// Copyright 2015 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. #include "src/cancelable-task.h" #include "src/base/platform/platform.h" #include "src/isolate.h" namespace v8 { namespace internal { Cancelable::Cancelable(CancelableTaskManager* parent) : parent_(parent), status_(kWaiting), id_(0), cancel_counter_(0) { id_ = parent->Register(this); } Cancelable::~Cancelable() { // The following check is needed to avoid calling an already terminated // manager object. This happens when the manager cancels all pending tasks // in {CancelAndWait} only before destroying the manager object. if (TryRun() || IsRunning()) { parent_->RemoveFinishedTask(id_); } } CancelableTaskManager::CancelableTaskManager() : task_id_counter_(0), canceled_(false) {} uint32_t CancelableTaskManager::Register(Cancelable* task) { base::LockGuard<base::Mutex> guard(&mutex_); uint32_t id = ++task_id_counter_; // The loop below is just used when task_id_counter_ overflows. while (cancelable_tasks_.count(id) > 0) ++id; CHECK(!canceled_); cancelable_tasks_[id] = task; return id; } void CancelableTaskManager::RemoveFinishedTask(uint32_t id) { base::LockGuard<base::Mutex> guard(&mutex_); size_t removed = cancelable_tasks_.erase(id); USE(removed); DCHECK_NE(0u, removed); cancelable_tasks_barrier_.NotifyOne(); } CancelableTaskManager::TryAbortResult CancelableTaskManager::TryAbort( uint32_t id) { base::LockGuard<base::Mutex> guard(&mutex_); auto entry = cancelable_tasks_.find(id); if (entry != cancelable_tasks_.end()) { Cancelable* value = entry->second; if (value->Cancel()) { // Cannot call RemoveFinishedTask here because of recursive locking. cancelable_tasks_.erase(entry); cancelable_tasks_barrier_.NotifyOne(); return kTaskAborted; } else { return kTaskRunning; } } return kTaskRemoved; } void CancelableTaskManager::CancelAndWait() { // Clean up all cancelable fore- and background tasks. Tasks are canceled on // the way if possible, i.e., if they have not started yet. After each round // of canceling we wait for the background tasks that have already been // started. base::LockGuard<base::Mutex> guard(&mutex_); canceled_ = true; // Cancelable tasks could be running or could potentially register new // tasks, requiring a loop here. while (!cancelable_tasks_.empty()) { for (auto it = cancelable_tasks_.begin(); it != cancelable_tasks_.end();) { auto current = it; // We need to get to the next element before erasing the current. ++it; if (current->second->Cancel()) { cancelable_tasks_.erase(current); } } // Wait for already running background tasks. if (!cancelable_tasks_.empty()) { cancelable_tasks_barrier_.Wait(&mutex_); } } } CancelableTaskManager::TryAbortResult CancelableTaskManager::TryAbortAll() { // Clean up all cancelable fore- and background tasks. Tasks are canceled on // the way if possible, i.e., if they have not started yet. base::LockGuard<base::Mutex> guard(&mutex_); if (cancelable_tasks_.empty()) return kTaskRemoved; for (auto it = cancelable_tasks_.begin(); it != cancelable_tasks_.end();) { if (it->second->Cancel()) { it = cancelable_tasks_.erase(it); } else { ++it; } } return cancelable_tasks_.empty() ? kTaskAborted : kTaskRunning; } CancelableTask::CancelableTask(Isolate* isolate) : CancelableTask(isolate, isolate->cancelable_task_manager()) {} CancelableTask::CancelableTask(Isolate* isolate, CancelableTaskManager* manager) : Cancelable(manager), isolate_(isolate) {} CancelableIdleTask::CancelableIdleTask(Isolate* isolate) : CancelableIdleTask(isolate, isolate->cancelable_task_manager()) {} CancelableIdleTask::CancelableIdleTask(Isolate* isolate, CancelableTaskManager* manager) : Cancelable(manager), isolate_(isolate) {} } // namespace internal } // namespace v8