the rule indicates that the rule is always
true).
If none of the above rules applies then the node test returns the empty sequence, and the following dynamic rule is applied:
Introduction
Predicates are composed of zero or more expressions enclosed in square brackets.
[54 (XQuery)] | Predicates | ::= |
Predicates in path expressions are normalized with a special mapping rule:
[Expr]Predicates | ||||||||
== | ||||||||
|
Ed. Note: XQuery Section 2.3.4 has no semantic content -- it just contains examples! (This suggests that perhaps the section structure is a little weird.)
[52 (XQuery)] | AbbreviatedForwardStep | ::= | |
[53 (XQuery)] | AbbreviatedReverseStep | ::= |
Here are normalization rules for the abbreviated syntax.
[ Expr // RelativePathExpr ]Path |
== |
[Expr]Expr / descendant-or-self::node() / [RelativePathExpr]Path |
[ . ]Path |
== |
$fs:dot |
[ .. ]Path |
== |
parent::node() |
[ @ NameTest ]Path |
== |
attribute :: NameTest |
[ NodeTest ]Path |
== |
child :: NodeTest |
Introduction
[XPath/XQuery] supports operators to construct and combine sequences. A sequence is an ordered collection of zero or more items. An item is either an atomic value or a node.
[4 (XQuery)] | ExprSequence | ::= | |
[16 (XQuery)] | RangeExpr | ::= |
The sequence expression is normalized into a sequence of core expressions:
Ed. Note: Mike Kay remarks that it would be cleaner to have binary rules and recursion to define the semantics rather than the ... notation.
Core Grammar
The core grammar rule for sequence expressions is:
[4 (Core)] | ExprSequence | ::= |
The static semantics of the sequence expression follows. The type of the sequence expression is the sequence over the types of the individual expressions.
|
||
|
||
|
The dynamic semantics of the sequence expression follows. Each expression in the sequence is evaluated and the resulting values are concatenated into one sequence.
|
||
|
||
|
The normalization of the infix "to" operator maps it into an application of op:to.
The static semantics of the op:to function is defined in [7 Additional Semantics of Functions].
The dynamic semantics rules for function calls given in [5.1.4 Function Calls] are applied to the function call op:to above.
Ed. Note: Should the "to" operator be defined formally? See [Issue-0133: Should to also be described in the formal semantics?].
[XPath/XQuery] provides several operators for combining sequences.
[19 (XQuery)] | UnionExpr | ::= | |
[20 (XQuery)] | IntersectExceptExpr | ::= |
Notation
First, a union, intersect, or except expression is normalized into a corresponding core expression. The mapping function []SequenceOp is defined by the following tables:
SequenceOp | [SequenceOp]SequenceOp |
"union" | op:union |
"|" | op:union |
"intersect" | op:intersect |
"except" | op:except |
[Expr1 SequenceOp Expr2]Expr |
== |
[SequenceOp]SequenceOp ( [Expr1]Expr, [Expr2]Expr ) |
The static semantics of the functions that operate on sequences are defined in [7 Additional Semantics of Functions].
The dynamic semantics rules for function calls given in [5.1.4 Function Calls] are applied to the calls to functions on sequences above.
[XPath/XQuery] provides arithmetic operators for addition, subtraction, multiplication, division, and modulus, in their usual binary and unary forms.
[17 (XQuery)] | AdditiveExpr | ::= | |
[18 (XQuery)] | MultiplicativeExpr | ::= | |
[21 (XQuery)] | UnaryExpr | ::= | |
[22 (XQuery)] | ValueExpr | ::= | |
[24 (XPath)] | ValueExpr | ::= |
Core Grammar
All of those expressions are normalized to the following core grammar production:
[12 (Core)] | ValueExpr | ::= |
Notation
Ed. Note: MFF: The operator table in this section was produced by Don Chamberlin. This table should be in one place, probably the Formal Semantics
Ed. Note: [Kristoffer/XSL] The present rules mix static and dynamic dispatch of which primitive function is used. We are investigating how to repair that as well as make the definitions work with both static and dynamic typing. See [Issue-0122: Overloaded functions].
The tables in this section list the combinations of datatypes for which the various operators of [XPath/XQuery] are defined. For each valid combination of datatypes, the table indicates the name of the function that implements the operator and the datatype of the result. Definitions of the functions can be found in [XQuery 1.0 and XPath 2.0 Functions and Operators].
In the following tables, the term fs:numeric refers to the types xs:integer, xs:decimal, xs:float, and xs:double. When the result type of an operator is listed as numeric, it means "same as the highest type of any input operand, in promotion order." For example, when invoked with operands of type xs:integer and xs:float, the binary + operator returns a result of type xs:float.
In the following tables, the term Gregorian refers to the types xs:gYearMonth, xs:gYear, xs:gMonthDay, xs:gDay, and xs:gMonth. For binary operators that accept two Gregorian-type operands, both operands must have the same type (for example, if one operand is of type xs:gDay, the other operand must be of type xs:gDay.)
The functions []BinaryOp and []UnaryOp are defined by the following two tables. The function []BinaryOp takes the left-hand expression (A) and its type, the operator, the right-hand expression (b) and its type and returns a new expression, which applies the type-appropriate operator to the two expressions. The function []UnaryOp takes an operator and an expression and returns a new expression, which applies the appropriate operator to the expression.
Operator | Type(A) | Type(B) | [A; Type(A); Operator; B; Type(B)]BinaryOp | Result type |
---|---|---|---|---|
A + B | numeric | numeric | op:numeric-add(A, B) | numeric |
A + B | xs:date | xs:yearMonthDuration | op:add-yearMonthDuration-to-date(A, B) | xs:date |
A + B | xs:yearMonthDuration | xs:date | op:add-yearMonthDuration-to-date(B, A) | xs:date |
A + B | xs:date | xs:dayTimeDuration | op:add-dayTimeDuration-to-date(A, B) | xs:date |
A + B | xs:dayTimeDuration | xs:date | op:add-dayTimeDuration-to-date(B, A) | xs:date |
A + B | xs:time | xs:dayTimeDuration | op:add-dayTimeDuration-to-time(A, B) | xs:time |
A + B | xs:dayTimeDuration | xs:time | op:add-dayTimeDuration-to-time(B, A) | xs:time |
A + B | xs:datetime | xs:yearMonthDuration | op:add-yearMonthDuration-to-dateTime(A, B) | xs:dateTime |
A + B | xs:yearMonthDuration | xs:datetime | op:add-yearMonthDuration-to-dateTime(B, A) | xs:dateTime |
A + B | xs:datetime | xs:dayTimeDuration | op:add-dayTimeDuration-to-dateTime(A, B) | xs:dateTime |
A + B | xs:dayTimeDuration | xs:datetime | op:add-dayTimeDuration-to-dateTime(B, A) | xs:dateTime |
A + B | xs:yearMonthDuration | xs:yearMonthDuration | op:add-yearMonthDurations(A, B) | xs:yearMonthDuration |
A + B | xs:dayTimeDuration | xs:dayTimeDuration | op:add-dayTimeDurations(A, B) | xs:dayTimeDuration |
A - B | numeric | numeric | op:numeric-subtract(A, B) | numeric |
A - B | xs:date | xs:date | xf:subtract-dates(A, B) | xs:dayTimeDuration |
A - B | xs:date | xs:yearMonthDuration | op:subtract-yearMonthDuration-from-date(A, B) | xs:date |
A - B | xs:date | xs:dayTimeDuration | op:subtract-dayTimeDuration-from-date(A, B) | xs:date |
A - B | xs:time | xs:time | xf:subtract-times(A, B) | xs:dayTimeDuration |
A - B | xs:time | xs:dayTimeDuration | op:subtract-dayTimeDuration-from-time(A, B) | xs:time |
A - B | xs:dateTime | xs:dateTime | xf:get-yearMonthDuration-from-dateTimes(A, B) | xs:yearMonthDuration |
A - B | xs:dateTime | xs:dateTime | xf:get-dayTimeDuration-from-dateTimes(A, B) | xs:dayTimeDuration |
A - B | xs:datetime | xs:yearMonthDuration | op:subtract-yearMonthDuration-from-dateTime(A, B) | xs:dateTime |
A - B | xs:datetime | xs:dayTimeDuration | op:subtract-dayTimeDuration-from-dateTime(A, B) | xs:dateTime |
A - B | xs:yearMonthDuration | xs:yearMonthDuration | op:subtract-yearMonthDurations(A, B) | xs:yearMonthDuration |
A - B | xs:dayTimeDuration | xs:dayTimeDuration | op:subtract-dayTimeDurations(A, B) | xs:dayTimeDuration |
A * B | numeric | numeric | op:numeric-multiply(A, B) | numeric |
A * B | xs:yearMonthDuration | xs:decimal | op:multiply-yearMonthDuration(A, B) | xs:yearMonthDuration |
A * B | xs:decimal | xs:yearMonthDuration | op:multiply-yearMonthDuration(B, A) | xs:yearMonthDuration |
A * B | xs:dayTimeDuration | xs:decimal | op:multiply-dayTimeDuration(A, B) | xs:dayTimeDuration |
A * B | xs:decimal | xs:dayTimeDuration | op:multiply-dayTimeDuration(B, A) | xs:dayTimeDuration |
A div B | numeric | numeric | op:numeric-divide(A, B) | numeric |
A div B | xs:yearMonthDuration | xs:decimal | op:divide-yearMonthDuration(A, B) | xs:yearMonthDuration |
A div B | xs:dayTimeDuration | xs:decimal | op:divide-dayTimeDuration(A, B) | xs:dayTimeDuration |
A mod B | numeric | numeric | op:numeric-mod(A, B) | numeric |
A eq B | numeric | numeric | op:numeric-equal(A, B) | xs:boolean |
A eq B | xs:boolean | xs:boolean | op:boolean-equal(A, B) | xs:boolean |
A eq B | xs:string | xs:string | op:numeric-equal(xf:compare(A, B), 1) | xs:boolean |
A eq B | xs:date | xs:date | op:date-equal(A, B) | xs:boolean? |
A eq B | xs:time | xs:time | op:time-equal(A, B) | xs:boolean? |
A eq B | xs:dateTime | xs:dateTime | op:datetime-equal(A, B) | xs:boolean? |
A eq B | xs:yearMonthDuration | xs:yearMonthDuration | op:yearMonthDuration-equal(A, B) | xs:boolean |
A eq B | xs:dayTimeDuration | xs:dayTimeDuration | op:dayTimeDuration-equal(A, B) | xs:boolean |
A eq B | Gregorian | Gregorian | op:Gregorian-equal(A, B) | xs:boolean |
A eq B | xs:hexBinary | xs:hexBinary | op:hex-binary-equal(A, B) | xs:boolean |
A eq B | xs:base64Binary | xs:base64Binary | op:base64-binary-equal(A, B) | xs:boolean |
A eq B | xs:anyURI | xs:anyURI | op:anyURI-equal(A, B) | xs:boolean |
A eq B | xs:QName | xs:QName | op:QName-equal(A, B) | xs:boolean |
A eq B | xs:NOTATION | xs:NOTATION | op:NOTATION-equal(A, B) | xs:boolean |
A ne B | numeric | numeric | xf:not(op:numeric-equal(A, B)) | xs:boolean |
A ne B | xs:boolean | xs:boolean | xf:not(op:boolean-equal(A, B)) | xs:boolean |
A ne B | xs:string | xs:string | xf:not(op:numeric-equal(xf:compare(A, B), 1)) | xs:boolean |
A ne B | xs:date | xs:date | xf:not(op:date-equal(A,B)) | xs:boolean? |
A ne B | xs:time | xs:time | xf:not(op:time-equal(A,B)) | xs:boolean? |
A ne B | xs:dateTime | xs:dateTime | xf:not(op:datetime-equal(A, B)) | xs:boolean? |
A ne B | xs:yearMonthDuration | xs:yearMonthDuration | xf:not(op:yearMonthDuration-equal(A, B)) | xs:boolean |
A ne B | xs:dayTimeDuration | xs:dayTimeDuration | xf:not(op:dayTimeDuration-equal(A, B) | xs:boolean |
A ne B | Gregorian | Gregorian | xf:not(op:Gregorian-equal(A, B)) | xs:boolean |
A ne B | xs:hexBinary | xs:hexBinary | xf:not(op:hex-binary-equal(A, B)) | xs:boolean |
A ne B | xs:base64Binary | xs:base64Binary | xf:not(op:base64-binary-equal(A, B)) | xs:boolean |
A ne B | xs:anyURI | xs:anyURI | xf:not(op:anyURI-equal(A, B)) | xs:boolean |
A ne B | xs:QName | xs:QName | xf:not(op:QName-equal(A, B)) | xs:boolean |
A ne B | xs:NOTATION | xs:NOTATION | xs:not(op:NOTATION-equal(A, B)) | xs:boolean |
A gt B | numeric | numeric | op:numeric-greater-than(A, B) | xs:boolean |
A gt B | xs:boolean | xs:boolean | op:boolean-greater-than(A, B) | xs:boolean |
A gt B | xs:string | xs:string | op:numeric-greater-than(xf:compare(A, B), 0) | xs:boolean |
A gt B | xs:date | xs:date | op:date-greater-than(A, B) | xs:boolean? |
A gt B | xs:time | xs:time | op:time-greater-than(A, B) | xs:boolean? |
A gt B | xs:dateTime | xs:dateTime | op:datetime-greater-than(A, B) | xs:boolean? |
A gt B | xs:yearMonthDuration | xs:yearMonthDuration | op:yearMonthDuration-greater-than(A, B) | xs:boolean |
A gt B | xs:dayTimeDuration | xs:dayTimeDuration | op:dayTimeDuration-greater-than(A, B) | xs:boolean |
A lt B | numeric | numeric | op:numeric-less-than(A, B) | xs:boolean |
A lt B | xs:boolean | xs:boolean | op:boolean-less-than(A, B) | xs:boolean |
A lt B | xs:string | xs:string | op:numeric-less-than(xf:compare(A, B), 0) | xs:boolean |
A lt B | xs:date | xs:date | op:date-less-than(A, B) | xs:boolean? |
A lt B | xs:time | xs:time | op:time-less-than(A, B) | xs:boolean? |
A lt B | xs:dateTime | xs:dateTime | op:datetime-less-than(A, B) | xs:boolean? |
A lt B | xs:yearMonthDuration | xs:yearMonthDuration | op:yearMonthDuration-less-than(A, B) | xs:boolean |
A lt B | xs:dayTimeDuration | xs:dayTimeDuration | op:dayTimeDuration-less-than(A, B) | xs:boolean |
A ge B | numeric | numeric | op:numeric-less-than(B, A) | xs:boolean |
A ge B | xs:string | xs:string | op:numeric-greater-than(xf:compare(A, B), -1) | xs:boolean |
A ge B | xs:date | xs:date | op:date-less-than(B, A) | xs:boolean? |
A ge B | xs:time | xs:time | op:time-less-than(B, A) | xs:boolean? |
A ge B | xs:dateTime | xs:dateTime | op:datetime-less-than(B, A) | xs:boolean? |
A ge B | xs:yearMonthDuration | xs:yearMonthDuration | op:yearMonthDuration-less-than(B, A) | xs:boolean |
A ge B | xs:dayTimeDuration | xs:dayTimeDuration | op:dayTimeDuration-less-than(B, A) | xs:boolean |
A le B | numeric | numeric | op:numeric-greater-than(B, A) | xs:boolean |
A le B | xs:string | xs:string | op:numeric-less-than(xf:compare(A, B), 1) | xs:boolean |
A le B | xs:date | xs:date | op:date-greater-than(B, A) | xs:boolean? |
A le B | xs:time | xs:time | op:ime-greater-than(B, A) | xs:boolean? |
A le B | xs:dateTime | xs:dateTime | op:datetime-greater-than(B, A) | xs:boolean? |
A le B | xs:yearMonthDuration | xs:yearMonthDuration | op:yearMonthDuration-greater-than(B, A) | xs:boolean |
A le B | xs:dayTimeDuration | xs:dayTimeDuration | op:dayTimeDuration-greater-than(B, A) | xs:boolean |
A is B | node | node | op:node-equal(A, B) | xs:boolean |
A isnot B | node | node | xf:not(op:node-equal(A, B)) | xs:boolean |
A << B | node | node | op:node-before(A, B) | xs:boolean |
A >> B | node | node | op:node-after(A, B) | xs:boolean |
A precedes B | node | node | op:node-precedes(A, B) | xs:boolean |
A follows B | node | node | op:node-follows(A, B) | xs:boolean |
A union B | node* | node* | op:union(A, B) | node* |
A | B | node* | node* | op:union(A, B) | node* |
A intersect B | node* | node* | op:intersect(A, B) | node* |
A except B | node* | node* | op:except(A, B) | node* |
A to B | xs:decimal | xs:decimal | op:to(A, B) | xs:integer+ |
A , B | item* | item* | op:concatenate(A, B) | item* |
An analogous table exists for unary operators.
Operator | Operand type | [Operator; Expr]UnaryOp | Result type |
---|---|---|---|
+ A | numeric | op:numeric-unary-plus(A) | numeric |
- A | numeric | op:numeric-unary-minus(A) | numeric |
The normalization rules for the arithmetic operators "+
"
and "-
" are similar, but not identical, because as the table
above illustrates, "-
" is not commutative.
The following normalization rule for "+
" first
applies
[]Atomize
to each argument expression, binding the results
of these expressions to two new variables, $e1
and $e2
.
It then applies a typeswitch on the
left-hand operand $e1
, and
for each left-hand operand type, it applies a
second typeswitch on the right-hand operand $e2
. The function
[Operator]BinaryOp
takes the operator, the left-hand type, and the right-hand type
and returns the appropriate function, which is applied to the argument
values.
[Expr1 "+ " Expr2]Expr
|
||||||||||||||||||||||||||||||||||||||||||||||||||||||
== | ||||||||||||||||||||||||||||||||||||||||||||||||||||||
|
Ed. Note: MFF (01-May-2002) Not sure what to do about numeric promotion rules. Should they be expressed explicity in normalization rules?
Ed. Note: MFF: The Datatype production does not permit choices of item types -- this is annoying. See [Issue-0127: Datatype limitations].
Ed. Note: Peter: the static semantics of operators is as strict as the one for functions, and is still under discussion. See [Issue-0129: Static typing of union].
The following normalization rule for "-
" is analogous to
that for "+
".
[Expr1 "- " Expr2]Expr
|
||||||||||||||||||||||||||||||||||||||||||||||||||||
== | ||||||||||||||||||||||||||||||||||||||||||||||||||||
|
The multiplicative operators "*
" and "div" are
defined on numeric and xs:yearMonthDuration,
xs:dayTimeDuration. The multiplicative operator "mod
" is only
defined on numeric, so its normalization rule is simple.
[Expr1 "* " Expr2]Expr
|
|||||||||||||||||||||||||||||||||||||||
== | |||||||||||||||||||||||||||||||||||||||
|
[Expr1 "div" Expr2]Expr | ||||||||||||||||||||||||||||||||
== | ||||||||||||||||||||||||||||||||
|
[Expr1 mod Expr2]Expr
|
||||||||||||||||||||
== | ||||||||||||||||||||
|
For convenience, UnaryOp denotes the unary operators "+
" and
"-
". The normalization rule for unary operators is straightforward:
[UnaryOp Expr]Expr | ||||||
== | ||||||
|
Core Grammar
There are no core grammar rules for arithmetic expressions as they are normalized to function calls.
In the [XQuery 1.0 and XPath 2.0 Functions and Operators], type promotion rules are given for all the arithmetic operators, denoted by op:operation, and the result types of these operations. The following static semantics rules specify the result types for all arithmetic operators when applied to specific numeric types.
|
||
|
||
|
|
||
|
||
|
|
||
|
||
|
|
||
|
||
|
Ed. Note: MFF: Can the rules above be factored?
Analogous static type rules are given for the unary arithmetic operators.
|
||
|
||
|
|
||
|
||
|
The normalization rules map all arithmetic operators into core expressions, whose dynamic semantics is defined in other sections. Therefore, there are no dynamic semantics rules for arithmetic operators. The dynamic semantics rules for function calls given in [5.1.4 Function Calls] apply to all the function calls: op:numeric-add, etc.
Introduction
Comparison expressions allow two values to be compared. [XPath/XQuery] provides four kinds of comparison expressions, called value comparisons, general comparisons, node comparisons, and order comparisons.
[15 (XQuery)] | ComparisonExpr | ::= | |
[33 (XQuery)] | ValueComp | ::= | |
[32 (XQuery)] | GeneralComp | ::= | |
[34 (XQuery)] | NodeComp | ::= | |
[35 (XQuery)] | OrderComp | ::= |
Ed. Note: [Kristoffer/XSL] The present rules mix static and dynamic dispatch of which primitive function is used. We are investigating how to repair that as well as make the definitions work with both static and dynamic typing. See [Issue-0122: Overloaded functions].
The value comparison equality operators "eq
" and
"ne
" are defined on a large set of types.
[Expr1 ValueEqOp Expr2]Expr | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
== | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
|
Ed. Note: MFF: The definition of equality operators could be factored by introducing another normalization function, which would be applied to the bodies of the cases. Is it clearer (albeit longer) to just enumerate all the cases? For now, they are enumerated.
The value comparison in-equality operators "lt
",
"le
", "gt
", and "ge
" are defined
on a smaller set of types than are the equality operators
"eq
" and "ne
". For convenience, ValueInEqOp
denotes the operators "lt
", "le
", "gt
",
or "ge
".
[Expr1 ValueInEqOp Expr2]Expr | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
== | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
|
Core Grammar
There are no core grammar rules for value comparisons as they are normalized to function calls.
There are no static type rules for the value comparison operators. They all have return type xs:boolean, as specified in [XQuery 1.0 and XPath 2.0 Functions and Operators].
The normalization rules map all value comparison operators into core expressions, whose dynamic semantics is defined in other sections. Therefore, there are no dynamic semantics rules for value comparison operators. The dynamic semantics rules for function calls given in [5.1.4 Function Calls] apply to all the function calls: op:numeric-less-than, etc.
Introduction
General comparisons are defined by adding existential semantics to
value comparisons. The operands of a general comparison may be
sequences of any length. The result of a general comparison is always
true
or false
.
Notation
For convenience, GeneralOp denotes the operators "=
", "!=
",
"<
", "<=
",
">
", or ">=
".
The function []ValueOp is defined by the following table:
GeneralOp | [GeneralOp]ValueOp |
= | eq |
!= | ne |
< | lt |
<= | le |
> | gt |
>= | ge |
A general comparison expression is normalized by mapping it into an existentially quantified, value-comparison expression, which is normalized recursively.
[Expr1 GeneralOp Expr2]Expr |
== |
[some $v1 in Expr1 satisfies (some $v2 in Expr2 satisfies $v1 [GeneralOp]ValueOp $v2)]Expr |
Core Grammar
There are no core grammar rules for general comparisons as they are normalized to existentially quantified core expressions.
There are no static type rules for the general comparison operators. The existentially quantified "some" expression always returns xs:boolean. Its static typing semantics is given in [5.11 Quantified Expressions].
The normalization rules map all general comparison operators into core expressions, whose dynamic semantics is defined in other sections. Therefore, there are no dynamic semantics rules for general comparison operators.
Notation
For convenience, NodeOp denotes the operators "is
" and
"isnot
".
The normalization rule for node comparison expressions checks that both operands are optional node values, otherwise it generates an error. If both operands are nodes, it applies the operator specified by the []BinaryOp function.
[Expr1 NodeOp Expr2]Expr | ||||||||||||||
== | ||||||||||||||
|
Ed. Note: Don Chamberlin points out that the above rule is nearly identical to the one in the previous section. Merging the two rules should be considered.
Core Grammar
There are no core grammar rules for node comparisons as they are normalized to function calls.
There are no static type rules for the node comparison operators.
The normalization rules map the node comparison operators into core expressions, whose dynamic semantics is defined in other sections. Therefore, there are no dynamic semantics rules for node comparison operators.
Notation
For convenience, OrderOp denotes the operators "follow", "precedes", "<<", and ">>".
The normalization rule for order comparison expressions checks that both operands are optional node values, otherwise it generates an error. If both operands are nodes, it applies the operator specified by the []BinaryOp function.
[Expr1 OrderOp Expr2]Expr | ||||||||||||||
== | ||||||||||||||
|
Core Grammar
There are no core grammar rules for order comparisons as they are normalized to function calls.
There are no static type rules for the order comparison operators.
The normalization rules map the order comparison operators into core expressions, whose dynamic semantics is defined in other sections. Therefore, there are no dynamic semantics rules for order comparison operators.
Introduction
A logical expression is either an
and-expression or an or-expression. The
value of a logical expression is always one of the boolean values:
true
or false
.
[7 (XQuery)] | OrExpr | ::= | |
[8 (XQuery)] | AndExpr | ::= | |
[12 (XPath)] | AndExpr | ::= |
Ed. Note: [Kristoffer/XSL] The present rules mix static and dynamic dispatch of which primitive function is used. We are investigating how to repair that as well as make the definitions work with both static and dynamic typing. See [Issue-0122: Overloaded functions].
The normalization rules for "and" and "or
" first
get the effective boolean value of each argument, then apply the
appropriate operand.
[Expr1 and Expr2]Expr | |||||
== | |||||
|
Ed. Note: Note that non-determinism in the semantics of logical expressions is not modeled here. See [Issue-0136: Non-determinism in the semantics].
[Expr1 or Expr2]Expr
|
|||||
== | |||||
|
Core Grammar
There are no core grammar rules for logical expressions which normalized to other kinds of [XPath/XQuery] expressions.
There are no static type rules for the logical comparison operators. They both have return type xs:boolean, as specified in [XQuery 1.0 and XPath 2.0 Functions and Operators].
The normalization rules map the logical comparison operators into core expressions, whose dynamic semantics is defined in other sections. Therefore, there are no dynamic semantics rules for logical comparison operators.
[XPath/XQuery] supports two forms of constructors: a "literal" form that follows the XML syntax, and element and attribute constructors that can be used to construct stand-alone elements and attributes, possibly with a computed name.
Core Grammar
The core grammar productions for constructors are:
[20 (Core)] | Constructor | ::= | |
[57 (Core)] | EnclosedExpr | ::= |
Introduction
[77 (XQuery)] | ElementContent | ::= |
The static and dynamic semantics of the literal forms of element constructors is obtained after normalization to computed element constructors.
Notation
The auxiliary mapping rules []ElementContent and []AttributeContent are used for the normalization of element and attribute content respectively.
Literal characters, escaped curly braces, character references, and predefined entity references in element content are treated specially. This normalization rule assumes:
that the significant whitespace characters in element constructors have been preserved, as described in [5.7.3 Whitespace in Constructors];
that character references have been resolved to individual characters and predefined entity references have been resolved to sequences of characters, and
that the rule is applied to the longest contiguous sequence of characters.
The following normalization rules take the longest consecutive sequence of individual characters that arise from literal characters, escaped curly braces, character references, and predefined entity references and normalizes the character sequence as a text node.
[Char*]ElementContent |
== |
dm:text-node (fs:characters_to_string(Char*))
|
We start with the rules for normalizing a literal XML element's content. We normalize each individual value and construct a sequence of the normalized values. Consecutive sequences of characters are normalized as a unit, applying the rule above.
[ ElementContent0 ..., ElementContentn ]ElementContent |
== |
([ ElementContent0 ]ElementContent , ..., [ ElementContentn]ElementContent) |
We normalize an enclosed expression in element content by normalizing each individual expression in its expression sequence and then construct a sequence of the normalized values:
[ { Expr0, ..., Exprn } ]ElementContent |
== |
([ Expr0 ]Expr , ...,
[ Exprn]Expr, dm:text-node (""))
|
We need to distinguish between multiple enclosed expressions, because the rule for converting sequences of atomic values into strings are applied to sequences within distinct enclosed expressions. To distinguish between multiple enclosed expressions, we add an empty text node to the end of the constructed sequence above -- this empty text node is eliminated in the dynamic evaluation rule when consecutive text nodes are coalesced into a single text node. The text node guarantees that a whitespace character will not be inserted between atomic values computed by distinct enclosed expressions.
Processing instructions and comments in element content are normalized by applying the standard normalization rules.
[XmlProcessingInstruction]ElementContent |
== |
[XmlProcessingInstruction]Expr |
[XmlComment]ElementContent |
== |
[XmlComment]Expr |
The following rules normalize the two forms of literal XML element constructors by normalizing their name, attribute list, and element content and translates the normalized values into the corresponding computed element constructor.
[70 (XQuery)] | ElementConstructor | ::= |
[ < QName AttributeList > ElementContent* </ QName S? > ]Expr |
== |
element [QName]{ [ AttributeList ]AttributeContent , [ ElementContent* ]ElementContent } |
[ < QName AttributeList /> ]Expr |
== |
element [QName]{ [ AttributeList ]AttributeContent } |
Like literal XML element constructors, literal XML attribute constructors are normalized to computed attribute constructors.
[78 (XQuery)] | AttributeList | ::= | |
[79 (XQuery)] | AttributeValue | ::= | |
[80 (XQuery)] | AttributeValueContent | ::= |
Literal characters, escaped curly braces, character references, and predefined entity references in attribute content are treated as in element content. In addition, the normalization rule for characters in attributes assumes:
that an escaped single or double quote is converted to an individual single or double quote.
The following normalization rules take the longest consecutive sequence of individual characters that arise from literal characters, escaped curly braces, character references, predefined entity references, and escaped single and double quotes and normalizes the character sequence as a string.
[Char*]AttributeContent |
== |
fs:characters_to_string(Char*) |
We normalize an enclosed expression in attribute content by normalizing each individual expression in its expression sequence and then construct a sequence of the normalized values:
[ { Expr0, ..., Exprn } ]AttributeContent |
== |
([ Expr0 ]Expr , ..., [
Exprn]Expr, dm:text-node (""))
|
As in literal XML elements, we need to distinguish between multiple enclosed expressions in attribute content, because the rule for converting sequences of atomic values into strings are applied to sequences within distinct enclosed expressions. As in element content, to distinguish between multiple enclosed expressions in attribute content, we add an empty text node to the end of the constructed sequence above -- this empty text node is eliminated in the dynamic evaluation rule.
We normalize an AttributeValue (a literal attribute's value) by normalizing each individual value in its content and then construct a sequence of the normalized values. Consecutive sequences of characters are normalized as a unit, applying the rules above.
[ AttributeValueContent0 ..., AttributeValueContentn ]AttributeContent |
== |
([ AttributeValueContent0 ]AttributeContent , ..., [ AttributeValueContentn]AttributeContent) |
An AttributeList is normalized by the following rule, which maps each of the individual attribute-value expressions in the attribute list and constructs a sequence of the normalized values.
[
|
|||
== | |||
|
Core Grammar
There are no core grammar rules for literal XML element or attribute constructors as they are normalized to computed constructors.
There are no additional static type rules for literal XML element or attribute constructors.
There are no additional dynamic evaluation rules for literal XML element or attribute constructors.
[72 (XQuery)] | ComputedElementConstructor | ::= | |
[73 (XQuery)] | ComputedAttributeConstructor | ::= | |
[71 (XQuery)] | ComputedDocumentConstructor | ::= |
An element constructor may contain an arbitrary sequence of items, e.g., atomic values, attributes, and child elements. Here's an element constructor that contains an integer, an element, a string, and an attribute:
element address { 123, element street {"Roosevelt Ave."}, "Flushing, NY", attribute zip { "11368" } }
Computed element constructors are normalized by mapping their name and expression sequence. The normalization rule partitions attribute nodes from other nodes and atomic values in the element content.
[element QName { ExprSequence }]Expr | |||||||||||
== | |||||||||||
|
When the name of an element is computed, the normalization rule also checks that the value of the element's name is a xs:QName.
[element { Expr } { ExprSequence }]Expr | ||||||||||||
== | ||||||||||||
|
Computed attribute expressions are normalized by mapping their sub-expressions.
Core Grammar
The core grammar rules for computed constructors are:
[53 (Core)] | ComputedElementConstructor | ::= | |
[54 (Core)] | ComputedAttributeConstructor | ::= | |
[52 (Core)] | ComputedDocumentConstructor | ::= |
The normalization rules leave us with only the operator form of the element or attribute constructor to handle. The element (attribute) operator still has two forms: one in which a QName is supplied as the element (attribute) name, and the other in which a computed expression is supplied. In the latter case, the name cannot be known until runtime, and the element (attribute) is given a wildcard type.
Note that the static type for constructed elements and attributes is very poor as the static type of their content is lost during construction. A possible solution is to implicitly validate when the element is constructed. See [Issue-0169: Conformance Levels] for suggestions.
|
||
|
||
statEnv |-
element QName { ExprSequence }
: element qname { xs:anyType }
|
|
||
|
||
statEnv |-
element { Expr } { ExprSequence }
: element { xs:anyType }
|
|
||
|
||
statEnv |-
attribute { Expr } { ExprSequence }
: attribute { xs:anySimpleType }
|
|
||
|
||
statEnv |-
attribute QName { ExprSequence }
: attribute qname { xs:anySimpleType }
|
Ed. Note: DD: the above is a necessary consequence of our current evaluation model. One variation that I can think of is that the static rules could try looking up the element name in element environment. If the element name is found, then the associated, named type is used (and the contents are required to match). If the named element type is not found, then the constructed type is used, as before. Thus, in this scenario, validation would be done whenever an element with a "global" name was created. See also comments on the impact of (non-)validation on element construction, in the next section.
The following rules construct an element from its name and content. The earlier normalization rule guarantees that all attributes precede other element content, which is a sequence of node and atomic values. Section [3.7.4 Data Model Representation] in [XQuery 1.0: A Query Language for XML] specifies the rules for converting a sequence of atomic values into a text node prior to element construction. As formal specification of these conversion rules is not instructive, the function [7.1.3 The fs:item-sequence-to-node-sequence function] implements this conversion.
|
||||||||||
|
||||||||||
dynEnv |-
element QName { ExprSequence } =>
|
|
||||||||||
|
||||||||||
dynEnv |-
element { Expr } { ExprSequence } =>
|
Note that the element constructor dm:element-node
makes
copies of any nodes in its arguments; therefore the result
of element construction is a completely "new"
element.
The following rules construct an attribute from its name and values and are similar to those for elements. Section [3.7.2 Data Model Representation] in [XQuery 1.0: A Query Language for XML] specifies the rules for converting a sequence of atomic values into a string prior to attribute construction. Each node is replaced by its string value. For each adjacent sequence of one or more atomic values returned by an enclosed expression, a string is constructed, containing the canonical lexical representation of all the atomic values, with a single blank character inserted between adjacent values. As formal specification of these conversion rules is not instructive, the function [7.1.4 The fs:item-sequence-to-string function] implements this conversion.
|
||||||
|
||||||
dynEnv |-
attribute QName { ExprSequence } =>
|
|
||||||
|
||||||
dynEnv |-
attribute { Expr } { ExprSequence } =>
|
Ed. Note: DD: There are several issues with element construction:
Namespaces and more precise type annotations in the constructor are not supported. This is due to the bottom-up nature of element construction: in general, one does not know either the namespaces in scope or the validation-associated schema type until this element has been "seated" in some containing element (and so on recursively). See [Issue-0165: Namespaces in element constructors].
There is a possible solution to this chicken-and-egg problem, however: because the element constructor makes copies of its children, it could be the responsibility of the element constructor to "fill in" the values for namespaces-in-scope and schema-component on each newly-copied child (recursively), based on information provided for the node. In this scenario, these fields would remain "blank" until some appropriate activity caused a schema component to become associated with a node, etc.
One implication of such a scheme would be that the "value" of elements could change as they are copied into a new containing element. For example, defaulted attributes could be added. Possibly the interpretation of data values would change as well, e.g. a data value supplied as a string could be re-interpreted as a number.
Any special treatment of xmlns, etc. that would be needed to associate namespaces with elements is not modeled.
Even if/when schema components are available, it is not clear when or how defaulted attributes and/or elements are created.
Section [3.7.3
Whitespace in Constructors] in [XQuery 1.0: A Query Language for XML] describes
how whitespace in element and attribute constructors is
processed depending on the value of the xmlspace
declaration in the query prolog. The formal semantics assumes
that the rules for handling whitespace are applied prior to
normalization rules, for example, during parsing of a query.
Therefore, there are no formal rules for handling
whitespace.
[74 (XQuery)] | CdataSection | ::= | |
[75 (XQuery)] | XmlProcessingInstruction | ::= | |
[76 (XQuery)] | XmlComment | ::= |
Core Grammar
The core grammar productions for other constructors and comments are:
[55 (Core)] | XmlProcessingInstruction | ::= | |
[56 (Core)] | XmlComment | ::= |
A literal XML character data (CDATA) section is normalized into a text node constructor by applying the rule for converting characters to a text node in element content.
[<![CDATA[" Char* "]]>]Expr |
== |
[Char*]ElementContent |
A literal XML processing instruction is normalized into a processing instructor constructor; its character content is converted to a string as in attribute content.
[<? NCName Char* ?>"]Expr |
== |
dm:processing-instruction-node (NCName [Char*]AttributeContent)
|
A literal XML comment is normalized into a comment constructor; its character content is converted to a string as in attribute content.
[<!-- Char* -->]Expr |
== |
dm:comment-node ([Char*]AttributeContent)
|
There are no additional static type rules for CDATA, processing instructions or comments.
There are no additional dynamic evaluation rules for CDATA, processing instructions or comments.
Introduction
[XPath/XQuery] provides [For/FLWR] expressions for iteration, for binding variables to intermediate results, and filtering bound variables according to a predicate.
A FLWRExpr in XQuery 1.0 consists of a sequence of ForClauses and LetClauses, followed by an optional WhereClause, followed by an expression to be "return"ed, as described by the following grammar productions. Each variable binding is preceded by an optional type assertion which specify the type expected for the variable.
[10 (XQuery)] | FLWRExpr | ::= | |
[26 (XQuery)] | ForClause | ::= | |
[27 (XQuery)] | LetClause | ::= | |
[28 (XQuery)] | WhereClause | ::= | |
[63 (XQuery)] | TypeDeclaration | ::= | |
[13 (XPath)] | ForExpr | ::= |
Notation
Individual [For/FLWR] clauses are normalized by means of the auxiliary normalization rules:
Where FLWRClause can be any either a ForClause, a LetClause, or a WhereClause:
[56 (Formal)] | FLWRClause | ::= |
Note that, as is, this auxiliary rule normalizes a fragment of the [For/FLWR] expression, while taking the remainder of the expression (in Expr) as an additional parameter.
Full [For/FLWR] expressions are normalized to nested core expressions using two sets of normalization rules. Note that some of the rules also accept ungrammatical FLWRExprs such as "where Expr1 return Expr2". This does not matter, as normalization is always applied on parsed [XPath/XQuery] expressions, and ungrammatical FLWRExprs would be rejected by the parser beforehand.
The first set of rules is applied on a full [For/FLWR] expression, splitting it at the clause level, then applying further normalization on each separate clause.
[ (ForClause | LetClause | WhereClause) FLWRExpr ]Expr |
== |
[(ForClause | LetClause | WhereClause)]FLWR([FLWRExpr]) |
[ (ForClause | LetClause | WhereClause) return Expr ]Expr |
== |
[(ForClause | LetClause | WhereClause)]FLWR([Expr]) |
Then each [For/FLWR] clause is normalized separately. A ForClause may bind more than one variable, whereas a for expression in the [XPath/XQuery] core binds and iterates over only one variable. Therefore, a ForClause is normalized to nested for expressions:
[ for TypeDeclaration1? Variable1 in Expr1,..., TypeDeclarationn? Variablen in Exprn ] FLWR(Expr) | |||
== | |||
|
Each individual for clause, is then normalized to always have a type assertion.
Note that the additional Expr parameter of the auxiliary normalization rule is used as the final return expression.
Likewise, a LetClause clause is normalized to nested let expressions:
[ let TypeDeclaration1? Variable1 := Expr1, ···, TypeDeclarationn? Variablen := Exprn]FLWR(Expr) | |||
== | |||
|
A WhereClause is normalized to an IfExpr, with the else-branch returning the empty list:
Example
The following simple example illustrates, how a
FLWRExpr is normalized. The for
expression
in the example below is used to iterate over two collections,
binding variables $i
and $j
to items
in these collections. It uses a let
clause to
binds the local variable $k
to the sum of both
numbers, and a where
clause to select only those
numbers that have a sum equal to or greater than the integer
5
.
for xs:integer $i in (1, 2), $j in (3, 4) let $k := $i + $j where $k >= 5 return <tuple> <i> { $i } </i> <j> { $j } </j> </tuple>
By the first set of rules, this is normalized to (except for the operators and element constructor which are not treated here):
for xs:integer $i in (1, 2) return for $j in (3, 4) return let $k := $i + $j return if ($k >= 5) then <tuple> <i> { $i } </i> <j> { $j } </j> </tuple> else ()
For each binding of $i
to an item in the
sequence (1 , 2)
the inner for
expression iterates over the sequence (3 , 4)
to
produce tuples ordered by the ordering of the outer sequence
and then by the ordering of the inner sequence. This core
expression eventually results in the following document
fragment:
(<tuple> <i>1</i> <j>4</j> </tuple>, <tuple> <i>2</i> <j>3</j> </tuple>, <tuple> <i>2</i> <j>4</j> </tuple>)
with the static type:
element tuple { element i { xs:integer }, element j { xs:integer } }*
Core Grammar
After normalization, single for
expressions are
described by the following core grammar production.
[8 (Core)] | ForExpr | ::= | |
[16 (Core)] | ForClause | ::= | |
[45 (Core)] | TypeDeclaration | ::= |
A single for
expression is typed as follows:
First Type1 of the iteration expression Expr1 is
inferred. Then the prime type of Type1 -
prime(Type1) - is determined. This is a choice over
all item types in Type1 (see also [3.6 Auxiliary typing judgments for for,
unordered, and sortby
expressions]). With the variable component of the static
environment statEnv extended with Variable1 of type
prime(Type1), the type Type2 of Expr2 is
inferred. Because the for
expression iterates
over the result of Expr1, the final type of the iteration
is Type2 multiplied with the possible number of items in
Type1 (one, ?
, *
, or
+
). This number is determined by the auxiliary
type-function quantifier(Type1).
|
|||
|
|||
statEnv |- for Variable1 in Expr1 return Expr2 : Type2 · quantifier(Type1) |
In the case a type assertion is present, the static semantics also checks that the type of the input expression is a subtype of the asserted type. This semantics is specified as the following typing rule.
|
|||||
|
|||||
statEnv |- for SequenceType Variable1 in Expr1 return Expr2 : Type2 · quantifier(Type1) |
Example
For example, if $example
is bound to the
sequence (<one/> , <two/> ,
<three/>)
of type element one {}, element
two {}, element three {}
, then the query
for $s in $example return <out> {$s} </out>
is typed as follows:
(1) prime(element one {}, element two {}, element three {}) = element one {} | element two {} | element three {} (2) quantifier(element one {}, element two {}, element three {}) = + (3) $s : element one {} | element two {} | element three {} (4) <out> {$s} </out> : element out {element one {} | element two {} | element three {}} (5) result-type : element out {element one {} | element two {} | element three {}}+
This result-type is not the most specific type possible. It
does not take into account the order of elements in the input
type, and it ignores the individual and overall number
of elements in the input type. The most specific type possible
is: element out {element one {}}, element out {element
two {}}, element out {element three {}}
. However,
inferring such a specific type for arbitrary input types and
arbitrary return clauses requires significantly more
complex type inference rules. In addition, if put into the
context of an element, the specific type violates the
"unique particle attribution" restriction of XML schema, which requires
that an element must have a unique content model within a
particular context.
The evaluation of a for
expression distinguishes two
cases: If the iteration expression Expr1 evaluates to the empty
sequence, then the entire expression evaluates to the empty
sequence:
dynEnv |- Expr1 => Value empty(Value) |
|
dynEnv |- for TypeDeclaration? Variable1 in Expr1 return Expr2 => dm:empty-sequence() |
Otherwise, the iteration expression Expr1, is
evaluated to produce the sequence Item1, ...,
Itemn. For each item Itemi in this
sequence, the body of the for
expression
Expr2 is evaluated in the environment dynEnv
extended with Variable1 bound to Itemi. This
produces values Valuei, ..., Valuen which are
concatenated to produce the result sequence.
|
|||||
|
|||||
dynEnv |- for Variable1 in Expr1 return Expr2 => op:concatenate(Value1 ,..., Valuen) |
In the case a type assertion is present, the dynamic semantics also checks that the input value matches the asserted type. This semantics is specified as the following dynamic rule.
|
||||||||
|
||||||||
dynEnv |- for SequenceType Variable1 in Expr1 return Expr2 => op:concatenate(Value1 ,..., Valuen) |
Ed. Note: The dynamic semantics of for could be better defined without the use of ··· and using recursion. See [Issue-0134: Should we define for with head and tail?].
Example
Note that if the expression in the return
clause
results in a sequence, sequences are never nested in the
[XPath/XQuery] data model. For instance, in the following for
expression:
for $i in (1,2) return (<i> {$i} </i>, <negi> {-$i} </negi>)
each iteration in the for
results in a sequence of two
elements, which are then concatenated and flattened in the
resulting sequence (using the op:concatenate function):
(<i>1</i>, <negi>-1</negi>, <i>2</i>, <negi>-2</negi>)
Core Grammar
After normalization, single let
expressions are
described by the following core grammar production.
[9 (Core)] | LetExpr | ::= | |
[17 (Core)] | LetClause | ::= |
A let
expression extends the type environment
statEnv with Variable1 of type Type1 inferred from
Expr1, and infers the type of Expr2 in the extended
environment to produce the result type Type2.
statEnv |- Expr1 : Type1 statEnv [ varType(Variable1 : Type1) ] |- Expr2 : Type2 |
|
statEnv |- let Variable1 := Expr1 return Expr2 : Type2 |
In the case a type assertion is present, the static semantics also checks that the type of the input expression is a subtype of the asserted type. This semantics is specified as the following typing rule.
|
|||||
|
|||||
statEnv |- let Variable1 := Expr1 return Expr2 : Type2 |
A let
expression extends the dynamic environment
dynEnv with Variable bound to Value1 returned by
Expr1, and evaluates Expr2 in the extended
environment to produce Value2.
|
|||
|
|||
dynEnv |- let Variable1 := Expr1 return Expr2 => Value2 |
In the case a type assertion is present, the dynamic semantics also checks that the input value matches the asserted type. This semantics is specified as the following dynamic rule.
|
|||||
|
|||||
dynEnv |- let SequenceType Variable1 := Expr1 return Expr2 => Value2 |
Example
Note the use of the environment discipline to define the
scope of each variable. For instance, in the following nested
let
expression:
let $k := 5 return let $k := $k + 1 return $k+1
the outermost let
expression binds variable
$k
to the
integer 5
in the environment, then the expression
$k+1
is computed, yielding value 6
, to
which the second variable $k
is bound.
The expression then results in
the final integer 7
.
[6 (XQuery)] | SortExpr | ::= | |
[36 (XQuery)] | SortSpecList | ::= | |
[37 (XQuery)] | SortModifier | ::= |
Core Grammar
The core grammar productions for sortby are:
[6 (Core)] | SortExpr | ::= | |
[21 (Core)] | SortSpecList | ::= | |
[22 (Core)] | SortModifier | ::= |
Ed. Note: Status: The semantics of sortby is not currently specified. Revision is pending agreement about the semantics of sorting.See [Issue-0109: Semantics of sortby].
[9 (XQuery)] | UnorderedExpr | ::= |
Introduction
The unordered
keyword may be used as a prefix
to any expression to indicate that its order is not
significant.
Core Grammar
The core grammar production for unordered expressions is:
[7 (Core)] | UnorderedExpr | ::= |
Notation
The dynamic semantics for unordered use an auxiliary judgments which disregards order between the items in a sequence.
The following judgment
dynEnv |- Value1 permutes to Value2holds if the sequence of items in Value2 is a permutation of the sequence of items in Value1.
The static semantics for unordered uses the auxiliary type functions prime(Type) and quantifier(Type); which are defined in [3.6 Auxiliary typing judgments for for, unordered, and sortby expressions]. The type of each argument is determined, and then prime(.) and quantifier(.) are applied to the sequence type (Type1, Type2).
The dynamic semantics for unordered is specified using the auxiliary judgments permutes to as follows.
It is important to remark that the permutes to judgments is non deterministics. There are many sequences which can be a permutation of a given sequence. Any of those permutations would satisfy the above semantics.
Introduction
A conditional expression supports conditional evaluation of one of two expressions.
[13 (XQuery)] | IfExpr | ::= |
[if (Expr1) then Expr2 else Expr3]Expr | ||
== | ||
|
where $fs:new is a newly created variable that does not appear in the rest of the query.
Core Grammar
The core grammar rule for the conditional expression is:
[11 (Core)] | IfExpr | ::= |
statEnv |- Expr1 : xs:boolean statEnv |- Expr2 : Type2 statEnv |- Expr3 : Type3 |
|
statEnv |-
if (Expr1) then
Expr2 else Expr3 :
(Type2 | Type3)
|
If the conditional's boolean expression Expr1 evaluates to true, Expr2 is evaluated and its value is produced. If the conditional's boolean expression evaluates to false, Expr3 is evaluated and its value is produced. Note that the existence of two separate evaluation rules ensures that only one branch of the conditional is evaluated.
Ed. Note: DD: actually, I would like that last sentence to be true, but I don't think it is: there is nothing that I know of in the semantics of evaluation rules that says that the clauses must be evaluated left-to-right, so currently nothing stops an implementation from evaluating the body expressions first. Even if this is a functional language generally, I am sure there will be non-functional side-effects in implementation-dependent extensions to the language, and I think there must be a way to formally state that bodies of conditionals do not get executed if their test fails.
Introduction
[XPath/XQuery] defines two quantification expressions:
[11 (XQuery)] | QuantifiedExpr | ::= | |
[14 (XPath)] | QuantifiedExpr | ::= |
The quantification expressions are entirely normalized into other core expressions using the following normalization rules.
First, multiple variable quantifiers are normalized to single variable quantifiers.
[some Variable1 in Expr1, ..., Variablen in Exprn satisfies Expr]Expr | |||||
== | |||||
[
|
[every Variable1 in Expr1, ..., Variablen in Exprn satisfies Expr]Expr | |||||
== | |||||
[
|
[some Variable in Expr1 satisfies Expr2]Expr | |||||
== | |||||
|
[every Variable in Expr1 satisfies Expr2]Expr | |||||
== | |||||
|
Ed. Note: Note that the non-determinism in the semantics of quantified expressions is not modeled here. See [Issue-0136: Non-determinism in the semantics].
Core Grammar
There are no core grammar rules for quantified expressions as they are normalized to other core expressions.
There are no additional static type rules for the quantified expressions.
There are no additional dynamic evaluation rules for the quantified expressions.
Introduction
Expressions on SequenceTypes are expressions whose semantics depends on the type of some of the sub-expressions to which they are applied. The syntax of SequenceType expressions is described in [4.4.2 SequenceType].
[14 (XQuery)] | InstanceofExpr | ::= |
Introduction
The SequenceType expression "Expr instance of SequenceType" is true if and only if the result of evaluating expression Expr is an instance of the type referred to by SequenceType.
An "instance of" expression is normalized into a "typeswitch" expression. Note that the following normalization rule uses a variable $fs:new, which is a newly created variable which must not conflict with any variables already in scope. This variable is necessary to comply with the syntax of typeswitch expressions in the core [XPath/XQuery], but is never used.
[Expr instance of SequenceType]Expr | |||
== | |||
|
Ed. Note: MFF: The "instance of" expression allows an optional "only" modifier. The use case for such a modifier is based on named typing, while the [XPath/XQuery] semantics is currently based on structural typing. It is not clear what the semantics of the "only" modifier under structural typing should be and how it can be supported. See [Issue-0111: Semantics of instance of ... only].
[12 (XQuery)] | TypeswitchExpr | ::= | |
[38 (XQuery)] | CaseClause | ::= |
Introduction
The typeswitch expression of XQuery allows users to perform different operations according to the type of an input expression.
Each branch of a typeswitch expression may have an optional "Variable" statement, used to bind a variable to the result of the input expression. This variable is optional in [XPath/XQuery] but mandatory in the [XPath/XQuery] core. One of the reasons for having this variable is that it can have a more specific type for the corresponding branch.
Normalization of typeswitch expressions is applied to make sure an appropriate "Variable" is present in each branch.
The following general normalization rule merely adds a newly created variable which does not appear in the rest of the query. Note that $fs:new is a newly generated variable that must not conflict with any variables already in scope but is not used in any of the sub-expressions.
[
|
|||||
== | |||||
|
Core Grammar
The core grammar productions for typeswitch are:
[10 (Core)] | TypeswitchExpr | ::= | |
[23 (Core)] | CaseClause | ::= |
Notation
The following auxiliary grammar production is used to identify branches of the typeswitch.
[57 (Formal)] | CaseRules | ::= |
Notation
The following judgment
dynEnv |- Value1 against CaseRules => Value2is used in the dynamic semantics of typeswitch. It indicate that under the environment dynEnv, and with the input value of the typeswitch being "Value1", the given case rules yields the value Value2.
Notation
The following judgment
statEnv |- Type knowing (Type1 | ... | Typen) against CaseRules : Type2is used in the static semantics of typeswitch. It indicates that under the type environment statEnv, with the input type of the typeswitch being "Type", and with the previously visited types Type1 | ... | Typen, the given case rules (e.g., "CaseRules") has type Type2. This typing judgment keep track of all previously visited types in the typeswitch. This additional information is used later on in typing the default clause.
The typeswitch expression possesses one of the more complex sets of static typing rules. The rules account for the fact that if the static type of the conditional expression is known, then it is possible to determine statically that some of the case clauses do not apply, and thus do not contribute to the static type of a typeswitch expression.
Like the dynamic typeswitch rule, the static typeswitch rule relies upon auxiliary rules to determine the type of each of the case clauses and of the default clause. These auxiliary rules are provided after the main rule. Note that the type of the input expression is always treated as a sequence of prime types, using the "prime" and "quantifier" operations on types. This is necessary because the further typing rules compute the common prime types for each case clause of the type switch.
Ed. Note: Jerome: the use of the common prime types replaces the previous use of type intersection. Common prime types simplifies significantly the complexity in implementing typeswitch, but is less precise in certain cases.
|
||||||||||
|
||||||||||
|
The rules that determine the static type of each case clause in the typeswitch are given next. In each rule, one needs to compute the "common prime types" between the input type and the case clause SequenceType.
The first rule is applied if the "common prime types" is none. In that case, it is known for sure the corresponding case clause is not evaluated and that the corresponding result type is none. Thanks to this rule, it is often possible to infer a precise type for the overall typeswitch by eliminating some of the cases.
|
|||
|
|||
statEnv |- CaseType0 knowing (CaseType1 | ... | CaseTyper)) against case SequenceType Variable return Expr : none |
The second rule is applied if the "common prime types" is anything other than none. In that case, the input variable is added into the type environment and type inference is applied on the expression on the right-hand side of the case clause. Note that the type of the input variable is set to the "common prime types", and not to the input type.
|
||||||
|
||||||
statEnv |- CaseType0 knowing (CaseType1 | ... | CaseTyper)) against case SequenceType Variable return Expr : Type1 |
Note that these two rules do not take the visited datatypes into account. The "default" clause differs from the other clauses in that it does not specify a SequenceType. The typing rule for the "default" clause uses the visited type instead. Intuitively, the type corresponding to the "default" clause is any type but the ones in the other cases clauses.
Therefore, if the type of the input expression is a subtype of the choice of all visited types, then it is known for sure that the case clause is not evaluated and that the type of the default clause is none.
CaseType0 <: (CaseType1 | ... | CaseTypen) |
|
statEnv |- CaseType0 knowing (CaseType1 | ... | CaseTyper)) against default Variable return Expr : none |
Otherwise, the input variable is added into the type environment, and type inference is applied to the expression on the right-hand side of the default clause. Note that the type of the input variable is set to the input type of the expression.
|
|||
|
|||
statEnv |- CaseType0 knowing (CaseType1 | ... | CaseTyper)) against default Variable return Expr : Type1 |
Ed. Note: Jerome: There is an asymmetry here. It would be nicer to be able to have the type be more precise, like for the other case clauses. The technical problem is the need for some form of negation. I think one could define a "non-common-primes" function that would do the trick, but I leave that open for now until further review of the new typeswitch section is made. See [Issue-0112: Typing for the typeswitch default clause].
Example
The typing rules for typeswitch provides reasonably precise type information in a number of useful cases. For example consider the following simple schema and query.
<xs:element name="book"> <xs:complexType> <xs:element name="title" type="xs:string"/> <xs:element name="author> <xs:complexType> <xs:element name="name" type="xs:string"/> <xs:element name="affiliation" type="xs:string"/> </xs:complexType> </xs:element> </xs:complexType> </xs:element> <xs:element name="bib"> <xs:complexType> <xs:element ref="book" minOccurs="0" maxOccurs="unbounded"/> </xs:complexType> </xs:element> ... for $x in $bib/book/* return typeswitch $x case element author $a return $a/name case element editor $e return $e case element title $t return <wrote>{data($t)}</wrote> default return ()
The static rules for typeswitch can determine (1) that,
with the given input schema, the second case matching
against element editor
never applies, and (2)
that the data() function in the third case matching against
element title
, will not raise an error, because
$e
is guaranteed to contain data rather than
more nodes. The resulting type corresponds to the following
schema fragment.
<xs:choice minOccurs="0" maxOccurs="unbounded"> <xs:element name="name" type="xs:string"/> <xs:element name="wrote" type="xs:string"/> </xs:choice>
The type rules for typeswitch do not, however, account for the interdependence between successive case clauses. Thus if two case clauses had overlapping SequenceTypes, the static rules would behave as if both case clauses "fired", rather than just the first one.
Ed. Note: Jerome: It seems that the simpler version of typeswitch proposed here would actually allow us to take previous case clauses into account. This is something worth exploring as it would improve the static analysis in a way that might be helpful to users. See [Issue-0112: Typing for the typeswitch default clause].
Ed. Note: Issue: There seem to be cases where the current semantics of typeswitch breaks type substitutability. See [Issue-0174: Semantics of 'element foo of type T'].
The evaluation of a typeswitch proceeds as follows. First, the input expression is evaluated, yielding an input value. Then the first case clause whose SequenceType type matches that value is selected and its corresponding expression is evaluated.
Note that the dynamic environmentdynEnv is only extended with this binding by the first auxiliary rule, which applies, if the input value matches the corresponding sequence type, or by the third auxiliary rule for the default case.
|
|||
|
|||
dynEnv |- typeswitch (Expr) CaseRules => Value1 |
If the value matches the sequence type, the first auxiliary rule applies: It extends the environment by binding the variable Variable to Value0 and evaluates the body of the case rule.
|
||||
|
||||
dynEnv |- Value0 against case SequenceType Variable return Expr CaseRules => Value1 |
If the value does not match the sequence type, the second auxiliary rule evaluates on the remaining case rules, and the current case rule is not evaluated.
CaseType = [ SequenceType ]sequencetype not (Value0 matches CaseType) dynEnv |- Value0 against CaseRules => Value1 |
|
dynEnv |- Value0 against case SequenceType Variable return Expr CaseRules => Value1 |
Finally, the last rule states that the "default" branch of a typeswitch expression always evaluates to its given expression.
[30 (XQuery)] | CastExpr | ::= | |
[30 (XPath)] | CastExpr | ::= |
Core Grammar
The core grammar production for cast as is:
[19 (Core)] | CastExpr | ::= |
Cast expressions are expressions that check or change the type of an expression against a given type.
Introduction
The expression "cast as SequenceType ( Expr )" can be used to explicitly convert the result of an expression from one type to another. It changes both the type and value of the result of an expression, and can only be applied on an atomic value.
The semantics of cast expressions follows the specification given in Section [14. Casting Functions] of the [XQuery 1.0 and XPath 2.0 Functions and Operators] document. The casting table in Section [14. Casting Functions] of the [XQuery 1.0 and XPath 2.0 Functions and Operators] document indicates whether a cast is allowed or not. In case it is allowed, a specific cast function is applied, based on the input and output XML Schema simple types. The semantics of the cast function follows casting rules which are described in the the remainder of Section [14. Casting Functions] of the [XQuery 1.0 and XPath 2.0 Functions and Operators] document and is not specified further here.
Ed. Note: Jerome: The [XQuery 1.0 and XPath 2.0 Functions and Operators] document does not provide any function for casting, just a table and casting rules. It would be preferable to either have an explicit function to normalize to, or to put the semantics of casts in the Formal Semantics. This relates to Issue 17 in the [XQuery 1.0 and XPath 2.0 Functions and Operators] document.
Cast operations perform atomization. This is captured during normalization, as specified by the following rule.
Notation
The following auxiliary judgments are used to represent access to the casting table and to the semantics of casting, as described in Section [14. Casting Functions] of the [XQuery 1.0 and XPath 2.0 Functions and Operators] document.
The judgment:
holds if casting from type Type1 to Type2 is always possible (Y), may be possible (M), or is not allowed (N).
The notation:
indicates that applying the casting rules for Type2 on Value1 yields the value Value2.
If the cast table indicates the cast is not allowed (N), the system raises a static type error. Otherwise, the following static typing rules give the static semantics of "cast as" expression. Two cases are distinguished: if the static type of the expression Type1 can be the empty sequence, then the static output type of the cast is the given type Type2 made optional. Otherwise the static output type is the given type Type2
|
|||||
|
|||||
statEnv |- cast as SequenceType2 (Expr) : Type2 ? |
|
|||||
|
|||||
statEnv |- cast as SequenceType2 (Expr) : Type2 |
If the cast is allowed (Y or M), the following
evaluation rule applies the casting rules on the result of
the input expression. The rule uses the data model
function dm:type
in order to obtain the
dynamic type of the input value, SequenceType
normalization to obtain the output type, and the above
auxiliary judgments to check whether the cast is allowed
and to apply the casting rules.
|
||||
|
||||
|
Note that in the case that the casting table indicates "M", the casting operation is allowed but might fail at run-time if the input value is inappropriate (e.g. attempting to cast the string "VRAI" into xs:boolean). In that case, the dynamic evaluation returns an error value.
If the casting table returns "N", the cast is not allowed and the dynamic semantics always returns an error value.
|
|||||
|
|||||
|
Introduction
The expression "treat as SequenceType ( Expr )", can be used to change the static type of the result of an expression without changing its value. Treat as raises a static type error, if the static type of expression and the specified type are incompatible. Treat as raises a run-time error, if the dynamic type of the expression is not an instance of the specified type.
Treat as expressions are normalized to typeswitch expressions. Note that the following normalization rule uses a variable $fs:new, which is a newly created variable which must not conflict with any variables already in scope.
[29 (XQuery)] | ValidateExpr | ::= |
Core Grammar
The core grammar production for validate is:
[18 (Core)] | ValidateExpr | ::= |
A validate
expression validates its argument
with respect to the in-scope schema definitions,
using the schema validation process described in
[XML Schema]. The argument to a validate expression may be any
sequence of elements. Validation replaces element and attribute
nodes with new nodes that have their own identity and contain
type annotations and defaults created by the validation
process. If a node that has a parent is validated, the parent of
the original node will not be the parent of the validated
node.
Ed. Note: Issue: The current form of validate cannot be typed statically. See [Issue-0166: Static typing for validate].
An important effect of validation is that it removes existing type annotations and values (erasure), and it revalidates the corresponding data model instance, possibly adding new type annotations and values (annotation). Both erasure and annotation are described formally in [3.4 Erase and Annotate]. Indeed, the conjunction of erasure and annotation provides a formal model for a large part of actual schema validation. The semantics of the "validate" operation is (partially) specified as follows.
|
||||
|
||||
dynEnv |- validate element ElementName { Expr } => Value3 |
Ed. Note: Issue: This semantics only applies when validating against a top-level element. See [Issue-0138: Semantics of Schema Context]
Introduction
The Query Prolog is a series of declarations and definitions that affect query processing. The Query Prolog can be used to define namespaces, import type definitions from XML Schemas, and define functions. Namespace declarations and schema imports always precede function definitions, as specified by the following grammar productions.
[1 (XQuery)] | Query | ::= | |
[2 (XQuery)] | QueryProlog | ::= | |
[3 (XQuery)] | QueryBody | ::= |
The order in which functions are defined is immaterial. Notably, user-defined functions may invoke other user-defined functions in any order.
Namespace Declarations and Schema Import are not part of the query proper but are used to modify the input context for the rest of the query processing. Namespace Declarations and Schema Import are processed before the normalization phase.
The semantics of Schema Import is described in terms of the XQuery type system. The process of converting an XML Schema into a sequence of type declarations is described in Section [8 Importing Schemas]. This section describes how the resulting sequence of type declarations is added into the static environment when the prolog is processed.
Notation
Prolog declarations are either namespace declarations or type declarations.
[58 (Formal)] | PrologDeclList | ::= | PrologDecl* |
[59 (Formal)] | PrologDecl | ::= | NamespaceDecl
| XMLSpaceDecl | DefaultNamespaceDecl | DefaultCollationDecl | SchemaImport |
Notation
The following auxiliary judgments are used when processing the [XPath/XQuery] prolog.
The judgment:
holds if the sequence of prolog declarations PrologDeclList yields the static environment statEnv.
The judgment:
holds if under the static environment statEnv1, the single prolog declarations PrologDeclList yields the new static environment statEnv2.
Prolog declarations are processed in the order they are encountered, as described by the following inference rules. The first rule specifies that for an empty sequence of prolog declarations, the static environment is composed of a default context.
Ed. Note: Jerome: What do the default namespace and type environments contain? I believe at least the default namespace environment should contain the "xs", "xf" and "op" prefixes, as well as the default namespaces bound to the empty namespace. Should the default type environment contain wildcard types? See [Issue-0115: What is in the default context?].
|
||
|
[84 (XQuery)] | NamespaceDecl | ::= | |
[86 (XQuery)] | DefaultNamespaceDecl | ::= |
A namespace declaration adds a new (prefix,uri) binding in the namespace component of the static environment.
statEnv1 = statEnv [ namespace(NCName |-> StringLiteral) ] | ||
|
||
|
A default element namespace declaration changes the default element namespace prefix binding in the namespace component of the static environment.
statEnv1 = statEnv [ namespace(fsdefaultelem |-> StringLiteral) ] | ||
|
||
|
A default function namespace declaration changes the default function namespace prefix binding in the namespace component of the static environment.
statEnv1 = statEnv [ namespace(fsdefaultfunc |-> StringLiteral) ] | ||
|
||
|
Note that for namespaces, later declarations can override earlier declarations of the same prefix.
[89 (XQuery)] | SchemaImport | ::= | |
[85 (XQuery)] | SubNamespaceDecl | ::= |
Notation
The following auxiliary judgments are used when processing schema imports.
The judgment:
holds if under the static environment statEnv1, the sequence of type definitions Definition* yields the new static environment statEnv2.
The judgment:
holds if under the static environment statEnv1, the single definition Definition yields the new static environment statEnv2.
Schema imports are first imported into the query type system and yield a sequence of type definitions. Then each type definitions is added to the static environment.
|
|||
|
|||
|
An empty sequence of definitions yields the original environment.
Each definition is added into the static environment.
|
|||
|
|||
|
Type, element and attribute declarations are added respectively to the type, element and attribute declarations components of the static environment.
|
||
|
||
|
|
||
|
||
|
|
||
|
||
|
Note that for namespaces, later declarations can override earlier declarations of the same prefix. In the case of global elements, attributes and types, multiple declarations correspond to an error.
[82 (XQuery)] | XMLSpaceDecl | ::= |
The impact of xmlspace declaration is not formally specified in this document.
[83 (XQuery)] | DefaultCollationDecl | ::= |
The impact of default collation is not formally specified in this document. See [Issue-0160: Collations in the static environment].
Introduction
User defined functions specify the name of the function, the names and types of the parameters, and the type of the result. The function body defines how the result of the function is computed from its parameters.
[87 (XQuery)] | FunctionDefn | ::= | |
[88 (XQuery)] | ParamList | ::= | |
[59 (XQuery)] | Param | ::= |
Notation
The following auxiliary mapping rule is used for the normalization of parameters in function definitions: []Param.
The only form of normalization required for user defined functions is adding the type for its parameters or for the return clause if it is not provided.
[ define function QName ( ParamList? ) returns SequenceType EnclosedExpr ]Expr |
== |
define function [QName] ( [ParamList?]Param ) returns SequenceType [EnclosedExpr]Expr |
If the return type of the function is not provided, it is given the item* sequence type.
[define function QName ( ParamList? ) EnclosedExpr ]Expr |
== |
define function [QName] ( [ParamList?]Param ) returns item* [EnclosedExpr]Expr |
Parameters without a declared typed are given the item* sequence type.
[Variable]Param |
== |
item* Variable |
[SequenceType Variable]Param |
== |
SequenceType Variable |
First, all the function signatures are added into the static environment, and all the function bodies are added into the dynamic environment. This process happens before static type analysis occurs.
|
||||
|
||||
|
The static typing rules for function definitions checks whether the type of the enclosed expression is consistent with the type of the input parameters, and the type of the return clause.
|
|||
|
|||
statEnv |-
define function QName
( SequenceType1 Variable1 , ···
SequenceTypen Variablen ) returns SequenceTyper { Expr } |
What this typing rule is checking is: if the input parameters are of the given type, then is it true that the result of the function is of the return type. If the type checking fails, the system raises an error. Otherwise, it does not have any other effect, as function signatures are already inside the static environment.
There is no need to describe a dynamic semantics at this point, as functions are only evaluated when called. The actual semantics of function calls is described in [5.1.4 Function Calls].
Ed. Note: Status: This section is still incomplete. This section will be completed as soon as Sections 4 and 5 are consolidated. See [Issue-0135: Semantics of special functions].
As was explained in section [2.5 Functions], a number of functions play a role in defining the formal semantics of [XPath/XQuery]. Some other functions from the [XQuery 1.0 and XPath 2.0 Functions and Operators] document need special static typing rules. This section gives the semantics of all "special" functions, used in the formal semantics.
Introduction
This section gives the definition and semantics of functions which are used in the formal semantics but are not part of the [XQuery 1.0 and XPath 2.0 Functions and Operators] document.
fs:characters-to-string
functionThe fs:characters-to-string function takes a sequence of character values and synthecizes a string.
fs:distinct-doc-order
functionThe fs:distinct-doc-order function sorts by document order and removes duplicates. It is defined as the composition of the [XQuery 1.0 and XPath 2.0 Functions and Operators] functions xf:distinct-nodes and sorting by document order.
The dynamic semantics of fs:distinct-doc-order cannot be specified as a simple sortby expression. See [Issue-0168: Sorting by document order].
fs:item-sequence-to-node-sequence
functionThe fs:item-sequence-to-node-sequence function converts a sequence of item values to nodes by applying the rules in Section [3.7.2 Data Model Representation] in .
fs:item-sequence-to-string
functionThe fs:item-sequence-to-node-sequence function converts a sequence of item values to a string by applying the rules in Section [3.7.2 Data Model Representation] in .
In particular, each node is replaced by its string value. For each adjacent sequence of one or more atomic values returned by an enclosed expression, a string is constructed, containing the canonical lexical representation of all the atomic values, with a single blank character inserted between adjacent values.
xf:error
functionThe xf:error function always returns the none type.
|
||
|
xf:distinct-nodes
, and
xf:distinct-values
functionsThe xf:distinct-nodes function takes a sequence of nodes as input and returns a sequence of prime types.
|
|||
|
|||
statEnv |- xf:distinct-nodes(Expr) : prime(Type) · quantifier(Type) |
The xf:distinct-values function takes a sequence of atomic values as input and returns a sequence of prime types.
op:union
, op:intersect
and
op:except
operatorsThe static semantics for op:union uses the auxiliary type functions prime(Type) and quantifier(Type); which are defined in [3.6 Auxiliary typing judgments for for, unordered, and sortby expressions]. The type of each argument is determined, and then prime(.) and quantifier(.) are applied to the sequence type (Type1, Type2).
|
||
|
||
|
The static semantics of op:intersect is analogous to that for op:union, but uses the common-prime and common-occurrence operations. Because an intersection may always be empty, the result type needs to be made optional.
|
|||||
|
|||||
|
The static semantics of op:except follows. The type of the second argument is ignored as it does not contribute to the result type. Like with op:intersect the result of op:except may be the empty list.
|
||
|
||
|
op:to
operatorThe static semantics of the op:to function states that it always returns an integer sequence:
|
||
|
||
|
Ed. Note: MFF: the binary operator "to" is not defined on empty sequences. The [XQuery 1.0 and XPath 2.0 Functions and Operators] document says operands are decimals, while the XQuery document says they are integers. What happens when Expr1 > Expr2? See [Issue-0119: Semantics of op:to].
xf:data
functionIntroduction
The xf:data function is used to access the value content of an element or attribute. This function corresponds to the dm:typed-value accessor in the [XPath/XQuery] data model.
Ed. Note: Some aspects of the semantics of the xf:data() function are still an open issue. For instance, what should be the result of xf:data() over a text node. See [Issue-0107: Semantics of data()].
Notation
Infering the type for the xf:data function is done by applying the xf:data function as a Filter, using the same approach as for the XPath steps.
The following notation, adapted from the Filter judgment in [5.2.1 Steps], is used.
Static type analysis for the xf:data function checks that the function is applied on an element or attribute with a simple type content. If so, it returns the corresponding simple type through an application of the Filter judgment on the input type of the function.
|
||||
|
||||
statEnv |- xf:data(Expr) : Type2 |
|
statEnv ; element ElementName { AttrType, SimpleType } |- xf:data : SimpleType; |
|
statEnv ; attribute AttributeName { SimpleType } |- xf:data : SimpleType; |
If applied on any other kind of item, it returns the empty sequence.
|
||||
|
||||
dynEnv |- xf:data(Expr) : () |
Otherwise (for empty sequences or sequences of more than one item value), it raises an error.
Example
Consider the following variables and its corresponding static type.
$x : (element price { attribute currency { xs:string }, xs:decimal } | element price_code { xs:integer })
Applying the xf:data function on that variable results in the following type.
xf:data($x) : (xs:decimal | xs:integer)
Remark that, as the input type is a choice, applying the Filter judgment results in a choice of simple types for the output of the xf:data function.
Dynamically, the xf:data function is implemented as the dm:typed-value data model accessor.
Ed. Note: Status:This section has been extensively revised to reflect the addition of named typing to the [XPath/XQuery] type system, and improve the editorial level. Feedback on the new mapping and on the new presentation is solicited.
This section describes how XML Schema declarations, as specified by [XML Schema] are imported into the [XPath/XQuery] type system.
At compile time, the [XPath/XQuery] environment imports XML Schema declarations and loads them as declarations in the [XPath/XQuery] type system. The semantics of that loading process is defined by normalization rules that map XML Schema descriptions into the [XPath/XQuery] type system.
Here is summarized the XML Schema features which are covered by the formal semantics, and handled by the import mapping described in this section. For each feature, the following indications are used.
Handled indicates features which are relevant for [XPath/XQuery], are modeled within the [XPath/XQuery] type system, and handled by the mapping.
Not yet indicates features which are relevant for [XPath/XQuery], but are not yet modeled within the [XPath/XQuery] type system or are not yet handled by the mapping. Those features correspond to open issues. In case the [XPath/XQuery] type system provides appropriate support for those features, but the mapping is incomplete, the additional annotation mapping only is used.
Not handled indicates features which are relevant for [XPath/XQuery], but are not modeled within the [XPath/XQuery] type system, and are not handled by the mapping. Such feature are typically only related to validation, for which the formal semantics will only give a partial model.
Ignored Indicates features which are not relevant for [XPath/XQuery], are not modeled within the [XPath/XQuery] type system, and are not relevant for the mapping. Such features might have to do with documentation of the schema, or might affect which Schemas are legal, but do not affect which documents match which Schemas.
Here is the exhaustive list of XML Schema features and their status in this document.
Feature: | Supported |
Primitive Simple types | Handled |
Simple type derivation by restriction | Handled |
Derivation by list and union | Handled |
Facets on simple types | Not handled |
ID and IDREF constraints | Ignored |
Attribute Declarations | |
default,fixed,use | Not yet |
Element Declarations | |
default, fixed (value constraint) | Not yet |
nillable | Handled |
substitution group affiliation | Handled |
substitution group exclusions | Ignored |
disallowed substitutions | Ignored |
abstract | Not yet |
Complex Type Definitions | |
derivation by restriction | Handled |
derivation by extension | Handled |
final | Ignored |
abstract | Not yet |
AttributeUses | |
required | Not yet, mapping only |
default, fixed (value constraint) | Not yet |
Attribute Group Definitions | Not yet, mapping only |
Model Group Definitions | Not yet, mapping only |
Model Groups | Handled |
Particles | Handled |
Wildcards | |
process contents strict, skip, lax | Not yet |
Identity-constraint Definitions | Ignored |
Notation Declarations | Ignored |
Annotations | Ignored |
Note that the schema import feature specified here assumes it is given a legal schema as input. As a result, it is not necessary to check for 'block' or 'abstract' attributes.
The presentation of the schema mapping is done according to the following organization.
Schema component
First each schema component is summarized using the same notation used in the XML Representation Summary sections in [XML Schema]. For instance, here is the XML Representation Summary for complex types.
<complexType |
[ ignored ] abstract = boolean : false |
[ ignored ] block = (#all | List of (extension | restriction)) |
[ ignored ] final = (#all | List of (extension | restriction)) |
[ ignored ] id = ID |
mixed = boolean : false |
name = NCName |
[ ignored ] {any attributes with non-schema namespace . . .} > |
Content: (annotation?, (simpleContent | complexContent | ((group | all | choice | sequence)?, ((attribute | attributeGroup)*, anyAttribute?)))) |
</complexType> |
Attributes indicated as [ ignored ] are not mapped into the [XPath/XQuery] type system.
Attributes indicated as [ not handled ] are not currently handled by the mapping.
Note that in order to simplify the mapping, it is assumed
that the default values for all attributes in the XML
Representation of Schema are filled in. For instance in the
above complex type, if the mixed
attribute is not
present, it will be treated as being present and having the
value "false"
.
Schema mapping
XML Schema import is specified by means of mapping rules. All mapping rules have the structure below.
[SchemaComponent]Subscript |
== |
TypeComponent |
The SchemaComponent above the horizontal rule denotes an XML Schema component before translation and the TypeComponent beneath the horizontal rule denotes an equivalent type component in the [XPath/XQuery] type system.
Notation
Whenever necessary for the mapping rules, specific grammar productions which describe fragments of XML Schema may be introduced. For instance, here are grammar productions used to describes fragments of the XML Representation Summary for the complexType Element Information Item.
[43 (Formal)] | ComplexTypeContent | ::= | |
[46 (Formal)] | AttributeContent | ::= | |
[44 (Formal)] | ChildrenContent | ::= |
As in the rest of this document, some mapping rules may use fragments of the XML Representation corresponding to the syntactic categories defined by those grammar productions. For instance, the following complex type fragment uses the syntactic categories: TypeName, ComplexTypeContent, and AttributeContent, ChildrenContent, and MixedAttribute.
<complexType |
name = TypeName |
MixedAttribute> |
ChildrenContent AttributeContent |
</complexType> |
Notation
The normalization rule
[Schema]Schema |
== |
Definition* |
maps a complete schema into a set of Definition in the [XPath/XQuery] type system.
The normalization rule
[SchemaComponent]definition(targetNCName) |
== |
Definition |
maps a toplevel schema component into a Definition in the [XPath/XQuery] type system, given the target namespace .
The normalization rule
[SchemaComponent]content(targetNCName) |
== |
TypeComponent |
maps a schema component not directly under the schema element, into a TypeComponent in the [XPath/XQuery] type system, given the target namespace .
The XML Schema attributes: use, minOccurs, maxOccurs, mixed, nillable, and substitutionGroup, require specific mapping rules.
The "use" attribute is used to describe the occurrence and default behavior of a given attribute.
Notation
The following auxiliary grammar productions are used to describe the "use" attribute.
The normalization rule
[UseAttribute]use |
== |
Occurrence |
maps the use attribute UseAttribute in Schema into the occurrence indicator Occurrence in the [XPath/XQuery] type system.
Schema mapping
Use attributes are mapped to the type system in the following way.
use = "optional"use |
== |
? |
use = "required"use |
== |
Ed. Note: Issue: how derivation of attribute declaration and the "prohibited" use attributes are mapped in the [XPath/XQuery] type system is still an open issue.
Notation
The following auxiliary grammar productions are used to describe occurrence attributes.
[42 (Formal)] | OccursAttributes | ::= | |
[40 (Formal)] | maxOccurs | ::= | |
[41 (Formal)] | minOccurs | ::= |
The normalization rule
[OccursAttributes]occurs |
== |
Occurrence |
maps the occurrence attributes OccursAttributes in Schema into the occurrence indicator Occurrence in the [XPath/XQuery] type system.
Schema mapping
Occurrence attributes are mapped to the type system in the following way.
[minOccurs="0" maxOccurs="1"]occurs |
== |
? |
[minOccurs="1" maxOccurs="1"]occurs |
== |
[minOccurs="0" maxOccurs="n"]occurs |
== |
* |
[minOccurs="1" maxOccurs="n"]occurs |
== |
+ |
where n > 1.
[minOccurs="n" maxOccurs="m"]occurs |
== |
* |
where n >= m > 1
Notation
The following auxiliary grammar productions are used to describe the "mixed" attribute.
[37 (Formal)] | MixedAttribute | ::= |
The normalization rule
[MixedAttribute]mixed |
== |
Mixed |
maps the mixed attribute MixedAttribute in Schema into a Mixed notation in the [XPath/XQuery] type system.
Schema mapping
If the mixed attribute is true it is mapped to a mixed notation in the [XPath/XQuery] type system.
[ mixed = "true" ]mixed |
== |
mixed |
If the mixed attribute is false it is mapped to empty in the [XPath/XQuery] type system.
[ mixed = "false" ]mixed |
== |
Notation
The following auxiliary grammar productions are used to describe the "nillable" attribute.
[38 (Formal)] | NillableAttribute | ::= |
The normalization rule
[NillableAttribute]nillable |
== |
Nillable |
maps the nillable attribute NillableAttribute in Schema into a Nillable notation in the [XPath/XQuery] type system.
Schema mapping
If the nillable attribute is true it is mapped to a nillable notation in the [XPath/XQuery] type system.
[ nillable = "true" ]nillable |
== |
nillable |
If the nillable attribute is false it is mapped to empty in the [XPath/XQuery] type system.
[ nillable = "false" ]nillable |
== |
Notation
The substitution group declaration indicates the element that a given element can be substituted for. The following auxiliary grammar productions are used to describe the "substitutionGroup" attribute.
[39 (Formal)] | substitutionGroupAttribute | ::= |
The normalization rule
[substitutionGroupAttribute]substitution |
== |
Substitution |
maps the substitutionGroup attribute substitutionGroupAttribute in Schema into a Substitution notation in the [XPath/XQuery] type system.
Schema mapping
If the substitutionGroup attribute is present, it is mapped to a substitutionGroup notation in the [XPath/XQuery] type system.
[ substitutionGroup = QName ]substitution |
== |
substitutes for QName |
Otherwise, it is mapped to empty.
Schema component
The following structure describes attribute declarations in XML Schema.
<attribute |
[ not handled ] default = string |
[ not handled ] fixed = string |
[ not handled ] form = (qualified | unqualified) |
[ ignored ] id = ID |
name = NCName |
ref = QName |
type = QName |
use = (optional | prohibited | required) : optional |
[ ignored ] {any attributes with non-schema namespace . . .} > |
Content: (annotation?, (simpleType?)) |
</attribute> |
Schema import distinguishes between global attribute declarations and local attribute declarations.
Schema mapping
Global attribute declarations are mapped like local attribute declarations, but are prefixed by a "define" keyword in the [XPath/XQuery] type system.
[AttributeDecl]definition(targetNCName) |
== |
define [AttributeDecl]content(targetNCName) |
Schema mapping
Local attributes whose type is given by a reference to a global type name are mapped in the type system as follows.
[
|
||||
== | ||||
( attribute targetNCName:NCName { of type QName } )[UseAttribute]use |
References to a global attribute are mapped in the type system as follows.
[
|
|||
== | |||
( attribute QName )[UseAttribute]use |
A local attribute with a local content is mapped to the [XPath/XQuery] type system as follows.
[
|
|||||
== | |||||
( attribute targetNCName:NCName { [simpleType]content(targetNCName) } )[UseAttribute]use |
Schema component
The following structure describes attribute declarations in XML Schema.
<element |
[ ignored ] abstract = boolean : false |
[ ignored ] block = (#all | List of (extension | restriction)) |
[ not handled ] default = string |
[ ignored ] final = (#all | List of (extension | restriction)) |
[ not handled ] fixed = string |
[ not handled ] form = (qualified | unqualified) |
[ ignored ] id = ID |
maxOccurs = (nonNegativeInteger | unbounded) : 1 |
minOccurs = nonNegativeInteger : 1 |
name = NCName |
nillable = boolean : false |
ref = QName |
substitutionGroup = QName |
type = QName |
[ ignored ] {any attributes with non-schema namespace . . .} > |
Content: (annotation?, ((simpleType | complexType)?, (unique | key | keyref)*)) |
</element> |
Schema import distinguishes between global element declarations and local element declarations.
Schema mapping
Global element declarations are mapped like local element declarations, but are prefixed by a "define" keyword in the [XPath/XQuery] type system.
[
|
|||||
== | |||||
define element targetNCName:NCName [substitutionGroupAttribute]substitution [NillableAttribute]nillable of type QName |
[
|
||||||
== | ||||||
define element targetNCName:NCName [substitutionGroupAttribute]substitution [NillableAttribute]nillable [ElementContent]content(targetNCName) |
Schema mapping
Local element declarations, but mapped into corresponding notations in the [XPath/XQuery] type system. Note that substitution group cannot be declared on local elements.
[
|
|||||
== | |||||
( element targetNCName:NCName [NillableAttribute]nillable of type QName ) [OccursAttributes]occurs |
[
|
|||
== | |||
( element QName ) [OccursAttributes]occurs |
[
|
||||||
== | ||||||
( element targetNCName:NCName [NillableAttribute]nillable [ElementContent]content(targetNCName) ) [OccursAttributes]occurs |
Schema component
A complex type definition is represented in XML by the following structure.
<complexType |
[ ignored ] abstract = boolean : false |
[ ignored ] block = (#all | List of (extension | restriction)) |
[ ignored ] final = (#all | List of (extension | restriction)) |
[ ignored ] id = ID |
mixed = boolean : false |
name = NCName |
[ ignored ] {any attributes with non-schema namespace . . .} > |
Content: (annotation?, (simpleContent | complexContent | ((group | all | choice | sequence)?, ((attribute | attributeGroup)*, anyAttribute?)))) |
</complexType> |
Notation
The following auxiliary grammar productions are used to describe the content of a complex type definition.
[43 (Formal)] | ComplexTypeContent | ::= | |
[46 (Formal)] | AttributeContent | ::= | |
[44 (Formal)] | ChildrenContent | ::= |
Schema import distinguishes between global complex types (which are mapped to sort declarations) and local complex types (which are mapped to type definitions).
Schema mapping
In the case of global complex types, the mapping rule which applies is denoted by []definition(targetNCName).
[
|
|||||
== | |||||
define type targetNCName:NCName [MixedAttribute ComplexTypeContent]mixed_content(targetNCName) |
Note that the mixed
is passed along in the
normalization rules, in order to map it later on to the
appropriate indication in the [XPath/XQuery] type system.
Schema mapping
In the case of a local complex types, there must not be a name attribute and the mapping rule which applies is denoted by []content(targetNCName).
[
|
||||
== | ||||
[MixedAttribute ComplexTypeContent]mixed_content(targetNCName) |
Note that the mixed
is passed along in the
normalization rules, in order to map it later on to the
appropriate indication in the [XPath/XQuery] type system.
Schema component
A complex type can be of simple content. A simple content is represented in XML by the following structure.
<simpleContent |
[ ignored ] id = ID |
[ ignored ] {any attributes with non-schema namespace . . .} > |
Content: (annotation?, (restriction | extension)) |
</simpleContent> |
Derivation by restriction inside a simple content is represented in XML by the following structure.
<restriction |
base = QName |
[ ignored ] id = ID |
[ ignored ] {any attributes with non-schema namespace . . .} > |
Content: (annotation?, (simpleType?, (minExclusive | minInclusive | maxExclusive | maxInclusive | totalDigits | fractionDigits | length | minLength | maxLength | enumeration | whiteSpace | pattern)*)?, ((attribute | attributeGroup)*, anyAttribute?)) |
</restriction> |
Derivation by extension inside a simple content is represented in XML by the following structure.
<extension |
base = QName |
[ ignored ] id = ID |
[ ignored ] {any attributes with non-schema namespace . . .} > |
Content: (annotation?, ((attribute | attributeGroup)*, anyAttribute?)) |
</extension> |
Notation
The normalization rule
[MixedAttribute ComplexTypeContent]mixed_content(targetNCName) |
== |
TypeSpecifier |
maps a pair of mixed attribute and complex type content to a type specifier.
Schema mapping
A complex types with simple content must not have a
mixed
attribute set to "true".
If the simple content is derived by restriction, it is mapped into a simple type restriction in the [XPath/XQuery] type system. Only the name of the base atomic type and attributes are mapped, while the actual simple type restriction is ignored. (Remember that facets are not captured in the [XPath/XQuery] type system.)
[
|
|||||||||
== | |||||||||
restricts QName { [AttributeContent]content(targetNCName) QName } |
If the simple type is derived by extension, it is mapped into an extended type specifier into the [XPath/XQuery] type system.
[
|
|||||||||
== | |||||||||
extends QName { [AttributeContent]content(targetNCName) } |
Schema component
A complex type can be of complex content. A complex content is represented in XML by the following structure.
<complexContent |
[ ignored ] id = ID |
mixed = boolean : false |
[ ignored ] {any attributes with non-schema namespace . . .} > |
Content: (annotation?, (restriction | extension)) |
</complexContent> |
Derivation by restriction inside a complex content is represented in XML by the following structure.
<restriction |
base = QName |
[ ignored ] id = ID |
[ ignored ] {any attributes with non-schema namespace . . .} > |
Content: (annotation?, (group | all | choice | sequence)?, ((attribute | attributeGroup)*, anyAttribute?)) |
</restriction> |
Derivation by extension inside a complex content is represented in XML by the following structure.
<extension |
base = QName |
[ ignored ] id = ID |
[ ignored ] {any attributes with non-schema namespace . . .} > |
Content: (annotation?, ((group | all | choice | sequence)?, ((attribute | attributeGroup)*, anyAttribute?))) |
</extension> |
Schema mapping
If the complex content is derived by restriction, it is mapped into a type restriction in the [XPath/XQuery] type system, and the
[
|
|||||||||
== | |||||||||
restricts QName [MixedAttribute]mixed { [AttributeContent]content(targetNCName) [ChildrenContent]content(targetNCName) } |
If the complex content is derived by extension, it is mapped into an extended type specifier into the [XPath/XQuery] type system.
[
|
|||||||||
== | |||||||||
extends QName [MixedAttribute]mixed { [AttributeContent]content(targetNCName) [ChildrenContent]content(targetNCName) } |
Mapping for attribute uses is given in [8.1.4.1 use].
Schema component
Model group definitions are represented in XML by the following structure.
<attributeGroup |
[ ignored ] id = ID |
name = NCame |
ref = QName |
[ ignored ] {any attributes with non-schema namespace . . .} > |
Content: (annotation?, ((attribute | attributeGroup)*, anyAttribute?)) |
</attributeGroup> |
Schema mapping
Attribute group definitions are not currently handled by the mapping. See [Issue-0158: Support for XML Schema groups].
Schema mapping
Attribute group references are not currently handled by the mapping. See [Issue-0158: Support for XML Schema groups].
Schema component
Model group definitions are represented in XML by the following structure.
<group |
name = NCame > |
Content: (annotation?, (all | choice | sequence)) |
</group> |
Schema mapping
Model group definitions are not currently handled by the mapping. See [Issue-0158: Support for XML Schema groups].
Model groups are either "all", "sequence" or "choice". One can also refer to a model group definition.
Schema component
All groups are represented in XML by the following structure.
<all |
[ ignored ] id = ID |
maxOccurs = 1 : 1 |
minOccurs = (0 | 1) : 1 |
[ ignored ] {any attributes with non-schema namespace . . .} > |
Content: (annotation?, element*) |
</all> |
Schema mapping
All groups are mapped into the "&" operation in the [XPath/XQuery] type system.
.
[
|
||||
== | ||||
([Element1]content(targetNCName) & ... & [Elementn]content(targetNCName)) [OccursAttributes]occurs |
Schema component
Choice groups are represented in XML by the following structure.
<choice |
[ ignored ] id = ID |
maxOccurs = (nonNegativeInteger | unbounded) : 1 |
minOccurs = nonNegativeInteger : 1 |
[ ignored ] {any attributes with non-schema namespace . . .} > |
Content: (annotation?, (element | group | choice | sequence | any)*) |
</choice> |
Notation
The following auxiliary grammar productions are used to describe group components.
[45 (Formal)] | GroupComponent | ::= |
Schema mapping
Choice groups are mapped into the "|" operation in the [XPath/XQuery] type system.
.
[
|
||||
== | ||||
([GroupComponent1]content(targetNCName) | ... | [GroupComponentn]content(targetNCName)) [OccursAttributes]occurs |
Schema component
Sequence groups are represented in XML by the following structure.
<sequence |
[ ignored ] id = ID |
maxOccurs = (nonNegativeInteger | unbounded) : 1 |
minOccurs = nonNegativeInteger : 1 |
[ ignored ] {any attributes with non-schema namespace . . .} > |
Content: (annotation?, (element | group | choice | sequence | any)*) |
</sequence> |
Schema mapping
Choice groups are mapped into the "," operation in the [XPath/XQuery] type system.
.
[
|
||||
== | ||||
([GroupComponent1]content(targetNCName) , ... , [GroupComponentn]content(targetNCName)) [OccursAttributes]occurs |
Particles contribute to the definition of content models.
Particle can be either and element reference, a group reference or a wildcard.
Schema component
Element reference particles are represented in XML by the following structure.
<element |
ref = QName |
maxOccurs = (nonNegativeInteger | unbounded) : 1 |
minOccurs = nonNegativeInteger : 1 |
[ ignored ] {any attributes with non-schema namespace . . .} > |
Schema mapping
Element references are mapped into element references in the [XPath/XQuery] type system.
[
|
|||
== | |||
element QName [OccursAttributes]occurs |
Schema component
Group reference particles are represented in XML by the following structure.
<group |
ref = QName |
maxOccurs = (nonNegativeInteger | unbounded) : 1 |
minOccurs = nonNegativeInteger : 1 |
[ ignored ] {any attributes with non-schema namespace . . .} > |
Schema mapping
Model group references are not currently handled by the mapping.
Schema component
Attribute wilcards are represented in XML by the following structure.
<anyAttribute |
[ ignored ] id = ID |
[ not handled ] namespace = ((##any | ##other) | List of (anyURI | (##targetNamespace | ##local)) ) : ##any |
processContents = (lax | skip | strict) : strict |
[ ignored ] {any attributes with non-schema namespace . . .} > |
Content: (annotation?) |
</anyAttribute> |
Schema mapping
An attribute wildcard with a "skip" process content is mapped as an attribute wildcard in the [XPath/XQuery] type system.
[
|
||||
== | ||||
attribute* |
Ed. Note: Issue: Attribute wildcards with a "lax" or "strict" process content are not currently handled by the mapping. See [Issue-0153: Support for lax and strict wildcards].
Ed. Note: Issue: Namespace wildcards are not currently handled by the mapping. See [Issue-0157: Support for wildcard namespaces].
Schema component
Element wilcards are represented in XML by the following structure.
<any |
[ ignored ] id = ID |
maxOccurs = (nonNegativeInteger | unbounded) : 1 |
minOccurs = nonNegativeInteger : 1 |
[ not handled ] namespace = ((##any | ##other) | List of (anyURI | (##targetNamespace | ##local)) ) : ##any |
processContents = (lax | skip | strict) : strict |
[ ignored ] {any attributes with non-schema namespace . . .} > |
Content: (annotation?) |
</any> |
Schema mapping
An element wildcard with a "skip" process content is mapped as an element wildcard in the [XPath/XQuery] type system.
[
|
|||||
== | |||||
( element )[OccursAttributes]occurs |
Ed. Note: Issue: Element wildcards with a "lax" or "strict" process content are not currently handled by the mapping.
Ed. Note: Issue: Namespace wildcards are not currently handled by the mapping. See [Issue-0157: Support for wildcard namespaces].
All identity-constraints definitions are ignored when mapping into the [XPath/XQuery] type system.
All notation declarations are ignored when mapping into the [XPath/XQuery] type system.
Schema component
A simple type is represented in XML by the following structure.
<simpleType |
[ ignored ] final = (#all | (list | union | restriction)) |
[ ignored ] id = ID |
name = NCName |
[ ignored ] {any attributes with non-schema namespace . . .} > |
name = NCName |
</simpleType> |
Derivation by restriction inside a simple type is represented in XML by the following structure.
<restriction |
base = QName |
[ ignored ] id = ID |
[ ignored ] {any attributes with non-schema namespace . . .} > |
Content: (annotation?, (simpleType?, (minExclusive | minInclusive | maxExclusive | maxInclusive | totalDigits | fractionDigits | length | minLength | maxLength | enumeration | whiteSpace | pattern)*)?) |
</restriction> |
Derivation by list inside a simple type is represented in XML by the following structure.
<list |
[ ignored ] id = ID |
itemType = QName |
[ ignored ] {any attributes with non-schema namespace . . .} > |
Content: (annotation?, (simpleType?)) |
</list> |
Derivation by union inside a simple type is represented in XML by the following structure.
<union |
[ ignored ] id = ID |
memberTypes = List of QName |
[ ignored ] {any attributes with non-schema namespace . . .} > |
Content: (annotation?, (simpleType*)) |
</union> |
Schema import distinguishes between global simple types (which are mapped to sort declarations) and local simple types (which are mapped to type definitions).
Schema mapping
In the case of global simple types, the mapping rule which applies is denoted by []definition(targetNCName).
[
|
||||
== | ||||
define type targetNCName:NCName [SimpleTypeContent]simple_content(targetNCName) |
Schema mapping
In the case of global simple types, the mapping rule which applies is denoted by []content(targetNCName).
[
|
|||
== | |||
[SimpleTypeContent]simple_content(targetNCName) |
Notation
The normalization rule []simple_content(targetNCName) maps a simple type content to a type specifier.
Schema mapping
If the simple type is derived by restriction, it is mapped into a simple type restriction in the [XPath/XQuery] type system. Only the name of the base atomic type and attributes are mapped, while the actual simple type restriction is ignored. (Remember that facets are not captured in the [XPath/XQuery] type system.)
[
|
||||
== | ||||
restricts QName { QName } |
If the simple type is derived by list, it is mapped into a repetition type into the [XPath/XQuery] type system.
[
|
|||
== | |||
{ ([SimpleType]content(targetNCName))* } |
[
|
||
== | ||
{ QName* } |
If the simple type is derived by union, it is mapped into a union type into the [XPath/XQuery] type system.
[
|
|||
== | |||
{ ([SimpleType]content(targetNCName) | ... | [SimpleTypen]content(targetNCName)) } |
[
|
||
== | ||
{ QName1 | ... | QNamen } |
Schema component
A schema is represented in XML by the following structure.
<schema |
[ not handled ] attributeFormDefault = (qualified | unqualified) : unqualified |
[ ignored ] blockDefault = (#all | List of (extension | restriction | substitution)) : ' ' |
[ not handled ] elementFormDefault = (qualified | unqualified) : unqualified |
[ ignored ] finalDefault = (#all | List of (extension | restriction)) : ' ' |
[ ignored ] id = ID |
targetNamespace = anyURI |
[ ignored ] version = token |
[ ignored ] xml:lang = language |
[ ignored ] {any attributes with non-schema namespace . . .} > |
Content: ((include | import | redefine | annotation)*, (((simpleType | complexType | group | attributeGroup) | element | attribute | notation), annotation*)*) |
</schema> |
Notation
The following auxiliary grammar productions are used.
[35 (Formal)] | Pragma | ::= | |
[36 (Formal)] | Content | ::= |
The auxiliary normalization rule
[Pragma]pragma(targetNCName) |
== |
Definition* |
maps the a schema pragma into a set of definitions in the [XPath/XQuery] type system.
Schema mapping
Schemas are imported by the "schema" declaration in the preamble of a query. To import a schema, the document referred to by the given URI is opened and the schema declarations contained in the document are translated into the corresponding in-line type definitions.
[
|
||||
== | ||||
[Pragma]pragma(targetNCName) [Content]definition(targetNCName) |
Schema component
A schema include is represented in XML by the following structure.
<include |
[ ignored ] id = ID |
schemaLocation = anyURI |
[ ignored ] {any attributes with non-schema namespace . . .} > |
Content: (annotation?) |
</include> |
Schema mapping
A schema include is not specified here, and is assumed to be handled by the XML Schema processor.
Schema component
A schema redefinition is represented in XML by the following structure.
<redefine |
[ ignored ] id = ID |
schemaLocation = anyURI |
[ ignored ] {any attributes with non-schema namespace . . .} > |
Content: (annotation | (simpleType | complexType | group | attributeGroup))* |
</redefine> |
Schema mapping
A schema redefine is not specified here, and is assumed to be handled by the XML Schema processor.
Schema component
A schema import is represented in XML by the following structure.
<import |
[ ignored ] id = ID |
namespace = anyURI |
schemaLocation = anyURI |
[ ignored ] {any attributes with non-schema namespace . . .} > |
Content: (annotation?) |
</import> |
Schema mapping
A schema import is not specified here, and is assumed to be handled by the XML Schema processor.
This section contains the grammar of [XPath/XQuery] after it has been normalized, sometimes referred to as the "core" syntax.
Character Classes
The following basic tokens are defined in [XML].
Identifiers
The following identifier components are defined in [XML Names].
String Literals and Numbers
[138 (Core)] | IntegerLiteral | ::= | |
[139 (Core)] | DecimalLiteral | ::= | |
[140 (Core)] | DoubleLiteral | ::= | |
[158 (Core)] | StringLiteral | ::= |
Defined Tokens
The following is a list of defined tokens for the [XPath/XQuery] grammar.
[71 (Core)] | S | ::= | |
[119 (Core)] | Nmstart | ::= | |
[120 (Core)] | Nmchar | ::= | |
[137 (Core)] | Digits | ::= | |
[160 (Core)] | URLLiteral | ::= | |
[167 (Core)] | PITarget | ::= | |
[169 (Core)] | VarName | ::= | |
[170 (Core)] | FuncName | ::= | |
[173 (Core)] | NCNameForPrefix | ::= | |
[175 (Core)] | HexDigits | ::= | |
[176 (Core)] | CharRef | ::= | |
[182 (Core)] | Char | ::= | |
[183 (Core)] | WhitespaceChar | ::= |
The following grammar uses the same Basic EBNF notation as [XML], except that grammar symbols always have initial capital letters. The EBNF contains the lexemes embedded in the productions.
The issues in [C.2 Issues list] serve as a design history for this document. The ordering of issues is irrelevant. Each issue has a unique id of the form Issue-<dddd> (where d is a digit). This can be used for referring to the issue by <url-of-this-document>#Issue-<dddd>. Furthermore, each issue has a mnemonic header, a date, an optional description, and an optional resolution. For convenience, resolved issues are displayed in green. Some of the descriptions of the resolved issues are obsolete w.r.t. to the current version of the document.
Ed. Note: Peter (Aug-05-2000): For the sake of archival, there are some duplicate issues raised in multiple instances. Duplicate issues are marked as "resolved" with reference to the representative issue.
Issue-0001: Attributes
Date: Jul-26-2000
Raised by: Algebra Editors
Description: One example of the need for support of [Issue-0049: Unordered Collections], but also: Attributes need to be constrained to contain white space separated lists of simple types only.
Resolution: Attributes are represented by attribute attribute-name { content }.
Issue-0002: Namespaces
Date: Jul-26-2000
Raised by: Algebra Editors
Resolution: Namespaces are represented by {uri-of-namespace}localname.
Issue-0003: Document Order
Date: Jul-26-2000
Raised by: Algebra Editors
Description: The data model and algebra do not define a global order on documents. Querying global order is often required in document-oriented queries.
Resolution: Resolved by adding < operator defined on nodes in same document. See [Issue-0079: Global order between nodes in different documents] for order between nodes in different documents.
Issue-0004: References vs containment
Date: Jul-26-2000
Raised by: Algebra Editors
Description: The query-algebra datamodel currently does not explicitly model children-elements by references (other than the XML-Query Datamodel. This facilitates presentation, but may be an oversimplification with regard to [Issue-0005: Element identity].
Resolution: This issue is resolved by subsumption as follows: (1) All child-elements are (implicit) references to nodes. (2) Thus, having resolved [Issue-0005: Element identity] this issue is resolved too.
Issue-0005: Element identity
Date: Jul-26-2000
Raised by: Algebra Editors
Description: Do expressions preserve element identity or don't they? And does "=" and distinct use comparison by reference or comparison by value?
Resolution: The first part of the question has been resolved by resolution of [Issue-0010: Construct values by copy]. The second part raises a more specific issue [Issue-0066: Shallow or Deep Equality?].
Issue-0006: Source and join syntax instead of "for"
Date: Jul-26-2000
Raised by: Algebra Editors
Description: Another term for "source and join syntax" is "comprehension".
Resolution: This issue is resolved by subsumption under [Issue-0021: Syntax]. List comprehension is a syntactic alternative to "for v in e1 do e2", which has been favored by the WG in the resolution of [Issue-0021: Syntax].
Issue-0007: References: IDREFS, Keyrefs, Joins
Date: Jul-26-2000
Raised by: Algebra Editors
Description:
Currently, the Algebra does not support reference values,
such as IDREF, or Keyref (not to be mixed up with
"node-references" - see [Issue-0005:
Element identity], which are
defined in the XML Query Data Model. The Algebra's type system
should be extended to support reference types and the data
model operators ref
, and deref
should be supported (similar to id() in XPath).
Resolution: Delegated to XPath 2.0. Algebra should adopt solutions (e.g., id()/keyref() functions) provided in XPath 2.0. There may be an interaction between IDREFs and RefNodes, but we're not going to cover that now.
Issue-0008: Fixed point operator or recursive functions
Date: Jul-26-2000
Raised by: Algebra Editors
Description: It may be useful to add a fixed-point operator, which can be used in lieu of recursive functions to compute, for example, the transitive closure of a collection.
Currently, the Algebra does not guarantee termination of recursive expressions. In order to ensure termination, we might require that a recursive function take one argument that is a singleton element, and any recursive invocation should be on a descendant of that element; since any element has a finite number of descendants, this avoids infinite regress. (Ideally, we should have a simple syntactic rule that enforces this restriction, but we have not yet devised such a rule.)
Impacts optimization; hard to do static type inference; current algebra is first-order
Resolution: The functionality described is appropriately covered by the use of recursive functions. XQuery is a functional language and does not provide a fixed-point operator in its current version.
Issue-0009: Externally defined functions
Date: Jul-26-2000
Raised by: Algebra Editors
Description: There is no explicit support for externally defined functions.
The set of built-in functions may be extended to support other important operators.
Resolution: Algebra editors endorse a solution that uses XP for specifying signatures of external functions. Algebra will adopt solution provided by [XPath/XQuery].
Issue-0010: Construct values by copy
Date: Jul-26-2000
Raised by: Algebra Editors
Description: Need to be able to construct new types from bits of old types by reference and by copy. Related to [Issue-0005: Element identity].
Resolution: The WG wishes to support both: construction of values by copy, as well as references to original nodes. This needs some further investigation to sort out all technical difficulties (see [Issue-0062: Open questions for constructing elements by reference]) so the change has not yet been reflected in the Algebra document.
Issue-0011: XPath tumbler syntax instead of index?
Date: Jul-26-2000
Raised by: Algebra Editors
Description: XPath provides as a shorthand syntax [integer] to select child-elements by their position on the sibling axes, whereas the xml-query algebra uses a combination of a built-in function index() and iteration.
Addendum by JS (submitted by MF) Dec 19/2000: The typing of
index is lossy : it produces a factored type. Jerome suggests
the more precise range
operator:
e : q min m max n n' - (m'-1) = r m' >= m n' <= n ----------------------------------------------- range(e;m';n') : q min r max r nth(e;n) == range(e;n;n)
The range
operator takes a repetition of prime
types and those values in the range m'
to
n'
; if the repetition does not include that
range, a run-time error is raised. The range
and
nth
operators could also be defined in terms of
head
and tail
and polymorphic
recursive functions. In the absence of parameteric
polymorphism, it is not possible to define range
and nth
with precise types.
Here are Peter's rules:
e : p min m max n n!=* ------------------------------------------------- range(e;m';n') : p{n'-max(m,m')+1,min(n',n)-m'+1} For example: let v1 = a[] min 2 max 4 range(v1;3;3): a[] min 1 max 1 range(v1;1;3): a[] min 2 max 3 range(v1;3;5): a[] min 1 max 2 range(v1;1;5): a[] min 2 max 4 e : p min m max * ----------------------------- range(e;m';n') : p min 0 max n'-m'+1 let v2 = a[] min 0 max * range(v2;1;3): a[] min 0 max 2 this follows the typical semantics for head() and tail(): head(()) = tail(()) = () and the semantics behind range(e;m',n') = tail o ...(m' times) ... o tail o head, tail o ...(m'+1 times) ... o tail o head, ... tail o ...(n' times) ... o tail o head
I would have no troubles in restricting ourselves to nth() instead of range() in the algebra (range can always be enumerated by nth()). Furthermore, we should consider whether m',n' can be computed numbers.
Issue-0012: GroupBy - needs second order functions?
Date: Jul-26-2000
Raised by: Algebra Editors
Description: The type system is currently first order: it does not support function types nor higher-order functions. Higher-order functions are useful for specifying, for example, sorting and grouping operators, which take other functions as arguments.
Resolution:
The WG has decided to express groupBy by a combination of
for
and distinct
.
Thus w.r.t. to GroupBy this Issue is
resolved. Because GroupBy is not the only use case for higher
order functions, a new issue [Issue-0063:
Do we need (user defined) higher order functions?] is
raised.
Issue-0013: Collations
Date: Jul-26-2000
Raised by: Algebra Editors
Description: Collations identify the ordering to be applied for sorting strings. Currently, it is considered to have an (optional parameter) collation "name" as follows: "SORT variable IN exp BY +(expression {ASCENDING|DESCENDING} {COLLATION name}). An alternative would be to model a collation as a simple type derived from string, and use type-level casting, i.e. expression :collationtype (which is already supported in the XML Query Algebra), for specifying the collation. That would make: "SORT variable IN exp BY +(expression:collationname {ASCENDING|DESCENDING}). But that requires some support from XML-Schema.
More generally, collations are important for any operator in the Algebra that involves string comparison, among them: sort, distinct, "=" and "<".
Resolution: Formal semantics will adopt solution provided by Operators.
Issue-0014: Polymorphic types
Date: Jul-26-2000
Raised by: Algebra Editors
Description: The type system is currently monomorphic: it does not permit the definition of a function over generalized types. Polymorphic functions are useful for factoring equivalent functions, each of which operate on a fixed type.
The current type system has already a built-in polymorphic type (lists) and is likely to have more (unordered collections). The question is, whether to allow for user-defined polymorphic types and user defined polymorphic functions.
Resolution: It has been decided this feature was not required for XQuery 1.0.
Issue-0015: 3-valued logic to support NULLs
Date: Jul-26-2000
Raised by: Algebra Editors
Resolution: The Formal Semantics supports the current semantics of NULL values, as described in the XQuery December working draft. The Formal Semantics will reflect further resolution of open issues on NULLs and 3 valued logic as decided by XQuery.
Issue-0016: Mixed content
Date: Jul-26-2000
Raised by: Algebra Editors
Description: The XML-Query Algebra allows to generate elements with an arbitrary mixture of data (of simple type) and elements. XML-Schema only allows for a combination of strings interspersed with elements (aka mixed content). We need to figure out whether and how to constrain the XML-Query Algebra accordingly (e.g. by typing rules?)
Resolution:
The type system has been extended to support the
interleaving operator &
- see [3 The XQuery Type System]. Mixed content is defined
in terms of &
.
Issue-0017: Unordered content
Date: Jul-26-2000
Raised by: Algebra Editors
Description: All-groups in XML-Schema, not to be mixed up with [Issue-0049: Unordered Collections]
Resolution: The type system has been extended with the support of all-groups - see [3 The XQuery Type System].
Issue-0018: Align algebra types with schema
Date: Jul-26-2000
Raised by: Algebra Editors
Description: The Algebra's internal type system is the type system of XDuce. A potentially significant problem is that the Algebra's types may lose information when converted into XML Schema types, for example, when a result is serialized into an XML document and XML Schema.
James Clark points out : "The definition of AnyComplexType doesn't match the concrete syntax for types since it applies unbounded repetition to AnyTree and one alternative for AnyTree is AnyAttribute." This is another example of an alignment issue.
This issue comprises also issues [Issue-0016: Mixed content], [Issue-0017: Unordered content], [Issue-0053: Global vs. local elements], [Issue-0054: Global vs. local complex types], [Issue-0019: Support derived types], substitution groups.
Resolution: Closed by the semantics of named typing. See Sections 3 and 7 of the Formal Semantics document.
Issue-0019: Support derived types
Date: Jul-26-2000
Raised by: Algebra Editors
Description: The current type system does not support user defined type hierarchies (by extension or by restriction).
Resolution: Closed by the semantics of named typing. Derived types are now supported in the type system. See Sections 3 and 7 of the Formal Semantics document.
Issue-0020: Structural vs. name equivalence
Date: Jul-26-2000
Raised by: Algebra Editors
Description: The subtyping rules in [3.5 Subtyping] only define structural subtyping. We need to extend this with support for subtyping via user defined type hierarchies - this is related to [Issue-0019: Support derived types].
Resolution: Closed by the semantics of named typing. The Formal Semantics now support both named and structural typing. See Sections 3 and 7 of the Formal Semantics document.
Issue-0021: Syntax
Date: Jul-26-2000
Raised by: Algebra Editors
Description: (e.g. for.<-.in vs for.in.do)
Resolution: The WG has voted for several syntax changes , "for v in e do e", "let v = e do", "sort v in e by e ...", "distinct", "match case v:t e ... else e".
Issue-0022: Indentation, Whitespaces
Date: Jul-26-2000
Raised by: Algebra Editors
Description: Is indentation significant?
Resolution: The WG has consensus that indentation is not significant , i.e., all documents are white space normalized.
Issue-0023: Catch exceptions and process in algebra?
Date: Jul-26-2000
Raised by: Algebra Editors
Description: Does the Algebra give explicit support for catching exceptions and processing them?
Resolution: Subsumed by new issue [Issue-0064: Error code handling in Query Algebra].
Issue-0024: Value for empty sequences
Date: Jul-26-2000
Raised by: Algebra Editors
Description: What does "value" do with empty sequences?
Resolution: The definition of value(e) has changed to:
value(e) = typeswitch children(e) case v: AnyScalar do v else()
Furthermore, the typing rules for "for v in e1 do e2" have been changed such that the variable v is typed-checked seperately for each unit-type occuring in expression e1.
Consequently the following example would be typed as follows:
query for b in b0/book do value(b/year): xs:integer min 0 max *
rather than leading to an error.
Issue-0025: Treatment of empty results at type level
Date: Jul-26-2000
Raised by: Algebra Editors
Description: This is related to [Issue-0024: Value for empty sequences].
Resolution: Resolved by resolution of [Issue-0025: Treatment of empty results at type level].
Issue-0026: Project - one tag only
Date: Jul-26-2000
Raised by: Algebra Editors
Description: Project is only parameterized by one tag. How can we translate a0/(b | c)?
Resolution: With the new syntax (and type system) a0/(b | c) can be translated to "for v in a0 do typeswitch case v1:b[AnyType] do v1 case v2:c[AnyType] do c else ()".
Issue-0027: Case syntax
Date: Jul-26-2000
Raised by: Quilt Comments et al.
Description: N-ary case can be realized by nested binary cases.
Resolution: New (n-ary) case syntax is introduced.
Issue-0028: Fusion
Date: Jul-26-2000
Raised by: Michael Rys
Description: Does the Algebra support fusion as introduced by query languages such as LOREL? This is related to [Issue-0005: Element identity], because fusion only makes sense with support of element identity.
Resolution: Fusion is equivalent to 'natural full-outer join'. [XPath/XQuery] can reraise issue if desired. If added, the Algebra editors should review any solution w.r.t typing.
Issue-0029: Views
Date: Jul-26-2000
Raised by: Michael Rys
Description: One of the problems in views: Can we undeclare/hide things in environment? For example, if we support element-identity, can we explicitly discard a parent, and/or children from an element in the result-set? Related to [Issue-0005: Element identity].
Resolution: [XPath/XQuery] can reraise issue if desired. If added, the Algebra editors should review any solution w.r.t typing.
Issue-0030: Automatic type coercion
Date: Jul-26-2000
Raised by: Dana Florescu
Description: What do we do if a value does not have a type or a different type from what is required?
Suggested Resolution: We believe that the XML Query Language should specify default type coercions for mixed mode arithmetic should be performed according to a fixed precedence hierarchy of types, specifically integer to fixed decimal, fixed decimal to float, float to double. This policy has the advantage of simplicity, tradition, and static type inference. Programmers could explicitly specify alternative type coercions when desirable.
Resolution: Delegation to XPath 2.0, [XPath/XQuery], and/or Operators.
Issue-0031: Recursive functions
Date: Jul-26-2000
Raised by: Dana Florescu
Resolution: subsumed by [Issue-0008: Fixed point operator or recursive functions]
Issue-0032: Full regular path expressions
Date: Jul-26-2000
Raised by: Dana Florescu
Description: Full regular path expressions allow to constrain recursive navigation along paths by means of regular expressions, e.g. a/b*/c denotes all paths starting with an a, proceeding with arbitrarily many b's and ending in a c. Currently the XML-Query Algebra can express this by means of (structurally) recursive functions. An alternative may be the introduction of a fixpoint operator [Issue-0008: Fixed point operator or recursive functions].
Resolution: XPath 2.0 can raise issue if desired. The Algebra editors should review any solution w.r.t typing.
Issue-0033: Metadata Queries
Date: Jul-26-2000
Raised by: Dana Florescu
Description: Metadata queries are queries that require runtime access to type information.
Resolution: Metadata queries are believed to be appropriately covered by XQuery 1.0 (e.g., using typeswitch).
Issue-0034: Fusion
Date: Jul-26-2000
Raised by: Dana Florescu
Resolution: Identical with [Issue-0028: Fusion]
Issue-0035: Exception handling
Date: Jul-26-2000
Raised by: Dana Florescu
Resolution: Subsumed by [Issue-0023: Catch exceptions and process in algebra?] and [Issue-0064: Error code handling in Query Algebra].
Issue-0036: Global-order based operators
Date: Jul-26-2000
Raised by: Dana Florescu
Resolution: Subsumed by [Issue-0003: Document Order]
Issue-0037: Copy vs identity semantics
Date: Jul-26-2000
Raised by: Dana Florescu
Resolution: subsumed by [Issue-0005: Element identity]
Issue-0038: Copy by reachability
Date: Jul-26-2000
Raised by: Dana Florescu
Description: Is it possible to copy children as well as IDREFs, Links, etc.? Related to [Issue-0005: Element identity] and [Issue-0008: Fixed point operator or recursive functions]
Resolution: Resolved by addition of "deep" copy operator in [XQuery 1.0 and XPath 2.0 Data Model].
Issue-0039: Dereferencing semantics
Date: Jul-26-2000
Raised by: Dana Florescu
Resolution: Subsumed by [Issue-0005: Element identity]
Issue-0040: Case Syntax
Date: Aug-01-2000
Raised by: Quilt
Description: We suggest that the syntax for "case" be made more regular. At present, it takes only two branches, the first labelled with a tag-name and the second labelled with a variable. A more traditional syntax for "case" would have multiple branches and label them in a uniform way. If the algebra is intended only for semantic specification, "case" may not even be necessary.
Resolution: subsumed by [Issue-0027: Case syntax]
Issue-0041: Sorting
Date: Aug-01-2000
Raised by: Quilt
Description: We are not happy about the three-step sorting process in the Algebra. We would prefer a one-step sorting operator such as the one illustrated below, which handles multiple sort keys and mixed sorting directions: SORT emp <- employees BY emp/deptno ASCENDING emp/salary DESCENDING
Resolution: The WG has decided to go for the above syntax, with an (optional) indication of COLLATION.
Issue-0042: GroupBy
Date: Aug-01-2000
Raised by: Quilt
Description: We do not think the algebra needs an explicit grouping operator. Quilt and other high-level languages perform grouping by nested iteration. The algebra can do the same.
related to [Issue-0012: GroupBy - needs second order functions?]
Resolution: The WG has decided to skip groupBy for the time being.
Issue-0043: Recursive Descent for XPath
Date: Aug-01-2000
Raised by: Quilt
Description: The very important XPath operator "//" is supported in the Algebra only by writing a recursive function. This is adequate for a semantic specification, but if the Algebra is intended as an optimizable target language it will need better support for "//" (possibly in the form of a fix-point operator.)
Resolution: Resolved by subsumption under [Issue-0043: Recursive Descent for XPath]
Issue-0044: Keys and IDREF
Date: Aug-01-2000
Raised by: Quilt
Description: We think the algebra needs some facility for dereferencing keys and IDREFs (exploiting information in the schema.)
Resolution: Subsumed by [Issue-0007: References: IDREFS, Keyrefs, Joins]
Issue-0045: Global Order
Date: Aug-01-2000
Raised by: Quilt
Description: We are concerned about absence of support for operators based on global document ordering such as BEFORE and AFTER.
Resolution: Subsumed by [Issue-0003: Document Order]
Issue-0046: FOR Syntax
Date: Aug-01-2000
Raised by: Quilt
Description: We agree with comments made in the face-to-face meeting about the aesthetics of the Algebra's syntax for iteration. For example, the following syntax is relatively easy to understand: FOR x IN some_expr EVAL f(x) whereas we find the current algebra equivalent to be confusing and misleading: FOR x <- some_expr IN f(x) This syntax appears to assign the result of some_expr to variable x, and uses the word IN in a non-intuitive way.
Resolution: Subsumed by [Issue-0021: Syntax]
Issue-0047: Attributes
Date: Aug-01-2000
Raised by: Quilt
Description: See [Issue-0001: Attributes].
Resolution: Subsumed by [Issue-0001: Attributes]
Issue-0048: Explicit Type Declarations
Date: Jul-27-2000
Raised by: Group 1 at F2F, Redmond
Description: Type Declaration for the results of a query: The issue is whether to auto construct the result type from a query or to pre-declare the type of the result from a query and check for correct type on the return value. Suggestion: Support for pre-declared result data type and as well as to coerce the output to a new type is desirable. Runtime or compile time type checking is to be resolved? Once you attach a name to a type, it is preserved during the query processing.
Resolution: W.r.t. compile time type casts this is already possible with e:t. For run-time casts an issue has been raised in [Issue-0062: Open questions for constructing elements by reference].
Issue-0049: Unordered Collections
Date: Jul-27-2000
Raised by: Algebra Editors, Group 1, F2F, Redmond
Description:
Currently, all sequences in the data model are ordered. It
may be useful to have unordered forests. The
distinct-node
function, for example, produces an
inherently unordered forest. Unordered forests can benefit
from many optimizations for the relational algebra, such as
commutable joins.
Handling of collection of attributes is easy but the collection of elements is complex due to complex type support for the elements. It makes sense to allow casting from unordered to ordered collection and vice versa. It is not clear whether the new ordered or unordered collection is a new type or not. It affects function resolution, optimization.
Our request to Schema to represent insignificance of ordering at schema level has not been fulfilled. Thus we need to be aware that this information may get lost, when mapping to schema.
Resolution: Unordered collections are described by {t} see [3 The XQuery Type System], some operators (sort, distinct-node, for, and sequence) are overloaded, and some operators (difference, intersection) are added). A new issue [Issue-0076: Unordered types] is raised.
Issue-0050: Recursive Descent for XPath
Date: Jul-27-2000
Raised by: Group 1, F2F, Redmond
Description: Suggestion: The group likes to add a support for fixed-point operator in the query language that will allow us to express the semantics of the // operator in an xpath expression. A path expression of the form a//b may be represented by a fixed-point operator fp(a, "/.")/b.
Resolution: Subsumed by [Issue-0043: Recursive Descent for XPath]
Issue-0051: Project redundant?
Date: Aug-05-2000
Raised by: Peter Fankhauser
Description: It appears that project a e could be reduced to sth. like
for v <- e in case v of a[v1] => a[v1] | v2 => ()
... or would that generate a less precise type?
Resolution: With the new type system and handling of the for operator, project is indeed redundant.
Issue-0052: Axes of XPath
Date: Aug-05-2000
Raised by: Peter Fankhauser
Description: The current algebra makes navigation to parents difficult to impossible. With support of Element Identity [Issue-0005: Element identity] and recursive functions [Issue-0008: Fixed point operator or recursive functions] one can express parent() by a recursive function via the document root. More direct support needs to be investigated w.r.t its effect on the type system.
The WG wishes to support a built-in operator parent().
Resolution: XPath 2.0 and [XPath/XQuery] can reraise issue if desired. Algebra should review any solution w.r.t typing. Question: whether namespace axis (i.e., access namespace nodes) will be included in [XPath/XQuery]. Algebra currently has issues related to typing of parent() and descendant(). If sibling axes are included in [XPath/XQuery], then Algebra should review w.r.t. typing.
Issue-0053: Global vs. local elements
Date: Aug-05-2000
Raised by: Peter Fankhauser
Description: The current type system cannot represent global element-declarations of XML-Schema. All element declarations are local.
Resolution: The type system now supports both local and global elements and attributes.
Issue-0054: Global vs. local complex types
Date: Aug-05-2000
Raised by: Peter Fankhauser
Description: The current type system does not distinguish between global and local types as XML-Schema does. All types appear to be fully nested (i.e. local types)
Resolution: The type system now supports both local and global types.
Issue-0055: Types with non-wellformed instances
Date: Aug-05-2000
Raised by: Peter Fankhauser
Description: The type system and algebra allows for sequences of simple types, which can usually be not represented as a well-formed document. How shall we constrain this? Related to [Issue-0016: Mixed content].
Resolution: XQuery 1.0 supports non-well-formed heterogeneous sequences for intermediate results. The XQuery type system supports a way to type such intermediate results.
Issue-0056: Operators on Simple Types
Date: Jul-15-2000
Raised by: Fernandez et al.
Description: We intentionally did not define equality or relational operators on element and simple type. These operators should be defined by consensus.
Resolution: [XPath/XQuery] formal semantics adopts solution provided by Operators task force.
Issue-0057: More precise type system; choice in path
Date: Aug-07-2000
Raised by: LA-Team
Description: (This subsumes [Issue-0051: Project redundant?]). If the type system were more precise, then (project a e) could be replaced by:
for v <- e in case v of a[v1] => a[v1] | v2 => ()
One could also represent (e/(a|b)) directly in a similar style.
for v <- e in case v of a[v1] => a[v1] | v2 => case v2 of b[v3] => b[v3] | v4 => ()
Currently, there is no way to represent (e/(a|b)) without loss of precision, so if we do not change the type system, we may need to have some way to represent (e/(a|b)) and similar terms without losing precision. (The LA team has a design for this more precise type system, but it is too large to fit in the margin of this web page!)
Resolution: See resolution of [Issue-0051: Project redundant?]
Issue-0058: Downward Navigation only?
Date: Aug-07-2000
Raised by: LA-Team
Description: Related to [Issue-0052: Axes of XPath]. The current type system (and the more precise system alluded to in [Issue-0057: More precise type system; choice in path]) seems well suited for handling XPath children and descendant axes, but not parent, ancestor, sibling, preceding, or following axes. Is this limitation one we can live with?
Resolution: Subsumed by [Issue-0052: Axes of XPath]
Issue-0059: Testing Subtyping
Date: Aug-07-2000
Raised by: LA-Team
Description: One operation required in the Algebra is to test whether XML type t1 is a subtype of XML type t2, indicated by writing t1 <: t2. There is a well-known algorithm for this, based on tree automata, which is a straightforward variant of the well-known algorithm for testing whether the language generated by one regular-expression is a subset of the language generated by another. (The algorithm involves generating deterministic automata for both regular expressions or types.)
However, the naive implementation of the algorithm for comparing XML types can be slow in practice, whereas the naive algorithm for regular expressions is tolerably fast. The only acceptably fast implementation of a comparison for XML types that the LA team knows of has been implemented by Haruo Hasoya, Jerome Voullion, and Benjamin Pierce at the University of Pennsylvania, for their implementation of Xduce. (Our implementation of the Algebra re-uses their code, with permission.)
So, should we adopt a simpler definition of subtyping which is easier to test? One possibility is to adopt the sibling restriction from Schema, which requires that any two elements which appear a siblings in the same content model must themselves have contents of the same type. Jerome Simeon and Philip Wadler discovered that adopting the sibling restriction reduces the problem of checking subtyping of XML types to that of checking regular languages for inclusion, so it may be worth adopting the restriction for that reason.
Issue-0060: Internationalization aspects for strings
Date: Jun-26-2000
Raised by: I18N
Description: These issues are taken from the comments on the Requirements Document by I18N
Further information can be found at http://www.w3.org/TR/WD-charreq.
It is a goal of i18n that queries involving string matching ("select x where x='some_constant'") treat canonically equivalent strings (in the Unicode sense) as matching. If the query and the target are both XML, early normalization (as per the Character Model) is assumed and binary comparison ensures that the equivalence requirement is satisfied. However, if the target is originally a legacy database which logically has a layer that exports the data as XML, that XML must be exported in normalized form. The XML Query spec must impose the normalization requirement upon such layers.
Similarly, the query may come from a user-interface layer that creates the XML query. The XML Query spec must impose the normalization requirement upon such layers.
Provided that the query and the target are in normalized form C, the output of the query must itself be in normalized form C.
Queries involving string matching should support various kinds of loose matching (such as case-insensitivity, katakana-hiragana equivalence, accent-accentless equivalence, etc.)
If such features as case-insensitivity are present in queries involving string matching, these features must be properly internationalized (e.g. case folding works for accented letters) and language-dependence must be taken into account (e.g. Turkish dotless-i).
Queries involving character counting and indexing must take into account the Character Model. Specifically, they should follow Layer 3 (locale-independent graphemes). Additional details can be found in The Unicode Standard 3.0 and UTR#18. Queries involving word counting and indexing should similarly follow the recommendations in these references.
Resolution: [XPath/XQuery] formal semantics adopts solution provided by Operators task force.
Issue-0061: Model for References
Date: Aug-16-2000
Raised by: Group 3, F2F, Redmond
Description: Related to a number of issues around [Issue-0005: Element identity].
Use Cases
Table of Contents
REF *could* do this well if it were restructured - it does not maintain unforeseen relationships or use them...
Bibliographies
Recursive parts
RDF assertions
Inversion of simple parent/child references (related to [Issue-0058: Downward Navigation only?]).
What can we leave out?
can we leave out transitive closure?
can we limit recursion?
can we leave out fixed point recursion?
related to [Issue-0008: Fixed point operator or recursive functions]
Do we need to be able to...
a. Find the person with the maximum number of descendants?
b. Airplane routes: how can I get from RDU to Raleigh? (fixed point: guaranteeing termination in reasonable time...)
c. Given children and their mothers, can I get mothers and their children? (without respect to the form of the original reference...)
related to [Issue-0008: Fixed point operator or recursive functions].
Should we abstract out the difference between different kinds of references? If so, should we be able to cast to a particular kind of reference in the output?
a. abstracting out the differences is cheaper, which is kewl...
b. the kind of reference gives me useful information about: locality (same document, same repository, big bad internet...) static vs. dynamic (xpointer *may* be resolved dynamically, or *may* be resolved at run time, ID/IDREF is static).
related to [Issue-0007: References: IDREFS, Keyrefs, Joins].
do we need to be able to generate ids, e.g. using skolem functions?
for a document in RAM, or in a persistent tree, identity may be present, implicit, system dependent, and cheap - it's nice to have an abstraction that requires no more than the implicit identity
persistable ID is more expensive, may want to be able to serialize with ID/IDREF to instantiate references in the data model
can use XPath instead of generating ID/IDREF, but these references are fragile, and one reason for queries is to create data that may be processed further
persistable ID unique within a repository context
persistable ID that is globally unique
related to [Issue-0005: Element identity].
copy vs. reference semantics
"MUST not preclude updates..."
in a pure query environment, sans update, we do not need to distinguish these
if we have update, we may need to distinguish, perhaps in a manner similar to "updatable cursors" in SQL
programs may do queries to get DOM nodes that can that be modified. It is essential to be able to distinguish copies of nodes from the nodes themselves.
copy semantics - what does it mean?
copy the descendant hierarchy?
copy the reachability tree? (to avoid dangling references)
related to [Issue-0038: Copy by reachability].
Resolution: Handled in current data model and algebra.
Issue-0062: Open questions for constructing elements by reference
Date: Sep-25-2000
Raised by: Mary Fernandez et al.
Description: (1) What is the value of parent() when constructing new elements with children refering to original nodes?
(2) Is an approach to either make copies for all children or provide references to all children, or should we allow for a more flexible combination of copies and references?
Resolution: Operational semantics specifies that element node constructor creates copies of all its children. Addition of RefNode in [XQuery 1.0 and XPath 2.0 Data Model] supports explicit reference value.
Issue-0063: Do we need (user defined) higher order functions?
Date: Oct-16-2000
Raised by: Peter Fankhauser
Description: The current XML-Query-Algebra does not allow functions to be parameters of another function - so called higher order functions. However, most of the Algebra operators are (built-in) higher functions, taking expressions as an argument ("sort", "for", "case" to name a few). Even a fixpoint operator, "fun f(x)=e, fix f(x) in e" (see also [Issue-0008: Fixed point operator or recursive functions]), would be a built-in higher order function.
Resolution: The XML Query Algebra will not support user defined higher order functions. It does support a number of built-in higher order functions.
Issue-0064: Error code handling in Query Algebra
Date: Oct-04-2000
Raised by: Rezaur Rahman
Description: How do we return an error code from a function defined in current Query algebra. Do we need to create an array (or a structure) to merge the return value and error code to do this. If that is true, it may be inefficient to implement. In order for cleaner and efficient implementation, it may be necessary to allow a function declaration to take a parameter of type "output" and allow it to return an error code as part of the function definition.
Resolution: One does not need to create a structure to combine return values with error codes, provided each operator or function /either/ returns a value /or/ raises an error. The XML-Query Algebra supports means to raise errors, but does not define standard means to catch errors. Raising errors is accomplished by the expression "error" of type Ø (empty choice). Because Ø | t = t, such runtype errors do not influence static typing. The surface syntax and/or detailed specification of operators on simple types (see [Issue-0056: Operators on Simple Types]) may choose to differentiate errors into several error-codes.
Issue-0065: Built-In GroupBy?
Date: Oct-16-2000
Raised by: Peter Fankhauser
Description: We may revisit the resolution of [Issue-0042: GroupBy] and reintroduce GroupBy along the lines of sort: "group v in e1 by [e2 {collation}]". One reason for this may be that this allows to use collation for deciding about the equality of strings.
Resolution: The WG has decided to close this issue, and for the time being not consider GroupBy as a built-in operator. Furthermore, [Issue-0013: Collations] is ammended to deal with collations for all operators involving a comparison of strings.
Issue-0066: Shallow or Deep Equality?
Date: Oct-16-2000
Raised by: Peter Fankhauser
Description: What is the meaning of "=" and "distinct"? Equality of references to nodes or deep equality of data?
Resolution: [XQuery 1.0 and XPath 2.0 Data Model] defines "=" (value equality) and "==" (identity equality) operators. Description of distinct states that it uses "==".
Issue-0067: Runtime Casts
Date: Sep-21-2000
Raised by: ???
Description: In some contexts it may be desirable to cast values at runtime. Such runtime casts lead to an error if a value cannot be cast to a given type.
Resolution:
cast
e :
t has been introduced as a reducible operator
expressed in terms of typeswitch
.
Issue-0068: Document Collections
Date: Oct-16-2000
Raised by: Peter Fankhauser
Description: Per our requirements document we are chartered to support document collections. The current XML-Query Algebra deals with single documents only. There are a number of subissues:
(a) Do we need a more elaborate notion of node-references? E.g. pair of (URI of root-node, local node-ref)
(b) Does the namespace mechanism suffice to type collections of nodes from different documents? Probably yes.
(c) Provided (a) and (b) can be settled, will the approach taken for [Issue-0049: Unordered Collections] do the rest?
Resolution: Document collections are now supported in XQuery 1.0. Input functions have been added, the SequenceType production supports types for document nodes. The XQuery Type system has been extended to support document nodes.
Issue-0069: Organization of Document
Date: Oct-16-2000
Raised by: Peter Fankhauser
Description: The current document belongs more to the genre (scientific) paper than to the genre specification. One may consider the following modifications: (a) reorganize intro to give a short overview and then state the purpose (strongly typed, neutral syntax with formal semantics as a basis for possibly multiple syntaxes, etc.) (compared to version Aug-23, this version has already gone a good deal in this direction). (b) Equip various definitions and type rules with id's. (c) Elaborate appendices on mapping XML-Query-Algebra Model vs. XML-Query-Datamodel, XML-Query-Type System vs. XML-Schema-Type System. (d) Maybe add an appendix on use-case-solutions. The problem is of course: Part of this is a lot of work, and we may not achieve all for the first release.
Resolution: The WG decided to dispose of this issue. The current overall organization of the document is quite adequate, but of course editorial decisions will have to made all the time.
Issue-0070: Stable vs. Unstable Sort/Distinct
Date: Oct-02-2000
Raised by: Steve Tolkin
Description: Should sort (and distinct) be stable on ordered collections, i.e. lists, and unstable on unordered collections (see [Issue-0049: Unordered Collections])?
Resolution: sort and distinct are stable on ordered collections, and unstable on unordered collections.
Issue-0071: Alignment with the XML Query Datamodel
Date: Sep-26-2000
Raised by: Mary Fernandez
Description: Currently, the XML Query Algebra Datamodel does not model PI's and comments.
Resolution: Addition of operational semantics defines relationship of Algebra to Data Model.
Issue-0072: Facet value access in Query Algebra
Date: Oct-04-2000
Raised by: Rezaur Rahman
Description: Each of the date-time data types have facet values as defined by the schema data types draft spec. This problem is general enough to be applied to other simple data types.
The question is : Should we provide access to these facet values on an instance of a particular data types? If so, what type of access? My take is the facets are to be treated like read-only attributes of a data instance and one should have a read access to them.
Issue-0073: Facets for simple types and their role for typechecking
Date: Oct-16-2000
Raised by: Peter Fankhauser
Description: XML-Schema introduces a number of constraining facets http://www.w3.org/TR/xmlschema-2/ for simple types (among them: length, pattern, enumeration, ...). We need to figure out whether and how to use these constraining facets for type-checking.
Issue-0074: Operational semantics for expressions
Date: Nov-16-2000
Raised by: Mary Fernandez
Description: It is necessary to add an operational semantics that formally defines each operator in the Algebra.
Resolution: The new document contains a full specification of the dynamic semantics.
Issue-0075: Overloading user defined functions
Date: Nov-17-2000
Raised by: Don Chamberlain
Description: User defined functions can not be overloaded in the XML Query Algebra, i.e., a function is exclusively identified by its name, and not by its signature. Should this restriction be relaxed and if so - to which extent?
Resolution: No overloading in Query 1.0
Issue-0076: Unordered types
Date: Dec-11-2000
Raised by: Phil Wadler
Description: Currently unorderedness is represented at type level by {t}, and some (built-in) operators are overloaded such they have different semantics (and potentially different return type) depending on their input type. An alternative is to not represent unorderedness at type level, but rather support unordered for, unordered (unstable) sort, unordered (unstable) distinct.
Resolution: Removed unordered types from type system. Added support for unordered operator.
Issue-0077: Interleaved repetition and closure
Date: Dec-12-2000
Raised by: Peter Fankhauser
Description: Regular Languages are closed w.r.t. to the interleaved product. However, they are not closed w.r.t. to interleaved repetition, which can (e.g) generate the 1 degree Dyck language D[1] = () | a D[1] b | D[1] D[1] = (a,b)^{0,*}, and more generally, any language that coordinates cardinalities of individual members from an alphabeth: E.g. (a ^ b)^ min 0 max * = all strings with equally many a's and b's. These are beyond regular languages. Should we thus try to do without interleaved repetition?
Resolution: if we use interleaved repetition (which we will because it is in MSL), they will be restricted to prime types.
Issue-0078: Generation of ambiguous types
Date: Dec-12-2000
Raised by: Jerome Simeon
Description: Unambiguous content-models in XML 1.0 and XML Schema are not closed w.r.t. union. It appears that the XML Query-Algebra can generate result types which can not be transformed to an unambiguous content-model.
Resolution: The XQuery type system supports ambiguous types only for intermediate types generated during type inference.
Issue-0079: Global order between nodes in different documents
Date: Dec-16-2000
Raised by: Algebra Editors
Description: The global order operator < is defined on nodes in the same document, but not between nodes in different documents.
Resolution: Resolution follows from the [XPath/XQuery] Data Model. Order between documents is implementation defined but stable.
Issue-0080: Typing of parent
Date: Dec-16-2000
Raised by: Algebra Editors
Description:
Currently, the parent
operator yields an
imprecise type : AnyElement min 0 max 1
. It
might be possible to type parent
more precisely,
for example, by using the normalized names in MSL, which
encode containment of types.
Issue-0081: Lexical representation of Schema simple types
Date: Jan-17-2001
Raised by: Algebra Editors
Description: Schema simple types must be defined for the Algebra and [XPath/XQuery].
Resolution: Algebra will adopt lexical reps supported by [XPath/XQuery].
Issue-0082: Type and expression operator precedence
Date: Jan-17-2001
Raised by: Algebra Editors
Description: The precedence of the type expressions is not defined.
Issue-0083: Expressive power and complexity of typeswitch expression
Date: Jan-17-2001
Raised by: Algebra Editors, Michael Brundage
Description: When processing an XML document without schema information, i.e., the type of the document is AnyComplexType, then match expressions may be very expensive to evaluate:
typeswitch x case t1 : AnyTree do 1 case t2 : AnyTree min 0 max 2 do 2 case t3 : *[*[*[*[* ... [AnyAttribute] ]]]] do 3 else ERROR
typeswitch itself is not the issue. The real problem is having very liberal type patterns. We could restrict the kinds of type patterns that we permit.
Resolution: Typeswitch types are now restricted to datatypes. Named typing will further help in reducing the complexity by allowing type annotation contained in the data model as a means for optimization.
Issue-0084: Execution model
Date: Jan-17-2001
Raised by: Algebra Editors
Description: Need prose describing execution model scenarios : interpretor vs. compile/runtime vs. translation into another query language. Explain relationship between static and dynamic semantics.
Resolution: Section [2.1 Processing model] defines a procesing model which serves as a framework for the Formal Semantics specification.
Issue-0085: Semantics of Wildcard type
Date: Jan-17-2001
Raised by: Algebra Editors, Michael Brundage
Description: Cite: wildcard types cannot be implemented. If x!y means any name in x except names in y, what does x!y!z mean? In general, how do ! and | operate (precedence, associativity)? Parentheses are required to force the desired grouping of these two operators. Also, what does x!* mean? (There's an infinite family of such examples.)
Resolution: The [XPath/XQuery] type systyem now uses only simple wildcard names based on XPath's NameTest production.
Issue-0086: Syntactic rules
Date: Jan-17-2001
Raised by: Algebra Editors
Description: Need rules for specifying syntactic correctness of query: symbol spaces; variable def'ns precede uses; list of keywords, etc.
Resolution: Syntactic rules should be dealt with in [XPath/XQuery] document
Issue-0087: More examples of Joins
Date: Jan-17-2001
Raised by: Algebra Editors, Michael Brundage
Description: Cite: no join operator; wants example of many-to-many joins, inner join, left and full outer joins.
Resolution: The XQuery document gives a number of such examples.
Issue-0088: Align types with XML Schema : Formal Description.
Date: 02-Apr-2001
Raised by: Mary Fernandez
Description: Sources of misalignment: [XPath/XQuery] types include comment and processing instruction; [XML Schema : Formal Description] does not. [XPath/XQuery] uses () for empty sequence; MSL uses the epsilon character. [XPath/XQuery] permits the names of attribute and element components to be wildcard expressions. MSL only permits literal names for attributes and elements, but permits stand-alone wildcard expressions. [XPath/XQuery] types call '&' interleaved repetition, but MSL says it means 'all g1 and g2 in either order'. Does MSL mean interleaved repetition?
Resolution: Closed by the semantics of named typing. The XQuery Type System aligns directly with XML Schema. See Sections 3 and 7 of the Formal Semantics document.
Issue-0089: Syntax for types in XQuery
Date: 30-Apr-2001
Raised by: Mary Fernandez
Description: Formalism document gives a particular syntax for type expressions that is not supported in the [XPath/XQuery] surface syntax.
Issue-0090: Static type-assertion expression
Date: 30-Apr-2001
Raised by: Mary Fernandez
Description: Formalism document uses a static type-assertion expression that is not supported in the [XPath/XQuery] surface syntax.
Resolution: Static type assertion is supported in XQuery with the new "assert as" expression.
Issue-0091: Attribute expression
Date: 30-Apr-2001
Raised by: Mary Fernandez
Description:
[XPath/XQuery] formal semantics has stand-alone attribute
constructor/expression ATTRIBUTE QName (Exp)
that
is not supported in [XPath/XQuery] surface
syntax.
Resolution: Stand-alone attribute construction is supported in XQuery with the new syntax for element and attribute constructors.
Issue-0092: Error expression
Date: 11-May-2001
Raised by: Jerome Simeon
Description:
[XPath/XQuery] formal semantics has an error expression
Error
that is not supported in [XPath/XQuery] surface
syntax.
Resolution: Errors are raised by a function "dm:erorr()" instead of a separate expression.
Issue-0093: Representation of Text Nodes in type system
Date: 11-May-2001
Raised by: Mary Fernandez
Description: The data model distinguished between text nodes and strings, which are atomic values. Text nodes have identity, parents, and siblings. Strings do not. Text nodes are accessed by the children() accessor; strings and other atomic values are accessed by the typed-value() accessor. The distinction between text nodes and atomic values should exist in type system as well.
Resolution: Subsumed by new issue [Issue-0105: Types for nodes in the data model.].
Issue-0094: Static type errors and warnings
Date: 31-May-2001
Raised by: Don Chamberlin
Description: Static type errors and warnings are not specified. We need to enumerate in both the [XPath/XQuery] and formal semantics documents what kinds of static type errors and warnings are produced by the type system. See also [Issue-0090: Static type-assertion expression].
Issue-0095: Importing Schemas and DTDs into query
Date: 31-May-2001
Raised by: Don Chamberlin
Description: We do not specify how a Schema or DTD is 'imported' into a query so that its information is available during type checking. Schema and DTDs can either be named explicitly (e.g., by an 'IMPORT SCHEMA' clause in a query) or implicitly, by accessing documents that refer to a Schema or DTD. The mechanism for statically accessing a Schema or DTD is unspecified.
Resolution: Closed by the semantics of named typing. The new Formal Semantics document contains a complete mapping from XML Schema to the XQuery type system. See Section 7 of the Formal Semantics. Import of DTDs is supported, but should not be described in the Formal Semantics document.
Issue-0096: Support for schema-less and incompletely validated documents
Date: 31-May-2001
Raised by: Don Chamberlin/Mary Fernandez
Description: This is related to [Issue-0095: Importing Schemas and DTDs into query]. We do not specify what is the effect of type checking a query that is applied to a document without a DTD or Schema. In general, a schema-less document has type xs:AnyType and type checking can proceed under that assumption. A related issue is what is the effect of type checking a query that is applied to an incompletely validated document. As above, we can make *no* assumptions about the static type of an incompletely validated document and must assume its static type is xs:AnyType.
Resolution: XQuery supports schema-less document, and valid documents. It does not support invalid document, I.e., document with a schema for which validation fails. It can support those documents in a well-formed manner.
Issue-0097: Static type-checking vs. Schema validation
Date: 31-May-2001
Raised by: Mary Fernandez
Description: Static type checking and schema validation are not equivalent, but we might want to do both in a query. For example, we might want to assert statically that an expression has a particular type and also validate dynamically the value of an expression w.r.t a particular schema.
The differences between static type checking and schema validation must be enumerated clearly (the XSFD people should help us with this).
Resolution: Closed by the semantics of named typing. XQuery and the XQuery Formals Semantics support both a validate operation and static typing.
Issue-0098: Implementation of and conformance levels for static type checking
Date: 31-May-2001
Raised by: Don Chamberlin
Description: This issue is related to [Issue-0059: Testing Subtyping] Static type checking may be difficult and/or expensive to implement. Some discussion of algorithmic issues of type checking are needed. In addition, we may want to define "conformance levels" for [XPath/XQuery], in which some processors (or some processing modes) are more permissive about types. This would allow [XPath/XQuery] implementations that do not understand all of Schema, and it would allow customers some control over the cost/benefit tradeoff of type checking.
Issue-0099: Incomplete/inconsistent mapping from to core
Date: 06-June-2001
Raised by: Don Chamberlin
Description: This mapping is still preliminary and contains inconsistencies. These inconsistencies will be addressed in detail in the next draft of the document.
Resolution: The Formal Semantics now provides a complete mapping from [XPath/XQuery] to the Core [XPath/XQuery]. Remaining issues with respect to that mapping are indicated separately.
Issue-0100: Namespace resolution
Date: March-11-2002
Raised by: FS Editors
Issue-0101: Support for mixed content in the type system
Date: March-11-2002
Raised by: FS Editors
Description: Support for mixed content in the type system is an open issue. This reopens issue [Issue-0016: Mixed content]. Dealing with mixed content with interleaving raises complexity issue. See also [Issue-0103: Complexity of interleaving].
Issue-0102: Indentation, Whitespace
Date: March-11-2002
Raised by: FS Editors
Description: Whitespace normalization in [XPath/XQuery] is still an open issue. This reopens issue [Issue-0022: Indentation, Whitespaces].
Resolution: New version now describes the semantics of element constructors and whitespace handling.
Issue-0103: Complexity of interleaving
Date: March-11-2002
Raised by: FS Editors
Description: The current type system allows interleaving is allowed on arbitrary types. Interleaving is an expensive operation and it is not clear how to define subtyping for it. Should we restrict use of interleaving on (optional) atomic types ? Should this restriction reflects the one in XML schema ? Related to [Issue-0077: Interleaved repetition and closure].
Issue-0104: Support for named typing
Date: March-11-2002
Raised by: FS Editors
Description: XML Schema is based on named typing, while the [XPath/XQuery] type system is based on strucural typing. Directly related issues are [Issue-0019: Support derived types] and [Issue-0018: Align algebra types with schema]. Other impacted issues are [Issue-0020: Structural vs. name equivalence], [Issue-0072: Facet value access in Query Algebra], [Issue-0073: Facets for simple types and their role for typechecking], [Issue-0088: Align types with XML Schema : Formal Description.], [Issue-0095: Importing Schemas and DTDs into query], [Issue-0097: Static type-checking vs. Schema validation], [Issue-0098: Implementation of and conformance levels for static type checking], [Issue-0111: Semantics of instance of ... only].
Resolution: Closed by the semantics of named typing. The Formal Semantics now support both named and structural typing. See Sections 3 and 7 of the Formal Semantics document.
Issue-0105: Types for nodes in the data model.
Date: March-11-2002
Raised by: FS Editors
Description: The [XPath/XQuery] type system only supports element and attribute nodes. It needs to support other kinds of nodes from the [XPath/XQuery] datamodel, notably: text nodes and document nodes. Should it also include support for PI nodes, comment nodes and namespace nodes?
The data model distinguishes between text nodes and strings, which are atomic values. Text nodes have identity, parents, and siblings. Strings do not. Text nodes are accessed by the children() accessor; strings and other atomic values are accessed by the typed-value() accessor. The distinction between text nodes and atomic values should exist in type system as well.
Resolution: The new type system supports document and text nodes. Support for other kinds of nodes is discussed in [Issue-0143: Support for PI, comment and namespace nodes]
Issue-0106: Constraint on attribute and element content models
Date: March-11-2002
Raised by: Jerome
Description: The [XPath/XQuery] type system allows more content model than what XML Schema allows. For instance, the current type grammar allows the following types:
element d { (attribute a | element b, attribute c)* } attribute a { element b }
Section [3 The XQuery Type System] indicates corresponding constraints on the [XPath/XQuery] type system to avoid that problem. The status of these constraints is unclear. When are they enforced and checked?
Issue-0107: Semantics of data()
Date: March-11-2002
Raised by: FS Editors
Description: What is the semantics of data() applied to anything else than an element or attribute node ?
Issue-0108: Principal node types in XPath
Date: March-11-2002
Raised by: Michael Kay
Description: There is a known bug in the formal semantics which does not deal properly with principal node types. This bug should be resolved based on some semantics previously proposed by Phil Wadler.
Resolution: The bug in the semantics of XPath has been fixed in the current version of the document. See [5.2.1 Steps].
Issue-0109: Semantics of sortby
Date: March-11-2002
Raised by: Jerome
Description: The precise semantics of sortby is still open issue.
Issue-0110: Semantics of element and attribute constructors
Date: March-11-2002
Raised by: Jerome
Description: The precise semantics of element constructors is still an open issue.
Issue-0111: Semantics of instance of ... only
Date: March-11-2002
Raised by: Mary Fernandez
Description: The "instance of" expression allows an optional "only" modifier. The use case for such a modifier is based on named typing, while the XQuery semantics is currently based on structural typing. It is not clear what the semantics of the "only" modifier under structural typing should be and how it can be supported.
Resolution: XQuery does not support only anymore.
Issue-0112: Typing for the typeswitch default clause
Date: March-11-2002
Raised by: Jerome
Description: There is an asymetry in the typing for the default clause in typeswitch vs. the other case clauses. This results in a less precise type when the default clause can be applied.
It would be nicer to be able to have the type be more precise, like for the other case clauses.
The technical problem is the need for some form of negation. I think one could define a "non-common-primes" function that would do the trick, but I leave that as open for now until further review of the new typeswitch section is made.
Issue-0113: Incomplete specification of type conversions
Date: March-11-2002
Raised by: Mary Fernandez
Description: Not all the fallback conversion rules are specified yet in section [4.4.3 Type Conversions]. All the remaining rules in the fallback conversions table must be specified.
Issue-0114: Dynamic context for current date and time
Date: March-11-2002
Raised by: Jerome
Description: The following components dynamic contexts have no formal representation yet: current date and time.
Related question: where are these context components used?
Issue-0115: What is in the default context?
Date: March-11-2002
Raised by: Jerome
Description: What do the default namespace and type environments contain? I believe at least the default namespace environment should contain the "xs", "xf" and "op" prefixes, as well as the default namespaces bound to the empty namespace. Should the default type environment contain wildcard types?
Issue-0116: Serialization
Date: March-11-2002
Raised by: Jerome
Description: Serialization of data model instances, and XQuery results is still an open issue.
Issue-0117: Data model constructor for error values
Date: March-11-2002
Raised by: Jerome
Description: The [XPath/XQuery] data model supports an error value, but there is no constructor for it. Currently the formal semantics is using the notation dm:error() to create an error value. Should there be some function(s) in the [XQuery 1.0 and XPath 2.0 Functions and Operators] document to create error values?
Issue-0118: Data model syntax and literal values
Date: March-11-2002
Raised by: Phil Wadler
Description: Phil suggests the data model should support primitive literals in their lexical form, in which case no explicit dynamic semantic rule would be necessary.
More generally, should the data model support a constructor syntax?
Issue-0119: Semantics of op:to
Date: March-11-2002
Raised by: Mary Fernandez
Description: The binary operator "to" is not defined on empty sequences. The [XQuery 1.0 and XPath 2.0 Functions and Operators] document says operands are decimals, while the XQuery document says they are integers. What happens when Expr1 > Expr2?
Issue-0120: Sequence operations: value vs. node identity
Date: March-11-2002
Raised by: Mary Fernandez
Description: The [XQuery 1.0 and XPath 2.0 Functions and Operators] document provides only one function for union (intersect, etc.) of sequences of nodes and values. The semantics is very different for node only and value only sequences. The semantics is undefined for heterogeneous sequences. Should we have two union (intersect, etc.) functions, one for nodes, and one for values?
Issue-0121: Casting functions
Date: March-11-2002
Raised by: Jerome
Description: The [XQuery 1.0 and XPath 2.0 Functions and Operators] document does not provide any function for casting, just a table and casting rules. Wouldn't it be preferable to either have an explicit function to normalize to? This relates to Issue 17 in the [XQuery 1.0 and XPath 2.0 Functions and Operators] document.
Issue-0122: Overloaded functions
Date: March-11-2002
Raised by: Denise Draper
Description: Some [XQuery 1.0 and XPath 2.0 Functions and Operators] functions are overloaded. How to deal with overloaded built-in functions in the Formal Semantics is still an open issue.
Issue-0123: Semantics of /
Date: March-11-2002
Raised by: FS Editors
Description:
Some of the semantics of the root expression /
is still an open issue. For instance, what should be the
semantics of '/'
in case of a document fragment
(I.e., created using XQuery element constructor).
Issue-0124: Binding position in FLWR expressions
Date: March-11-2002
Raised by: FS Editors
Description: The only way to bind position() is through implicit operations. It would be useful and cleaner to also have a way to bind position in a sequence explicitely. The FS editors proposed several syntax for such an operation, one of these syntaxes look like "for $v at $i in E1 return E2" which modifies the for expression to bind a variable "$i" to the position in sequence "E1" explicitely.
Issue-0125: Operations on node only in XPath
Date: March-11-2002
Raised by: FS Editors
Description: Generally steps may operate on nodes and values alike; the axis rules only can operate on nodes (NodeValue). Is it a dynamic error to apply an axis rule on a value?
More generally, the XQuery document states that XPath operates on nodes only. Where that restriction should be applied is an open issue.
Issue-0126: Semantics of effective boolean value
Date: March-11-2002
Raised by: FS Editors
Description: Some of the semantics of effective boolean value is still an open issue.
Issue-0127: Datatype limitations
Date: March-11-2002
Raised by: FS Editors
Description: Should the Datatype production allow the following: fs:atomic, fs:numeric, fs:UnknownSimpleType ?
The formal semantics makes use of several built-in types which are not in XML Schema: fs:numeric, fs:atomic, and fs:UnknownSimpleType. These types are necessary for the specification of some of XPath type conversion rules, and will be accepted without raising an error.
Issue-0128: Casting based on the lexical form
Date: March-11-2002
Raised by: Mary Fernandez
Description: The XQuery/XPath spec says : "If an operand is an untyped simple value (...), it is cast to the type suggested by its lexical form." It is not clear how to define the semantics for this.
Issue-0129: Static typing of union
Date: March-11-2002
Raised by: Michael Rys
Description: What should be the semantics of arithmetics expressions over unions. Right now, it would raise a dynamic error. Do we want to raise a static error?
Should operators and functions consistenly with respect to typing?
With the current semantics in Section 4.5 expr1 + expr2 raises a static type error if (e.g.) expr1 has type string and expr2 has type integer. It raises only a dynamic error, if expr1 has type (string | integer) and expr2 has type integer, and expr1 actually evaluates to a string. An alternative would be that this raises also a static error, because it cannot be guarantueed to succeed on all instances.
Issue-0130: When to process the query prolog
Date: March-11-2002
Raised by: Jerome
Description: The query prolog needs to be processed before the normalization phase. This is not reflected yet in the processing model.
Issue-0131: Boolean node test and sequences
Date: March-11-2002
Raised by: Michael Rys
Description: The current semantics for boolean node tests makes it "true if the expression is a sequence that contains at least one node and error if the sequence contains no node". This is inefficient to implement. Some alternative semantics have been proposed.
Issue-0132: Typing for descendant
Date: March-11-2002
Raised by: Peter Fankhauser
Description: The current static typing for descendant is still under review and the inferences rules in that version are probably containing bugs.
Issue-0133: Should to also be described in the formal semantics?
Date: March-11-2002
Raised by: Michael Kay
Description: The current semantics of the op operator is using the op:to function from the [XQuery 1.0 and XPath 2.0 Functions and Operators] document. Should it be defined formally?
Mike Kay suggests the following definition: [A to B]
=> if A=B then (A) else (A, A+1 to B)
Issue-0134: Should we define for with head and tail?
Date: March-11-2002
Raised by: Michael Kay
Description: Mike Kay proposes to use the following recursion to define the dynamic semantics of for:
[for $x in () return E2] => () [for $x in SEQ return E2] => (let $x := head(SEQ) return E2, for $x in tail(SEQ) return E2)
Unfortunately head and tail are not define in [XQuery 1.0 and XPath 2.0 Functions and Operators] right now.
Issue-0135: Semantics of special functions
Date: March-11-2002
Raised by: Michael Kay
Description: The current semantics does not completely cover built-in functions. Some functions used in the Formal semantics, or some functions from the [XQuery 1.0 and XPath 2.0 Functions and Operators] document need additional semantics specification.
Issue-0136: Non-determinism in the semantics
Date: May-01-2002
Raised by: Mary Fernandez
Description: Some operations, such as logical operations and quantified operations are not deterministics ("early-out" semantics allowing not to evaluate all of the expressions). The formal semantics cannot capture the non-determinism in those operations.
Issue-0137: Typing of input functions
Date: May-01-2002
Raised by: Jerome Simeon
Description:
Static typing for the input functions input
,
collection
, and document
is still
undefined.
Issue-0138: Semantics of Schema Context
Date: May-01-2002
Raised by: Jerome Simeon
Description: The semantics of Schema Context types in the SequenceType production is still an open issue.
Issue-0139: Type equivalence rules
Date: May-08-2002
Raised by: Michael Rys
Description:
Should we add back equivalence rules for types (e.g.,
T1** == T1*
or (T1 | T1) ==
T1
). They are useful in practical implementations
(e.g., to print an infered type or reduce complexity of
infered types), and could be added in an appendix.
Issue-0140: Dependency in normalization and function resolution
Date: May-08-2002
Raised by: Michael Rys
Description: The normalization of functions calls depends on the function signature. But you cannot gather the function signature for built-in functions without knowing the type of the parameters.
Issue-0141: Treatment of nillability and xsi:nil
Date: May-08-2002
Raised by: Michael Rys
Description: Nillability on an element declaration indicates that content of the corresponding element can be empty. The current data model preserves the xsi:nil attribute and this is used in the semantics at the type level. An alternative design would be to remove the xsi:nil attribute and add a 'nillable' marker in the schema component in the data model. This might be helping when we perform updates.
Issue-0142: Treatment of xsi:type in validation
Date: May-15-2002
Raised by: XQuery Editors
Description: The treatment of xsi:type in the formal semantics differs from the one specified in the XQuery and XPath documents. The XQuery and XPath documents indicate that validation is performed by serializing the data model value with newly created xsi:type attributes, then removing those xsi:type attributes after validation. The semantics of 'erases to' as described in the formal semantics document is not creating any xsi:type attributes. The semantics of 'annotate as' as described in the formal semantics document is not removing any xsi:type attributes.
Issue-0143: Support for PI, comment and namespace nodes
Date: May-15-2002
Raised by: FS Editors
Description: The [XPath/XQuery] type system does not currently support PI nodes, comment nodes and namespace nodes.
Issue-0144: Representation of text nodes in formal values
Date: May-15-2002
Raised by: Jonathan Robie
Description: Formal Values described in section [3.1 Values and Types] represents either text nodes for well-formed documents or values for validated documents. Do we need to support a dual representation with both text nodes and values in the formal semantics?
Issue-0145: Static typing of path expressions in the presence of derivation by extension
Date: May-15-2002
Raised by: Jerome Simeon
Description: The current static type analysis rules for Step expressions is broken in the presence of derivation by extension. This bug is impacting section [5.2.1 Steps].
Issue-0146: Support for substitution groups
Date: May-15-2002
Raised by: Jerome Simeon
Description: The formal semantics document gives a semantics of substitution groups. This is not aligned with the XQuery document. Support for substitution group in XQuery is still an open issue.
Note that this issue is related to the typing of substitution groups, and should be distinguished from the question about whether we need expressions in the language that operate on substitution groups.
Issue-0147: What should be the type annotation in the data model for anonymous types?
Date: May-15-2002
Raised by: Jerome Simeon
Description: It is not clear what should be the type annotation in the data model for anonymous types. The mapping from the PSVI to the data model and the formal semantics document need to be aligned.
Resolution: XQuery does not support only anymore.
Issue-0148: Validation of an empty string against a string list
Date: May-15-2002
Raised by: Jerome Simeon
Description: The formal semantics assumes that the result of validating an element with empty content or with an empty text node against a list of strings is the empty sequence, not the empty string. Is that consistent with XML Schema?
Issue-0149: Derivation by extension in XQuery
Date: May-15-2002
Raised by: Phil Wadler
Description: If type u is derived from type t by extension, then the formal semantics document specifies that type u may appear wherever type t is expected. It is not clear what the XQuery document says on this point.
Issue-0150: May the content of a text node be the empty string?
Date: May-15-2002
Raised by: Phil Wadler
Description: May the content of a text node be the empty string? None of the formal semantics, the datamodel, or the XQuery document addresses this point.
Issue-0151: Should type annotations be optional?
Date: May-15-2002
Raised by: Phil Wadler
Description: The formal semantics and the data model both state that the type annotation is required, while the XQuery document says that it is optional.
Issue-0152: What is the type of the input functions?
Date: May-30-2002
Raised by: FS Editors
Description: What are the (static) types for the input functions: document(), collection(), and input()?
Issue-0153: Support for lax and strict wildcards
Date: May-30-2002
Raised by: FS Editors
Description: The Formal Semantics does not currently model lax and strict wildcards. The mapping in Section 7, only describes how XML Schema wilcards with the 'skip validation' semantics are imported into the XQuery Type System.
Issue-0154: Semantics of =>
Date: May-30-2002
Raised by: Jerome Simeon
Description: The Formal Semantics of the => operator is not defined.
Resolution: The => operator has been removed from the language.
Issue-0155: Common primes for incomparable types
Date: June-06-2002
Raised by: Jerome Simeon
Description: The common-prime auxiliary type function does not deal with "incomparable" types, (i.e., types for which there is a non empty intersection, but subtyping does not hold -- e.g., element a | element b vs. element b | element c). One way to resolves that issue would be to re-introduce a limited form of intersection (i.e., returning true if the intersection is not empty instead of full-fledge intersection) and use it within the definition of common-prime.
Issue-0156: Casting and validation
Date: Jun-06-2002
Raised by: Jerome Simeon
Description: Validation from text to simple type performs an operation similar to casting. Should validation of simple type values and 'cast as' in [XPath/XQuery] be aligned?
Issue-0157: Support for wildcard namespaces
Date: Jun-06-2002
Raised by: Jerome Simeon
Description: The Formal Semantics does not currently model wildcard namespaces.
Issue-0158: Support for XML Schema groups
Date: Jun-06-2002
Raised by: Jerome Simeon
Description: How to support XML Schema groups during the schema import phase is not clear. If the mapping is based on the XML Schema syntax, then it should be handled durin the mapping phase. Should we have support for XML Schema groups in the XQuery type system?
Issue-0159: Element and attribute declarations in the static context
Date: Jun-06-2002
Raised by: Jerome Simeon
Description: The [XPath/XQuery] static context only contains type definitions, but no global element and attribute declarations. Element and attribute declarations are necessary to give the semantics of SequenceTypes.
Issue-0160: Collations in the static environment
Date: Jun-06-2002
Raised by: Jerome Simeon
Description: The Formal Semantics does not represent collations in the static environment. Should it?
Issue-0161: Type promotion in Atomization
Date: Jun-06-2002
Raised by: Don Chamberlin
Description: Should the normalization rules for atomization also perform type promotion?
Issue-0162: How to describe the semantics of built-in functions
Date: Jun-06-2002
Raised by: Don Chamberlin
Description: The semantics of function calls assumes the function environment returns an [XPath/XQuery] expression which describes the function body. This only works for user-defined functions, but not for external functions or built-in functions.
Issue-0163: Normalization of XPath predicates
Date: Jun-06-2002
Raised by: Don Chamberlin
Description: The semantics of XPath predicates relies on whether they are applied on forward or reverse axis. The semantics of predicates applied on arbitrary expressions is not correctly specified.
Issue-0164: Coalescing text nodes in element constructors
Date: Jun-06-2002
Raised by: Don Chamberlin
Description: The semantics does not model how text nodes are coalesced in element or constructors. Whether it should be described or left out for the data model is still an open issue. Impact on this operation on the static semantics is still an open issue.
Resolution: The data model element constructor coalesces text nodes.
Issue-0165: Namespaces in element constructors
Date: Jun-06-2002
Raised by: Denise Draper
Description: We do not supply either namespaces or schema-components to the constructor. We cannot do these things because of the bottom-up nature of element construction: we do not, in general, know either the namespaces in scope or the validation-associated schema type until this element has been "seated" in some containing element (and so on recursively).
Issue-0166: Static typing for validate
Date: Jun-06-2002
Raised by: Jerome Simeon
Description: Although validate should always return a typed value, there is no way to do static analysis for it, since the type against which it is validated cannot be known at static type (it depends on the result of evaluation for the input expression).
Issue-0167: Is validate working on sequences?
Date: Jun-06-2002
Raised by: Jerome Simeon
Description: Should validate work on sequences of nodes, or only on a single node?
Issue-0168: Sorting by document order
Date: Jun-06-2002
Raised by: Jerome Simeon
Description: There is no way in [XPath/XQuery] to express sorting by document order as a core expression. Since sortby is doing atomization, there is no way it can be used to express sorting by document order.
Issue-0169: Conformance Levels
Date: Jun-06-2002
Raised by: Jerome Simeon
Description: [XPath/XQuery] supports several conformance levels. Whether the formal semantics need to distinguish those conformance levels is an open issue. If yes, how to distinguish those conformance levels in the formal semantics is an open issue.
Issue-0170: Imprecise static type of constructed elements
Date: Jul-26-2002
Raised by: Mary Fernandez
Description: Implementation of Alternative 1 means that the static type for constructed elements and attributes is very imprecise. E.g., the type of {(1,2,3)} is element a { xs: anyType }. See remark by Denise in section on element constructors for possible fix.
Issue-0171: Raising errors
Date: Jul-26-2002
Raised by: Mary Fernandez
Description: The semantics of raising errors in [XPath/XQuery] is not formally specified.
Issue-0172: Element constructors aligned with XSLT
Date: Jul-26-2002
Raised by: Jerome Simeon
Description: Should the semantics of element constructors be aligned with XSLT?.
Issue-0173: Typeswitch and type substitutability
Date: Jul-26-2002
Raised by: XSL Working Group
Description: It seems that some examples of typeswitch with xs:anySimpleType might break type substitutability.
Issue-0174: Semantics of 'element foo of type T'
Date: Jul-30-2002
Raised by: Jerome Simeon
Description: When using the form 'element foo of type T', should 'foo' be a globally declared element in the in-scope schema or not? Should there be constraints on which type T is allowed? The language document assumes foo is globally declared and T is a restriction of the type of foo. The formal semantics does not make that assumption.
Issue-0175: Static typing for atomization, effective boolean values, and function arguments.
Date: Jul-30-2002
Raised by: Jerome Simeon
Description: Currently, normalization rules for atomization, effective boolean values, and function arguments are not type safe. They cannot raise a static errors, but can only raise dynamic errors. This makes the static semantics much less usable.
[Issue-0124:
Binding position in FLWR expressions]
[Issue-0131:
Boolean node test and sequences]
[Issue-0156:
Casting and validation]
[Issue-0128:
Casting based on the lexical form]
[Issue-0121:
Casting functions]
[Issue-0160:
Collations in the static environment]
[Issue-0155:
Common primes for incomparable types]
[Issue-0103:
Complexity of interleaving]
[Issue-0169:
Conformance Levels]
[Issue-0106:
Constraint on attribute and element content models]
[Issue-0117:
Data model constructor for error values]
[Issue-0118:
Data model syntax and literal values]
[Issue-0127:
Datatype limitations]
[Issue-0140:
Dependency in normalization and function resolution]
[Issue-0149:
Derivation by extension in XQuery]
[Issue-0114:
Dynamic context for current date and time]
[Issue-0159:
Element and attribute declarations in the static context]
[Issue-0172:
Element constructors aligned with XSLT]
[Issue-0073:
Facets for simple types and their role for
typechecking]
[Issue-0072:
Facet value access in Query Algebra]
[Issue-0162:
How to describe the semantics of built-in functions]
[Issue-0098:
Implementation of and conformance levels for static type
checking]
[Issue-0170:
Imprecise static type of constructed elements]
[Issue-0113:
Incomplete specification of type conversions]
[Issue-0167:
Is validate working on sequences?]
[Issue-0150:
May the content of a text node be the empty string?]
[Issue-0100:
Namespace resolution]
[Issue-0165:
Namespaces in element constructors]
[Issue-0136:
Non-determinism in the semantics]
[Issue-0163:
Normalization of XPath predicates]
[Issue-0125:
Operations on node only in XPath]
[Issue-0122:
Overloaded functions]
[Issue-0171:
Raising errors]
[Issue-0144:
Representation of text nodes in formal values]
[Issue-0123:
Semantics of /]
[Issue-0174:
Semantics of 'element foo of type T']
[Issue-0107:
Semantics of data()]
[Issue-0126:
Semantics of effective boolean value]
[Issue-0110:
Semantics of element and attribute constructors]
[Issue-0119:
Semantics of op:to]
[Issue-0138:
Semantics of Schema Context]
[Issue-0109:
Semantics of sortby]
[Issue-0135:
Semantics of special functions]
[Issue-0120:
Sequence operations: value vs. node identity]
[Issue-0116:
Serialization]
[Issue-0133:
Should to also be described in the formal
semantics?]
[Issue-0151:
Should type annotations be optional?]
[Issue-0134:
Should we define for with head and tail?]
[Issue-0168:
Sorting by document order]
[Issue-0094:
Static type errors and warnings]
[Issue-0175:
Static typing for atomization, effective boolean values,
and function arguments.]
[Issue-0166:
Static typing for validate]
[Issue-0145:
Static typing of path expressions in the presence of
derivation by extension]
[Issue-0129:
Static typing of union]
[Issue-0153:
Support for lax and strict wildcards]
[Issue-0101:
Support for mixed content in the type system]
[Issue-0143:
Support for PI, comment and namespace nodes]
[Issue-0146:
Support for substitution groups]
[Issue-0157:
Support for wildcard namespaces]
[Issue-0158:
Support for XML Schema groups]
[Issue-0089:
Syntax for types in XQuery]
[Issue-0059:
Testing Subtyping]
[Issue-0141:
Treatment of nillability and xsi:nil]
[Issue-0142:
Treatment of xsi:type in validation]
[Issue-0082:
Type and expression operator precedence]
[Issue-0139:
Type equivalence rules]
[Issue-0161:
Type promotion in Atomization]
[Issue-0173:
Typeswitch and type substitutability]
[Issue-0132:
Typing for descendant]
[Issue-0112:
Typing for the typeswitch default clause]
[Issue-0137:
Typing of input functions]
[Issue-0080:
Typing of parent]
[Issue-0148:
Validation of an empty string against a string list]
[Issue-0115:
What is in the default context?]
[Issue-0152:
What is the type of the input functions?]
[Issue-0130:
When to process the query prolog]
[Issue-0011:
XPath tumbler syntax instead of index?]
[Issue-0015:
3-valued logic to support NULLs]
[Issue-0018:
Align algebra types with schema]
[Issue-0071:
Alignment with the XML Query Datamodel]
[Issue-0088:
Align types with XML Schema : Formal
Description.]
[Issue-0091:
Attribute expression]
[Issue-0001:
Attributes]
[Issue-0047:
Attributes]
[Issue-0030:
Automatic type coercion]
[Issue-0052:
Axes of XPath]
[Issue-0065:
Built-In GroupBy?]
[Issue-0027:
Case syntax]
[Issue-0040:
Case Syntax]
[Issue-0023:
Catch exceptions and process in algebra?]
[Issue-0164:
Coalescing text nodes in element constructors]
[Issue-0013:
Collations]
[Issue-0010:
Construct values by copy]
[Issue-0038:
Copy by reachability]
[Issue-0037:
Copy vs identity semantics]
[Issue-0039:
Dereferencing semantics]
[Issue-0068:
Document Collections]
[Issue-0003:
Document Order]
[Issue-0063:
Do we need (user defined) higher order functions?]
[Issue-0058:
Downward Navigation only?]
[Issue-0005:
Element identity]
[Issue-0064:
Error code handling in Query Algebra]
[Issue-0092:
Error expression]
[Issue-0035:
Exception handling]
[Issue-0084:
Execution model]
[Issue-0048:
Explicit Type Declarations]
[Issue-0083:
Expressive power and complexity of typeswitch expression]
[Issue-0009:
Externally defined functions]
[Issue-0008:
Fixed point operator or recursive functions]
[Issue-0046:
FOR Syntax]
[Issue-0032:
Full regular path expressions]
[Issue-0028:
Fusion]
[Issue-0034:
Fusion]
[Issue-0078:
Generation of ambiguous types ]
[Issue-0045:
Global Order]
[Issue-0036:
Global-order based operators]
[Issue-0079:
Global order between nodes in different documents]
[Issue-0054:
Global vs. local complex types]
[Issue-0053:
Global vs. local elements]
[Issue-0042:
GroupBy]
[Issue-0012:
GroupBy - needs second order functions?]
[Issue-0095:
Importing Schemas and DTDs into query]
[Issue-0099:
Incomplete/inconsistent mapping from to
core]
[Issue-0102:
Indentation, Whitespace]
[Issue-0022:
Indentation, Whitespaces]
[Issue-0077:
Interleaved repetition and closure]
[Issue-0060:
Internationalization aspects for strings]
[Issue-0044:
Keys and IDREF]
[Issue-0081:
Lexical representation of Schema simple types]
[Issue-0033:
Metadata Queries]
[Issue-0016:
Mixed content]
[Issue-0061:
Model for References]
[Issue-0087:
More examples of Joins]
[Issue-0057:
More precise type system; choice in path]
[Issue-0002:
Namespaces]
[Issue-0062:
Open questions for constructing elements by
reference]
[Issue-0074:
Operational semantics for expressions]
[Issue-0056:
Operators on Simple Types]
[Issue-0069:
Organization of Document]
[Issue-0075:
Overloading user defined functions]
[Issue-0014:
Polymorphic types]
[Issue-0108:
Principal node types in XPath]
[Issue-0026:
Project - one tag only]
[Issue-0051:
Project redundant?]
[Issue-0050:
Recursive Descent for XPath]
[Issue-0043:
Recursive Descent for
XPath]
[Issue-0031:
Recursive functions]
[Issue-0007:
References: IDREFS, Keyrefs, Joins]
[Issue-0004:
References vs containment]
[Issue-0093:
Representation of Text Nodes in type system]
[Issue-0067:
Runtime Casts]
[Issue-0154:
Semantics of =>]
[Issue-0111:
Semantics of instance of ... only]
[Issue-0085:
Semantics of Wildcard type]
[Issue-0066:
Shallow or Deep Equality?]
[Issue-0041:
Sorting]
[Issue-0006:
Source and join syntax instead of "for"]
[Issue-0070:
Stable vs. Unstable Sort/Distinct]
[Issue-0090:
Static type-assertion expression]
[Issue-0097:
Static type-checking vs. Schema validation]
[Issue-0020:
Structural vs. name equivalence]
[Issue-0019:
Support derived types]
[Issue-0104:
Support for named typing]
[Issue-0096:
Support for schema-less and incompletely validated
documents]
[Issue-0086:
Syntactic rules]
[Issue-0021:
Syntax]
[Issue-0025:
Treatment of empty results at type level]
[Issue-0105:
Types for nodes in the data model.]
[Issue-0055:
Types with non-wellformed instances]
[Issue-0049:
Unordered Collections]
[Issue-0017:
Unordered content]
[Issue-0076:
Unordered types]
[Issue-0024:
Value for empty sequences]
[Issue-0029:
Views]
[Issue-0147:
What should be the type annotation in the data model for
anonymous types?]
The following issues are delegated to XPath 2.0: [Issue-0007: References: IDREFS, Keyrefs, Joins], [Issue-0030: Automatic type coercion], [Issue-0032: Full regular path expressions], [Issue-0052: Axes of XPath].
The following issues are delegated to [XPath/XQuery]: [Issue-0009: Externally defined functions], [Issue-0028: Fusion], [Issue-0029: Views], [Issue-0030: Automatic type coercion], [Issue-0052: Axes of XPath], [Issue-0081: Lexical representation of Schema simple types], [Issue-0082: Type and expression operator precedence], [Issue-0086: Syntactic rules].
The following issues are delegated to XPath 2.0:[Issue-0013: Collations], [Issue-0030: Automatic type coercion], [Issue-0056: Operators on Simple Types], [Issue-0060: Internationalization aspects for strings].