rtc_base/task_queue.h - src/webrtc - Git at Google

 /*
  *  Copyright 2016 The WebRTC 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 in the root of the source
  *  tree. An additional intellectual property rights grant can be found
  *  in the file PATENTS.  All contributing project authors may
  *  be found in the AUTHORS file in the root of the source tree.
  */

 #ifndef WEBRTC_RTC_BASE_TASK_QUEUE_H_
 #define WEBRTC_RTC_BASE_TASK_QUEUE_H_

 #include <list>
 #include <memory>
 #include <queue>
 #include <type_traits>

 #include "webrtc/rtc_base/constructormagic.h"
 #include "webrtc/rtc_base/criticalsection.h"
 #include "webrtc/rtc_base/scoped_ref_ptr.h"

 namespace rtc {

 // Base interface for asynchronously executed tasks.
 // The interface basically consists of a single function, Run(), that executes
 // on the target queue.  For more details see the Run() method and TaskQueue.
 class QueuedTask {
  public:
   QueuedTask() {}
   virtual ~QueuedTask() {}

   // Main routine that will run when the task is executed on the desired queue.
   // The task should return |true| to indicate that it should be deleted or
   // |false| to indicate that the queue should consider ownership of the task
   // having been transferred.  Returning |false| can be useful if a task has
   // re-posted itself to a different queue or is otherwise being re-used.
   virtual bool Run() = 0;

  private:
   RTC_DISALLOW_COPY_AND_ASSIGN(QueuedTask);
 };

 // Simple implementation of QueuedTask for use with rtc::Bind and lambdas.
 template <class Closure>
 class ClosureTask : public QueuedTask {
  public:
   explicit ClosureTask(const Closure& closure) : closure_(closure) {}

  private:
   bool Run() override {
     closure_();
     return true;
   }

   Closure closure_;
 };

 // Extends ClosureTask to also allow specifying cleanup code.
 // This is useful when using lambdas if guaranteeing cleanup, even if a task
 // was dropped (queue is too full), is required.
 template <class Closure, class Cleanup>
 class ClosureTaskWithCleanup : public ClosureTask<Closure> {
  public:
   ClosureTaskWithCleanup(const Closure& closure, Cleanup cleanup)
       : ClosureTask<Closure>(closure), cleanup_(cleanup) {}
   ~ClosureTaskWithCleanup() { cleanup_(); }

  private:
   Cleanup cleanup_;
 };

 // Convenience function to construct closures that can be passed directly
 // to methods that support std::unique_ptr<QueuedTask> but not template
 // based parameters.
 template <class Closure>
 static std::unique_ptr<QueuedTask> NewClosure(const Closure& closure) {
   return std::unique_ptr<QueuedTask>(new ClosureTask<Closure>(closure));
 }

 template <class Closure, class Cleanup>
 static std::unique_ptr<QueuedTask> NewClosure(const Closure& closure,
                                               const Cleanup& cleanup) {
   return std::unique_ptr<QueuedTask>(
       new ClosureTaskWithCleanup<Closure, Cleanup>(closure, cleanup));
 }

 // Implements a task queue that asynchronously executes tasks in a way that
 // guarantees that they're executed in FIFO order and that tasks never overlap.
 // Tasks may always execute on the same worker thread and they may not.
 // To DCHECK that tasks are executing on a known task queue, use IsCurrent().
 //
 // Here are some usage examples:
 //
 //   1) Asynchronously running a lambda:
 //
 //     class MyClass {
 //       ...
 //       TaskQueue queue_("MyQueue");
 //     };
 //
 //     void MyClass::StartWork() {
 //       queue_.PostTask([]() { Work(); });
 //     ...
 //
 //   2) Doing work asynchronously on a worker queue and providing a notification
 //      callback on the current queue, when the work has been done:
 //
 //     void MyClass::StartWorkAndLetMeKnowWhenDone(
 //         std::unique_ptr<QueuedTask> callback) {
 //       DCHECK(TaskQueue::Current()) << "Need to be running on a queue";
 //       queue_.PostTaskAndReply([]() { Work(); }, std::move(callback));
 //     }
 //     ...
 //     my_class->StartWorkAndLetMeKnowWhenDone(
 //         NewClosure([]() { LOG(INFO) << "The work is done!";}));
 //
 //   3) Posting a custom task on a timer.  The task posts itself again after
 //      every running:
 //
 //     class TimerTask : public QueuedTask {
 //      public:
 //       TimerTask() {}
 //      private:
 //       bool Run() override {
 //         ++count_;
 //         TaskQueue::Current()->PostDelayedTask(
 //             std::unique_ptr<QueuedTask>(this), 1000);
 //         // Ownership has been transferred to the next occurance,
 //         // so return false to prevent from being deleted now.
 //         return false;
 //       }
 //       int count_ = 0;
 //     };
 //     ...
 //     queue_.PostDelayedTask(
 //         std::unique_ptr<QueuedTask>(new TimerTask()), 1000);
 //
 // For more examples, see task_queue_unittests.cc.
 //
 // A note on destruction:
 //
 // When a TaskQueue is deleted, pending tasks will not be executed but they will
 // be deleted.  The deletion of tasks may happen asynchronously after the
 // TaskQueue itself has been deleted or it may happen synchronously while the
 // TaskQueue instance is being deleted.  This may vary from one OS to the next
 // so assumptions about lifetimes of pending tasks should not be made.
 class RTC_LOCKABLE TaskQueue {
  public:
   // TaskQueue priority levels. On some platforms these will map to thread
   // priorities, on others such as Mac and iOS, GCD queue priorities.
   enum class Priority {
     NORMAL = 0,
     HIGH,
     LOW,
   };

   explicit TaskQueue(const char* queue_name,
                      Priority priority = Priority::NORMAL);
   ~TaskQueue();

   static TaskQueue* Current();

   // Used for DCHECKing the current queue.
   bool IsCurrent() const;

   // TODO(tommi): For better debuggability, implement RTC_FROM_HERE.

   // Ownership of the task is passed to PostTask.
   void PostTask(std::unique_ptr<QueuedTask> task);
   void PostTaskAndReply(std::unique_ptr<QueuedTask> task,
                         std::unique_ptr<QueuedTask> reply,
                         TaskQueue* reply_queue);
   void PostTaskAndReply(std::unique_ptr<QueuedTask> task,
                         std::unique_ptr<QueuedTask> reply);

   // Schedules a task to execute a specified number of milliseconds from when
   // the call is made. The precision should be considered as "best effort"
   // and in some cases, such as on Windows when all high precision timers have
   // been used up, can be off by as much as 15 millseconds (although 8 would be
   // more likely). This can be mitigated by limiting the use of delayed tasks.
   void PostDelayedTask(std::unique_ptr<QueuedTask> task, uint32_t milliseconds);

   // std::enable_if is used here to make sure that calls to PostTask() with
   // std::unique_ptr<SomeClassDerivedFromQueuedTask> would not end up being
   // caught by this template.
   template <class Closure,
             typename std::enable_if<
                 std::is_copy_constructible<Closure>::value>::type* = nullptr>
   void PostTask(const Closure& closure) {
     PostTask(std::unique_ptr<QueuedTask>(new ClosureTask<Closure>(closure)));
   }

   // See documentation above for performance expectations.
   template <class Closure>
   void PostDelayedTask(const Closure& closure, uint32_t milliseconds) {
     PostDelayedTask(
         std::unique_ptr<QueuedTask>(new ClosureTask<Closure>(closure)),
         milliseconds);
   }

   template <class Closure1, class Closure2>
   void PostTaskAndReply(const Closure1& task,
                         const Closure2& reply,
                         TaskQueue* reply_queue) {
     PostTaskAndReply(
         std::unique_ptr<QueuedTask>(new ClosureTask<Closure1>(task)),
         std::unique_ptr<QueuedTask>(new ClosureTask<Closure2>(reply)),
         reply_queue);
   }

   template <class Closure>
   void PostTaskAndReply(std::unique_ptr<QueuedTask> task,
                         const Closure& reply) {
     PostTaskAndReply(std::move(task), std::unique_ptr<QueuedTask>(
                                           new ClosureTask<Closure>(reply)));
   }

   template <class Closure>
   void PostTaskAndReply(const Closure& task,
                         std::unique_ptr<QueuedTask> reply) {
     PostTaskAndReply(
         std::unique_ptr<QueuedTask>(new ClosureTask<Closure>(task)),
         std::move(reply));
   }

   template <class Closure1, class Closure2>
   void PostTaskAndReply(const Closure1& task, const Closure2& reply) {
     PostTaskAndReply(
         std::unique_ptr<QueuedTask>(new ClosureTask<Closure1>(task)),
         std::unique_ptr<QueuedTask>(new ClosureTask<Closure2>(reply)));
   }

  private:
   class Impl;
   const scoped_refptr<Impl> impl_;

   RTC_DISALLOW_COPY_AND_ASSIGN(TaskQueue);
 };

 }  // namespace rtc

 #endif  // WEBRTC_RTC_BASE_TASK_QUEUE_H_
	/*
	* Copyright 2016 The WebRTC 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 in the root of the source
	* tree. An additional intellectual property rights grant can be found
	* in the file PATENTS. All contributing project authors may
	* be found in the AUTHORS file in the root of the source tree.
	*/

	#ifndef WEBRTC_RTC_BASE_TASK_QUEUE_H_
	#define WEBRTC_RTC_BASE_TASK_QUEUE_H_

	#include <list>
	#include <memory>
	#include <queue>
	#include <type_traits>

	#include "webrtc/rtc_base/constructormagic.h"
	#include "webrtc/rtc_base/criticalsection.h"
	#include "webrtc/rtc_base/scoped_ref_ptr.h"

	namespace rtc {

	// Base interface for asynchronously executed tasks.
	// The interface basically consists of a single function, Run(), that executes
	// on the target queue. For more details see the Run() method and TaskQueue.
	class QueuedTask {
	public:
	QueuedTask() {}
	virtual ~QueuedTask() {}

	// Main routine that will run when the task is executed on the desired queue.
	// The task should return \|true\| to indicate that it should be deleted or
	// \|false\| to indicate that the queue should consider ownership of the task
	// having been transferred. Returning \|false\| can be useful if a task has
	// re-posted itself to a different queue or is otherwise being re-used.
	virtual bool Run() = 0;

	private:
	RTC_DISALLOW_COPY_AND_ASSIGN(QueuedTask);
	};

	// Simple implementation of QueuedTask for use with rtc::Bind and lambdas.
	template <class Closure>
	class ClosureTask : public QueuedTask {
	public:
	explicit ClosureTask(const Closure& closure) : closure_(closure) {}

	private:
	bool Run() override {
	closure_();
	return true;
	}

	Closure closure_;
	};

	// Extends ClosureTask to also allow specifying cleanup code.
	// This is useful when using lambdas if guaranteeing cleanup, even if a task
	// was dropped (queue is too full), is required.
	template <class Closure, class Cleanup>
	class ClosureTaskWithCleanup : public ClosureTask<Closure> {
	public:
	ClosureTaskWithCleanup(const Closure& closure, Cleanup cleanup)
	: ClosureTask<Closure>(closure), cleanup_(cleanup) {}
	~ClosureTaskWithCleanup() { cleanup_(); }

	private:
	Cleanup cleanup_;
	};

	// Convenience function to construct closures that can be passed directly
	// to methods that support std::unique_ptr<QueuedTask> but not template
	// based parameters.
	template <class Closure>
	static std::unique_ptr<QueuedTask> NewClosure(const Closure& closure) {
	return std::unique_ptr<QueuedTask>(new ClosureTask<Closure>(closure));
	}

	template <class Closure, class Cleanup>
	static std::unique_ptr<QueuedTask> NewClosure(const Closure& closure,
	const Cleanup& cleanup) {
	return std::unique_ptr<QueuedTask>(
	new ClosureTaskWithCleanup<Closure, Cleanup>(closure, cleanup));
	}

	// Implements a task queue that asynchronously executes tasks in a way that
	// guarantees that they're executed in FIFO order and that tasks never overlap.
	// Tasks may always execute on the same worker thread and they may not.
	// To DCHECK that tasks are executing on a known task queue, use IsCurrent().
	//
	// Here are some usage examples:
	//
	// 1) Asynchronously running a lambda:
	//
	// class MyClass {
	// ...
	// TaskQueue queue_("MyQueue");
	// };
	//
	// void MyClass::StartWork() {
	// queue_.PostTask([]() { Work(); });
	// ...
	//
	// 2) Doing work asynchronously on a worker queue and providing a notification
	// callback on the current queue, when the work has been done:
	//
	// void MyClass::StartWorkAndLetMeKnowWhenDone(
	// std::unique_ptr<QueuedTask> callback) {
	// DCHECK(TaskQueue::Current()) << "Need to be running on a queue";
	// queue_.PostTaskAndReply([]() { Work(); }, std::move(callback));
	// }
	// ...
	// my_class->StartWorkAndLetMeKnowWhenDone(
	// NewClosure([]() { LOG(INFO) << "The work is done!";}));
	//
	// 3) Posting a custom task on a timer. The task posts itself again after
	// every running:
	//
	// class TimerTask : public QueuedTask {
	// public:
	// TimerTask() {}
	// private:
	// bool Run() override {
	// ++count_;
	// TaskQueue::Current()->PostDelayedTask(
	// std::unique_ptr<QueuedTask>(this), 1000);
	// // Ownership has been transferred to the next occurance,
	// // so return false to prevent from being deleted now.
	// return false;
	// }
	// int count_ = 0;
	// };
	// ...
	// queue_.PostDelayedTask(
	// std::unique_ptr<QueuedTask>(new TimerTask()), 1000);
	//
	// For more examples, see task_queue_unittests.cc.
	//
	// A note on destruction:
	//
	// When a TaskQueue is deleted, pending tasks will not be executed but they will
	// be deleted. The deletion of tasks may happen asynchronously after the
	// TaskQueue itself has been deleted or it may happen synchronously while the
	// TaskQueue instance is being deleted. This may vary from one OS to the next
	// so assumptions about lifetimes of pending tasks should not be made.
	class RTC_LOCKABLE TaskQueue {
	public:
	// TaskQueue priority levels. On some platforms these will map to thread
	// priorities, on others such as Mac and iOS, GCD queue priorities.
	enum class Priority {
	NORMAL = 0,
	HIGH,
	LOW,
	};

	explicit TaskQueue(const char* queue_name,
	Priority priority = Priority::NORMAL);
	~TaskQueue();

	static TaskQueue* Current();

	// Used for DCHECKing the current queue.
	bool IsCurrent() const;

	// TODO(tommi): For better debuggability, implement RTC_FROM_HERE.

	// Ownership of the task is passed to PostTask.
	void PostTask(std::unique_ptr<QueuedTask> task);
	void PostTaskAndReply(std::unique_ptr<QueuedTask> task,
	std::unique_ptr<QueuedTask> reply,
	TaskQueue* reply_queue);
	void PostTaskAndReply(std::unique_ptr<QueuedTask> task,
	std::unique_ptr<QueuedTask> reply);

	// Schedules a task to execute a specified number of milliseconds from when
	// the call is made. The precision should be considered as "best effort"
	// and in some cases, such as on Windows when all high precision timers have
	// been used up, can be off by as much as 15 millseconds (although 8 would be
	// more likely). This can be mitigated by limiting the use of delayed tasks.
	void PostDelayedTask(std::unique_ptr<QueuedTask> task, uint32_t milliseconds);

	// std::enable_if is used here to make sure that calls to PostTask() with
	// std::unique_ptr<SomeClassDerivedFromQueuedTask> would not end up being
	// caught by this template.
	template <class Closure,
	typename std::enable_if<
	std::is_copy_constructible<Closure>::value>::type* = nullptr>
	void PostTask(const Closure& closure) {
	PostTask(std::unique_ptr<QueuedTask>(new ClosureTask<Closure>(closure)));
	}

	// See documentation above for performance expectations.
	template <class Closure>
	void PostDelayedTask(const Closure& closure, uint32_t milliseconds) {
	PostDelayedTask(
	std::unique_ptr<QueuedTask>(new ClosureTask<Closure>(closure)),
	milliseconds);
	}

	template <class Closure1, class Closure2>
	void PostTaskAndReply(const Closure1& task,
	const Closure2& reply,
	TaskQueue* reply_queue) {
	PostTaskAndReply(
	std::unique_ptr<QueuedTask>(new ClosureTask<Closure1>(task)),
	std::unique_ptr<QueuedTask>(new ClosureTask<Closure2>(reply)),
	reply_queue);
	}

	template <class Closure>
	void PostTaskAndReply(std::unique_ptr<QueuedTask> task,
	const Closure& reply) {
	PostTaskAndReply(std::move(task), std::unique_ptr<QueuedTask>(
	new ClosureTask<Closure>(reply)));
	}

	template <class Closure>
	void PostTaskAndReply(const Closure& task,
	std::unique_ptr<QueuedTask> reply) {
	PostTaskAndReply(
	std::unique_ptr<QueuedTask>(new ClosureTask<Closure>(task)),
	std::move(reply));
	}

	template <class Closure1, class Closure2>
	void PostTaskAndReply(const Closure1& task, const Closure2& reply) {
	PostTaskAndReply(
	std::unique_ptr<QueuedTask>(new ClosureTask<Closure1>(task)),
	std::unique_ptr<QueuedTask>(new ClosureTask<Closure2>(reply)));
	}

	private:
	class Impl;
	const scoped_refptr<Impl> impl_;

	RTC_DISALLOW_COPY_AND_ASSIGN(TaskQueue);
	};

	} // namespace rtc

	#endif // WEBRTC_RTC_BASE_TASK_QUEUE_H_