gecko-dev/dom/base/nsScriptLoader.h

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/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*- */
/* vim: set ts=8 sts=2 et sw=2 tw=80: */
/* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
/*
* A class that handles loading and evaluation of <script> elements.
*/
#ifndef __nsScriptLoader_h__
#define __nsScriptLoader_h__
#include "nsCOMPtr.h"
#include "nsRefPtrHashtable.h"
#include "nsIUnicodeDecoder.h"
#include "nsIScriptElement.h"
#include "nsCOMArray.h"
#include "nsCycleCollectionParticipant.h"
#include "nsTArray.h"
#include "nsAutoPtr.h"
#include "nsICacheInfoChannel.h"
#include "nsIDocument.h"
#include "nsIIncrementalStreamLoader.h"
#include "nsURIHashKey.h"
#include "mozilla/CORSMode.h"
#include "mozilla/dom/SRIMetadata.h"
#include "mozilla/dom/SRICheck.h"
#include "mozilla/LinkedList.h"
#include "mozilla/MozPromise.h"
#include "mozilla/net/ReferrerPolicy.h"
#include "mozilla/Vector.h"
class nsModuleLoadRequest;
class nsModuleScript;
class nsScriptLoadRequestList;
class nsIURI;
namespace JS {
class SourceBufferHolder;
} // namespace JS
namespace mozilla {
namespace dom {
class AutoJSAPI;
} // namespace dom
} // namespace mozilla
//////////////////////////////////////////////////////////////
// Per-request data structure
//////////////////////////////////////////////////////////////
enum class nsScriptKind {
Classic,
Module
};
class nsScriptLoadRequest : public nsISupports,
private mozilla::LinkedListElement<nsScriptLoadRequest>
{
typedef LinkedListElement<nsScriptLoadRequest> super;
// Allow LinkedListElement<nsScriptLoadRequest> to cast us to itself as needed.
friend class mozilla::LinkedListElement<nsScriptLoadRequest>;
friend class nsScriptLoadRequestList;
protected:
virtual ~nsScriptLoadRequest();
public:
nsScriptLoadRequest(nsScriptKind aKind,
nsIScriptElement* aElement,
uint32_t aVersion,
mozilla::CORSMode aCORSMode,
const mozilla::dom::SRIMetadata &aIntegrity)
: mKind(aKind),
mElement(aElement),
mScriptFromHead(false),
mProgress(Progress::Loading),
mDataType(DataType::Unknown),
mIsInline(true),
mHasSourceMapURL(false),
mIsDefer(false),
mIsAsync(false),
mIsNonAsyncScriptInserted(false),
mIsXSLT(false),
mIsCanceled(false),
mWasCompiledOMT(false),
mIsTracking(false),
mOffThreadToken(nullptr),
mScriptText(),
mScriptBytecode(),
mBytecodeOffset(0),
mJSVersion(aVersion),
mLineNo(1),
mCORSMode(aCORSMode),
mIntegrity(aIntegrity),
mReferrerPolicy(mozilla::net::RP_Unset)
{
}
NS_DECL_CYCLE_COLLECTING_ISUPPORTS
NS_DECL_CYCLE_COLLECTION_SCRIPT_HOLDER_CLASS(nsScriptLoadRequest)
bool IsModuleRequest() const
{
return mKind == nsScriptKind::Module;
}
nsModuleLoadRequest* AsModuleRequest();
void FireScriptAvailable(nsresult aResult)
{
mElement->ScriptAvailable(aResult, mElement, mIsInline, mURI, mLineNo);
}
void FireScriptEvaluated(nsresult aResult)
{
mElement->ScriptEvaluated(aResult, mElement, mIsInline);
}
bool IsPreload()
{
return mElement == nullptr;
}
virtual void Cancel();
bool IsCanceled() const
{
return mIsCanceled;
}
virtual void SetReady();
void** OffThreadTokenPtr()
{
return mOffThreadToken ? &mOffThreadToken : nullptr;
}
bool IsTracking() const
{
return mIsTracking;
}
void SetIsTracking()
{
MOZ_ASSERT(!mIsTracking);
mIsTracking = true;
}
enum class Progress : uint8_t {
Loading, // Request either source or bytecode
Loading_Source, // Explicitly Request source stream
Compiling,
FetchingImports,
Ready
};
bool IsReadyToRun() const {
return mProgress == Progress::Ready;
}
bool IsLoading() const {
return mProgress == Progress::Loading ||
mProgress == Progress::Loading_Source;
}
bool IsLoadingSource() const {
return mProgress == Progress::Loading_Source;
}
bool InCompilingStage() const {
return mProgress == Progress::Compiling ||
(IsReadyToRun() && mWasCompiledOMT);
}
// Type of data provided by the nsChannel.
enum class DataType : uint8_t {
Unknown,
Source,
Bytecode
};
bool IsUnknownDataType() const {
return mDataType == DataType::Unknown;
}
bool IsSource() const {
return mDataType == DataType::Source;
}
bool IsBytecode() const {
return mDataType == DataType::Bytecode;
}
void MaybeCancelOffThreadScript();
void DropBytecodeCacheReferences();
using super::getNext;
using super::isInList;
const nsScriptKind mKind;
nsCOMPtr<nsIScriptElement> mElement;
bool mScriptFromHead; // Synchronous head script block loading of other non js/css content.
Progress mProgress; // Are we still waiting for a load to complete?
DataType mDataType; // Does this contain Source or Bytecode?
bool mIsInline; // Is the script inline or loaded?
bool mHasSourceMapURL; // Does the HTTP header have a source map url?
bool mIsDefer; // True if we live in mDeferRequests.
bool mIsAsync; // True if we live in mLoadingAsyncRequests or mLoadedAsyncRequests.
bool mIsNonAsyncScriptInserted; // True if we live in mNonAsyncExternalScriptInsertedRequests
bool mIsXSLT; // True if we live in mXSLTRequests.
bool mIsCanceled; // True if we have been explicitly canceled.
bool mWasCompiledOMT; // True if the script has been compiled off main thread.
bool mIsTracking; // True if the script comes from a source on our tracking protection list.
void* mOffThreadToken; // Off-thread parsing token.
nsString mSourceMapURL; // Holds source map url for loaded scripts
// Holds the top-level JSScript that corresponds to the current source, once
// it is parsed, and planned to be saved in the bytecode cache.
JS::Heap<JSScript*> mScript;
// Holds script text for non-inline scripts. Don't use nsString so we can give
// ownership to jsapi.
mozilla::Vector<char16_t> mScriptText;
// Holds the SRI serialized hash and the script bytecode for non-inline
// scripts.
mozilla::Vector<uint8_t> mScriptBytecode;
uint32_t mBytecodeOffset; // Offset of the bytecode in mScriptBytecode
uint32_t mJSVersion;
nsCOMPtr<nsIURI> mURI;
nsCOMPtr<nsIPrincipal> mOriginPrincipal;
nsAutoCString mURL; // Keep the URI's filename alive during off thread parsing.
int32_t mLineNo;
const mozilla::CORSMode mCORSMode;
const mozilla::dom::SRIMetadata mIntegrity;
mozilla::net::ReferrerPolicy mReferrerPolicy;
// Holds the Cache information, which is used to register the bytecode
// on the cache entry, such that we can load it the next time.
nsCOMPtr<nsICacheInfoChannel> mCacheInfo;
};
class nsScriptLoadRequestList : private mozilla::LinkedList<nsScriptLoadRequest>
{
typedef mozilla::LinkedList<nsScriptLoadRequest> super;
public:
~nsScriptLoadRequestList();
void Clear();
#ifdef DEBUG
bool Contains(nsScriptLoadRequest* aElem) const;
#endif // DEBUG
using super::getFirst;
using super::isEmpty;
void AppendElement(nsScriptLoadRequest* aElem)
{
MOZ_ASSERT(!aElem->isInList());
NS_ADDREF(aElem);
insertBack(aElem);
}
MOZ_MUST_USE
already_AddRefed<nsScriptLoadRequest> Steal(nsScriptLoadRequest* aElem)
{
aElem->removeFrom(*this);
return dont_AddRef(aElem);
}
MOZ_MUST_USE
already_AddRefed<nsScriptLoadRequest> StealFirst()
{
MOZ_ASSERT(!isEmpty());
return Steal(getFirst());
}
void Remove(nsScriptLoadRequest* aElem)
{
aElem->removeFrom(*this);
NS_RELEASE(aElem);
}
};
//////////////////////////////////////////////////////////////
// Script loader implementation
//////////////////////////////////////////////////////////////
class nsScriptLoader final : public nsISupports
{
class MOZ_STACK_CLASS AutoCurrentScriptUpdater
{
public:
AutoCurrentScriptUpdater(nsScriptLoader* aScriptLoader,
nsIScriptElement* aCurrentScript)
: mOldScript(aScriptLoader->mCurrentScript)
, mScriptLoader(aScriptLoader)
{
mScriptLoader->mCurrentScript = aCurrentScript;
}
~AutoCurrentScriptUpdater()
{
mScriptLoader->mCurrentScript.swap(mOldScript);
}
private:
nsCOMPtr<nsIScriptElement> mOldScript;
nsScriptLoader* mScriptLoader;
};
friend class nsModuleLoadRequest;
friend class nsScriptRequestProcessor;
friend class nsScriptLoadHandler;
friend class AutoCurrentScriptUpdater;
public:
explicit nsScriptLoader(nsIDocument* aDocument);
NS_DECL_CYCLE_COLLECTING_ISUPPORTS
NS_DECL_CYCLE_COLLECTION_CLASS(nsScriptLoader)
/**
* The loader maintains a weak reference to the document with
* which it is initialized. This call forces the reference to
* be dropped.
*/
void DropDocumentReference()
{
mDocument = nullptr;
}
/**
* Add an observer for all scripts loaded through this loader.
*
* @param aObserver observer for all script processing.
*/
nsresult AddObserver(nsIScriptLoaderObserver* aObserver)
{
return mObservers.AppendObject(aObserver) ? NS_OK :
NS_ERROR_OUT_OF_MEMORY;
}
/**
* Remove an observer.
*
* @param aObserver observer to be removed
*/
void RemoveObserver(nsIScriptLoaderObserver* aObserver)
{
mObservers.RemoveObject(aObserver);
}
/**
* Process a script element. This will include both loading the
* source of the element if it is not inline and evaluating
* the script itself.
*
* If the script is an inline script that can be executed immediately
* (i.e. there are no other scripts pending) then ScriptAvailable
* and ScriptEvaluated will be called before the function returns.
*
* If true is returned the script could not be executed immediately.
* In this case ScriptAvailable is guaranteed to be called at a later
* point (as well as possibly ScriptEvaluated).
*
* @param aElement The element representing the script to be loaded and
* evaluated.
*/
bool ProcessScriptElement(nsIScriptElement* aElement);
/**
* Gets the currently executing script. This is useful if you want to
* generate a unique key based on the currently executing script.
*/
nsIScriptElement* GetCurrentScript()
{
return mCurrentScript;
}
nsIScriptElement* GetCurrentParserInsertedScript()
{
return mCurrentParserInsertedScript;
}
/**
* Whether the loader is enabled or not.
* When disabled, processing of new script elements is disabled.
* Any call to ProcessScriptElement() will return false. Note that
* this DOES NOT disable currently loading or executing scripts.
*/
bool GetEnabled()
{
return mEnabled;
}
void SetEnabled(bool aEnabled)
{
if (!mEnabled && aEnabled) {
ProcessPendingRequestsAsync();
}
mEnabled = aEnabled;
}
/**
* Add/remove a blocker for parser-blocking scripts (and XSLT
* scripts). Blockers will stop such scripts from executing, but not from
* loading.
*/
void AddParserBlockingScriptExecutionBlocker()
{
++mParserBlockingBlockerCount;
}
void RemoveParserBlockingScriptExecutionBlocker()
{
if (!--mParserBlockingBlockerCount && ReadyToExecuteScripts()) {
ProcessPendingRequestsAsync();
}
}
/**
* Add/remove a blocker for execution of all scripts. Blockers will stop
* scripts from executing, but not from loading.
*/
void AddExecuteBlocker()
{
++mBlockerCount;
}
void RemoveExecuteBlocker()
{
MOZ_ASSERT(mBlockerCount);
if (!--mBlockerCount) {
ProcessPendingRequestsAsync();
}
}
/**
* Convert the given buffer to a UTF-16 string.
* @param aChannel Channel corresponding to the data. May be null.
* @param aData The data to convert
* @param aLength Length of the data
* @param aHintCharset Hint for the character set (e.g., from a charset
* attribute). May be the empty string.
* @param aDocument Document which the data is loaded for. Must not be
* null.
* @param aBufOut [out] char16_t array allocated by ConvertToUTF16 and
* containing data converted to unicode. Caller must
* js_free() this data when no longer needed.
* @param aLengthOut [out] Length of array returned in aBufOut in number
* of char16_t code units.
*/
static nsresult ConvertToUTF16(nsIChannel* aChannel, const uint8_t* aData,
uint32_t aLength,
const nsAString& aHintCharset,
nsIDocument* aDocument,
char16_t*& aBufOut, size_t& aLengthOut);
static inline nsresult
ConvertToUTF16(nsIChannel* aChannel, const uint8_t* aData,
uint32_t aLength, const nsAString& aHintCharset,
nsIDocument* aDocument,
JS::UniqueTwoByteChars& aBufOut, size_t& aLengthOut)
{
char16_t* bufOut;
nsresult rv = ConvertToUTF16(aChannel, aData, aLength, aHintCharset, aDocument,
bufOut, aLengthOut);
if (NS_SUCCEEDED(rv)) {
aBufOut.reset(bufOut);
}
return rv;
};
/**
* Handle the completion of a stream. This is called by the
* nsScriptLoadHandler object which observes the IncrementalStreamLoader
* loading the script. The streamed content is expected to be stored on the
* aRequest argument.
*/
nsresult OnStreamComplete(nsIIncrementalStreamLoader* aLoader,
nsScriptLoadRequest* aRequest,
nsresult aChannelStatus,
nsresult aSRIStatus,
mozilla::dom::SRICheckDataVerifier* aSRIDataVerifier);
/**
* Returns wether any request is queued, and not executed yet.
*/
bool HasPendingRequests();
/**
* Processes any pending requests that are ready for processing.
*/
void ProcessPendingRequests();
/**
* Starts deferring deferred scripts and puts them in the mDeferredRequests
* queue instead.
*/
void BeginDeferringScripts()
{
mDeferEnabled = true;
if (mDocument) {
mDocument->BlockOnload();
}
}
/**
* Notifies the script loader that parsing is done. If aTerminated is true,
* this will drop any pending scripts that haven't run yet. Otherwise, it
* will stops deferring scripts and immediately processes the
* mDeferredRequests queue.
*
* WARNING: This function will synchronously execute content scripts, so be
* prepared that the world might change around you.
*/
void ParsingComplete(bool aTerminated);
/**
* Returns the number of pending scripts, deferred or not.
*/
uint32_t HasPendingOrCurrentScripts()
{
return mCurrentScript || mParserBlockingRequest;
}
/**
* Adds aURI to the preload list and starts loading it.
*
* @param aURI The URI of the external script.
* @param aCharset The charset parameter for the script.
* @param aType The type parameter for the script.
* @param aCrossOrigin The crossorigin attribute for the script.
* Void if not present.
* @param aIntegrity The expect hash url, if avail, of the request
* @param aScriptFromHead Whether or not the script was a child of head
*/
virtual void PreloadURI(nsIURI *aURI, const nsAString &aCharset,
const nsAString &aType,
const nsAString &aCrossOrigin,
const nsAString& aIntegrity,
bool aScriptFromHead,
const mozilla::net::ReferrerPolicy aReferrerPolicy);
/**
* Process a request that was deferred so that the script could be compiled
* off thread.
*/
nsresult ProcessOffThreadRequest(nsScriptLoadRequest *aRequest);
bool AddPendingChildLoader(nsScriptLoader* aChild) {
return mPendingChildLoaders.AppendElement(aChild) != nullptr;
}
mozilla::dom::DocGroup* GetDocGroup() const
{
return mDocument->GetDocGroup();
}
/**
* Register the fact that we saw the load event, and that we need to save the
* bytecode at the next loop cycle unless new scripts are waiting in the
* pipeline.
*/
void LoadEventFired();
private:
virtual ~nsScriptLoader();
nsScriptLoadRequest* CreateLoadRequest(
nsScriptKind aKind,
nsIScriptElement* aElement,
uint32_t aVersion,
mozilla::CORSMode aCORSMode,
const mozilla::dom::SRIMetadata &aIntegrity);
/**
* Unblocks the creator parser of the parser-blocking scripts.
*/
void UnblockParser(nsScriptLoadRequest* aParserBlockingRequest);
/**
* Asynchronously resumes the creator parser of the parser-blocking scripts.
*/
void ContinueParserAsync(nsScriptLoadRequest* aParserBlockingRequest);
/**
* Helper function to check the content policy for a given request.
*/
static nsresult CheckContentPolicy(nsIDocument* aDocument,
nsISupports *aContext,
nsIURI *aURI,
const nsAString &aType,
bool aIsPreLoad);
/**
* Start a load for aRequest's URI.
*/
nsresult StartLoad(nsScriptLoadRequest *aRequest);
/**
* Abort the current stream, and re-start with a new load request from scratch
* without requesting any alternate data. Returns NS_BINDING_RETARGETED on
* success, as this error code is used to abort the input stream.
*/
nsresult RestartLoad(nsScriptLoadRequest *aRequest);
/**
* Process any pending requests asynchronously (i.e. off an event) if there
* are any. Note that this is a no-op if there aren't any currently pending
* requests.
*
* This function is virtual to allow cross-library calls to SetEnabled()
*/
virtual void ProcessPendingRequestsAsync();
/**
* If true, the loader is ready to execute parser-blocking scripts, and so are
* all its ancestors. If the loader itself is ready but some ancestor is not,
* this function will add an execute blocker and ask the ancestor to remove it
* once it becomes ready.
*/
bool ReadyToExecuteParserBlockingScripts();
/**
* Return whether just this loader is ready to execute parser-blocking
* scripts.
*/
bool SelfReadyToExecuteParserBlockingScripts()
{
return ReadyToExecuteScripts() && !mParserBlockingBlockerCount;
}
/**
* Return whether this loader is ready to execute scripts in general.
*/
bool ReadyToExecuteScripts()
{
return mEnabled && !mBlockerCount;
}
nsresult AttemptAsyncScriptCompile(nsScriptLoadRequest* aRequest);
nsresult ProcessRequest(nsScriptLoadRequest* aRequest);
nsresult CompileOffThreadOrProcessRequest(nsScriptLoadRequest* aRequest);
void FireScriptAvailable(nsresult aResult,
nsScriptLoadRequest* aRequest);
void FireScriptEvaluated(nsresult aResult,
nsScriptLoadRequest* aRequest);
nsresult EvaluateScript(nsScriptLoadRequest* aRequest);
/**
* Queue the current script load request to be saved, when the page
* initialization ends. The page initialization end is defined as being the
* time when the load event got received, and when no more scripts are waiting
* to be executed.
*/
void RegisterForBytecodeEncoding(nsScriptLoadRequest* aRequest);
/**
* Check if all conditions are met, i-e that the onLoad event fired and that
* no more script have to be processed. If all conditions are met, queue an
* event to encode all the bytecode and save them on the cache.
*/
void MaybeTriggerBytecodeEncoding();
/**
* Iterate over all script load request and save the bytecode of executed
* functions on the cache provided by the channel.
*/
void EncodeBytecode();
void EncodeRequestBytecode(JSContext* aCx, nsScriptLoadRequest* aRequest);
void GiveUpBytecodeEncoding();
already_AddRefed<nsIScriptGlobalObject> GetScriptGlobalObject();
nsresult FillCompileOptionsForRequest(const mozilla::dom::AutoJSAPI& jsapi,
nsScriptLoadRequest* aRequest,
JS::Handle<JSObject*> aScopeChain,
JS::CompileOptions* aOptions);
uint32_t NumberOfProcessors();
nsresult PrepareLoadedRequest(nsScriptLoadRequest* aRequest,
nsIIncrementalStreamLoader* aLoader,
nsresult aStatus);
void AddDeferRequest(nsScriptLoadRequest* aRequest);
bool MaybeRemovedDeferRequests();
void MaybeMoveToLoadedList(nsScriptLoadRequest* aRequest);
JS::SourceBufferHolder GetScriptSource(nsScriptLoadRequest* aRequest,
nsAutoString& inlineData);
bool ModuleScriptsEnabled();
void SetModuleFetchStarted(nsModuleLoadRequest *aRequest);
void SetModuleFetchFinishedAndResumeWaitingRequests(nsModuleLoadRequest *aRequest,
nsresult aResult);
bool IsFetchingModule(nsModuleLoadRequest *aRequest) const;
bool ModuleMapContainsModule(nsModuleLoadRequest *aRequest) const;
RefPtr<mozilla::GenericPromise> WaitForModuleFetch(nsModuleLoadRequest *aRequest);
nsModuleScript* GetFetchedModule(nsIURI* aURL) const;
friend bool
HostResolveImportedModule(JSContext* aCx, unsigned argc, JS::Value* vp);
nsresult CreateModuleScript(nsModuleLoadRequest* aRequest);
nsresult ProcessFetchedModuleSource(nsModuleLoadRequest* aRequest);
void ProcessLoadedModuleTree(nsModuleLoadRequest* aRequest);
bool InstantiateModuleTree(nsModuleLoadRequest* aRequest);
void StartFetchingModuleDependencies(nsModuleLoadRequest* aRequest);
RefPtr<mozilla::GenericPromise>
StartFetchingModuleAndDependencies(nsModuleLoadRequest* aRequest, nsIURI* aURI);
nsIDocument* mDocument; // [WEAK]
nsCOMArray<nsIScriptLoaderObserver> mObservers;
nsScriptLoadRequestList mNonAsyncExternalScriptInsertedRequests;
// mLoadingAsyncRequests holds async requests while they're loading; when they
// have been loaded they are moved to mLoadedAsyncRequests.
nsScriptLoadRequestList mLoadingAsyncRequests;
nsScriptLoadRequestList mLoadedAsyncRequests;
nsScriptLoadRequestList mDeferRequests;
nsScriptLoadRequestList mXSLTRequests;
RefPtr<nsScriptLoadRequest> mParserBlockingRequest;
// List of script load request that are holding a buffer which has to be saved
// on the cache.
nsScriptLoadRequestList mBytecodeEncodingQueue;
// In mRequests, the additional information here is stored by the element.
struct PreloadInfo {
RefPtr<nsScriptLoadRequest> mRequest;
nsString mCharset;
};
friend void ImplCycleCollectionUnlink(nsScriptLoader::PreloadInfo& aField);
friend void ImplCycleCollectionTraverse(nsCycleCollectionTraversalCallback& aCallback,
nsScriptLoader::PreloadInfo& aField,
const char* aName, uint32_t aFlags);
struct PreloadRequestComparator {
bool Equals(const PreloadInfo &aPi, nsScriptLoadRequest * const &aRequest)
const
{
return aRequest == aPi.mRequest;
}
};
struct PreloadURIComparator {
bool Equals(const PreloadInfo &aPi, nsIURI * const &aURI) const;
};
nsTArray<PreloadInfo> mPreloads;
nsCOMPtr<nsIScriptElement> mCurrentScript;
nsCOMPtr<nsIScriptElement> mCurrentParserInsertedScript;
nsTArray< RefPtr<nsScriptLoader> > mPendingChildLoaders;
uint32_t mParserBlockingBlockerCount;
uint32_t mBlockerCount;
uint32_t mNumberOfProcessors;
bool mEnabled;
bool mDeferEnabled;
bool mDocumentParsingDone;
bool mBlockingDOMContentLoaded;
bool mLoadEventFired;
// Module map
nsRefPtrHashtable<nsURIHashKey, mozilla::GenericPromise::Private> mFetchingModules;
nsRefPtrHashtable<nsURIHashKey, nsModuleScript> mFetchedModules;
nsCOMPtr<nsIConsoleReportCollector> mReporter;
};
class nsScriptLoadHandler final : public nsIIncrementalStreamLoaderObserver
{
public:
explicit nsScriptLoadHandler(nsScriptLoader* aScriptLoader,
nsScriptLoadRequest *aRequest,
mozilla::dom::SRICheckDataVerifier *aSRIDataVerifier);
NS_DECL_ISUPPORTS
NS_DECL_NSIINCREMENTALSTREAMLOADEROBSERVER
private:
virtual ~nsScriptLoadHandler();
/*
* Once the charset is found by the EnsureDecoder function, we can
* incrementally convert the charset to the one expected by the JS Parser.
*/
nsresult DecodeRawData(const uint8_t* aData, uint32_t aDataLength,
bool aEndOfStream);
/*
* Discover the charset by looking at the stream data, the script
* tag, and other indicators. Returns true if charset has been
* discovered.
*/
bool EnsureDecoder(nsIIncrementalStreamLoader *aLoader,
const uint8_t* aData, uint32_t aDataLength,
bool aEndOfStream);
bool EnsureDecoder(nsIIncrementalStreamLoader *aLoader,
const uint8_t* aData, uint32_t aDataLength,
bool aEndOfStream, nsCString& oCharset);
/*
* When streaming bytecode, we have the opportunity to fallback early if SRI
* does not match the expectation of the document.
*/
nsresult MaybeDecodeSRI();
// Query the channel to find the data type associated with the input stream.
nsresult EnsureKnownDataType(nsIIncrementalStreamLoader *aLoader);
// ScriptLoader which will handle the parsed script.
RefPtr<nsScriptLoader> mScriptLoader;
// The nsScriptLoadRequest for this load. Decoded data are accumulated on it.
RefPtr<nsScriptLoadRequest> mRequest;
// SRI data verifier.
nsAutoPtr<mozilla::dom::SRICheckDataVerifier> mSRIDataVerifier;
// Status of SRI data operations.
nsresult mSRIStatus;
// Unicode decoder for charset.
nsCOMPtr<nsIUnicodeDecoder> mDecoder;
};
class nsAutoScriptLoaderDisabler
{
public:
explicit nsAutoScriptLoaderDisabler(nsIDocument* aDoc)
{
mLoader = aDoc->ScriptLoader();
mWasEnabled = mLoader->GetEnabled();
if (mWasEnabled) {
mLoader->SetEnabled(false);
}
}
~nsAutoScriptLoaderDisabler()
{
if (mWasEnabled) {
mLoader->SetEnabled(true);
}
}
bool mWasEnabled;
RefPtr<nsScriptLoader> mLoader;
};
#endif //__nsScriptLoader_h__