// Copyright 2016 the V8 project authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. #ifndef V8_HEAP_PAGE_PARALLEL_JOB_ #define V8_HEAP_PAGE_PARALLEL_JOB_ #include "src/allocation.h" #include "src/cancelable-task.h" #include "src/utils.h" #include "src/v8.h" namespace v8 { namespace internal { class Heap; class Isolate; // This class manages background tasks that process set of pages in parallel. // The JobTraits class needs to define: // - PerPageData type - state associated with each page. // - PerTaskData type - state associated with each task. // - static bool ProcessPageInParallel(Heap* heap, // PerTaskData task_data, // MemoryChunk* page, // PerPageData page_data) // The function should return true iff processing succeeded. // - static const bool NeedSequentialFinalization // - static void FinalizePageSequentially(Heap* heap, // bool processing_succeeded, // MemoryChunk* page, // PerPageData page_data) template class PageParallelJob { public: // PageParallelJob cannot dynamically create a semaphore because of a bug in // glibc. See http://crbug.com/609249 and // https://sourceware.org/bugzilla/show_bug.cgi?id=12674. // The caller must provide a semaphore with value 0 and ensure that // the lifetime of the semaphore is the same as the lifetime of the Isolate. // It is guaranteed that the semaphore value will be 0 after Run() call. PageParallelJob(Heap* heap, CancelableTaskManager* cancelable_task_manager, base::Semaphore* semaphore) : heap_(heap), cancelable_task_manager_(cancelable_task_manager), items_(nullptr), num_items_(0), num_tasks_(0), pending_tasks_(semaphore) {} ~PageParallelJob() { Item* item = items_; while (item != nullptr) { Item* next = item->next; delete item; item = next; } } void AddPage(MemoryChunk* chunk, typename JobTraits::PerPageData data) { Item* item = new Item(chunk, data, items_); items_ = item; ++num_items_; } int NumberOfPages() { return num_items_; } // Returns the number of tasks that were spawned when running the job. int NumberOfTasks() { return num_tasks_; } // Runs the given number of tasks in parallel and processes the previously // added pages. This function blocks until all tasks finish. // The callback takes the index of a task and returns data for that task. template void Run(int num_tasks, Callback per_task_data_callback) { if (num_items_ == 0) return; DCHECK_GE(num_tasks, 1); uint32_t task_ids[kMaxNumberOfTasks]; const int max_num_tasks = Min( kMaxNumberOfTasks, static_cast( V8::GetCurrentPlatform()->NumberOfAvailableBackgroundThreads())); num_tasks_ = Max(1, Min(num_tasks, max_num_tasks)); int items_per_task = (num_items_ + num_tasks_ - 1) / num_tasks_; int start_index = 0; Task* main_task = nullptr; for (int i = 0; i < num_tasks_; i++, start_index += items_per_task) { if (start_index >= num_items_) { start_index -= num_items_; } Task* task = new Task(heap_, items_, num_items_, start_index, pending_tasks_, per_task_data_callback(i)); task_ids[i] = task->id(); if (i > 0) { V8::GetCurrentPlatform()->CallOnBackgroundThread( task, v8::Platform::kShortRunningTask); } else { main_task = task; } } // Contribute on main thread. main_task->Run(); delete main_task; // Wait for background tasks. for (int i = 0; i < num_tasks_; i++) { if (cancelable_task_manager_->TryAbort(task_ids[i]) != CancelableTaskManager::kTaskAborted) { pending_tasks_->Wait(); } } if (JobTraits::NeedSequentialFinalization) { Item* item = items_; while (item != nullptr) { bool success = (item->state.Value() == kFinished); JobTraits::FinalizePageSequentially(heap_, item->chunk, success, item->data); item = item->next; } } } private: static const int kMaxNumberOfTasks = 10; enum ProcessingState { kAvailable, kProcessing, kFinished, kFailed }; struct Item : public Malloced { Item(MemoryChunk* chunk, typename JobTraits::PerPageData data, Item* next) : chunk(chunk), state(kAvailable), data(data), next(next) {} MemoryChunk* chunk; base::AtomicValue state; typename JobTraits::PerPageData data; Item* next; }; class Task : public CancelableTask { public: Task(Heap* heap, Item* items, int num_items, int start_index, base::Semaphore* on_finish, typename JobTraits::PerTaskData data) : CancelableTask(heap->isolate()), heap_(heap), items_(items), num_items_(num_items), start_index_(start_index), on_finish_(on_finish), data_(data) {} virtual ~Task() {} private: // v8::internal::CancelableTask overrides. void RunInternal() override { // Each task starts at a different index to improve parallelization. Item* current = items_; int skip = start_index_; while (skip-- > 0) { current = current->next; } for (int i = 0; i < num_items_; i++) { if (current->state.TrySetValue(kAvailable, kProcessing)) { bool success = JobTraits::ProcessPageInParallel( heap_, data_, current->chunk, current->data); current->state.SetValue(success ? kFinished : kFailed); } current = current->next; // Wrap around if needed. if (current == nullptr) { current = items_; } } on_finish_->Signal(); } Heap* heap_; Item* items_; int num_items_; int start_index_; base::Semaphore* on_finish_; typename JobTraits::PerTaskData data_; DISALLOW_COPY_AND_ASSIGN(Task); }; Heap* heap_; CancelableTaskManager* cancelable_task_manager_; Item* items_; int num_items_; int num_tasks_; base::Semaphore* pending_tasks_; DISALLOW_COPY_AND_ASSIGN(PageParallelJob); }; } // namespace internal } // namespace v8 #endif // V8_HEAP_PAGE_PARALLEL_JOB_