Living Standard — Last Updated 17 December 2024
プラットフォームオブジェクトを含むJavaScriptオブジェクトをレルムの境界を越えて渡すことをサポートするために、この仕様では、オブジェクトをシリアル化および逆シリアル化するための次のインフラを定義する。これには、基になるデータをコピーする代わりに転送する場合も含まれる。総称して、このシリアル化/逆シリアル化プロセスは"構造化クローン"と呼ばれるが、ほとんどのAPIは別々のシリアル化と逆シリアル化のステップを実行する。(注目すべき例外はstructuredClone()
メソッドである。)
This section uses the terminology and typographic conventions from the JavaScript specification. [JAVASCRIPT]
/developer.mozilla.org/en-US/docs/Glossary/Serializable_object
/developer.mozilla.org/en-US/docs/Glossary/Serializable_object
/developer.mozilla.org/en-US/docs/Glossary/Serializable_object
/developer.mozilla.org/en-US/docs/Glossary/Serializable_object
/developer.mozilla.org/en-US/docs/Glossary/Serializable_object
/developer.mozilla.org/en-US/docs/Glossary/Serializable_object
/developer.mozilla.org/en-US/docs/Glossary/Serializable_object
シリアル化可能なオブジェクトは、特定のrealmから独立した方法で、シリアル化され、後で逆シリアル化されることをサポートする。 これにより、それらをディスクに保存して後で復元したり、エージェントやエージェントクラスターの境界を越えて複製したりすることができる。
すべてのオブジェクトがシリアル化可能なオブジェクトであるとは限らない。また、シリアル化可能なオブジェクトであるオブジェクトのすべての側面が、シリアル化されるときに必ずしも保持されるわけではない。
Platform objects can be serializable objects if their primary interface is decorated with the [Serializable]
IDL extended attribute. Such interfaces must also define the following algorithms:
A set of steps that serializes the data in value into fields of serialized. The resulting data serialized into serialized must be independent of any realm.
These steps may throw an exception if serialization is not possible.
These steps may perform a sub-serialization to serialize nested data structures. They should not call StructuredSerialize directly, as doing so will omit the important memory argument.
The introduction of these steps should omit mention of the forStorage argument if it is not relevant to the algorithm.
A set of steps that deserializes the data in serialized, using it to set up value as appropriate. value will be a newly-created instance of the platform object type in question, with none of its internal data set up; setting that up is the job of these steps.
These steps may throw an exception if deserialization is not possible.
These steps may perform a sub-deserialization to deserialize nested data structures. They should not call StructuredDeserialize directly, as doing so will omit the important targetRealm and memory arguments.
It is up to the definition of individual platform objects to determine what data is serialized and deserialized by these steps. Typically the steps are very symmetric.
The [Serializable]
extended attribute must take no arguments, and must only appear on an interface. It must not appear more than once on an interface.
For a given platform object, only the object's primary interface is considered during the (de)serialization process. Thus, if inheritance is involved in defining the interface, each [Serializable]
-annotated interface in the inheritance chain needs to define standalone serialization steps and deserialization steps, including taking into account any important data that might come from inherited interfaces.
Let's say we were defining a platform object Person
, which had associated with it two pieces of associated data:
a name value, which is a string; and
a best friend value, which is either another Person
instance or null.
We could then define Person
instances to be serializable objects by annotating the Person
interface with the [Serializable]
extended attribute, and defining the following accompanying algorithms:
Set serialized.[[Name]] to value's associated name value.
Let serializedBestFriend be the sub-serialization of value's associated best friend value.
Set serialized.[[BestFriend]] to serializedBestFriend.
Set value's associated name value to serialized.[[Name]].
Let deserializedBestFriend be the sub-deserialization of serialized.[[BestFriend]].
Set value's associated best friend value to deserializedBestFriend.
Objects defined in the JavaScript specification are handled by the StructuredSerialize abstract operation directly.
Originally, this specification defined the concept of "cloneable objects", which could be cloned from one realm to another. However, to better specify the behavior of certain more complex situations, the model was updated to make the serialization and deserialization explicit.
転送可能なオブジェクトは、エージェント間での転送をサポートする。 転送とは、基になるデータへの参照を共有し、転送されるオブジェクトを切り離しながら、オブジェクトを効果的に再作成することである。これは、高価なリソースの所有権を譲渡するのに役立つ。すべてのオブジェクトが転送可能なオブジェクトであるとは限らない。また、転送可能なオブジェクトであるオブジェクトのすべての側面が、転送時に必ずしも保持されるわけではない。
転送は、不可逆的かつ非べき等な操作である。一度転送されたものは、二度と転送することはできず、実際に使用することもできない。
Platform objects can be transferable objects if their primary interface is decorated with the [Transferable]
IDL extended attribute. Such interfaces must also define the following algorithms:
A set of steps that transfers the data in value into fields of dataHolder. The resulting data held in dataHolder must be independent of any realm.
These steps may throw an exception if transferral is not possible.
A set of steps that receives the data in dataHolder, using it to set up value as appropriate. value will be a newly-created instance of the platform object type in question, with none of its internal data set up; setting that up is the job of these steps.
These steps may throw an exception if it is not possible to receive the transfer.
It is up to the definition of individual platform objects to determine what data is transferred by these steps. Typically the steps are very symmetric.
The [Transferable]
extended attribute must take no arguments, and must only appear on an interface. It must not appear more than once on an interface.
For a given platform object, only the object's primary interface is considered during the transferring process. Thus, if inheritance is involved in defining the interface, each [Transferable]
-annotated interface in the inheritance chain needs to define standalone transfer steps and transfer-receiving steps, including taking into account any important data that might come from inherited interfaces.
Platform objects that are transferable objects have a [[Detached]] internal slot. This is used to ensure that once a platform object has been transferred, it cannot be transferred again.
Objects defined in the JavaScript specification are handled by the StructuredSerializeWithTransfer abstract operation directly.
The StructuredSerializeInternal abstract operation takes as input a JavaScript value value and serializes it to a realm-independent form, represented here as a Record. This serialized form has all the information necessary to later deserialize into a new JavaScript value in a different realm.
This process can throw an exception, for example when trying to serialize un-serializable objects.
If memory was not supplied, let memory be an empty map.
The purpose of the memory map is to avoid serializing objects twice. This ends up preserving cycles and the identity of duplicate objects in graphs.
If memory[value] exists, then return memory[value].
Let deep be false.
If value is undefined, null, a Boolean, a Number, a BigInt, or a String, then return { [[Type]]: "primitive", [[Value]]: value }.
If value is a Symbol, then throw a "DataCloneError
" DOMException
.
Let serialized be an uninitialized value.
If value has a [[BooleanData]] internal slot, then set serialized to { [[Type]]: "Boolean", [[BooleanData]]: value.[[BooleanData]] }.
Otherwise, if value has a [[NumberData]] internal slot, then set serialized to { [[Type]]: "Number", [[NumberData]]: value.[[NumberData]] }.
Otherwise, if value has a [[BigIntData]] internal slot, then set serialized to { [[Type]]: "BigInt", [[BigIntData]]: value.[[BigIntData]] }.
Otherwise, if value has a [[StringData]] internal slot, then set serialized to { [[Type]]: "String", [[StringData]]: value.[[StringData]] }.
Otherwise, if value has a [[DateValue]] internal slot, then set serialized to { [[Type]]: "Date", [[DateValue]]: value.[[DateValue]] }.
Otherwise, if value has a [[RegExpMatcher]] internal slot, then set serialized to { [[Type]]: "RegExp", [[RegExpMatcher]]: value.[[RegExpMatcher]], [[OriginalSource]]: value.[[OriginalSource]], [[OriginalFlags]]: value.[[OriginalFlags]] }.
Otherwise, if value has an [[ArrayBufferData]] internal slot, then:
If IsSharedArrayBuffer(value) is true, then:
If the current settings object's cross-origin isolated capability is false, then throw a "DataCloneError
" DOMException
.
This check is only needed when serializing (and not when deserializing) as the cross-origin isolated capability cannot change over time and a SharedArrayBuffer
cannot leave an agent cluster.
If forStorage is true, then throw a "DataCloneError
" DOMException
.
If value has an [[ArrayBufferMaxByteLength]] internal slot, then set serialized to { [[Type]]: "GrowableSharedArrayBuffer", [[ArrayBufferData]]: value.[[ArrayBufferData]], [[ArrayBufferByteLengthData]]: value.[[ArrayBufferByteLengthData]], [[ArrayBufferMaxByteLength]]: value.[[ArrayBufferMaxByteLength]], [[AgentCluster]]: the surrounding agent's agent cluster }.
Otherwise, set serialized to { [[Type]]: "SharedArrayBuffer", [[ArrayBufferData]]: value.[[ArrayBufferData]], [[ArrayBufferByteLength]]: value.[[ArrayBufferByteLength]], [[AgentCluster]]: the surrounding agent's agent cluster }.
Otherwise:
If IsDetachedBuffer(value) is true, then throw a "DataCloneError
" DOMException
.
Let size be value.[[ArrayBufferByteLength]].
Let dataCopy be ? CreateByteDataBlock(size).
This can throw a RangeError
exception upon allocation failure.
Perform CopyDataBlockBytes(dataCopy, 0, value.[[ArrayBufferData]], 0, size).
If value has an [[ArrayBufferMaxByteLength]] internal slot, then set serialized to { [[Type]]: "ResizableArrayBuffer", [[ArrayBufferData]]: dataCopy, [[ArrayBufferByteLength]]: size, [[ArrayBufferMaxByteLength]]: value.[[ArrayBufferMaxByteLength]] }.
Otherwise, set serialized to { [[Type]]: "ArrayBuffer", [[ArrayBufferData]]: dataCopy, [[ArrayBufferByteLength]]: size }.
Otherwise, if value has a [[ViewedArrayBuffer]] internal slot, then:
If IsArrayBufferViewOutOfBounds(value) is true, then throw a "DataCloneError
" DOMException
.
Let buffer be the value of value's [[ViewedArrayBuffer]] internal slot.
Let bufferSerialized be ? StructuredSerializeInternal(buffer, forStorage, memory).
Assert: bufferSerialized.[[Type]] is "ArrayBuffer", "ResizableArrayBuffer", "SharedArrayBuffer", or "GrowableSharedArrayBuffer".
If value has a [[DataView]] internal slot, then set serialized to { [[Type]]: "ArrayBufferView", [[Constructor]]: "DataView", [[ArrayBufferSerialized]]: bufferSerialized, [[ByteLength]]: value.[[ByteLength]], [[ByteOffset]]: value.[[ByteOffset]] }.
Otherwise:
Assert: value has a [[TypedArrayName]] internal slot.
Set serialized to { [[Type]]: "ArrayBufferView", [[Constructor]]: value.[[TypedArrayName]], [[ArrayBufferSerialized]]: bufferSerialized, [[ByteLength]]: value.[[ByteLength]], [[ByteOffset]]: value.[[ByteOffset]], [[ArrayLength]]: value.[[ArrayLength]] }.
Otherwise, if value has [[MapData]] internal slot, then:
Set serialized to { [[Type]]: "Map", [[MapData]]: a new empty List }.
Set deep to true.
Otherwise, if value has [[SetData]] internal slot, then:
Set serialized to { [[Type]]: "Set", [[SetData]]: a new empty List }.
Set deep to true.
Otherwise, if value has an [[ErrorData]] internal slot and value is not a platform object, then:
Let name be ? Get(value, "name").
If name is not one of "Error", "EvalError", "RangeError", "ReferenceError", "SyntaxError", "TypeError", or "URIError", then set name to "Error".
Let valueMessageDesc be ? value.[[GetOwnProperty]]("message
").
Let message be undefined if IsDataDescriptor(valueMessageDesc) is false, and ? ToString(valueMessageDesc.[[Value]]) otherwise.
Set serialized to { [[Type]]: "Error", [[Name]]: name, [[Message]]: message }.
User agents should attach a serialized representation of any interesting accompanying data which are not yet specified, notably the stack
property, to serialized.
See the Error Stacks proposal for in-progress work on specifying this data. [JSERRORSTACKS]
Otherwise, if value is an Array exotic object, then:
Let valueLenDescriptor be ? OrdinaryGetOwnProperty(value, "length
").
Let valueLen be valueLenDescriptor.[[Value]].
Set serialized to { [[Type]]: "Array", [[Length]]: valueLen, [[Properties]]: a new empty List }.
Set deep to true.
Otherwise, if value is a platform object that is a serializable object:
If value has a [[Detached]] internal slot whose value is true, then throw a "DataCloneError
" DOMException
.
Let typeString be the identifier of the primary interface of value.
Set serialized to { [[Type]]: typeString }.
Set deep to true.
Otherwise, if value is a platform object, then throw a "DataCloneError
" DOMException
.
Otherwise, if IsCallable(value) is true, then throw a "DataCloneError
" DOMException
.
Otherwise, if value has any internal slot other than [[Prototype]], [[Extensible]], or [[PrivateElements]], then throw a "DataCloneError
" DOMException
.
For instance, a [[PromiseState]] or [[WeakMapData]] internal slot.
Otherwise, if value is an exotic object and value is not the %Object.prototype% intrinsic object associated with any realm, then throw a "DataCloneError
" DOMException
.
For instance, a proxy object.
Otherwise:
Set serialized to { [[Type]]: "Object", [[Properties]]: a new empty List }.
Set deep to true.
%Object.prototype% will end up being handled via this step and subsequent steps. The end result is that its exoticness is ignored, and after deserialization the result will be an empty object (not an immutable prototype exotic object).
Set memory[value] to serialized.
If deep is true, then:
If value has a [[MapData]] internal slot, then:
Let copiedList be a new empty List.
For each Record { [[Key]], [[Value]] } entry of value.[[MapData]]:
For each Record { [[Key]], [[Value]] } entry of copiedList:
Let serializedKey be ? StructuredSerializeInternal(entry.[[Key]], forStorage, memory).
Let serializedValue be ? StructuredSerializeInternal(entry.[[Value]], forStorage, memory).
Append { [[Key]]: serializedKey, [[Value]]: serializedValue } to serialized.[[MapData]].
Otherwise, if value has a [[SetData]] internal slot, then:
Let copiedList be a new empty List.
For each entry of value.[[SetData]]:
If entry is not the special value empty, append entry to copiedList.
For each entry of copiedList:
Let serializedEntry be ? StructuredSerializeInternal(entry, forStorage, memory).
Append serializedEntry to serialized.[[SetData]].
Otherwise, if value is a platform object that is a serializable object, then perform the serialization steps for value's primary interface, given value, serialized, and forStorage.
The serialization steps may need to perform a sub-serialization. This is an operation which takes as input a value subValue, and returns StructuredSerializeInternal(subValue, forStorage, memory). (In other words, a sub-serialization is a specialization of StructuredSerializeInternal to be consistent within this invocation.)
Otherwise, for each key in ! EnumerableOwnProperties(value, key):
If ! HasOwnProperty(value, key) is true, then:
Let inputValue be ? value.[[Get]](key, value).
Let outputValue be ? StructuredSerializeInternal(inputValue, forStorage, memory).
Append { [[Key]]: key, [[Value]]: outputValue } to serialized.[[Properties]].
Return serialized.
It's important to realize that the Records produced by StructuredSerializeInternal might contain "pointers" to other records that create circular references. For example, when we pass the following JavaScript object into StructuredSerializeInternal:
const o = {};
o. myself = o;
it produces the following result:
{ [[Type]]: "Object", [[Properties]]: « { [[Key]]: "myself", [[Value]]: <a pointer to this whole structure> } » }
Return ? StructuredSerializeInternal(value, false).
Return ? StructuredSerializeInternal(value, true).
The StructuredDeserialize abstract operation takes as input a Record serialized, which was previously produced by StructuredSerialize or StructuredSerializeForStorage, and deserializes it into a new JavaScript value, created in targetRealm.
This process can throw an exception, for example when trying to allocate memory for the new objects (especially ArrayBuffer
objects).
If memory was not supplied, let memory be an empty map.
The purpose of the memory map is to avoid deserializing objects twice. This ends up preserving cycles and the identity of duplicate objects in graphs.
If memory[serialized] exists, then return memory[serialized].
Let deep be false.
Let value be an uninitialized value.
If serialized.[[Type]] is "primitive", then set value to serialized.[[Value]].
Otherwise, if serialized.[[Type]] is "Boolean", then set value to a new Boolean object in targetRealm whose [[BooleanData]] internal slot value is serialized.[[BooleanData]].
Otherwise, if serialized.[[Type]] is "Number", then set value to a new Number object in targetRealm whose [[NumberData]] internal slot value is serialized.[[NumberData]].
Otherwise, if serialized.[[Type]] is "BigInt", then set value to a new BigInt object in targetRealm whose [[BigIntData]] internal slot value is serialized.[[BigIntData]].
Otherwise, if serialized.[[Type]] is "String", then set value to a new String object in targetRealm whose [[StringData]] internal slot value is serialized.[[StringData]].
Otherwise, if serialized.[[Type]] is "Date", then set value to a new Date object in targetRealm whose [[DateValue]] internal slot value is serialized.[[DateValue]].
Otherwise, if serialized.[[Type]] is "RegExp", then set value to a new RegExp object in targetRealm whose [[RegExpMatcher]] internal slot value is serialized.[[RegExpMatcher]], whose [[OriginalSource]] internal slot value is serialized.[[OriginalSource]], and whose [[OriginalFlags]] internal slot value is serialized.[[OriginalFlags]].
Otherwise, if serialized.[[Type]] is "SharedArrayBuffer", then:
If targetRealm's corresponding agent cluster is not serialized.[[AgentCluster]], then throw a "DataCloneError
" DOMException
.
Otherwise, set value to a new SharedArrayBuffer object in targetRealm whose [[ArrayBufferData]] internal slot value is serialized.[[ArrayBufferData]] and whose [[ArrayBufferByteLength]] internal slot value is serialized.[[ArrayBufferByteLength]].
Otherwise, if serialized.[[Type]] is "GrowableSharedArrayBuffer", then:
If targetRealm's corresponding agent cluster is not serialized.[[AgentCluster]], then throw a "DataCloneError
" DOMException
.
Otherwise, set value to a new SharedArrayBuffer object in targetRealm whose [[ArrayBufferData]] internal slot value is serialized.[[ArrayBufferData]], whose [[ArrayBufferByteLengthData]] internal slot value is serialized.[[ArrayBufferByteLengthData]], and whose [[ArrayBufferMaxByteLength]] internal slot value is serialized.[[ArrayBufferMaxByteLength]].
Otherwise, if serialized.[[Type]] is "ArrayBuffer", then set value to a new ArrayBuffer object in targetRealm whose [[ArrayBufferData]] internal slot value is serialized.[[ArrayBufferData]], and whose [[ArrayBufferByteLength]] internal slot value is serialized.[[ArrayBufferByteLength]].
If this throws an exception, catch it, and then throw a "DataCloneError
" DOMException
.
This step might throw an exception if there is not enough memory available to create such an ArrayBuffer object.
Otherwise, if serialized.[[Type]] is "ResizableArrayBuffer", then set value to a new ArrayBuffer object in targetRealm whose [[ArrayBufferData]] internal slot value is serialized.[[ArrayBufferData]], whose [[ArrayBufferByteLength]] internal slot value is serialized.[[ArrayBufferByteLength]], and whose [[ArrayBufferMaxByteLength]] internal slot value is serialized.[[ArrayBufferMaxByteLength]].
If this throws an exception, catch it, and then throw a "DataCloneError
" DOMException
.
This step might throw an exception if there is not enough memory available to create such an ArrayBuffer object.
Otherwise, if serialized.[[Type]] is "ArrayBufferView", then:
Let deserializedArrayBuffer be ? StructuredDeserialize(serialized.[[ArrayBufferSerialized]], targetRealm, memory).
If serialized.[[Constructor]] is "DataView", then set value to a new DataView object in targetRealm whose [[ViewedArrayBuffer]] internal slot value is deserializedArrayBuffer, whose [[ByteLength]] internal slot value is serialized.[[ByteLength]], and whose [[ByteOffset]] internal slot value is serialized.[[ByteOffset]].
Otherwise, set value to a new typed array object in targetRealm, using the constructor given by serialized.[[Constructor]], whose [[ViewedArrayBuffer]] internal slot value is deserializedArrayBuffer, whose [[TypedArrayName]] internal slot value is serialized.[[Constructor]], whose [[ByteLength]] internal slot value is serialized.[[ByteLength]], whose [[ByteOffset]] internal slot value is serialized.[[ByteOffset]], and whose [[ArrayLength]] internal slot value is serialized.[[ArrayLength]].
Otherwise, if serialized.[[Type]] is "Map", then:
Set value to a new Map object in targetRealm whose [[MapData]] internal slot value is a new empty List.
Set deep to true.
Otherwise, if serialized.[[Type]] is "Set", then:
Set value to a new Set object in targetRealm whose [[SetData]] internal slot value is a new empty List.
Set deep to true.
Otherwise, if serialized.[[Type]] is "Array", then:
Let outputProto be targetRealm.[[Intrinsics]].[[%Array.prototype%]].
Set value to ! ArrayCreate(serialized.[[Length]], outputProto).
Set deep to true.
Otherwise, if serialized.[[Type]] is "Object", then:
Set value to a new Object in targetRealm.
Set deep to true.
Otherwise, if serialized.[[Type]] is "Error", then:
Let prototype be %Error.prototype%.
If serialized.[[Name]] is "EvalError", then set prototype to %EvalError.prototype%.
If serialized.[[Name]] is "RangeError", then set prototype to %RangeError.prototype%.
If serialized.[[Name]] is "ReferenceError", then set prototype to %ReferenceError.prototype%.
If serialized.[[Name]] is "SyntaxError", then set prototype to %SyntaxError.prototype%.
If serialized.[[Name]] is "TypeError", then set prototype to %TypeError.prototype%.
If serialized.[[Name]] is "URIError", then set prototype to %URIError.prototype%.
Let message be serialized.[[Message]].
Set value to OrdinaryObjectCreate(prototype, « [[ErrorData]] »).
Let messageDesc be PropertyDescriptor{ [[Value]]: message, [[Writable]]: true, [[Enumerable]]: false, [[Configurable]]: true }.
If message is not undefined, then perform ! OrdinaryDefineOwnProperty(value, "message
", messageDesc).
Any interesting accompanying data attached to serialized should be deserialized and attached to value.
Otherwise:
Let interfaceName be serialized.[[Type]].
If the interface identified by interfaceName is not exposed in targetRealm, then throw a "DataCloneError
" DOMException
.
Set value to a new instance of the interface identified by interfaceName, created in targetRealm.
Set deep to true.
Set memory[serialized] to value.
If deep is true, then:
If serialized.[[Type]] is "Map", then:
For each Record { [[Key]], [[Value]] } entry of serialized.[[MapData]]:
Let deserializedKey be ? StructuredDeserialize(entry.[[Key]], targetRealm, memory).
Let deserializedValue be ? StructuredDeserialize(entry.[[Value]], targetRealm, memory).
Append { [[Key]]: deserializedKey, [[Value]]: deserializedValue } to value.[[MapData]].
Otherwise, if serialized.[[Type]] is "Set", then:
For each entry of serialized.[[SetData]]:
Let deserializedEntry be ? StructuredDeserialize(entry, targetRealm, memory).
Append deserializedEntry to value.[[SetData]].
Otherwise, if serialized.[[Type]] is "Array" or "Object", then:
For each Record { [[Key]], [[Value]] } entry of serialized.[[Properties]]:
Let deserializedValue be ? StructuredDeserialize(entry.[[Value]], targetRealm, memory).
Let result be ! CreateDataProperty(value, entry.[[Key]], deserializedValue).
Assert: result is true.
Otherwise:
Perform the appropriate deserialization steps for the interface identified by serialized.[[Type]], given serialized, value, and targetRealm.
The deserialization steps may need to perform a sub-deserialization. This is an operation which takes as input a previously-serialized Record subSerialized, and returns StructuredDeserialize(subSerialized, targetRealm, memory). (In other words, a sub-deserialization is a specialization of StructuredDeserialize to be consistent within this invocation.)
Return value.
Let memory be an empty map.
In addition to how it is used normally by StructuredSerializeInternal, in this algorithm memory is also used to ensure that StructuredSerializeInternal ignores items in transferList, and let us do our own handling instead.
For each transferable of transferList:
If transferable has neither an [[ArrayBufferData]] internal slot nor a [[Detached]] internal slot, then throw a "DataCloneError
" DOMException
.
If transferable has an [[ArrayBufferData]] internal slot and IsSharedArrayBuffer(transferable) is true, then throw a "DataCloneError
" DOMException
.
If memory[transferable] exists, then throw a "DataCloneError
" DOMException
.
Set memory[transferable] to { [[Type]]: an uninitialized value }.
transferable is not transferred yet as transferring has side effects and StructuredSerializeInternal needs to be able to throw first.
Let serialized be ? StructuredSerializeInternal(value, false, memory).
Let transferDataHolders be a new empty List.
For each transferable of transferList:
If transferable has an [[ArrayBufferData]] internal slot and IsDetachedBuffer(transferable) is true, then throw a "DataCloneError
" DOMException
.
If transferable has a [[Detached]] internal slot and transferable.[[Detached]] is true, then throw a "DataCloneError
" DOMException
.
Let dataHolder be memory[transferable].
If transferable has an [[ArrayBufferData]] internal slot, then:
If transferable has an [[ArrayBufferMaxByteLength]] internal slot, then:
Set dataHolder.[[Type]] to "ResizableArrayBuffer".
Set dataHolder.[[ArrayBufferData]] to transferable.[[ArrayBufferData]].
Set dataHolder.[[ArrayBufferByteLength]] to transferable.[[ArrayBufferByteLength]].
Set dataHolder.[[ArrayBufferMaxByteLength]] to transferable.[[ArrayBufferMaxByteLength]].
Otherwise:
Set dataHolder.[[Type]] to "ArrayBuffer".
Set dataHolder.[[ArrayBufferData]] to transferable.[[ArrayBufferData]].
Set dataHolder.[[ArrayBufferByteLength]] to transferable.[[ArrayBufferByteLength]].
Perform ? DetachArrayBuffer(transferable).
Specifications can use the [[ArrayBufferDetachKey]] internal slot to prevent ArrayBuffer
s from being detached. This is used in WebAssembly JavaScript Interface, for example. [WASMJS]
Otherwise:
Assert: transferable is a platform object that is a transferable object.
Let interfaceName be the identifier of the primary interface of transferable.
Set dataHolder.[[Type]] to interfaceName.
Perform the appropriate transfer steps for the interface identified by interfaceName, given transferable and dataHolder.
Set transferable.[[Detached]] to true.
Append dataHolder to transferDataHolders.
Return { [[Serialized]]: serialized, [[TransferDataHolders]]: transferDataHolders }.
Let memory be an empty map.
Analogous to StructuredSerializeWithTransfer, in addition to how it is used normally by StructuredDeserialize, in this algorithm memory is also used to ensure that StructuredDeserialize ignores items in serializeWithTransferResult.[[TransferDataHolders]], and let us do our own handling instead.
Let transferredValues be a new empty List.
For each transferDataHolder of serializeWithTransferResult.[[TransferDataHolders]]:
Let value be an uninitialized value.
If transferDataHolder.[[Type]] is "ArrayBuffer", then set value to a new ArrayBuffer object in targetRealm whose [[ArrayBufferData]] internal slot value is transferDataHolder.[[ArrayBufferData]], and whose [[ArrayBufferByteLength]] internal slot value is transferDataHolder.[[ArrayBufferByteLength]].
In cases where the original memory occupied by [[ArrayBufferData]] is accessible during the deserialization, this step is unlikely to throw an exception, as no new memory needs to be allocated: the memory occupied by [[ArrayBufferData]] is instead just getting transferred into the new ArrayBuffer. This could be true, for example, when both the source and target realms are in the same process.
Otherwise, if transferDataHolder.[[Type]] is "ResizableArrayBuffer", then set value to a new ArrayBuffer object in targetRealm whose [[ArrayBufferData]] internal slot value is transferDataHolder.[[ArrayBufferData]], whose [[ArrayBufferByteLength]] internal slot value is transferDataHolder.[[ArrayBufferByteLength]], and whose [[ArrayBufferMaxByteLength]] internal slot value is transferDataHolder.[[ArrayBufferMaxByteLength]].
For the same reason as the previous step, this step is also unlikely to throw an exception.
Otherwise:
Let interfaceName be transferDataHolder.[[Type]].
If the interface identified by interfaceName is not exposed in targetRealm, then throw a "DataCloneError
" DOMException
.
Set value to a new instance of the interface identified by interfaceName, created in targetRealm.
Perform the appropriate transfer-receiving steps for the interface identified by interfaceName given transferDataHolder and value.
Set memory[transferDataHolder] to value.
Append value to transferredValues.
Let deserialized be ? StructuredDeserialize(serializeWithTransferResult.[[Serialized]], targetRealm, memory).
Return { [[Deserialized]]: deserialized, [[TransferredValues]]: transferredValues }.
Other specifications may use the abstract operations defined here. The following provides some guidance on when each abstract operation is typically useful, with examples.
Cloning a value to another realm, with a transfer list, but where the target realm is not known ahead of time. In this case the serialization step can be performed immediately, with the deserialization step delayed until the target realm becomes known.
messagePort.postMessage()
uses this pair of abstract operations, as the destination realm is not known until the MessagePort
has been shipped.
Creating a realm-independent snapshot of a given value which can be saved for an indefinite amount of time, and then reified back into a JavaScript value later, possibly multiple times.
StructuredSerializeForStorage can be used for situations where the serialization is anticipated to be stored in a persistent manner, instead of passed between realms. It throws when attempting to serialize SharedArrayBuffer
objects, since storing shared memory does not make sense. Similarly, it can throw or possibly have different behavior when given a platform object with custom serialization steps when the forStorage argument is true.
history.pushState()
and history.replaceState()
use StructuredSerializeForStorage on author-supplied state objects, storing them as serialized state in the appropriate session history entry. Then, StructuredDeserialize is used so that the history.state
property can return a clone of the originally-supplied state object.
broadcastChannel.postMessage()
uses StructuredSerialize on its input, then uses StructuredDeserialize multiple times on the result to produce a fresh clone for each destination being broadcast to. Note that transferring does not make sense in multi-destination situations.
Any API for persisting JavaScript values to the filesystem would also use StructuredSerializeForStorage on its input and StructuredDeserialize on its output.
In general, call sites may pass in Web IDL values instead of JavaScript values; this is to be understood to perform an implicit conversion to the JavaScript value before invoking these algorithms.
Call sites that are not invoked as a result of author code synchronously calling into a user agent method must take care to properly prepare to run script and prepare to run a callback before invoking StructuredSerialize, StructuredSerializeForStorage, or StructuredSerializeWithTransfer abstract operations, if they are being performed on arbitrary objects. This is necessary because the serialization process can invoke author-defined accessors as part of its final deep-serialization steps, and these accessors could call into operations that rely on the entry and incumbent concepts being properly set up.
window.postMessage()
performs StructuredSerializeWithTransfer on its arguments, but is careful to do so immediately, inside the synchronous portion of its algorithm. Thus it is able to use the algorithms without needing to prepare to run script and prepare to run a callback.
In contrast, a hypothetical API that used StructuredSerialize to serialize some author-supplied object periodically, directly from a task on the event loop, would need to ensure it performs the appropriate preparations beforehand. As of this time, we know of no such APIs on the platform; usually it is simpler to perform the serialization ahead of time, as a synchronous consequence of author code.
result = self.structuredClone(value[, { transfer }])
入力値を取得し、構造化クローンアルゴリズムを実行してディープコピーを返す。transfer
配列にリストされている転送可能なオブジェクトは、複製されるだけでなく転送される。つまり、もはや入力値で使用できなくなる。
入力値のいずれかの部分がシリアル化できない場合、"DataCloneError
" DOMException
を投げる。
Support in all current engines.
The structuredClone(value, options)
method steps are:
Let serialized be ? StructuredSerializeWithTransfer(value, options["transfer
"]).
Let deserializeRecord be ? StructuredDeserializeWithTransfer(serialized, this's relevant realm).
Return deserializeRecord.[[Deserialized]].