// 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. #ifndef V8_CANCELABLE_TASK_H_ #define V8_CANCELABLE_TASK_H_ #include #include "include/v8-platform.h" #include "src/base/atomic-utils.h" #include "src/base/macros.h" #include "src/base/platform/condition-variable.h" namespace v8 { namespace internal { class Cancelable; class Isolate; // Keeps track of cancelable tasks. It is possible to register and remove tasks // from any fore- and background task/thread. class CancelableTaskManager { public: CancelableTaskManager(); // Registers a new cancelable {task}. Returns the unique {id} of the task that // can be used to try to abort a task by calling {Abort}. uint32_t Register(Cancelable* task); // Try to abort running a task identified by {id}. The possible outcomes are: // (1) The task is already finished running and thus has been removed from // the manager. // (2) The task is currently running and cannot be canceled anymore. // (3) The task is not yet running (or finished) so it is canceled and // removed. // // Returns {false} for (1) and (2), and {true} for (3). bool TryAbort(uint32_t id); // Cancels all remaining registered tasks and waits for tasks that are // already running. void CancelAndWait(); private: // Only called by {Cancelable} destructor. The task is done with executing, // but needs to be removed. void RemoveFinishedTask(uint32_t id); // To mitigate the ABA problem, the api refers to tasks through an id. uint32_t task_id_counter_; // A set of cancelable tasks that are currently registered. std::map cancelable_tasks_; // Mutex and condition variable enabling concurrent register and removing, as // well as waiting for background tasks on {CancelAndWait}. base::ConditionVariable cancelable_tasks_barrier_; base::Mutex mutex_; friend class Cancelable; DISALLOW_COPY_AND_ASSIGN(CancelableTaskManager); }; class Cancelable { public: explicit Cancelable(CancelableTaskManager* parent); virtual ~Cancelable(); // Never invoke after handing over the task to the platform! The reason is // that {Cancelable} is used in combination with {v8::Task} and handed to // a platform. This step transfers ownership to the platform, which destroys // the task after running it. Since the exact time is not known, we cannot // access the object after handing it to a platform. uint32_t id() { return id_; } protected: bool TryRun() { return status_.TrySetValue(kWaiting, kRunning); } bool IsRunning() { return status_.Value() == kRunning; } intptr_t CancelAttempts() { return cancel_counter_.Value(); } private: // Identifies the state a cancelable task is in: // |kWaiting|: The task is scheduled and waiting to be executed. {TryRun} will // succeed. // |kCanceled|: The task has been canceled. {TryRun} will fail. // |kRunning|: The task is currently running and cannot be canceled anymore. enum Status { kWaiting, kCanceled, kRunning, }; // Use {CancelableTaskManager} to abort a task that has not yet been // executed. bool Cancel() { if (status_.TrySetValue(kWaiting, kCanceled)) { return true; } cancel_counter_.Increment(1); return false; } CancelableTaskManager* parent_; base::AtomicValue status_; uint32_t id_; // The counter is incremented for failing tries to cancel a task. This can be // used by the task itself as an indication how often external entities tried // to abort it. base::AtomicNumber cancel_counter_; friend class CancelableTaskManager; DISALLOW_COPY_AND_ASSIGN(Cancelable); }; // Multiple inheritance can be used because Task is a pure interface. class CancelableTask : public Cancelable, public Task { public: explicit CancelableTask(Isolate* isolate); // Task overrides. void Run() final { if (TryRun()) { RunInternal(); } } virtual void RunInternal() = 0; Isolate* isolate() { return isolate_; } private: Isolate* isolate_; DISALLOW_COPY_AND_ASSIGN(CancelableTask); }; // Multiple inheritance can be used because IdleTask is a pure interface. class CancelableIdleTask : public Cancelable, public IdleTask { public: explicit CancelableIdleTask(Isolate* isolate); // IdleTask overrides. void Run(double deadline_in_seconds) final { if (TryRun()) { RunInternal(deadline_in_seconds); } } virtual void RunInternal(double deadline_in_seconds) = 0; Isolate* isolate() { return isolate_; } private: Isolate* isolate_; DISALLOW_COPY_AND_ASSIGN(CancelableIdleTask); }; } // namespace internal } // namespace v8 #endif // V8_CANCELABLE_TASK_H_