/* -*- 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/. */ /* * Definitions for managing off-thread work using a process wide list of * worklist items and pool of threads. Worklist items are engine internal, and * are distinct from e.g. web workers. */ #ifndef vm_HelperThreadState_h #define vm_HelperThreadState_h #include "mozilla/Attributes.h" #include "mozilla/EnumeratedArray.h" #include "mozilla/RefPtr.h" // RefPtr #include "mozilla/TimeStamp.h" #include "mozilla/Vector.h" // mozilla::Vector #include "ds/Fifo.h" #include "frontend/CompilationStencil.h" // CompilationStencil, CompilationGCOutput #include "frontend/FrontendContext.h" #include "js/CompileOptions.h" #include "js/experimental/JSStencil.h" #include "js/HelperThreadAPI.h" #include "js/Stack.h" // JS::NativeStackLimit #include "js/TypeDecls.h" #include "threading/ConditionVariable.h" #include "vm/HelperThreads.h" #include "vm/HelperThreadTask.h" #include "vm/JSContext.h" #include "vm/OffThreadPromiseRuntimeState.h" // js::OffThreadPromiseTask namespace js { struct ParseTask; struct DelazifyTask; struct FreeDelazifyTask; struct PromiseHelperTask; class PromiseObject; namespace jit { class IonCompileTask; class IonFreeTask; } // namespace jit enum class ParseTaskKind { // The output is CompilationStencil for script. ScriptStencil, // The output is CompilationStencil for module. ModuleStencil, // The output is CompilationStencil for script/stencil. StencilDecode, // The output is an array of CompilationStencil. MultiStencilsDecode, }; namespace wasm { struct CompileTask; typedef Fifo CompileTaskPtrFifo; struct Tier2GeneratorTask : public HelperThreadTask { virtual ~Tier2GeneratorTask() = default; virtual void cancel() = 0; }; using UniqueTier2GeneratorTask = UniquePtr; typedef Vector Tier2GeneratorTaskPtrVector; } // namespace wasm // Per-process state for off thread work items. class GlobalHelperThreadState { friend class AutoLockHelperThreadState; friend class AutoUnlockHelperThreadState; public: // A single tier-2 ModuleGenerator job spawns many compilation jobs, and we // do not want to allow more than one such ModuleGenerator to run at a time. static const size_t MaxTier2GeneratorTasks = 1; // Number of CPUs to treat this machine as having when creating threads. // May be accessed without locking. size_t cpuCount; // Number of threads to create. May be accessed without locking. size_t threadCount; // Thread stack quota to use when running tasks. size_t stackQuota; bool terminating_ = false; typedef Vector IonCompileTaskVector; using IonFreeTaskVector = Vector, 0, SystemAllocPolicy>; typedef Vector, 0, SystemAllocPolicy> ParseTaskVector; using ParseTaskList = mozilla::LinkedList; using DelazifyTaskList = mozilla::LinkedList; using FreeDelazifyTaskVector = Vector, 1, SystemAllocPolicy>; typedef Vector, 0, SystemAllocPolicy> SourceCompressionTaskVector; typedef Vector PromiseHelperTaskVector; typedef Vector ContextVector; // Count of running task by each threadType. mozilla::EnumeratedArray runningTaskCount; size_t totalCountRunningTasks; WriteOnceData registerThread; WriteOnceData unregisterThread; private: // The lists below are all protected by |lock|. // Ion compilation worklist and finished jobs. IonCompileTaskVector ionWorklist_, ionFinishedList_; IonFreeTaskVector ionFreeList_; // wasm worklists. wasm::CompileTaskPtrFifo wasmWorklist_tier1_; wasm::CompileTaskPtrFifo wasmWorklist_tier2_; wasm::Tier2GeneratorTaskPtrVector wasmTier2GeneratorWorklist_; // Count of finished Tier2Generator tasks. uint32_t wasmTier2GeneratorsFinished_; // Async tasks that, upon completion, are dispatched back to the JSContext's // owner thread via embedding callbacks instead of a finished list. PromiseHelperTaskVector promiseHelperTasks_; // Script parsing/emitting worklist and finished jobs. ParseTaskVector parseWorklist_; ParseTaskList parseFinishedList_; // Script worklist, which might still have function to delazify. DelazifyTaskList delazifyWorklist_; // Ideally an instance should not have a method to free it-self as, the method // has a this pointer, which aliases the deleted instance, and that the method // might have some of its fields aliased on the stack. // // Delazification task are complex and have a lot of fields. To reduce the // risk of having aliased fields on the stack while deleting instances of a // DelazifyTask, we have FreeDelazifyTask. While FreeDelazifyTask suffer from // the same problem, the limited scope of their actions should mitigate the // risk. FreeDelazifyTaskVector freeDelazifyTaskVector_; // Source compression worklist of tasks that we do not yet know can start. SourceCompressionTaskVector compressionPendingList_; // Source compression worklist of tasks that can start. SourceCompressionTaskVector compressionWorklist_; // Finished source compression tasks. SourceCompressionTaskVector compressionFinishedList_; // GC tasks needing to be done in parallel. GCParallelTaskList gcParallelWorklist_; size_t gcParallelThreadCount; // Global list of JSContext for GlobalHelperThreadState to use. ContextVector helperContexts_; using HelperThreadTaskVector = Vector; // Vector of running HelperThreadTask. // This is used to get the HelperThreadTask that are currently running. HelperThreadTaskVector helperTasks_; // Callback to dispatch a task to a thread pool. Set by // JS::SetHelperThreadTaskCallback. If this is not set the internal thread // pool is used. JS::HelperThreadTaskCallback dispatchTaskCallback = nullptr; // The number of tasks dispatched to the thread pool that have not started // running yet. size_t tasksPending_ = 0; bool isInitialized_ = false; bool useInternalThreadPool_ = true; ParseTask* removeFinishedParseTask(JSContext* cx, JS::OffThreadToken* token); public: void addSizeOfIncludingThis(JS::GlobalStats* stats, const AutoLockHelperThreadState& lock) const; size_t maxIonCompilationThreads() const; size_t maxWasmCompilationThreads() const; size_t maxWasmTier2GeneratorThreads() const; size_t maxPromiseHelperThreads() const; size_t maxParseThreads() const; size_t maxCompressionThreads() const; size_t maxGCParallelThreads(const AutoLockHelperThreadState& lock) const; GlobalHelperThreadState(); bool isInitialized(const AutoLockHelperThreadState& lock) const { return isInitialized_; } [[nodiscard]] bool ensureInitialized(); [[nodiscard]] bool ensureThreadCount(size_t count, AutoLockHelperThreadState& lock); void finish(AutoLockHelperThreadState& lock); void finishThreads(AutoLockHelperThreadState& lock); void setCpuCount(size_t count); void setDispatchTaskCallback(JS::HelperThreadTaskCallback callback, size_t threadCount, size_t stackSize, const AutoLockHelperThreadState& lock); JSContext* getFirstUnusedContext(AutoLockHelperThreadState& locked); void destroyHelperContexts(AutoLockHelperThreadState& lock); #ifdef DEBUG void assertIsLockedByCurrentThread() const; #endif void wait(AutoLockHelperThreadState& locked, mozilla::TimeDuration timeout = mozilla::TimeDuration::Forever()); void notifyAll(const AutoLockHelperThreadState&); bool useInternalThreadPool(const AutoLockHelperThreadState& lock) const { return useInternalThreadPool_; } bool isTerminating(const AutoLockHelperThreadState& locked) const { return terminating_; } private: void notifyOne(const AutoLockHelperThreadState&); public: // Helper method for removing items from the vectors below while iterating // over them. template void remove(T& vector, size_t* index) { // Self-moving is undefined behavior. if (*index != vector.length() - 1) { vector[*index] = std::move(vector.back()); } (*index)--; vector.popBack(); } IonCompileTaskVector& ionWorklist(const AutoLockHelperThreadState&) { return ionWorklist_; } IonCompileTaskVector& ionFinishedList(const AutoLockHelperThreadState&) { return ionFinishedList_; } IonFreeTaskVector& ionFreeList(const AutoLockHelperThreadState&) { return ionFreeList_; } wasm::CompileTaskPtrFifo& wasmWorklist(const AutoLockHelperThreadState&, wasm::CompileMode m) { switch (m) { case wasm::CompileMode::Once: case wasm::CompileMode::Tier1: return wasmWorklist_tier1_; case wasm::CompileMode::Tier2: return wasmWorklist_tier2_; default: MOZ_CRASH(); } } wasm::Tier2GeneratorTaskPtrVector& wasmTier2GeneratorWorklist( const AutoLockHelperThreadState&) { return wasmTier2GeneratorWorklist_; } void incWasmTier2GeneratorsFinished(const AutoLockHelperThreadState&) { wasmTier2GeneratorsFinished_++; } uint32_t wasmTier2GeneratorsFinished(const AutoLockHelperThreadState&) const { return wasmTier2GeneratorsFinished_; } PromiseHelperTaskVector& promiseHelperTasks( const AutoLockHelperThreadState&) { return promiseHelperTasks_; } ParseTaskVector& parseWorklist(const AutoLockHelperThreadState&) { return parseWorklist_; } ParseTaskList& parseFinishedList(const AutoLockHelperThreadState&) { return parseFinishedList_; } DelazifyTaskList& delazifyWorklist(const AutoLockHelperThreadState&) { return delazifyWorklist_; } FreeDelazifyTaskVector& freeDelazifyTaskVector( const AutoLockHelperThreadState&) { return freeDelazifyTaskVector_; } SourceCompressionTaskVector& compressionPendingList( const AutoLockHelperThreadState&) { return compressionPendingList_; } SourceCompressionTaskVector& compressionWorklist( const AutoLockHelperThreadState&) { return compressionWorklist_; } SourceCompressionTaskVector& compressionFinishedList( const AutoLockHelperThreadState&) { return compressionFinishedList_; } GCParallelTaskList& gcParallelWorklist() { return gcParallelWorklist_; } void setGCParallelThreadCount(size_t count, const AutoLockHelperThreadState&) { MOZ_ASSERT(count >= 1); MOZ_ASSERT(count <= threadCount); gcParallelThreadCount = count; } HelperThreadTaskVector& helperTasks(const AutoLockHelperThreadState&) { return helperTasks_; } bool canStartWasmCompile(const AutoLockHelperThreadState& lock, wasm::CompileMode mode); bool canStartWasmTier1CompileTask(const AutoLockHelperThreadState& lock); bool canStartWasmTier2CompileTask(const AutoLockHelperThreadState& lock); bool canStartWasmTier2GeneratorTask(const AutoLockHelperThreadState& lock); bool canStartPromiseHelperTask(const AutoLockHelperThreadState& lock); bool canStartIonCompileTask(const AutoLockHelperThreadState& lock); bool canStartIonFreeTask(const AutoLockHelperThreadState& lock); bool canStartParseTask(const AutoLockHelperThreadState& lock); bool canStartFreeDelazifyTask(const AutoLockHelperThreadState& lock); bool canStartDelazifyTask(const AutoLockHelperThreadState& lock); bool canStartCompressionTask(const AutoLockHelperThreadState& lock); bool canStartGCParallelTask(const AutoLockHelperThreadState& lock); HelperThreadTask* maybeGetWasmCompile(const AutoLockHelperThreadState& lock, wasm::CompileMode mode); HelperThreadTask* maybeGetWasmTier1CompileTask( const AutoLockHelperThreadState& lock); HelperThreadTask* maybeGetWasmTier2CompileTask( const AutoLockHelperThreadState& lock); HelperThreadTask* maybeGetWasmTier2GeneratorTask( const AutoLockHelperThreadState& lock); HelperThreadTask* maybeGetPromiseHelperTask( const AutoLockHelperThreadState& lock); HelperThreadTask* maybeGetIonCompileTask( const AutoLockHelperThreadState& lock); HelperThreadTask* maybeGetLowPrioIonCompileTask( const AutoLockHelperThreadState& lock); HelperThreadTask* maybeGetIonFreeTask(const AutoLockHelperThreadState& lock); HelperThreadTask* maybeGetParseTask(const AutoLockHelperThreadState& lock); HelperThreadTask* maybeGetFreeDelazifyTask( const AutoLockHelperThreadState& lock); HelperThreadTask* maybeGetDelazifyTask(const AutoLockHelperThreadState& lock); HelperThreadTask* maybeGetCompressionTask( const AutoLockHelperThreadState& lock); HelperThreadTask* maybeGetGCParallelTask( const AutoLockHelperThreadState& lock); enum class ScheduleCompressionTask { GC, API }; // Used by a major GC to signal processing enqueued compression tasks. void startHandlingCompressionTasks(ScheduleCompressionTask schedule, JSRuntime* maybeRuntime, const AutoLockHelperThreadState& lock); jit::IonCompileTask* highestPriorityPendingIonCompile( const AutoLockHelperThreadState& lock, bool checkExecutionStatus); private: UniquePtr finishParseTaskCommon(JSContext* cx, JS::OffThreadToken* token); bool finishMultiParseTask(JSContext* cx, ParseTaskKind kind, JS::OffThreadToken* token, mozilla::Vector>* stencils); public: void cancelParseTask(JSRuntime* rt, JS::OffThreadToken* token); void destroyParseTask(JSRuntime* rt, ParseTask* parseTask); void trace(JSTracer* trc); already_AddRefed finishStencilTask( JSContext* cx, JS::OffThreadToken* token, JS::InstantiationStorage* storage); bool finishMultiStencilsDecodeTask( JSContext* cx, JS::OffThreadToken* token, mozilla::Vector>* stencils); bool hasActiveThreads(const AutoLockHelperThreadState&); bool canStartTasks(const AutoLockHelperThreadState& locked); void waitForAllTasks(); void waitForAllTasksLocked(AutoLockHelperThreadState&); bool checkTaskThreadLimit(ThreadType threadType, size_t maxThreads, bool isMaster, const AutoLockHelperThreadState& lock) const; bool checkTaskThreadLimit(ThreadType threadType, size_t maxThreads, const AutoLockHelperThreadState& lock) const { return checkTaskThreadLimit(threadType, maxThreads, /* isMaster */ false, lock); } void triggerFreeUnusedMemory(); private: // Condition variable for notifiying the main thread that a helper task has // completed some work. js::ConditionVariable consumerWakeup; void dispatch(JS::DispatchReason reason, const AutoLockHelperThreadState& locked); void runTask(HelperThreadTask* task, AutoLockHelperThreadState& lock); public: bool submitTask(wasm::UniqueTier2GeneratorTask task); bool submitTask(wasm::CompileTask* task, wasm::CompileMode mode); bool submitTask(UniquePtr task, const AutoLockHelperThreadState& lock); bool submitTask(jit::IonCompileTask* task, const AutoLockHelperThreadState& locked); bool submitTask(UniquePtr task, const AutoLockHelperThreadState& locked); bool submitTask(JSRuntime* rt, UniquePtr task, const AutoLockHelperThreadState& locked); void submitTask(DelazifyTask* task, const AutoLockHelperThreadState& locked); bool submitTask(UniquePtr task, const AutoLockHelperThreadState& locked); bool submitTask(PromiseHelperTask* task); bool submitTask(GCParallelTask* task, const AutoLockHelperThreadState& locked); void runOneTask(AutoLockHelperThreadState& lock); void runTaskLocked(HelperThreadTask* task, AutoLockHelperThreadState& lock); using Selector = HelperThreadTask* ( GlobalHelperThreadState::*)(const AutoLockHelperThreadState&); static const Selector selectors[]; HelperThreadTask* findHighestPriorityTask( const AutoLockHelperThreadState& locked); }; static inline bool IsHelperThreadStateInitialized() { extern GlobalHelperThreadState* gHelperThreadState; return gHelperThreadState; } static inline GlobalHelperThreadState& HelperThreadState() { extern GlobalHelperThreadState* gHelperThreadState; MOZ_ASSERT(gHelperThreadState); return *gHelperThreadState; } class MOZ_RAII AutoSetHelperThreadContext { JSContext* cx; AutoLockHelperThreadState& lock; public: AutoSetHelperThreadContext(const JS::ContextOptions& options, AutoLockHelperThreadState& lock); ~AutoSetHelperThreadContext(); }; struct MOZ_RAII AutoSetContextRuntime { explicit AutoSetContextRuntime(JSRuntime* rt) { TlsContext.get()->setRuntime(rt); } ~AutoSetContextRuntime() { TlsContext.get()->setRuntime(nullptr); } }; struct ParseTask : public mozilla::LinkedListElement, public JS::OffThreadToken, public HelperThreadTask { JS::NativeStackLimit stackLimit; ParseTaskKind kind; JS::OwningCompileOptions options; // Context options from the main thread. const JS::ContextOptions contextOptions; // HelperThreads are shared between all runtimes in the process so explicitly // track which one we are associated with. JSRuntime* runtime = nullptr; // Callback invoked off thread when the parse finishes. JS::OffThreadCompileCallback callback; void* callbackData; // For the multi-decode stencil case, holds onto the set of stencils produced // offthread mozilla::Vector> stencils; // The input of the compilation. UniquePtr stencilInput_; // The output of the compilation/decode task. RefPtr stencil_; UniquePtr gcOutput_; // Record any errors happening while parsing or generating bytecode. FrontendContext fc_; ParseTask(ParseTaskKind kind, JSContext* cx, JS::OffThreadCompileCallback callback, void* callbackData); virtual ~ParseTask(); bool init(JSContext* cx, const JS::ReadOnlyCompileOptions& options); void moveGCOutputInto(JS::InstantiationStorage& storage); void activate(JSRuntime* rt); void deactivate(JSRuntime* rt); virtual void parse(JSContext* cx, FrontendContext* fc) = 0; bool runtimeMatches(JSRuntime* rt) { return runtime == rt; } void trace(JSTracer* trc); size_t sizeOfExcludingThis(mozilla::MallocSizeOf mallocSizeOf) const; size_t sizeOfIncludingThis(mozilla::MallocSizeOf mallocSizeOf) const { return mallocSizeOf(this) + sizeOfExcludingThis(mallocSizeOf); } void runHelperThreadTask(AutoLockHelperThreadState& locked) override; void runTask(AutoLockHelperThreadState& lock); void scheduleDelazifyTask(AutoLockHelperThreadState& lock); ThreadType threadType() override { return ThreadType::THREAD_TYPE_PARSE; } }; // Base class for implementing the various strategies to iterate over the // functions to be delazified, or to decide when to stop doing any // delazification. // // When created, the `add` function should be called with the top-level // ScriptIndex. struct DelazifyStrategy { using ScriptIndex = frontend::ScriptIndex; virtual ~DelazifyStrategy() = default; // Returns true if no more functions should be delazified. Note, this does not // imply that every function got delazified. virtual bool done() const = 0; // Return a function identifier which represent the next function to be // delazified. If no more function should be delazified, then return 0. virtual ScriptIndex next() = 0; // Empty the list of functions to be processed next. done() should return true // after this call. virtual void clear() = 0; // Insert an index in the container of the delazification strategy. A strategy // can choose to ignore the insertion of an index in its queue of function to // delazify. Return false only in case of errors while inserting, and true // otherwise. [[nodiscard]] virtual bool insert(ScriptIndex index, frontend::ScriptStencilRef& ref) = 0; // Add the inner functions of a delazified function. This function should only // be called with a function which has some bytecode associated with it, and // register functions which parent are already delazified. // // This function is called with the script index of: // - top-level script, when starting the off-thread delazification. // - functions added by `add` and delazified by `DelazifyTask`. [[nodiscard]] bool add(FrontendContext* fc, const frontend::CompilationStencil& stencil, ScriptIndex index); }; // Delazify all functions using a Depth First traversal of the function-tree // ordered, where each functions is visited in source-order. // // When `add` is called with the top-level ScriptIndex. This will push all inner // functions to a stack such that they are popped in source order. Each // function, once delazified, would be used to schedule their inner functions // the same way. // // Hypothesis: This strategy parses all functions in source order, with the // expectation that calls will follow the same order, and that helper thread // would always be ahead of the execution. struct DepthFirstDelazification final : public DelazifyStrategy { Vector stack; bool done() const override { return stack.empty(); } ScriptIndex next() override { return stack.popCopy(); } void clear() override { return stack.clear(); } bool insert(ScriptIndex index, frontend::ScriptStencilRef&) override { return stack.append(index); } }; // Delazify all functions using a traversal which select the largest function // first. The intent being that if the main thread races with the helper thread, // then the main thread should only have to parse small functions instead of the // large ones which would be prioritized by this delazification strategy. struct LargeFirstDelazification final : public DelazifyStrategy { using SourceSize = uint32_t; Vector, 0, SystemAllocPolicy> heap; bool done() const override { return heap.empty(); } ScriptIndex next() override; void clear() override { return heap.clear(); } bool insert(ScriptIndex, frontend::ScriptStencilRef&) override; }; // Eagerly delazify functions, and send the result back to the runtime which // requested the stencil to be parsed, by filling the stencil cache. // // This task is scheduled multiple times, each time it is scheduled, it // delazifies a single function. Once the function is delazified, it schedules // the inner functions of the delazified function for delazification using the // DelazifyStrategy. The DelazifyStrategy is responsible for ordering and // filtering functions to be delazified. // // When no more function have to be delazified, a FreeDelazifyTask is scheduled // to remove the memory held by the DelazifyTask. struct DelazifyTask : public mozilla::LinkedListElement, public HelperThreadTask { JS::NativeStackLimit stackLimit; // HelperThreads are shared between all runtimes in the process so explicitly // track which one we are associated with. JSRuntime* runtime = nullptr; // Context options originally from the main thread. const JS::ContextOptions contextOptions; // Queue of functions to be processed while delazifying. UniquePtr strategy; // Every delazified function is merged back to provide context for delazifying // even more functions. frontend::CompilationStencilMerger merger; // Record any errors happening while parsing or generating bytecode. FrontendContext fc_; // Create a new DelazifyTask and initialize it. // // In case of early failure, no errors are reported, as a DelazifyTask is an // optimization and the VM should remain working even without this // optimization in place. static UniquePtr Create( JSRuntime* runtime, const JS::ContextOptions& contextOptions, const JS::ReadOnlyCompileOptions& options, const frontend::CompilationStencil& stencil); DelazifyTask(JSRuntime* runtime, const JS::ContextOptions& options); ~DelazifyTask(); [[nodiscard]] bool init( const JS::ReadOnlyCompileOptions& options, UniquePtr&& initial); // This function is called by delazify task thread to know whether the task // should be interrupted. // // A delazify task holds on a thread until all functions iterated over by the // strategy. However, as a delazify task iterates over multiple functions, it // can easily be interrupted at function boundaries. // // TODO: (Bug 1773683) Plug this with the mozilla::Task::RequestInterrupt // function which is wrapping HelperThreads tasks within Mozilla. bool isInterrupted() { return false; } bool runtimeMatches(JSRuntime* rt) { return runtime == rt; } size_t sizeOfExcludingThis(mozilla::MallocSizeOf mallocSizeOf) const; size_t sizeOfIncludingThis(mozilla::MallocSizeOf mallocSizeOf) const { return mallocSizeOf(this) + sizeOfExcludingThis(mallocSizeOf); } void runHelperThreadTask(AutoLockHelperThreadState& locked) override; [[nodiscard]] bool runTask(JSContext* cx); ThreadType threadType() override { return ThreadType::THREAD_TYPE_DELAZIFY; } }; // The FreeDelazifyTask exists as this is a bad practice to `js_delete(this)`, // as fields might be aliased across the destructor, such as with RAII guards. // The FreeDelazifyTask limits the risk of adding these kind of issues by // limiting the number of fields to the DelazifyTask pointer, before deleting // it-self. struct FreeDelazifyTask : public HelperThreadTask { DelazifyTask* task; explicit FreeDelazifyTask(DelazifyTask* t) : task(t) {} void runHelperThreadTask(AutoLockHelperThreadState& locked) override; ThreadType threadType() override { return ThreadType::THREAD_TYPE_DELAZIFY_FREE; } }; // It is not desirable to eagerly compress: if lazy functions that are tied to // the ScriptSource were to be executed relatively soon after parsing, they // would need to block on decompression, which hurts responsiveness. // // To this end, compression tasks are heap allocated and enqueued in a pending // list by ScriptSource::setSourceCopy. When a major GC occurs, we schedule // pending compression tasks and move the ones that are ready to be compressed // to the worklist. Currently, a compression task is considered ready 2 major // GCs after being enqueued. Completed tasks are handled during the sweeping // phase by AttachCompressedSourcesTask, which runs in parallel with other GC // sweeping tasks. class SourceCompressionTask : public HelperThreadTask { friend class HelperThread; friend class ScriptSource; // The runtime that the ScriptSource is associated with, in the sense that // it uses the runtime's immutable string cache. JSRuntime* runtime_; // The major GC number of the runtime when the task was enqueued. uint64_t majorGCNumber_; // The source to be compressed. RefPtr source_; // The resultant compressed string. If the compressed string is larger // than the original, or we OOM'd during compression, or nothing else // except the task is holding the ScriptSource alive when scheduled to // compress, this will remain None upon completion. SharedImmutableString resultString_; public: // The majorGCNumber is used for scheduling tasks. SourceCompressionTask(JSRuntime* rt, ScriptSource* source) : runtime_(rt), majorGCNumber_(rt->gc.majorGCCount()), source_(source) { source->noteSourceCompressionTask(); } virtual ~SourceCompressionTask() = default; bool runtimeMatches(JSRuntime* runtime) const { return runtime == runtime_; } bool shouldStart() const { // We wait 2 major GCs to start compressing, in order to avoid // immediate compression. return runtime_->gc.majorGCCount() > majorGCNumber_ + 1; } bool shouldCancel() const { // If the refcount is exactly 1, then nothing else is holding on to the // ScriptSource, so no reason to compress it and we should cancel the task. return source_->refs == 1; } void runTask(); void runHelperThreadTask(AutoLockHelperThreadState& locked) override; void complete(); ThreadType threadType() override { return ThreadType::THREAD_TYPE_COMPRESS; } private: struct PerformTaskWork; friend struct PerformTaskWork; // The work algorithm, aware whether it's compressing one-byte UTF-8 source // text or UTF-16, for CharT either Utf8Unit or char16_t. Invoked by // work() after doing a type-test of the ScriptSource*. template void workEncodingSpecific(); }; // A PromiseHelperTask is an OffThreadPromiseTask that executes a single job on // a helper thread. Call js::StartOffThreadPromiseHelperTask to submit a // PromiseHelperTask for execution. // // Concrete subclasses must implement execute and OffThreadPromiseTask::resolve. // The helper thread will call execute() to do the main work. Then, the thread // of the JSContext used to create the PromiseHelperTask will call resolve() to // resolve promise according to those results. struct PromiseHelperTask : OffThreadPromiseTask, public HelperThreadTask { PromiseHelperTask(JSContext* cx, Handle promise) : OffThreadPromiseTask(cx, promise) {} // To be called on a helper thread and implemented by the derived class. virtual void execute() = 0; // May be called in the absence of helper threads or off-thread promise // support to synchronously execute and resolve a PromiseTask. // // Warning: After this function returns, 'this' can be deleted at any time, so // the caller must immediately return from the stream callback. void executeAndResolveAndDestroy(JSContext* cx); void runHelperThreadTask(AutoLockHelperThreadState& locked) override; ThreadType threadType() override { return THREAD_TYPE_PROMISE_TASK; } }; } /* namespace js */ #endif /* vm_HelperThreadState_h */