api/task_queue/pending_task_safety_flag.h - src - Git at Google

 /*
  *  Copyright 2020 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 API_TASK_QUEUE_PENDING_TASK_SAFETY_FLAG_H_
 #define API_TASK_QUEUE_PENDING_TASK_SAFETY_FLAG_H_

 #include <utility>

 #include "absl/functional/any_invocable.h"
 #include "api/ref_counted_base.h"
 #include "api/scoped_refptr.h"
 #include "api/sequence_checker.h"
 #include "rtc_base/checks.h"
 #include "rtc_base/system/no_unique_address.h"

 namespace webrtc {

 // The PendingTaskSafetyFlag and the ScopedTaskSafety are designed to address
 // the issue where you have a task to be executed later that has references,
 // but cannot guarantee that the referenced object is alive when the task is
 // executed.

 // This mechanism can be used with tasks that are created and destroyed
 // on a single thread / task queue, and with tasks posted to the same
 // thread/task queue, but tasks can be posted from any thread/TQ.

 // Typical usage:
 // When posting a task, post a copy (capture by-value in a lambda) of the flag
 // reference and before performing the work, check the `alive()` state. Abort if
 // alive() returns `false`:
 //
 // class ExampleClass {
 // ....
 //    rtc::scoped_refptr<PendingTaskSafetyFlag> flag = safety_flag_;
 //    my_task_queue_->PostTask(
 //        [flag = std::move(flag), this] {
 //          // Now running on the main thread.
 //          if (!flag->alive())
 //            return;
 //          MyMethod();
 //        });
 //   ....
 //   ~ExampleClass() {
 //     safety_flag_->SetNotAlive();
 //   }
 //   scoped_refptr<PendingTaskSafetyFlag> safety_flag_
 //        = PendingTaskSafetyFlag::Create();
 // }
 //
 // SafeTask makes this check automatic:
 //
 //   my_task_queue_->PostTask(SafeTask(safety_flag_, [this] { MyMethod(); }));
 //
 class PendingTaskSafetyFlag final
     : public rtc::RefCountedNonVirtual<PendingTaskSafetyFlag> {
  public:
   static rtc::scoped_refptr<PendingTaskSafetyFlag> Create();

   // Creates a flag, but with its SequenceChecker initially detached. Hence, it
   // may be created on a different thread than the flag will be used on.
   static rtc::scoped_refptr<PendingTaskSafetyFlag> CreateDetached();

   // Same as `CreateDetached()` except the initial state of the returned flag
   // will be `!alive()`.
   static rtc::scoped_refptr<PendingTaskSafetyFlag> CreateDetachedInactive();

   ~PendingTaskSafetyFlag() = default;

   void SetNotAlive();
   // The SetAlive method is intended to support Start/Stop/Restart usecases.
   // When a class has called SetNotAlive on a flag used for posted tasks, and
   // decides it wants to post new tasks and have them run, there are two
   // reasonable ways to do that:
   //
   // (i) Use the below SetAlive method. One subtlety is that any task posted
   //     prior to SetNotAlive, and still in the queue, is resurrected and will
   //     run.
   //
   // (ii) Create a fresh flag, and just drop the reference to the old one. This
   //      avoids the above problem, and ensures that tasks poster prior to
   //      SetNotAlive stay cancelled. Instead, there's a potential data race on
   //      the flag pointer itself. Some synchronization is required between the
   //      thread overwriting the flag pointer, and the threads that want to post
   //      tasks and therefore read that same pointer.
   void SetAlive();
   bool alive() const;

  protected:
   explicit PendingTaskSafetyFlag(bool alive) : alive_(alive) {}

  private:
   static rtc::scoped_refptr<PendingTaskSafetyFlag> CreateInternal(bool alive);

   bool alive_ = true;
   RTC_NO_UNIQUE_ADDRESS SequenceChecker main_sequence_;
 };

 // The ScopedTaskSafety makes using PendingTaskSafetyFlag very simple.
 // It does automatic PTSF creation and signalling of destruction when the
 // ScopedTaskSafety instance goes out of scope.
 //
 // Example usage:
 //
 //     my_task_queue->PostTask(SafeTask(scoped_task_safety.flag(),
 //        [this] {
 //             // task goes here
 //        }
 //
 // This should be used by the class that wants tasks dropped after destruction.
 // The requirement is that the instance has to be constructed and destructed on
 // the same thread as the potentially dropped tasks would be running on.
 class ScopedTaskSafety final {
  public:
   ScopedTaskSafety() = default;
   explicit ScopedTaskSafety(rtc::scoped_refptr<PendingTaskSafetyFlag> flag)
       : flag_(std::move(flag)) {}
   ~ScopedTaskSafety() { flag_->SetNotAlive(); }

   // Returns a new reference to the safety flag.
   rtc::scoped_refptr<PendingTaskSafetyFlag> flag() const { return flag_; }

   // Marks the current flag as not-alive and attaches to a new one.
   void reset(rtc::scoped_refptr<PendingTaskSafetyFlag> new_flag =
                  PendingTaskSafetyFlag::Create()) {
     flag_->SetNotAlive();
     flag_ = std::move(new_flag);
   }

  private:
   rtc::scoped_refptr<PendingTaskSafetyFlag> flag_ =
       PendingTaskSafetyFlag::Create();
 };

 // Like ScopedTaskSafety, but allows construction on a different thread than
 // where the flag will be used.
 class ScopedTaskSafetyDetached final {
  public:
   ScopedTaskSafetyDetached() = default;
   ~ScopedTaskSafetyDetached() { flag_->SetNotAlive(); }

   // Returns a new reference to the safety flag.
   rtc::scoped_refptr<PendingTaskSafetyFlag> flag() const { return flag_; }

  private:
   rtc::scoped_refptr<PendingTaskSafetyFlag> flag_ =
       PendingTaskSafetyFlag::CreateDetached();
 };

 inline absl::AnyInvocable<void() &&> SafeTask(
     rtc::scoped_refptr<PendingTaskSafetyFlag> flag,
     absl::AnyInvocable<void() &&> task) {
   return [flag = std::move(flag), task = std::move(task)]() mutable {
     if (flag->alive()) {
       std::move(task)();
     }
   };
 }

 }  // namespace webrtc

 #endif  // API_TASK_QUEUE_PENDING_TASK_SAFETY_FLAG_H_
	/*
	* Copyright 2020 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 API_TASK_QUEUE_PENDING_TASK_SAFETY_FLAG_H_
	#define API_TASK_QUEUE_PENDING_TASK_SAFETY_FLAG_H_

	#include <utility>

	#include "absl/functional/any_invocable.h"
	#include "api/ref_counted_base.h"
	#include "api/scoped_refptr.h"
	#include "api/sequence_checker.h"
	#include "rtc_base/checks.h"
	#include "rtc_base/system/no_unique_address.h"

	namespace webrtc {

	// The PendingTaskSafetyFlag and the ScopedTaskSafety are designed to address
	// the issue where you have a task to be executed later that has references,
	// but cannot guarantee that the referenced object is alive when the task is
	// executed.

	// This mechanism can be used with tasks that are created and destroyed
	// on a single thread / task queue, and with tasks posted to the same
	// thread/task queue, but tasks can be posted from any thread/TQ.

	// Typical usage:
	// When posting a task, post a copy (capture by-value in a lambda) of the flag
	// reference and before performing the work, check the `alive()` state. Abort if
	// alive() returns `false`:
	//
	// class ExampleClass {
	// ....
	// rtc::scoped_refptr<PendingTaskSafetyFlag> flag = safety_flag_;
	// my_task_queue_->PostTask(
	// [flag = std::move(flag), this] {
	// // Now running on the main thread.
	// if (!flag->alive())
	// return;
	// MyMethod();
	// });
	// ....
	// ~ExampleClass() {
	// safety_flag_->SetNotAlive();
	// }
	// scoped_refptr<PendingTaskSafetyFlag> safety_flag_
	// = PendingTaskSafetyFlag::Create();
	// }
	//
	// SafeTask makes this check automatic:
	//
	// my_task_queue_->PostTask(SafeTask(safety_flag_, [this] { MyMethod(); }));
	//
	class PendingTaskSafetyFlag final
	: public rtc::RefCountedNonVirtual<PendingTaskSafetyFlag> {
	public:
	static rtc::scoped_refptr<PendingTaskSafetyFlag> Create();

	// Creates a flag, but with its SequenceChecker initially detached. Hence, it
	// may be created on a different thread than the flag will be used on.
	static rtc::scoped_refptr<PendingTaskSafetyFlag> CreateDetached();

	// Same as `CreateDetached()` except the initial state of the returned flag
	// will be `!alive()`.
	static rtc::scoped_refptr<PendingTaskSafetyFlag> CreateDetachedInactive();

	~PendingTaskSafetyFlag() = default;

	void SetNotAlive();
	// The SetAlive method is intended to support Start/Stop/Restart usecases.
	// When a class has called SetNotAlive on a flag used for posted tasks, and
	// decides it wants to post new tasks and have them run, there are two
	// reasonable ways to do that:
	//
	// (i) Use the below SetAlive method. One subtlety is that any task posted
	// prior to SetNotAlive, and still in the queue, is resurrected and will
	// run.
	//
	// (ii) Create a fresh flag, and just drop the reference to the old one. This
	// avoids the above problem, and ensures that tasks poster prior to
	// SetNotAlive stay cancelled. Instead, there's a potential data race on
	// the flag pointer itself. Some synchronization is required between the
	// thread overwriting the flag pointer, and the threads that want to post
	// tasks and therefore read that same pointer.
	void SetAlive();
	bool alive() const;

	protected:
	explicit PendingTaskSafetyFlag(bool alive) : alive_(alive) {}

	private:
	static rtc::scoped_refptr<PendingTaskSafetyFlag> CreateInternal(bool alive);

	bool alive_ = true;
	RTC_NO_UNIQUE_ADDRESS SequenceChecker main_sequence_;
	};

	// The ScopedTaskSafety makes using PendingTaskSafetyFlag very simple.
	// It does automatic PTSF creation and signalling of destruction when the
	// ScopedTaskSafety instance goes out of scope.
	//
	// Example usage:
	//
	// my_task_queue->PostTask(SafeTask(scoped_task_safety.flag(),
	// [this] {
	// // task goes here
	// }
	//
	// This should be used by the class that wants tasks dropped after destruction.
	// The requirement is that the instance has to be constructed and destructed on
	// the same thread as the potentially dropped tasks would be running on.
	class ScopedTaskSafety final {
	public:
	ScopedTaskSafety() = default;
	explicit ScopedTaskSafety(rtc::scoped_refptr<PendingTaskSafetyFlag> flag)
	: flag_(std::move(flag)) {}
	~ScopedTaskSafety() { flag_->SetNotAlive(); }

	// Returns a new reference to the safety flag.
	rtc::scoped_refptr<PendingTaskSafetyFlag> flag() const { return flag_; }

	// Marks the current flag as not-alive and attaches to a new one.
	void reset(rtc::scoped_refptr<PendingTaskSafetyFlag> new_flag =
	PendingTaskSafetyFlag::Create()) {
	flag_->SetNotAlive();
	flag_ = std::move(new_flag);
	}

	private:
	rtc::scoped_refptr<PendingTaskSafetyFlag> flag_ =
	PendingTaskSafetyFlag::Create();
	};

	// Like ScopedTaskSafety, but allows construction on a different thread than
	// where the flag will be used.
	class ScopedTaskSafetyDetached final {
	public:
	ScopedTaskSafetyDetached() = default;
	~ScopedTaskSafetyDetached() { flag_->SetNotAlive(); }

	// Returns a new reference to the safety flag.
	rtc::scoped_refptr<PendingTaskSafetyFlag> flag() const { return flag_; }

	private:
	rtc::scoped_refptr<PendingTaskSafetyFlag> flag_ =
	PendingTaskSafetyFlag::CreateDetached();
	};

	inline absl::AnyInvocable<void() &&> SafeTask(
	rtc::scoped_refptr<PendingTaskSafetyFlag> flag,
	absl::AnyInvocable<void() &&> task) {
	return [flag = std::move(flag), task = std::move(task)]() mutable {
	if (flag->alive()) {
	std::move(task)();
	}
	};
	}

	} // namespace webrtc

	#endif // API_TASK_QUEUE_PENDING_TASK_SAFETY_FLAG_H_