3.2 Interfaces
IDL fragments are used to describe object oriented systems. In such systems, objects are entities that have identity and which are encapsulations of state and behavior. An interface is a definition (matching
Interface or
"callback" Interface) that declares some state and behavior that an object implementing that interface will expose.
interface identifier {
interface-members…
};
An interface is a specification of a set of
interface members (matching InterfaceMembers), which are the constants,
attributes,
operations and other declarations that appear between the braces in the interface declaration. Attributes describe the state that an object implementing the interface will expose, and operations describe the behaviors that can be invoked on the object. Constants declare named constant values that are exposed as a convenience to users of objects in the system.
Interfaces in Web IDL describe how objects that implement the interface behave. In bindings for object oriented languages, it is expected that an object that implements a particular IDL interface provides ways to inspect and modify the object's state and to invoke the behavior described by the interface.
An interface can be defined to inherit from another interface. If the identifier of the interface is followed by a
U+003A COLON (":") character and an identifier, then that identifier identifies the inherited interface. An object that implements an interface that inherits from another also implements that inherited interface. The object therefore will also have members that correspond to the interface members from the inherited interface.
interface identifier : identifier-of-inherited-interface {
interface-members…
};
The order that members appear in has no significance except in the case of overloading.
Interfaces may specify an interface member that has the same name as one from an inherited interface. Objects that implement the derived interface will expose the member on the derived interface. It is language binding specific whether the overridden member can be accessed on the object.
Consider the following two interfaces.
IDL
interface A {
void f();
void g();
};
interface B : A {
void f();
void g(DOMString x);
};
In the ECMAScript language binding, an instance of B will have a prototype chain that looks like the following:
[Object.prototype: the Object prototype object]
↑
[A.prototype: interface prototype object for A]
↑
[B.prototype: interface prototype object for B]
↑
[instanceOfB]
Calling instanceOfB.f() in ECMAScript will invoke the f defined on B. However, the f from A can still be invoked on an object that implements B by calling A.prototype.f.call(instanceOfB).
The inherited interfaces of a given interface A is the set of all interfaces that A inherits from, directly or indirectly. If A does not inherit from another interface, then the set is empty. Otherwise, the set includes the interface B that A inherits from and all of B’s inherited interfaces.
An interface MUST NOT be declared such that its inheritance hierarchy has a cycle. That is, an interface
A cannot inherit from itself, nor can it inherit from another interface B that inherits from A, and so on.
Note that general multiple inheritance of interfaces is not supported, and objects also cannot implement arbitrary sets of interfaces. Objects can be defined to implement a single given interface A, which means that it also implements all of A’s
inherited interfaces. In addition, an implements statement can be used to define that objects implementing an interface will always also implement another interface.
Each interface member can be preceded by a list of extended attributes (matching
ExtendedAttributeList), which can control how the interface member will be handled in language bindings.
interface identifier {
[extended-attributes]
const type identifier = value;
[extended-attributes]
attribute type identifier;
[extended-attributes]
return-type identifier(arguments…);
};
A callback interface is an interface that uses the callback keyword at the start of its definition. Callback interfaces are ones that can be implemented by user objects and not by platform objects, as described in section 3.9 .
callback interface identifier {
interface-members…
};
Callback interfaces
MUST NOT inherit from any non-callback interfaces, and non-callback interfaces MUST NOT inherit from any callback interfaces. Callback interfaces MUST NOT have any
consequential interfaces.
Static attributes and
static operations MUST NOT be defined on a callback interface.
Warning
Specification authors SHOULD NOT define
callback interfaces that have only a single operation, unless required to describe the requirements of existing APIs. Instead, a callback function SHOULD be used.
The definition of EventListener as a
callback interface is an example of an existing API that needs to allow
user objects with a given property (in this case “handleEvent”) to be considered to implement the interface. For new APIs, and those for which there are no compatibility concerns, using a callback function will allow only a Function object (in the ECMAScript language binding).
Note
Specification authors wanting to define APIs that take ECMAScript objects as “property bag” like function arguments are suggested to use
dictionary types rather than
callback interfaces.
For example, instead of this:
IDL
callback interface Options {
attribute DOMString? option1;
attribute DOMString? option2;
attribute long? option3;
};
interface A {
void doTask(DOMString type, Options options);
};
to be used like this:
ECMAScript
var a = getA();
a.doTask("something", { option1: "banana", option3: 100 });
instead write the following:
IDL
dictionary Options {
DOMString? option1;
DOMString? option2;
long? option3;
};
interface A {
void doTask(DOMString type, Options options);
};
The IDL for interfaces can be split into multiple parts by using
partial interface definitions (matching "partial" PartialInterface). The identifier of a partial interface definition MUST be the same as the identifier of an interface definition. All of the members that appear on each of the partial interfaces are considered to be members of the interface itself.
interface SomeInterface {
interface-members…
};
partial interface SomeInterface {
interface-members…
};
Note
Partial interface definitions are intended for use as a specification editorial aide, allowing the definition of an interface to be separated over more than one section of the document, and sometimes multiple documents.
The order of appearance of an interface definition and any of its partial interface definitions does not matter.
Note
A partial interface definition cannot specify that the interface
inherits from another interface. Inheritance must be specified on the original interface definition.
Extended attributes can be specified on
partial interface definitions, with some limitations. The following extended attributes MUST NOT be specified on partial interface definitions:
[Constructor],
[NamedConstructor],
[NoInterfaceObject].
Any extended attribute specified on a partial interface definition is considered to appear on the interface itself.
The relevant language binding determines how interfaces correspond to constructs in the language.
The following extended attributes are applicable to interfaces:
[Constructor],
[Exposed],
[Global],
[NamedConstructor],
[NoInterfaceObject],
[OverrideBuiltins].
[PrimaryGlobal],
[Unforgeable].
The following IDL fragment demonstrates the definition of two mutually referential interfaces. Both Human and Dog inherit from Animal. Objects that implement either of those two interfaces will thus have a name attribute.
IDL
interface Animal {
attribute DOMString name;
};
interface Human : Animal {
attribute Dog? pet;
};
interface Dog : Animal {
attribute Human? owner;
};
The following IDL fragment defines simplified versions of a few DOM interfaces, one of which is a callback interface.
IDL
interface Node {
readonly attribute DOMString nodeName;
readonly attribute Node? parentNode;
Node appendChild(Node newChild);
void addEventListener(DOMString type, EventListener listener);
};
callback interface EventListener {
void handleEvent(Event event);
};
Since the EventListener interface is annotated callback interface, user objects can implement it:
ECMAScript
var node = getNode();
var listener = {
handleEvent: function(event) {
...
}
};
node.addEventListener("click", listener);
node.addEventListener("click", function() { ... });
It is not possible for a user object to implement Node, however:
ECMAScript
var node = getNode();
var newNode = {
nodeName: "span",
parentNode: null,
appendChild: function(newchild) {
...
},
addEventListener: function(type, listener) {
...
}
};
node.appendChild(newNode);
3.2.1 Constants
A constant is a declaration (matching
Const) used to bind a constant value to a name. Constants can appear on interfaces.
Warning
Constants have in the past primarily been used to define named integer codes in the style of an enumeration. The Web platform is moving away from this design pattern in favor of the use of strings. Specification authors who wish to define constants are strongly advised to discuss this on the [email protected] mailing list before proceeding.
const type identifier = value;
The identifier of a
constant
MUST NOT be the same as the identifier of another interface member defined on the same interface. The identifier also MUST NOT be “length”, “name” or “prototype”.
Note
These three names are the names of properties that exist on all
Function objects.
The type of a constant (matching ConstType)
MUST NOT be any type other than a primitive type or a nullable primitive type. If an identifier is used, it MUST reference a typedef whose type is a primitive type or a nullable primitive type.
The ConstValue part of a constant declaration gives the value of the constant, which can be one of the two boolean literal tokens (true and false), the null token, an
integer token, a float token, or one of the three special floating point constant values (-Infinity, Infinity and NaN).
The value of the boolean literal tokens true and
false are the IDL boolean values
true and false.
The value of an integer token is an integer whose value is determined as follows:
- Let S be the sequence of characters matched by the integer token.
- Let sign be −1 if S begins with U+002D HYPHEN-MINUS ("-"), and 1 otherwise.
- Let base be the base of the number based on the characters that follow the optional leading U+002D HYPHEN-MINUS ("-") character:
- U+0030 DIGIT ZERO ("0"), U+0058 LATIN CAPITAL LETTER X ("X")
- U+0030 DIGIT ZERO ("0"), U+0078 LATIN SMALL LETTER X ("x")
- The base is 16.
- U+0030 DIGIT ZERO ("0")
- The base is 8.
- Otherwise
- The base is 10.
- Let number be the result of interpreting all remaining characters following the optional leading U+002D HYPHEN-MINUS ("-") character and any characters indicating the base as an integer specified in base base.
- Return sign × number.
The type of an integer token is the same as the type of the constant, dictionary member or optional argument it is being used as the value of. The value of the integer token MUST NOT lie outside the valid range of values for its type, as given in
section 3.10 .
The value of a float token is either an IEEE 754 single-precision floating point number or an IEEE 754 double-precision floating point number, depending on the type of the constant, dictionary member or optional argument it is being used as the value for, determined as follows:
- Let S be the sequence of characters matched by the float token.
- Let value be the Mathematical Value that would be obtained if S were parsed as an ECMAScript NumericLiteral ( [
ECMA-262] , section 11.8.3).
-
If the float token is being used as the value for a float or
unrestricted float, then the value of the float token is the IEEE 754 single-precision floating point number closest to
result. Otherwise, the float token is being used as the value for a double or
unrestricted double, and the value of the float token is the IEEE 754 double-precision floating point number closest to
result. [
IEEE-754]
The value of a constant value specified as
Infinity, -Infinity or NaN is either an IEEE 754 single-precision floating point number or an IEEE 754 double-precision floating point number, depending on the type of the constant, dictionary member or optional argument is is being used as the value for:
- Type unrestricted float, constant value
Infinity
- The value is the IEEE 754 single-precision positive infinity value.
- Type unrestricted double, constant value
Infinity
- The value is the IEEE 754 double-precision positive infinity value.
- Type unrestricted float, constant value
-Infinity
- The value is the IEEE 754 single-precision negative infinity value.
- Type unrestricted double, constant value
-Infinity
- The value is the IEEE 754 double-precision negative infinity value.
- Type unrestricted float, constant value
NaN
- The value is the IEEE 754 single-precision NaN value with the bit pattern 0x7fc00000.
- Type unrestricted double, constant value
NaN
- The value is the IEEE 754 double-precision NaN value with the bit pattern 0x7ff8000000000000.
The type of a float token is the same as the type of the constant, dictionary member or optional argument it is being used as the value of. The value of the
float token MUST NOT lie outside the valid range of values for its type, as given in
section 3.10 . Also, Infinity, -Infinity and NaN MUST NOT be used as the value of a float or double.
The value of the null token is the special
null value that is a member of the
nullable types. The type of the null token is the same as the type of the constant, dictionary member or optional argument it is being used as the value of.
If VT is the type of the value assigned to a constant, and DT is the type of the constant, dictionary member or optional argument itself, then these types MUST be compatible, which is the case if DT and VT are identical, or DT is a nullable type whose inner type is VT.
Constants are not associated with particular instances of the interface on which they appear. It is language binding specific whether
constants are exposed on instances.
Note
The ECMAScript language binding does however allow constants to be accessed through objects implementing the IDL interfaces on which the constants are declared. For example, with the following IDL:
IDL
interface A {
const short rambaldi = 47;
};
the constant value can be accessed in ECMAScript
either as
A.rambaldi or instanceOfA.rambaldi.
The following extended attributes are applicable to constants:
[Exposed].
The following IDL fragment demonstrates how constants of the above types can be defined.
IDL
interface Util {
const boolean DEBUG = false;
const octet LF = 10;
const unsigned long BIT_MASK = 0x0000fc00;
const double AVOGADRO = 6.022e23;
};
3.2.2 Attributes
An attribute is an interface member
(matching
"inherit" ReadOnly AttributeRest,
"static" ReadOnly AttributeRest,
"stringifier" ReadOnly AttributeRest,
or ReadOnly AttributeRest)
that is used to declare data fields with a given type and
identifier whose value can be retrieved and (in some cases) changed. There are two kinds of attributes:
- regular attributes, which are those used to declare that objects implementing the interface will have a data field member with the given identifier
attribute type identifier;
- static attributes, which are used to declare attributes that are not associated with a particular object implementing the interface
static attribute type identifier;
If an attribute has no static keyword, then it declares a
regular attribute. Otherwise, it declares a static attribute.
The identifier of an
attribute
MUST NOT be the same as the identifier of another interface member defined on the same interface. The identifier of a static attribute MUST NOT be “prototype”.
The type of the attribute is given by the type (matching Type) that appears after the attribute keyword. If the Type is an
identifier or an identifier followed by ?, then the identifier MUST identify an interface, enumeration,
callback function or typedef.
The type of the attribute, after resolving typedefs, MUST NOT be a
nullable or non-nullable version of any of the following types:
The attribute is read only if the
readonly keyword is used before the attribute keyword. An object that implements the interface on which a read only attribute is defined will not allow assignment to that attribute. It is language binding specific whether assignment is simply disallowed by the language, ignored or an exception is thrown.
readonly attribute type identifier;
A regular attribute that is not read only can be declared to inherit its getter from an ancestor interface. This can be used to make a read only attribute in an ancestor interface be writable on a derived interface. An attribute
inherits its getter if its declaration includes inherit in the declaration. The read only attribute from which the attribute inherits its getter is the attribute with the same identifier on the closest ancestor interface of the one on which the inheriting attribute is defined. The attribute whose getter is being inherited MUST be of the same type as the inheriting attribute, and inherit
MUST NOT appear on a read only attribute or a static attribute.
interface Ancestor {
readonly attribute TheType theIdentifier;
};
interface Derived : Ancestor {
inherit attribute TheType theIdentifier;
};
When the stringifier keyword is used in a regular attribute declaration, it indicates that objects implementing the interface will be stringified to the value of the attribute. See
section 3.2.4.2 for details.
stringifier attribute DOMString identifier;
If an implementation attempts to get or set the value of an
attribute on a
user object (for example, when a callback object has been supplied to the implementation), and that attempt results in an exception being thrown, then, unless otherwise specified, that exception will be propagated to the user code that caused the implementation to access the attribute. Similarly, if a value returned from getting the attribute cannot be converted to an IDL type, then any exception resulting from this will also be propagated to the user code that resulted in the implementation attempting to get the value of the attribute.
The following extended attributes are applicable to regular and static attributes:
[Clamp],
[EnforceRange],
[Exposed],
[SameObject],
[TreatNullAs].
The following extended attributes are applicable only to regular attributes:
[LenientThis],
[PutForwards],
[Replaceable],
[Unforgeable].
The following IDL fragment demonstrates how attributes can be declared on an interface:
IDL
interface Animal {
readonly attribute DOMString name;
attribute unsigned short age;
};
interface Person : Animal {
inherit attribute DOMString name;
};
3.2.3 Operations
An operation is an interface member (matching "static" OperationRest,
"stringifier" OperationRest,
"serializer" OperationRest,
ReturnType OperationRest or
SpecialOperation) that defines a behavior that can be invoked on objects implementing the interface. There are three kinds of operation:
- regular operations, which are those used to declare that objects implementing the
interface will have a method with the given identifier
return-type identifier(arguments…);
- special operations, which are used to declare special behavior on objects implementing the interface, such as object indexing and stringification
special-keywords… return-type identifier(arguments…);
special-keywords… return-type (arguments…);
- static operations, which are used to declare operations that are not associated with a particular object implementing the interface
static return-type identifier(arguments…);
If an operation has an identifier but no static keyword, then it declares a regular operation. If the operation has one or more
special keywords used in its declaration (that is, any keyword matching
Special, or the stringifier keyword), then it declares a special operation. A single operation can declare both a regular operation and a special operation; see
section 3.2.4 for details on special operations.
If an operation has no identifier, then it MUST be declared to be a special operation using one of the special keywords.
The identifier of a
regular operation or static operation
MUST NOT be the same as the identifier of a constant or
attribute defined on the same interface. The identifier of a static operation MUST NOT be “prototype”.
Note
The identifier can be the same as that of another operation on the interface, however. This is how operation overloading is specified.
The identifier of a static operation also MUST NOT be the same as the identifier of a regular operation defined on the same interface.
The return type of the operation is given by the type (matching ReturnType) that appears before the operation’s optional identifier. A return type of void indicates that the operation returns no value. If the return type is an
identifier followed by ?, then the identifier MUST identify an interface, dictionary, enumeration,
callback function or typedef.
An operation’s arguments (matching ArgumentList) are given between the parentheses in the declaration. Each individual argument is specified as a type (matching Type) followed by an identifier (matching ArgumentName).
Note
For expressiveness, the identifier of an operation argument can also be specified as one of the keywords matching the ArgumentNameKeyword symbol without needing to escape it.
If the Type of an operation argument is an identifier followed by ?, then the identifier MUST identify an interface,
enumeration, callback function or typedef. If the operation argument type is an identifier not followed by ?, then the identifier MUST identify any one of those definitions or a dictionary.
return-type identifier(type identifier, type identifier, …);
The identifier of each argument MUST NOT be the same as the identifier of another argument in the same operation declaration.
Each argument can be preceded by a list of
extended attributes (matching
ExtendedAttributeList), which can control how a value passed as the argument will be handled in language bindings.
return-type identifier([extended-attributes] type identifier, [extended-attributes] type identifier, …);
The following IDL fragment demonstrates how regular operations can be declared on an interface:
IDL
interface Dimensions {
attribute unsigned long width;
attribute unsigned long height;
};
interface Button {
boolean isMouseOver();
void setDimensions(Dimensions size);
void setDimensions(unsigned long width, unsigned long height);
};
An operation is considered to be variadic if the final argument uses the ... token just after the argument type. Declaring an operation to be variadic indicates that the operation can be invoked with any number of arguments after that final argument. Those extra implied formal arguments are of the same type as the final explicit argument in the operation declaration. The final argument can also be omitted when invoking the operation. An argument MUST NOT be declared with the ... token unless it is the final argument in the operation’s argument list.
return-type identifier(type... identifier);
return-type identifier(type identifier, type... identifier);
Extended attributes that take an argument list ([Constructor] and
[NamedConstructor], of those defined in this specification) and callback functions are also considered to be variadic when the ... token is used in their argument lists.
The following IDL fragment defines an interface that has two variadic operations:
IDL
interface IntegerSet {
readonly attribute unsigned long cardinality;
void union(long... ints);
void intersection(long... ints);
};
In the ECMAScript binding, variadic operations are implemented by functions that can accept the subsequent arguments:
ECMAScript
var s = getIntegerSet();
s.union();
s.union(1, 4, 7);
A binding for a language that does not support variadic functions might specify that an explicit array or list of integers be passed to such an operation.
An argument is considered to be an optional argument if it is declared with the optional keyword. The final argument of a variadic operation is also considered to be an optional argument. Declaring an argument to be optional indicates that the argument value can be omitted when the operation is invoked. The final argument in an operation MUST NOT explicitly be declared to be optional if the operation is variadic.
return-type identifier(type identifier, optional type identifier);
Optional arguments can also have a default value specified. If the argument’s identifier is followed by a U+003D EQUALS SIGN ("=") and a value (matching DefaultValue), then that gives the optional argument its default value. The implicitly optional final argument of a variadic operation MUST NOT have a default value specified. The default value is the value to be assumed when the operation is called with the corresponding argument omitted.
return-type identifier(type identifier, optional type identifier = value);
Warning
It is strongly suggested not to use default value of true for boolean-typed arguments, as this can be confusing for authors who might otherwise expect the default conversion of undefined to be used (i.e., false).
If the type of an argument is a dictionary type or a union type that has a dictionary type as one of its flattened member types, and that dictionary type and its ancestors have no required members, and the argument is either the final argument or is followed only by
optional arguments, then the argument MUST be specified as optional. Such arguments are always considered to have a
default value of an empty dictionary, unless otherwise specified.
Note
This is to encourage API designs that do not require authors to pass an empty dictionary value when they wish only to use the dictionary’s default values.
Dictionary types cannot have a default value specified explicitly, so the “unless otherwise specified” clause above can only be invoked for a union type that has a dictionary type as one of its flattened member types.
When a boolean literal token (true or false), the null token, an integer token, a
float token or one of the three special floating point literal values (Infinity,
-Infinity or NaN) is used as the
default value, it is interpreted in the same way as for a constant.
Optional argument default values can also be specified using a string token, whose value is a string type determined as follows:
- Let S be the sequence of Unicode scalar values matched by the string token with its leading and trailing U+0022 QUOTATION MARK ('"') characters removed.
- Depending on the type of the argument:
- DOMString
- an enumeration type
- The value of the string token is the sequence of 16 bit unsigned integer code units (hereafter referred to just as code units) corresponding to the UTF-16 encoding of S.
- ByteString
- The value of the string token is the sequence of 8 bit unsigned integer code units corresponding to the UTF-8 encoding of S.
- USVString
- The value of the string token is S.
If the type of the optional argument is an enumeration, then its
default value if specified MUST be one of the enumeration’s values.
Optional argument default values can also be specified using the two token value [], which represents an empty sequence value. The type of this value is the same the type of the optional argument it is being used as the default value of. That type
MUST be a
sequence type or a
nullable type.
The following IDL fragment defines an interface with a single operation that can be invoked with two different argument list lengths:
IDL
interface ColorCreator {
object createColor(double v1, double v2, double v3, optional double alpha);
};
It is equivalent to an interface that has two overloaded
operations:
IDL
interface ColorCreator {
object createColor(double v1, double v2, double v3);
object createColor(double v1, double v2, double v3, double alpha);
};
If an implementation attempts to invoke an
operation on a
user object (for example, when a callback object has been supplied to the implementation), and that attempt results in an exception being thrown, then, unless otherwise specified, that exception will be propagated to the user code that caused the implementation to invoke the operation. Similarly, if a value returned from invoking the operation cannot be converted to an IDL type, then any exception resulting from this will also be propagated to the user code that resulted in the implementation attempting to invoke the operation.
The following extended attributes are applicable to operations:
[Exposed],
[NewObject],
[TreatNullAs],
[Unforgeable].
The following extended attributes are applicable to operation arguments:
[Clamp],
[EnforceRange],
[TreatNullAs].
3.2.4 Special operations
A special operation is a declaration of a certain kind of special behavior on objects implementing the interface on which the special operation declarations appear. Special operations are declared by using one or more
special keywords in an operation declaration.
There are six kinds of special operations. The table below indicates for a given kind of special operation what special keyword is used to declare it and what the purpose of the special operation is:
| Special operation |
Keyword |
Purpose |
| Getters |
getter |
Defines behavior for when an object is indexed for property retrieval. |
| Setters |
setter |
Defines behavior for when an object is indexed for property assignment or creation. |
| Deleters |
deleter |
Defines behavior for when an object is indexed for property deletion. |
| Legacy callers |
legacycaller |
Defines behavior for when an object is called as if it were a function. |
| Stringifiers |
stringifier |
Defines how an object is converted into a DOMString. |
| Serializers |
serializer |
Defines how an object is converted into a serialized form. |
Not all language bindings support all of the six kinds of special object behavior. When special operations are declared using operations with no identifier, then in language bindings that do not support the particular kind of special operations there simply will not be such functionality.
The following IDL fragment defines an interface with a getter and a setter:
IDL
interface Dictionary {
readonly attribute unsigned long propertyCount;
getter double (DOMString propertyName);
setter void (DOMString propertyName, double propertyValue);
};
In language bindings that do not support property getters and setters, objects implementing Dictionary will not have that special behavior.
Defining a special operation
with an identifier is equivalent to separating the special operation out into its own declaration without an identifier. This approach is allowed to simplify prose descriptions of an interface’s operations.
The following two interfaces are equivalent:
IDL
interface Dictionary {
readonly attribute unsigned long propertyCount;
getter double getProperty(DOMString propertyName);
setter void setProperty(DOMString propertyName, double propertyValue);
};
IDL
interface Dictionary {
readonly attribute unsigned long propertyCount;
double getProperty(DOMString propertyName);
void setProperty(DOMString propertyName, double propertyValue);
getter double (DOMString propertyName);
setter void (DOMString propertyName, double propertyValue);
};
A given special keyword MUST NOT appear twice on an operation.
Getters and setters come in two varieties: ones that take a DOMString as a property name, known as
named property getters and
named property setters, and ones that take an unsigned long as a property index, known as
indexed property getters and
indexed property setters. There is only one variety of deleter:
named property deleters. See section 3.2.4.4 and section 3.2.4.5 for details.
On a given interface, there MUST exist at most one stringifier, at most one serializer, at most one
named property deleter, and at most one of each variety of getter and setter. Multiple legacy callers can exist on an interface to specify overloaded calling behavior.
If an interface has a setter of a given variety, then it MUST also have a getter of that variety. If it has a named property deleter, then it MUST also have a
named property getter.
Special operations declared using operations MUST NOT be variadic nor have any
optional arguments.
Special operations MUST NOT be declared on
callback interfaces.
If an object implements more than one interface that defines a given special operation, then it is undefined which (if any) special operation is invoked for that operation.
3.2.4.1 Legacy callers
When an interface has one or more
legacy callers, it indicates that objects that implement the interface can be called as if they were functions. As mentioned above, legacy callers can be specified using an operation declared with the legacycaller keyword.
legacycaller return-type identifier(arguments…);
legacycaller return-type (arguments…);
If multiple legacy callers are specified on an interface, overload resolution is used to determine which legacy caller is invoked when the object is called as if it were a function.
Legacy callers MUST NOT be defined to return a
promise type.
Warning
Legacy callers are universally recognised as an undesirable feature. They exist only so that legacy Web platform features can be specified. Legacy callers
SHOULD NOT be used in specifications unless required to specify the behavior of legacy APIs, and even then this should be discussed on the [email protected] mailing list before proceeding.
The following IDL fragment defines an interface with a legacy caller.
IDL
interface NumberQuadrupler {
legacycaller double compute(double x);
};
An ECMAScript implementation supporting this interface would allow a platform object that implements NumberQuadrupler to be called as a function:
ECMAScript
var f = getNumberQuadrupler();
f.compute(3);
f(3);
3.2.4.2 Stringifiers
When an interface has a
stringifier, it indicates that objects that implement the interface have a non-default conversion to a string. As mentioned above, stringifiers can be specified using an operation declared with the stringifier keyword.
stringifier DOMString identifier();
stringifier DOMString ();
If an operation used to declare a stringifier does not have an
identifier, then prose accompanying the interface MUST define the stringification behavior of the interface. If the operation does have an identifier, then the object is converted to a string by invoking the operation to obtain the string.
Stringifiers declared with operations MUST be declared to take zero arguments and return a DOMString.
As a shorthand, if the stringifier keyword is declared using an operation with no identifier, then the operation’s return type and argument list can be omitted.
stringifier;
The following two interfaces are equivalent:
IDL
interface A {
stringifier DOMString ();
};
IDL
interface A {
stringifier;
};
The stringifier keyword can also be placed on an attribute. In this case, the string to convert the object to is the value of the attribute. The stringifier keyword
MUST NOT be placed on an attribute unless it is declared to be of type DOMString or USVString. It also MUST NOT be placed on a static attribute.
stringifier attribute DOMString identifier;
The following IDL fragment defines an interface that will stringify to the value of its
name attribute:
IDL
[Constructor]
interface Student {
attribute unsigned long id;
stringifier attribute DOMString name;
};
In the ECMAScript binding, using a Student object in a context where a string is expected will result in the value of the object’s “name” property being used:
ECMAScript
var s = new Student();
s.id = 12345678;
s.name = '周杰倫';
var greeting = 'Hello, ' + s + '!';
The following IDL fragment defines an interface that has custom stringification behavior that is not specified in the IDL itself.
IDL
[Constructor]
interface Student {
attribute unsigned long id;
attribute DOMString? familyName;
attribute DOMString givenName;
stringifier DOMString ();
};
Thus, prose is required to explain the stringification behavior, such as the following paragraph:
Objects that implement the Student interface must stringify as follows. If the value of the
familyName attribute is
null, the stringification of the object is the value of the givenName attribute. Otherwise, if the value of the
familyName attribute is not null, the stringification of the object is the concatenation of the value of the givenName attribute, a single space character, and the value of the familyName attribute.
An ECMAScript implementation of the IDL would behave as follows:
ECMAScript
var s = new Student();
s.id = 12345679;
s.familyName = 'Smithee';
s.givenName = 'Alan';
var greeting = 'Hi ' + s;
3.2.4.3 Serializers
Warning
The NodeFilterSerializers will be simplified soon, please see discussions in Issue 188
When an interface has a
serializer, it indicates that objects provide a way for them to be converted into a serialized form. Serializers can be declared using the serializer keyword:
serializer;
Prose accompanying an interface that declares a serializer in this way MUST define the
serialization behavior of the interface. Serialization behavior is defined as returning a serialized value of one of the following types:
How the serialization behavior is made available on an object in a language binding, and how exactly the abstract
serialized value is converted into an appropriate concrete value, is language binding specific.
Serialization behavior can also be specified directly in IDL, rather than separately as prose. This is done by following the serializer keyword with a U+003D EQUALS SIGN ("=") character and a serialization pattern, which can take one of the following six forms:
-
A map with entries corresponding to zero or more attributes from the interface, and optionally attributes from an inherited interface:
serializer = { attribute-identifier, attribute-identifier, … };
serializer = { inherit, attribute-identifier, attribute-identifier, … };
Each identifier MUST be the identifier of an attribute declared on the interface. The identified attributes all MUST have a
serializable type.
The inherit keyword MUST NOT be used unless the interface inherits from another that defines a serializer, and the closest such interface defines its serializer using this serialization pattern form or the following form (i.e. { attribute }).
The serialization behavior for this form of serialization pattern is as follows:
- Let map be an empty map.
- If the
inherit keyword was used, then set map to be the result of the serialization behavior of the closest inherited interface that declares a serializer.
- For each attribute identifier i in the serialization pattern, in order:
- Remove any entry in map with key name i.
- Let V be the value of the attribute with identifier i.
- Add an entry to map whose key name is i and whose value is result of converting
V to a serialized value.
- Return map.
-
A map with entries corresponding to all attributes from the interface that have a serializable type, and optionally attributes from an inherited interface:
serializer = { attribute };
serializer = { inherit, attribute };
The inherit keyword MUST NOT be used unless the interface inherits from another that defines a serializer, and the closest such interface defines its serializer using this serialization pattern form or the previous form.
The serialization behavior for this form of serialization pattern is as follows:
- Let map be an empty map.
- If the
inherit keyword was used, then set map to be the result of the serialization behavior of the closest inherited interface that declares a serializer.
- For each identifier i of an attribute on the interface whose type is a serializable type, in the order they appear on the interface:
- Remove any entry in map with key name i.
- Let V be the value of the attribute with identifier i.
- Add an entry to map whose key name is i and whose value is result of converting
V to a serialized value.
- Return map.
-
A map with entries corresponding to the named properties:
serializer = { getter };
This form MUST NOT be used unless the interface or one it inherits from supports named properties and the return type of the named property getter is a serializable type.
The serialization behavior for this form of serialization pattern is as follows:
- Let map be an empty map.
- For each supported property name n on the object, in order:
- Let V be the value of the named property with name n.
- Add an entry to map whose key name is i and whose value is result of converting
V to a serialized value.
- Return map.
-
A list of value of zero or more attributes on the interface:
serializer = [ attribute-identifier, attribute-identifier, … ];
Each identifier MUST be the identifier of an attribute declared on the interface. The identified attributes all MUST have a
serializable type.
The serialization behavior for this form of serialization pattern is as follows:
- Let list be an empty list.
- For each attribute identifier i in the serialization pattern:
- Let V be the value of the attribute with identifier i.
- Append to list the value that is the result of
converting
V to a serialized value.
- Return list.
-
A list with entries corresponding to the indexed properties:
serializer = [ getter ];
This form MUST NOT be used unless the interface or one it inherits from supports indexed properties and the return type of the indexed property getter is a serializable type.
The serialization behavior for this form of serialization pattern is as follows:
- Let list be an empty list.
- Let i be 0.
- While i is less than or equal to the greatest supported property index on the object:
- Let V be the value of the indexed property with index i if i is a supported property index, or null otherwise.
- Append to list the value that is the result of
converting
V to a serialized value.
- Set i to i + 1.
- Return map.
-
A single attribute:
serializer = attribute-identifier;
The identifier MUST be the identifier of an attribute declared on the interface, and this attribute MUST have a
serializable type.
The serialization behavior for this form of serialization pattern is as follows:
- Let V be the value of the attribute with the specified identifier.
- Return the result of converting
V to a serialized value.
Note
Entries are added to maps in a particular order so that in the ECMAScript language binding it is defined what order properties are added to objects. This is because this order can influence the serialization that JSON.stringify can produce.
The list of serializable types and how they are
converted to serialized values is as follows:
- long long
- converted by choosing the closest equivalent double value (as when converting a long long to an ECMAScript Number value)
- unsigned long long
- converted by choosing the closest equivalent double value (as when converting a unsigned long long to an ECMAScript Number value)
- any other integer type
- float
- converted by choosing the equivalent double value
- double
- boolean
- DOMString
- the same value of the respective type
- an enumeration type
- the equivalent DOMString value
- a USVString
- the DOMString produced by encoding the given sequence of Unicode scalar values in UTF-16
- a ByteString
- the equivalent DOMString value where each code unit has the same value as the corresponding byte value
- a nullable serializable type
- converted to null if that is its value, otherwise converted as per its inner type
- a union type where
all of its member types
are serializable types
- converted as per its specific type
- a sequence type that
has a serializable type as its element type
- converted to a list where each element is the result of converting its corresponding sequence element to a serialized value
- a dictionary where
all of its members have
serializable types
- converted to a map consisting of an entry for each dictionary member that is present, where the entry’s key is the identifier of the dictionary member and its value is the result of converting the dictionary member’s value to a serializable type
- an interface type that has a
serializer
- converted by invoking the object’s serializer
Serializers can also be specified using an operation with the serializer keyword:
serializer type identifier();
Serializers declared with operations MUST be declared to take zero arguments and return a serializable type.
The serialization behavior of the interface with a serializer declared with an operation is the result of
converting the value returned from invoking the operation to a serialized value.
The following IDL fragment defines an interface Transaction that has a
serializer defines in prose:
IDL
interface Transaction {
readonly attribute Account from;
readonly attribute Account to;
readonly attribute double amount;
readonly attribute DOMString description;
readonly attribute unsigned long number;
serializer;
};
interface Account {
DOMString name;
unsigned long number;
};
The serializer could be defined as follows:
The serialization behavior of the Transaction interface is to run the following algorithm, where O is the object that implements Transaction:
- Let map be an empty map.
- Add an entry to map whose key is “from” and whose value is the serialized value of the
number attribute on the Account object referenced by the from attribute on O.
- Add an entry to map whose key is “to” and whose value is the serialized value of the
number attribute on the Account object referenced by the from attribute on O.
- For both of the attributes
amount and description, add an entry to map whose key is the
identifier of the attribute and whose value is the serialized value of the value of the attribute on O.
- Return map.
If it was acceptable for Account objects to be serializable on their own, then serialization patterns could be used to avoid having to define the serialization behavior in prose:
IDL
interface Transaction {
readonly attribute Account from;
readonly attribute Account to;
readonly attribute double amount;
readonly attribute DOMString description;
readonly attribute unsigned long number;
serializer = { from, to, amount, description };
};
interface Account {
DOMString name;
unsigned long number;
serializer = number;
};
In the ECMAScript language binding, there would exist a toJSON method on
Transaction objects:
ECMAScript
var txn = getTransaction();
txn.toJSON();
JSON.stringify(txn);
3.2.4.4 Indexed properties
An interface that defines an indexed property getter is said to support indexed properties.
If an interface supports indexed properties, then the interface definition MUST be accompanied by a description of what indices the object can be indexed with at any given time. These indices are called the supported property indices.
Indexed property getters MUST be declared to take a single unsigned long argument. Indexed property setters MUST be declared to take two arguments, where the first is an unsigned long.
getter type identifier(unsigned long identifier);
setter type identifier(unsigned long identifier, type identifier);
getter type (unsigned long identifier);
setter type (unsigned long identifier, type identifier);
The following requirements apply to the definitions of indexed property getters and setters:
-
If an indexed property getter was specified using an operation with an identifier, then the value returned when indexing the object with a given supported property index is the value that would be returned by invoking the operation, passing the index as its only argument. If the operation used to declare the indexed property getter did not have an identifier, then the interface definition must be accompanied by a description of how to determine the value of an indexed property for a given index.
-
If an indexed property setter was specified using an operation with an identifier, then the behavior that occurs when indexing the object for property assignment with a given supported property index and value is the same as if the operation is invoked, passing the index as the first argument and the value as the second argument. If the operation used to declare the indexed property setter did not have an identifier, then the interface definition must be accompanied by a description of how to set the value of an existing indexed property and how to set the value of a new indexed property for a given property index and value.
Note
Note that if an indexed property getter or
setter is specified using an operation with an identifier, then indexing an object with an integer that is not a supported property index does not necessarily elicit the same behavior as invoking the operation with that index. The actual behavior in this case is language binding specific.
In the ECMAScript language binding, a regular property lookup is done. For example, take the following IDL:
IDL
interface A {
getter DOMString toWord(unsigned long index);
};
Assume that an object implementing A has supported property indices in the range 0 ≤ index < 2. Also assume that toWord is defined to return its argument converted into an English word. The behavior when invoking the
operation with an out of range index is different from indexing the object directly:
ECMAScript
var a = getA();
a.toWord(0);
a[0];
a.toWord(5);
a[5];
The following IDL fragment defines an interface
OrderedMap which allows retrieving and setting values by name or by index number:
IDL
interface OrderedMap {
readonly attribute unsigned long size;
getter any getByIndex(unsigned long index);
setter void setByIndex(unsigned long index, any value);
getter any get(DOMString name);
setter void set(DOMString name, any value);
};
Since all of the special operations are declared using operations with identifiers, the only additional prose that is necessary is that which describes what keys those sets have. Assuming that the get() operation is defined to return null if an attempt is made to look up a non-existing entry in the
OrderedMap, then the following two sentences would suffice:
An object map implementing OrderedMap supports indexed properties with indices in the range 0 ≤
index < map.size.
Such objects also support a named property for every name that, if passed to get(), would return a non-null value.
As described in section 4.8 , an ECMAScript implementation would create properties on a platform object implementing
OrderedMap that correspond to entries in both the named and indexed property sets. These properties can then be used to interact with the object in the same way as invoking the object’s methods, as demonstrated below:
ECMAScript
var map = getOrderedMap();
var x, y;
x = map[0];
map[1] = false;
y = map.apple;
map.berry = 123;
delete map.cake;
3.2.4.5 Named properties
An interface that defines a named property getter is said to support named properties.
If an interface supports named properties, then the interface definition MUST be accompanied by a description of the ordered set of names that can be used to index the object at any given time. These names are called the
supported property names.
Named property getters and deleters MUST be declared to take a single DOMString argument. Named property setters MUST be declared to take two arguments, where the first is a DOMString.
getter type identifier(DOMString identifier);
setter type identifier(DOMString identifier, type identifier);
deleter type identifier(DOMString identifier);
getter type (DOMString identifier);
setter type (DOMString identifier, type identifier);
deleter type (DOMString identifier);
The following requirements apply to the definitions of named property getters, setters and deleters:
-
If a named property getter was specified using an operation with an identifier, then the value returned when indexing the object with a given supported property name is the value that would be returned by invoking the operation, passing the name as its only argument. If the operation used to declare the named property getter did not have an identifier, then the interface definition must be accompanied by a description of how to determine the value of a named property for a given property name.
-
If a named property setter was specified using an operation with an identifier, then the behavior that occurs when indexing the object for property assignment with a given supported property name and value is the same as if the operation is invoked, passing the name as the first argument and the value as the second argument. If the operation used to declare the named property setter did not have an identifier, then the interface definition must be accompanied by a description of how to set the value of an existing named property and how to set the value of a new named property for a given property name and value.
-
If a named property deleter was specified using an operation with an identifier, then the behavior that occurs when indexing the object for property deletion with a given supported property name is the same as if the operation is invoked, passing the name as the only argument. If the operation used to declare the named property deleter did not have an identifier, then the interface definition must be accompanied by a description of how to delete an existing named property for a given property name.
3.2.5 Static attributes and operations
Static attributes and
static operations are ones that are not associated with a particular instance of the
interface on which it is declared, and is instead associated with the interface itself. Static attributes and operations are declared by using the
static keyword in their declarations.
It is language binding specific whether it is possible to invoke a static operation or get or set a static attribute through a reference to an instance of the interface.
Static attributes and operations MUST NOT be declared on callback interfaces.
The following IDL fragment defines an interface
Circle that has a static operation declared on it:
IDL
interface Point { };
interface Circle {
attribute double cx;
attribute double cy;
attribute double radius;
static readonly attribute long triangulationCount;
static Point triangulate(Circle c1, Circle c2, Circle c3);
};
In the ECMAScript language binding, the Function object for
triangulate and the accessor property for triangulationCount will exist on the interface object for Circle:
ECMAScript
var circles = getCircles();
typeof Circle.triangulate;
typeof Circle.triangulationCount;
Circle.prototype.triangulate;
Circle.prototype.triangulationCount;
circles[0].triangulate;
circles[0].triangulationCount;
var triangulationPoint = Circle.triangulate(circles[0], circles[1], circles[2]);
window.alert(Circle.triangulationCount);
3.2.6 Overloading
If a regular operation or static operation defined on an interface has an identifier that is the same as the identifier of another operation on that interface of the same kind (regular or static), then the operation is said to be
overloaded. When the identifier of an overloaded operation is used to invoke one of the operations on an object that implements the interface, the number and types of the arguments passed to the operation determine which of the overloaded operations is actually invoked. If an interface has multiple
legacy callers defined on it, then those legacy callers are also said to be overloaded. In the ECMAScript language binding, constructors can be overloaded too. There are some restrictions on the arguments that overloaded operations, legacy callers and constructors can be specified to take, and in order to describe these restrictions, the notion of an effective overload set is used.
Operations and legacy callers
MUST NOT be overloaded across interface and partial interface definitions.
Note
For example, the overloads for both f and g are disallowed:
IDL
interface A {
void f();
};
partial interface A {
void f(double x);
void g();
};
partial interface A {
void g(DOMString x);
};
Note that the [Constructor] and
[NamedConstructor]
extended attributes are disallowed from appearing on partial interface definitions, so there is no need to also disallow overloading for constructors.
An effective overload set represents the allowable invocations for a particular
operation, constructor (specified with [Constructor] or [NamedConstructor]),
legacy caller or
callback function. The algorithm to compute an effective overload set operates on one of the following six types of IDL constructs, and listed with them below are the inputs to the algorithm needed to compute the set.
- For regular operations
- For static operations
-
- For legacy callers
-
- For constructors
-
- For named constructors
-
- For callback functions
-
An effective overload set is used, among other things, to determine whether there are ambiguities in the overloaded operations, constructors and callers specified on an interface.
The elements of an effective overload set are tuples of the form <
callable, type list, optionality list>. If the effective overload set is for regular operations, static operations or legacy callers, then callable is an operation; if it is for constructors or named constructors, then callable is an extended attribute; and if it is for callback functions, then callable is the callback function itself. In all cases, type list is a list of IDL types, and optionality list is a list of three possible optionality values – “required”, “optional” or “variadic” – indicating whether the argument at a given index was declared as being optional or corresponds to a variadic argument. Each tuple represents an allowable invocation of the operation, constructor, legacy caller or callback function with an argument value list of the given types. Due to the use of optional arguments and variadic operations and constructors, there may be multiple entries in an effective overload set identifying the same operation or constructor.
The algorithm below describes how to compute an effective overload set. The following input variables are used, if they are required:
- the identifier of the operation or named constructor is A
- the argument count is N
- the interface is I
- the callback function is C
Whenever an argument of an extended attribute is mentioned, it is referring to an argument of the extended attribute’s named argument list.
- Initialize S to ∅.
- Let F be a set with elements as follows, according to the kind of effective overload set:
- For regular operations
-
The elements of F are the regular operations with identifier A defined on interface I.
- For static operations
-
The elements of F are the static operations with identifier A defined on interface I.
- For constructors
-
The elements of F are the
[Constructor]
extended attributes on interface I.
- For named constructors
-
The elements of F are the
[NamedConstructor]
extended attributes on interface I whose
named argument lists’ identifiers are A.
- For legacy callers
-
The elements of F are the legacy callers defined on interface I.
- For callback functions
-
The single element of F is the callback function itself, C.
-
Let maxarg be the maximum number of arguments the operations, constructor extended attributes or callback functions in F are declared to take. For variadic operations and constructor extended attributes, the argument on which the ellipsis appears counts as a single argument.
Note
So void f(long x, long... y); is considered to be declared to take two arguments.
- Let m be the maximum of maxarg and N.
- For each operation, extended attribute or callback function X in F:
- Let n be the number of arguments X is declared to take.
- Let t0..n−1 be a list of types, where ti is the type of X’s argument at index i.
- Let o0..n−1 be a list of optionality values, where oi is “variadic” if X’s argument at index i is a final, variadic argument, “optional” if the argument is optional, and “required” otherwise.
- Add to S the tuple <X, t0..n−1, o0..n−1>.
- If X is declared to be variadic, then:
- Add to S the tuple <X, t0..n−2, o0..n−2>.
Note
This leaves off the final, variadic argument.
- For every integer i, such that n ≤ i ≤ m−1:
- Let u0..i be a list of types, where uj = tj (for j < n) and uj = tn−1 (for j ≥ n).
- Let p0..i be a list of optionality values, where pj = oj (for j < n) and pj = “variadic” (for j ≥ n).
- Add to S the tuple <X, u0..i, p0..i>.
- Initialize i to n−1.
- While i ≥ 0:
- If argument i of X is not optional, then break this loop.
- Otherwise, add to S the tuple <X, t0..i−1, o0..i−1>.
- Set i to i−1.
-
The effective overload set is S.
For the following interface:
IDL
interface A {
void f(DOMString a);
void f(Node a, DOMString b, double... c);
void f();
void f(Event a, DOMString b, optional DOMString c, double... d);
};
assuming Node and Event are two other interfaces of which no object can implement both, the effective overload set for regular operations with identifier f and argument count 4 is:
{ <f1, (DOMString), (required)>,
<f2, (Node, DOMString), (required, required)>,
<f2, (Node, DOMString, double), (required, required, variadic)>,
<f2, (Node, DOMString, double, double), (required, required, variadic, variadic)>,
<f3, (), ()>,
<f4, (Event, DOMString), (required, required)>,
<f4, (Event, DOMString, DOMString), (required, required, optional)>,
<f4, (Event, DOMString, DOMString, double), (required, required, optional, variadic)> }
Two types are distinguishable if at most one of the two includes a nullable type or is a dictionary type, and at least one of the following three conditions is true:
-
The two types (taking their inner types if they are nullable types) appear in the following table and there is a “●” mark in the corresponding entry or there is a letter in the corresponding entry and the designated additional requirement below the table is satisfied:
|
boolean |
numeric types |
string types |
interface |
object |
callback
function |
dictionary |
sequence<T> |
exception types |
buffer source types |
| boolean |
|
● |
● |
● |
● |
● |
● |
● |
● |
● |
| numeric types |
|
|
● |
● |
● |
● |
● |
● |
● |
● |
| string types |
|
|
|
● |
● |
● |
● |
● |
● |
● |
| interface |
|
|
|
(a) |
|
(b) |
(b) |
● |
● |
● |
| object |
|
|
|
|
|
|
|
|
|
|
| callback function |
|
|
|
|
|
|
|
● |
● |
● |
| dictionary |
|
|
|
|
|
|
|
● |
● |
● |
| sequence<T> |
|
|
|
|
|
|
|
|
● |
● |
| exception types |
|
|
|
|
|
|
|
|
|
● |
| buffer source types |
|
|
|
|
|
|
|
|
|
|
- The two identified interfaces are not the same, it is not possible for a single platform object to implement both interfaces, and it is not the case that both are callback interfaces.
- The interface type is not a callback interface.
-
One type is a union type or nullable union type, the other is neither a union type nor a nullable union type, and each
member type of the first is distinguishable with the second.
-
Both types are either a union type or nullable union type, and each member type of the one is distinguishable with each member type of the other.
Note
Promise types do not appear in the above table, and as a consequence are not distinguishable with any other type.
If there is more than one entry in an effective overload set that has a given type list length, then for those entries there
MUST be an index i such that for each pair of entries the types at index i are
distinguishable
.
The lowest such index is termed the distinguishing argument index for the entries of the effective overload set with the given type list length.
Consider the effective overload set shown in the previous example. There are multiple entries in the set with type lists 2, 3 and 4. For each of these type list lengths, the distinguishing
argument index is 0, since Node and
Event are distinguishable.
The following use of overloading however is invalid:
IDL
interface B {
void f(DOMString x);
void f(double x);
};
since DOMString and
double are not distinguishable.
In addition, for each index j, where j is less than the
distinguishing argument index for a given type list length, the types at index j in all of the entries’ type lists MUST be the same and the booleans in the corresponding list indicating argument optionality MUST be the same.
The following is invalid:
IDL
interface B {
void f(DOMString w);
void f(long w, double x, Node y, Node z);
void f(double w, double x, DOMString y, Node z);
};
For argument count 4, the effective overload set is:
{ <f1, (DOMString), (required)>,
<f2, (long, double, Node, Node), (required, required, required, required)>,
<f3, (double, double, DOMString, Node), (required, required, required, required)> }
Looking at entries with type list length 4, the
distinguishing argument index is 2, since Node and
DOMString are distinguishable. However, since the arguments in these two overloads at index 0 are different, the overloading is invalid.
3.2.7 Iterable declarations
An interface can be declared to be
iterable by using an iterable declaration (matching Iterable) in the body of the interface.
iterable<value-type>;
iterable<key-type, value-type>;
Objects implementing an interface that is declared to be iterable support being iterated over to obtain a sequence of values.
If a single type parameter is given, then the interface has a
value iterator and provides values of the specified type. If two type parameters are given, then the interface has a
pair iterator and provides value pairs, where the first value is a key and the second is the value associated with the key.
A value iterator
MUST only be declared on an interface that supports indexed properties and has an integer-typed
attribute named “length”. The value-type of the value iterator
MUST be the same as the type returned by the indexed property getter. A value iterator is implicitly defined to iterate over the object’s indexed properties.
A pair iterator
MUST NOT be declared on an interface that supports indexed properties. Prose accompanying an interface with a
pair iterator
MUST define what the list of
value pairs to iterate over is.
Note
The ECMAScript forEach method that is generated for a
value iterator invokes its callback like Array.prototype.forEach does, and the forEach method for a pair iterator invokes its callback like Map.prototype.forEach does.
Since value iterators are currently allowed only on interfaces that
support indexed properties, it makes sense to use an Array-like forEach method. There may be a need for value iterators (a) on interfaces that do not
support indexed properties, or (b) with a forEach method that instead invokes its callback like Set.protoype.forEach (where the key is the same as the value). If you’re creating an API that needs such a forEach method, please send a request to
[email protected].
Interfaces with iterable declarations MUST NOT have any interface members named “entries”, “forEach”, “keys” or “values”, or have any inherited or consequential interfaces that have interface members with these names.
Consider the following interface SessionManager, which allows access to a number of Session objects:
IDL
interface SessionManager {
Session getSessionForUser(DOMString username);
readonly attribute unsigned long sessionCount;
iterable<Session>;
};
interface Session {
readonly attribute DOMString username;
};
The behavior of the iterator could be defined like so:
The values to iterate over are the open Session objects on the SessionManager sorted by username.
In the ECMAScript language binding, the interface prototype object for the SessionManager interface has a values method that is a function, which, when invoked, returns an iterator object that itself has a next method that returns the next value to be iterated over. It has values and entries methods that iterate over the indexes of the list of session objects and [index, session object] pairs, respectively. It also has a @@iterator method that allows a SessionManager to be used in a for..of loop:
ECMAScript
var sm = getSessionManager();
typeof SessionManager.prototype.values;
var it = sm.values();
String(it);
typeof it.next;
for (;;) {
let result = it.next();
if (result.done) {
break;
}
let session = result.value;
window.alert(session.username);
}
for (let session of sm) {
window.alert(session.username);
}
An interface MUST NOT have more than one
iterable declaration. The inherited and consequential interfaces of an interface with an
iterable declaration
MUST NOT also have an
iterable declaration.
The following extended attributes are applicable to iterable declarations:
[Exposed].
3.3 Dictionaries
A dictionary is a definition (matching
Dictionary) used to define an associative array data type with a fixed, ordered set of key–value pairs, termed dictionary members, where keys are strings and values are of a particular type specified in the definition.
dictionary identifier {
dictionary-members…
};
Dictionaries are always passed by value. In language bindings where a dictionary is represented by an object of some kind, passing a dictionary to a platform object will not result in a reference to the dictionary being kept by that object. Similarly, any dictionary returned from a platform object will be a copy and modifications made to it will not be visible to the platform object.
A dictionary can be defined to inherit from another dictionary. If the identifier of the dictionary is followed by a colon and a identifier, then that identifier identifies the inherited dictionary. The identifier
MUST identify a dictionary.
A dictionary MUST NOT be declared such that its inheritance hierarchy has a cycle. That is, a dictionary
A cannot inherit from itself, nor can it inherit from another dictionary B that inherits from A, and so on.
dictionary Base {
dictionary-members…
};
dictionary Derived : Base {
dictionary-members…
};
The inherited dictionaries of a given dictionary D is the set of all dictionaries that D inherits from, directly or indirectly. If D does not inherit from another dictionary, then the set is empty. Otherwise, the set includes the dictionary E that D inherits from and all of E’s inherited dictionaries.
A dictionary value of type D can have key–value pairs corresponding to the dictionary members defined on D and on any of D’s
inherited dictionaries. On a given dictionary value, the presence of each dictionary member is optional, unless that member is specified as required. When specified in the dictionary value, a dictionary member is said to be
present, otherwise it is not present. Dictionary members can also optionally have a default value, which is the value to use for the dictionary member when passing a value to a
platform object that does not have a specified value. Dictionary members with default values are always considered to be present.
Each dictionary member (matching
DictionaryMember) is specified as a type (matching Type) followed by an
identifier (given by an identifier token following the type). The identifier is the key name of the key–value pair. If the Type is an identifier followed by ?, then the identifier
MUST identify an interface, enumeration,
callback function or typedef. If the dictionary member type is an identifier not followed by ?, then the identifier MUST identify any one of those definitions or a dictionary.
dictionary identifier {
type identifier;
};
If the identifier is followed by a U+003D EQUALS SIGN ("=") and a value (matching DefaultValue), then that gives the dictionary member its default value.
dictionary identifier {
type identifier = value;
};
When a boolean literal token (true or false), the null token, an integer token, a
float token, one of the three special floating point literal values (Infinity,
-Infinity or NaN), a string token or the two token sequence [] used as the
default value, it is interpreted in the same way as for an operation’s
optional argument default value.
If the type of the dictionary member is an enumeration, then its
default value if specified MUST be one of the enumeration’s values.
If the type of the dictionary member is preceded by the
required keyword, the member is considered a
required dictionary member and must be present on the dictionary. A
required dictionary
member MUST NOT have a default value.
dictionary identifier {
required type identifier;
};
The type of a dictionary member MUST NOT include the dictionary it appears on. A type includes a dictionary D if at least one of the following is true:
- the type is D
- the type is a dictionary that inherits from D
- the type is a nullable type whose inner type includes D
- the type is a sequence type whose element type includes D
- the type is a union type, one of whose member types includes D
- the type is a dictionary, one of whose members or inherited members has a type that includes D
As with interfaces, the IDL for dictionaries can be split into multiple parts by using partial dictionary definitions (matching "partial" Dictionary). The identifier of a partial dictionary definition MUST be the same as the identifier of a dictionary definition. All of the members that appear on each of the partial dictionary definitions are considered to be members of the dictionary itself.
dictionary SomeDictionary {
dictionary-members…
};
partial dictionary SomeDictionary {
dictionary-members…
};
Note
As with partial interface definitions, partial dictionary definitions are intended for use as a specification editorial aide, allowing the definition of an interface to be separated over more than one section of the document, and sometimes multiple documents.
The order of the dictionary members on a given dictionary is such that inherited dictionary members are ordered before non-inherited members, and the dictionary members on the one dictionary definition (including any partial dictionary definitions) are ordered lexicographically by the Unicode codepoints that comprise their identifiers.
Note
For example, with the following definitions:
IDL
dictionary B : A {
long b;
long a;
};
dictionary A {
long c;
long g;
};
dictionary C : B {
long e;
long f;
};
partial dictionary A {
long h;
long d;
};
the order of the dictionary members of a dictionary value of type C is c, d, g, h, a, b, e, f.
Dictionaries are required to have their members ordered because in some language bindings the behavior observed when passing a dictionary value to a platform object depends on the order the dictionary members are fetched. For example, consider the following additional interface:
IDL
interface Something {
void f(A a);
};
and this ECMAScript code:
ECMAScript
var something = getSomething();
var x = 0;
var dict = { };
Object.defineProperty(dict, "d", { get: function() { return ++x; } });
Object.defineProperty(dict, "c", { get: function() { return ++x; } });
something.f(dict);
The order that the dictionary members are fetched in determines what values they will be taken to have. Since the order for
A is defined to be c then d, the value for c will be 1 and the value for d will be 2.
The identifier of a dictionary member MUST NOT be the same as that of another dictionary member defined on the dictionary or on that dictionary’s inherited dictionaries.
Dictionaries MUST NOT be used as the type of an
attribute or
constant.
The following extended attributes are applicable to dictionaries:
[Constructor],
[Exposed].
The following extended attributes are applicable to dictionary members:
[Clamp],
[EnforceRange].
One use of dictionary types is to allow a number of optional arguments to an operation without being constrained as to the order they are specified at the call site. For example, consider the following IDL fragment:
IDL
[Constructor]
interface Point {
attribute double x;
attribute double y;
};
dictionary PaintOptions {
DOMString? fillPattern = "black";
DOMString? strokePattern = null;
Point position;
};
interface GraphicsContext {
void drawRectangle(double width, double height, optional PaintOptions options);
};
In an ECMAScript implementation of the IDL, an Object can be passed in for the optional PaintOptions dictionary:
ECMAScript
var ctx = getGraphicsContext();
ctx.drawRectangle(300, 200, { fillPattern: "red", position: new Point(10, 10) });
Both fillPattern and strokePattern are given default values, so if they are omitted, the definition of drawRectangle can assume that they have the given default values and not include explicit wording to handle their non-presence.
3.10 Types
This section lists the types supported by Web IDL, the set of values corresponding to each type, and how constants of that type are represented.
The following types are known as integer types:
byte,
octet,
short,
unsigned short,
long,
unsigned long,
long long and
unsigned long long.
The following types are known as numeric types: the integer types,
float,
unresticted float,
double and
unrestricted double.
The primitive types are
boolean and the numeric types.
The string types are
DOMString, all enumeration types,
ByteString and USVString.
The exception types are
Error and DOMException.
The typed array types are
Int8Array,
Int16Array,
Int32Array,
Uint8Array,
Uint16Array,
Uint32Array,
Uint8ClampedArray,
Float32Array and
Float64Array.
The buffer source types are ArrayBuffer,
DataView, and the typed array types.
The object type, all interface types and the exception types are known as object types.
Every type has a type name, which is a string, not necessarily unique, that identifies the type. Each sub-section below defines what the type name is for each type.
When conversions are made from language binding specific types to IDL types in order to invoke an operation or assign a value to an attribute, all conversions necessary will be performed before the specified functionality of the operation or attribute assignment is carried out. If the conversion cannot be performed, then the operation will not run or the attribute will not be updated. In some language bindings, type conversions could result in an exception being thrown. In such cases, these exceptions will be propagated to the code that made the attempt to invoke the operation or assign to the attribute.
3.10.1 any
The any type is the union of all other possible non-
union types. Its type name is “Any”.
The any type is like a discriminated union type, in that each of its values has a specific non-any type associated with it. For example, one value of the
any type is the
unsigned long 150, while another is the long 150. These are distinct values.
The particular type of an any value is known as its specific type. (Values of union types also have
specific types.)
3.10.2 boolean
The boolean type has two values:
true and false.
boolean constant values in IDL are represented with the true and
false tokens.
The type name of the
boolean type is “Boolean”.
3.10.3 byte
The byte type is a signed integer type that has values in the range [−128, 127].
byte constant values in IDL are represented with integer tokens.
The type name of the
byte type is “Byte”.
3.10.4 octet
The octet type is an unsigned integer type that has values in the range [0, 255].
octet constant values in IDL are represented with integer tokens.
The type name of the
octet type is “Octet”.
3.10.5 short
The short type is a signed integer type that has values in the range [−32768, 32767].
short constant values in IDL are represented with integer tokens.
The type name of the
short type is “Short”.
3.10.7 long
The long type is a signed integer type that has values in the range [−2147483648, 2147483647].
long constant values in IDL are represented with integer tokens.
The type name of the
long type is “Long”.
3.10.9 long long
The long long type is a signed integer type that has values in the range [−9223372036854775808, 9223372036854775807].
long long constant values in IDL are represented with integer tokens.
The type name of the
long long type is “LongLong”.
3.10.11 float
The float type is a floating point numeric type that corresponds to the set of finite single-precision 32 bit IEEE 754 floating point numbers. [IEEE-754]
float constant values in IDL are represented with float tokens.
The type name of the
float type is “Float”.
Warning
Unless there are specific reasons to use a 32 bit floating point type, specifications SHOULD use
double rather than float, since the set of values that a double can represent more closely matches an ECMAScript Number.
3.10.13 double
The double type is a floating point numeric type that corresponds to the set of finite double-precision 64 bit IEEE 754 floating point numbers. [IEEE-754]
double constant values in IDL are represented with float tokens.
The type name of the
double type is “Double”.
3.10.15 DOMString
The DOMString type corresponds to the set of all possible sequences of code units. Such sequences are commonly interpreted as UTF-16 encoded strings [RFC2781] although this is not required. While DOMString is defined to be an OMG IDL boxed
sequence<unsigned short> valuetype in DOM Level 3 Core ([
DOM3CORE], section 1.2.1), this document defines DOMString to be an intrinsic type so as to avoid special casing that sequence type in various situations where a string is required.
Note
Note also that null is not a value of type DOMString. To allow null, a
nullable DOMString, written as DOMString? in IDL, needs to be used.
Nothing in this specification requires a DOMString value to be a valid UTF-16 string. For example, a DOMString value might include unmatched surrogate pair characters. However, authors of specifications using Web IDL might want to obtain a sequence of
Unicode scalar values given a particular sequence of
code units. The following algorithm defines a way to
convert a DOMString to a sequence of Unicode scalar values:
- Let S be the DOMString value.
- Let n be the length of S.
- Initialize i to 0.
- Initialize U to be an empty sequence of Unicode characters.
- While i < n:
- Let c be the code unit in S at index i.
- Depending on the value of c:
- c < 0xD800 or c > 0xDFFF
- Append to U the Unicode character with code point c.
- 0xDC00 ≤ c ≤ 0xDFFF
- Append to U a U+FFFD REPLACEMENT CHARACTER.
- 0xD800 ≤ c ≤ 0xDBFF
-
- If i = n−1, then append to U a U+FFFD REPLACEMENT CHARACTER.
- Otherwise, i < n−1:
- Let d be the code unit in S at index
i+1.
- If 0xDC00 ≤ d ≤ 0xDFFF, then:
- Let a be c & 0x3FF.
- Let b be d & 0x3FF.
- Append to U the Unicode character with code point 216+210a+b.
- Set i to i+1.
- Otherwise, d < 0xDC00 or d > 0xDFFF. Append to U a U+FFFD REPLACEMENT CHARACTER.
- Set i to i+1.
- Return U.
There is no way to represent a constant DOMString value in IDL, although DOMString dictionary member and operation optional argument default values can be specified using a string literal.
The type name of the
DOMString type is “String”.
3.10.16 ByteString
The ByteString type corresponds to the set of all possible sequences of bytes. Such sequences might be interpreted as UTF-8 encoded strings [RFC3629] or strings in some other 8-bit-per-code-unit encoding, although this is not required.
There is no way to represent a constant ByteString value in IDL.
The type name of the
ByteString type is “ByteString”.
Warning
Specifications SHOULD only use
ByteString for interfacing with protocols that use bytes and strings interchangably, such as HTTP. In general, strings SHOULD be represented with
DOMString values, even if it is expected that values of the string will always be in ASCII or some 8 bit character encoding. Sequences or Typed Arrays with octet or byte elements SHOULD be used for holding 8 bit data rather than ByteString. [
TYPEDARRAYS]
3.10.18 object
The object type corresponds to the set of all possible non-null object references.
There is no way to represent a constant object value in IDL.
To denote a type that includes all possible object references plus the
null value, use the nullable type
object?.
The type name of the
object type is “Object”.
3.10.19 Interface types
An identifier that identifies an interface is used to refer to a type that corresponds to the set of all possible non-null references to objects that implement that interface.
For non-callback interfaces, an IDL value of the interface type is represented just by an object reference. For callback interfaces, an IDL value of the interface type is represented by a tuple of an object reference and a callback context. The callback context is a language binding specific value, and is used to store information about the execution context at the time the language binding specific object reference is converted to an IDL value.
There is no way to represent a constant object reference value for a particular interface type in IDL.
To denote a type that includes all possible references to objects implementing the given interface plus the null value, use a nullable type.
The type name of an interface type is the identifier of the interface.
3.10.20 Dictionary types
An identifier that identifies a dictionary is used to refer to a type that corresponds to the set of all dictionaries that adhere to the dictionary definition.
There is no way to represent a constant dictionary value in IDL.
The type name of a dictionary type is the identifier of the dictionary.
3.10.22 Callback function types
An identifier that identifies a callback function is used to refer to a type whose values are references to objects that are functions with the given signature.
An IDL value of the callback function type is represented by a tuple of an object reference and a callback context.
There is no way to represent a constant callback function value in IDL.
The type name of a callback function type is the identifier of the callback function.
3.10.23 Nullable types — T?
A nullable type is an IDL type constructed from an existing type (called the inner type), which just allows the additional value null to be a member of its set of values. Nullable types are represented in IDL by placing a U+003F QUESTION MARK ("?") character after an existing type. The inner type MUST NOT be any, another nullable type, or a union type that itself has includes a nullable type or has a dictionary type as one of its
flattened member types.
Note
Although dictionary types can in general be nullable, they cannot when used as the type of an operation argument or a dictionary member.
Nullable type constant values in IDL are represented in the same way that constant values of their inner type would be represented, or with the null token.
The type name of a nullable type is the concatenation of the type name of the inner type T and the string “OrNull”.
For example, a type that allows the values true,
false and null is written as boolean?:
IDL
interface MyConstants {
const boolean? ARE_WE_THERE_YET = false;
};
The following interface has two
attributes: one whose value can be a DOMString or the null value, and another whose value can be a reference to a Node object or the null value:
IDL
interface Node {
readonly attribute DOMString? namespaceURI;
readonly attribute Node? parentNode;
};
3.10.24 Sequences — sequence<T>
The sequence<T> type is a parameterized type whose values are (possibly zero-length) sequences of values of type T.
Sequences are always passed by value. In language bindings where a sequence is represented by an object of some kind, passing a sequence to a platform object will not result in a reference to the sequence being kept by that object. Similarly, any sequence returned from a platform object will be a copy and modifications made to it will not be visible to the platform object.
There is no way to represent a constant sequence value in IDL.
Sequences MUST NOT be used as the type of an attribute or
constant.
Note
This restriction exists so that it is clear to specification writers and API users that sequences are copied rather than having references to them passed around. Instead of a writable attribute of a sequence type, it is suggested that a pair of operations to get and set the sequence is used.
The type name of a sequence type is the concatenation of the type name for T and the string “Sequence”.
3.10.25 Promise types — Promise<T>
A promise type is a parameterized type whose values are references to objects that “is used as a place holder for the eventual results of a deferred (and possibly asynchronous) computation result of an asynchronous operation” [ECMA-262]. See section 25.4 of the ECMAScript specification for details on the semantics of promise objects.
There is no way to represent a promise value in IDL.
The type name of a promise type is the concatenation of the type name for T and the string “Promise”.
3.10.26 Union types
A union type is a type whose set of values is the union of those in two or more other types. Union types (matching
UnionType) are written as a series of types separated by the or keyword with a set of surrounding parentheses. The types which comprise the union type are known as the union’s member types.
Note
For example, you might write (Node or DOMString) or (double or sequence<double>). When applying a
? suffix to a
union type as a whole, it is placed after the closing parenthesis, as in (Node or DOMString)?.
Note that the member types of a union type do not descend into nested union types. So for
(double or (sequence<long> or Event) or (Node or DOMString)?) the member types are double, (sequence<long> or Event) and
(Node or DOMString)?.
Like the any type, values of union types have a specific type, which is the particular member type that matches the value.
The flattened member types of a union type is a set of types determined as follows:
- Let T be the union type.
- Initialize S to ∅.
- For each member type U of T:
- If U is a nullable type, then set U to be the inner type of U.
- If U is a union type, then add to S the flattened member types of U.
- Otherwise, U is not a union type. Add U to S.
- Return S.
Note
For example, the flattened member types of the union type
(Node or (sequence<long> or Event) or (XMLHttpRequest or DOMString)? or sequence<(sequence<double> or NodeList)>) are the six types Node, sequence<long>, Event,
XMLHttpRequest, DOMString and
sequence<(sequence<double> or NodeList)>.
The number of nullable member types of a union type is an integer determined as follows:
- Let T be the union type.
- Initialize n to 0.
- For each member type U of T:
- If U is a nullable type, then:
- Set n to n + 1.
- Set U to be the inner type of U.
- If U is a union type, then:
- Let m be the number
of nullable member types of U.
- Set n to n + m.
- Return n.
The any type MUST NOT be used as a union member type.
The number of nullable member types of a union type MUST be 0 or 1, and if it is 1 then the union type MUST also not have a dictionary type in its
flattened member types.
A type includes a nullable type if:
Each pair of flattened member types in a union type, T and U,
MUST be distinguishable.
Union type constant values in IDL are represented in the same way that constant values of their
member types would be represented.
The type name of a union type is formed by taking the type names of each member type, in order, and joining them with the string “Or”.
3.10.29 Buffer source types
There are a number of types that correspond to sets of all possible non-null references to objects that represent a buffer of data or a view on to a buffer of data. The table below lists these types and the kind of buffer or view they represent.
| Type |
Kind of buffer |
| ArrayBuffer |
An object that holds a pointer (which may be null) to a buffer of a fixed number of bytes |
| DataView |
A view on to an ArrayBuffer that allows typed access to integers and floating point values stored at arbitrary offsets into the buffer |
Int8Array,
Int16Array,
Int32Array |
A view on to an ArrayBuffer that exposes it as an array of two’s complement signed integers of the given size in bits |
Uint8Array,
Uint16Array,
Uint32Array |
A view on to an ArrayBuffer that exposes it as an array of unsigned integers of the given size in bits |
| Uint8ClampedArray |
A view on to an ArrayBuffer that exposes it as an array of unsigned 8 bit integers with clamped conversions |
Float32Array,
Float64Array |
A view on to an ArrayBuffer that exposes it as an array of IEEE 754 floating point numbers of the given size in bits |
Note
These types all correspond to classes defined in ECMAScript.
To detach an ArrayBuffer is to set its buffer pointer to null.
There is no way to represent a constant value of any of these types in IDL.
The type name of all of these types is the name of the type itself.
At the specification prose level, IDL buffer source types are simply references to objects. To inspect or manipulate the bytes inside the buffer, specification prose MUST first either
get a reference to the bytes held by the buffer source or get a copy of the bytes held by the buffer source. With a reference to the buffer source’s bytes, specification prose can get or set individual byte values using that reference.
Warning
Extreme care must be taken when writing specification text that gets a reference to the bytes held by a buffer source, as the underyling data can easily be changed by the script author or other APIs at unpredictable times. If you are using a buffer source type as an operation argument to obtain a chunk of binary data that will not be modified, it is strongly recommended to get a copy of the buffer source’s bytes at the beginning of the prose defining the operation.
Requiring prose to explicitly get a reference to or copy of the bytes is intended to help specification reviewers look for problematic uses of these buffer source types.
Note
When designing APIs that take a buffer, it is recommended to use the
BufferSource typedef rather than ArrayBuffer or any of the view types.
When designing APIs that create and return a buffer, it is recommended to use the ArrayBuffer type rather than
Uint8Array.
Attempting to get a reference to or
get a copy of the bytes held by a buffer source when the ArrayBuffer has been detached will fail in a language binding-specific manner.
Note
See section 4.2.30 below for how interacting with buffer source types works in the ECMAScript language binding.