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

 /*
  *  Copyright 2019 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_TASK_QUEUE_BASE_H_
 #define API_TASK_QUEUE_TASK_QUEUE_BASE_H_

 #include <memory>
 #include <utility>

 #include "absl/functional/any_invocable.h"
 #include "api/units/time_delta.h"
 #include "rtc_base/system/rtc_export.h"
 #include "rtc_base/thread_annotations.h"

 namespace webrtc {

 // 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().
 class RTC_LOCKABLE RTC_EXPORT TaskQueueBase {
  public:
   enum class DelayPrecision {
     // This may include up to a 17 ms leeway in addition to OS timer precision.
     // See PostDelayedTask() for more information.
     kLow,
     // This does not have the additional delay that kLow has, but it is still
     // limited by OS timer precision. See PostDelayedHighPrecisionTask() for
     // more information.
     kHigh,
   };

   // Starts destruction of the task queue.
   // On return ensures no task are running and no new tasks are able to start
   // on the task queue.
   // Responsible for deallocation. Deallocation may happen synchronously during
   // Delete or asynchronously after Delete returns.
   // Code not running on the TaskQueue should not make any assumption when
   // TaskQueue is deallocated and thus should not call any methods after Delete.
   // Code running on the TaskQueue should not call Delete, but can assume
   // TaskQueue still exists and may call other methods, e.g. PostTask.
   // Should be called on the same task queue or thread that this task queue
   // was created on.
   virtual void Delete() = 0;

   // Schedules a `task` to execute. Tasks are executed in FIFO order.
   // When a TaskQueue is deleted, pending tasks will not be executed but they
   // will be deleted. The deletion of tasks may happen synchronously on the
   // TaskQueue or it may happen asynchronously after TaskQueue is deleted.
   // This may vary from one implementation to the next so assumptions about
   // lifetimes of pending tasks should not be made.
   // May be called on any thread or task queue, including this task queue.
   virtual void PostTask(absl::AnyInvocable<void() &&> task) = 0;

   // Prefer PostDelayedTask() over PostDelayedHighPrecisionTask() whenever
   // possible.
   //
   // Schedules a `task` to execute a specified `delay` from when the call is
   // made, using "low" precision. All scheduling is affected by OS-specific
   // leeway and current workloads which means that in terms of precision there
   // are no hard guarantees, but in addition to the OS induced leeway, "low"
   // precision adds up to a 17 ms additional leeway. The purpose of this leeway
   // is to achieve more efficient CPU scheduling and reduce Idle Wake Up
   // frequency.
   //
   // The task may execute with [-1, 17 + OS induced leeway) ms additional delay.
   //
   // Avoid making assumptions about the precision of the OS scheduler. On macOS,
   // the OS induced leeway may be 10% of sleep interval. On Windows, 1 ms
   // precision timers may be used but there are cases, such as when running on
   // battery, when the timer precision can be as poor as 15 ms.
   //
   // "Low" precision is not implemented everywhere yet. Where not yet
   // implemented, PostDelayedTask() has "high" precision. See
   // https://crbug.com/webrtc/13583 for more information.
   //
   // May be called on any thread or task queue, including this task queue.
   virtual void PostDelayedTask(absl::AnyInvocable<void() &&> task,
                                TimeDelta delay) = 0;

   // Prefer PostDelayedTask() over PostDelayedHighPrecisionTask() whenever
   // possible.
   //
   // Schedules a `task` to execute a specified `delay` from when the call is
   // made, using "high" precision. All scheduling is affected by OS-specific
   // leeway and current workloads which means that in terms of precision there
   // are no hard guarantees.
   //
   // The task may execute with [-1, OS induced leeway] ms additional delay.
   //
   // Avoid making assumptions about the precision of the OS scheduler. On macOS,
   // the OS induced leeway may be 10% of sleep interval. On Windows, 1 ms
   // precision timers may be used but there are cases, such as when running on
   // battery, when the timer precision can be as poor as 15 ms.
   //
   // May be called on any thread or task queue, including this task queue.
   virtual void PostDelayedHighPrecisionTask(absl::AnyInvocable<void() &&> task,
                                             TimeDelta delay) = 0;

   // As specified by `precision`, calls either PostDelayedTask() or
   // PostDelayedHighPrecisionTask().
   void PostDelayedTaskWithPrecision(DelayPrecision precision,
                                     absl::AnyInvocable<void() &&> task,
                                     TimeDelta delay) {
     switch (precision) {
       case DelayPrecision::kLow:
         PostDelayedTask(std::move(task), delay);
         break;
       case DelayPrecision::kHigh:
         PostDelayedHighPrecisionTask(std::move(task), delay);
         break;
     }
   }

   // Returns the task queue that is running the current thread.
   // Returns nullptr if this thread is not associated with any task queue.
   // May be called on any thread or task queue, including this task queue.
   static TaskQueueBase* Current();
   bool IsCurrent() const { return Current() == this; }

  protected:
   class RTC_EXPORT CurrentTaskQueueSetter {
    public:
     explicit CurrentTaskQueueSetter(TaskQueueBase* task_queue);
     CurrentTaskQueueSetter(const CurrentTaskQueueSetter&) = delete;
     CurrentTaskQueueSetter& operator=(const CurrentTaskQueueSetter&) = delete;
     ~CurrentTaskQueueSetter();

    private:
     TaskQueueBase* const previous_;
   };

   // Users of the TaskQueue should call Delete instead of directly deleting
   // this object.
   virtual ~TaskQueueBase() = default;
 };

 struct TaskQueueDeleter {
   void operator()(TaskQueueBase* task_queue) const { task_queue->Delete(); }
 };

 }  // namespace webrtc

 #endif  // API_TASK_QUEUE_TASK_QUEUE_BASE_H_
	/*
	* Copyright 2019 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_TASK_QUEUE_BASE_H_
	#define API_TASK_QUEUE_TASK_QUEUE_BASE_H_

	#include <memory>
	#include <utility>

	#include "absl/functional/any_invocable.h"
	#include "api/units/time_delta.h"
	#include "rtc_base/system/rtc_export.h"
	#include "rtc_base/thread_annotations.h"

	namespace webrtc {

	// 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().
	class RTC_LOCKABLE RTC_EXPORT TaskQueueBase {
	public:
	enum class DelayPrecision {
	// This may include up to a 17 ms leeway in addition to OS timer precision.
	// See PostDelayedTask() for more information.
	kLow,
	// This does not have the additional delay that kLow has, but it is still
	// limited by OS timer precision. See PostDelayedHighPrecisionTask() for
	// more information.
	kHigh,
	};

	// Starts destruction of the task queue.
	// On return ensures no task are running and no new tasks are able to start
	// on the task queue.
	// Responsible for deallocation. Deallocation may happen synchronously during
	// Delete or asynchronously after Delete returns.
	// Code not running on the TaskQueue should not make any assumption when
	// TaskQueue is deallocated and thus should not call any methods after Delete.
	// Code running on the TaskQueue should not call Delete, but can assume
	// TaskQueue still exists and may call other methods, e.g. PostTask.
	// Should be called on the same task queue or thread that this task queue
	// was created on.
	virtual void Delete() = 0;

	// Schedules a `task` to execute. Tasks are executed in FIFO order.
	// When a TaskQueue is deleted, pending tasks will not be executed but they
	// will be deleted. The deletion of tasks may happen synchronously on the
	// TaskQueue or it may happen asynchronously after TaskQueue is deleted.
	// This may vary from one implementation to the next so assumptions about
	// lifetimes of pending tasks should not be made.
	// May be called on any thread or task queue, including this task queue.
	virtual void PostTask(absl::AnyInvocable<void() &&> task) = 0;

	// Prefer PostDelayedTask() over PostDelayedHighPrecisionTask() whenever
	// possible.
	//
	// Schedules a `task` to execute a specified `delay` from when the call is
	// made, using "low" precision. All scheduling is affected by OS-specific
	// leeway and current workloads which means that in terms of precision there
	// are no hard guarantees, but in addition to the OS induced leeway, "low"
	// precision adds up to a 17 ms additional leeway. The purpose of this leeway
	// is to achieve more efficient CPU scheduling and reduce Idle Wake Up
	// frequency.
	//
	// The task may execute with [-1, 17 + OS induced leeway) ms additional delay.
	//
	// Avoid making assumptions about the precision of the OS scheduler. On macOS,
	// the OS induced leeway may be 10% of sleep interval. On Windows, 1 ms
	// precision timers may be used but there are cases, such as when running on
	// battery, when the timer precision can be as poor as 15 ms.
	//
	// "Low" precision is not implemented everywhere yet. Where not yet
	// implemented, PostDelayedTask() has "high" precision. See
	// https://crbug.com/webrtc/13583 for more information.
	//
	// May be called on any thread or task queue, including this task queue.
	virtual void PostDelayedTask(absl::AnyInvocable<void() &&> task,
	TimeDelta delay) = 0;

	// Prefer PostDelayedTask() over PostDelayedHighPrecisionTask() whenever
	// possible.
	//
	// Schedules a `task` to execute a specified `delay` from when the call is
	// made, using "high" precision. All scheduling is affected by OS-specific
	// leeway and current workloads which means that in terms of precision there
	// are no hard guarantees.
	//
	// The task may execute with [-1, OS induced leeway] ms additional delay.
	//
	// Avoid making assumptions about the precision of the OS scheduler. On macOS,
	// the OS induced leeway may be 10% of sleep interval. On Windows, 1 ms
	// precision timers may be used but there are cases, such as when running on
	// battery, when the timer precision can be as poor as 15 ms.
	//
	// May be called on any thread or task queue, including this task queue.
	virtual void PostDelayedHighPrecisionTask(absl::AnyInvocable<void() &&> task,
	TimeDelta delay) = 0;

	// As specified by `precision`, calls either PostDelayedTask() or
	// PostDelayedHighPrecisionTask().
	void PostDelayedTaskWithPrecision(DelayPrecision precision,
	absl::AnyInvocable<void() &&> task,
	TimeDelta delay) {
	switch (precision) {
	case DelayPrecision::kLow:
	PostDelayedTask(std::move(task), delay);
	break;
	case DelayPrecision::kHigh:
	PostDelayedHighPrecisionTask(std::move(task), delay);
	break;
	}
	}

	// Returns the task queue that is running the current thread.
	// Returns nullptr if this thread is not associated with any task queue.
	// May be called on any thread or task queue, including this task queue.
	static TaskQueueBase* Current();
	bool IsCurrent() const { return Current() == this; }

	protected:
	class RTC_EXPORT CurrentTaskQueueSetter {
	public:
	explicit CurrentTaskQueueSetter(TaskQueueBase* task_queue);
	CurrentTaskQueueSetter(const CurrentTaskQueueSetter&) = delete;
	CurrentTaskQueueSetter& operator=(const CurrentTaskQueueSetter&) = delete;
	~CurrentTaskQueueSetter();

	private:
	TaskQueueBase* const previous_;
	};

	// Users of the TaskQueue should call Delete instead of directly deleting
	// this object.
	virtual ~TaskQueueBase() = default;
	};

	struct TaskQueueDeleter {
	void operator()(TaskQueueBase* task_queue) const { task_queue->Delete(); }
	};

	} // namespace webrtc

	#endif // API_TASK_QUEUE_TASK_QUEUE_BASE_H_