src/base/sequenced_task_runner.h - cobalt - Git at Google

 // Copyright (c) 2012 The Chromium 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 BASE_SEQUENCED_TASK_RUNNER_H_
 #define BASE_SEQUENCED_TASK_RUNNER_H_

 #include <memory>

 #include "base/base_export.h"
 #include "base/callback.h"
 #include "base/sequenced_task_runner_helpers.h"
 #include "base/task_runner.h"

 namespace base {

 // A SequencedTaskRunner is a subclass of TaskRunner that provides
 // additional guarantees on the order that tasks are started, as well
 // as guarantees on when tasks are in sequence, i.e. one task finishes
 // before the other one starts.
 //
 // Summary
 // -------
 // Non-nested tasks with the same delay will run one by one in FIFO
 // order.
 //
 // Detailed guarantees
 // -------------------
 //
 // SequencedTaskRunner also adds additional methods for posting
 // non-nestable tasks.  In general, an implementation of TaskRunner
 // may expose task-running methods which are themselves callable from
 // within tasks.  A non-nestable task is one that is guaranteed to not
 // be run from within an already-running task.  Conversely, a nestable
 // task (the default) is a task that can be run from within an
 // already-running task.
 //
 // The guarantees of SequencedTaskRunner are as follows:
 //
 //   - Given two tasks T2 and T1, T2 will start after T1 starts if:
 //
 //       * T2 is posted after T1; and
 //       * T2 has equal or higher delay than T1; and
 //       * T2 is non-nestable or T1 is nestable.
 //
 //   - If T2 will start after T1 starts by the above guarantee, then
 //     T2 will start after T1 finishes and is destroyed if:
 //
 //       * T2 is non-nestable, or
 //       * T1 doesn't call any task-running methods.
 //
 //   - If T2 will start after T1 finishes by the above guarantee, then
 //     all memory changes in T1 and T1's destruction will be visible
 //     to T2.
 //
 //   - If T2 runs nested within T1 via a call to the task-running
 //     method M, then all memory changes in T1 up to the call to M
 //     will be visible to T2, and all memory changes in T2 will be
 //     visible to T1 from the return from M.
 //
 // Note that SequencedTaskRunner does not guarantee that tasks are run
 // on a single dedicated thread, although the above guarantees provide
 // most (but not all) of the same guarantees.  If you do need to
 // guarantee that tasks are run on a single dedicated thread, see
 // SingleThreadTaskRunner (in single_thread_task_runner.h).
 //
 // Some corollaries to the above guarantees, assuming the tasks in
 // question don't call any task-running methods:
 //
 //   - Tasks posted via PostTask are run in FIFO order.
 //
 //   - Tasks posted via PostNonNestableTask are run in FIFO order.
 //
 //   - Tasks posted with the same delay and the same nestable state
 //     are run in FIFO order.
 //
 //   - A list of tasks with the same nestable state posted in order of
 //     non-decreasing delay is run in FIFO order.
 //
 //   - A list of tasks posted in order of non-decreasing delay with at
 //     most a single change in nestable state from nestable to
 //     non-nestable is run in FIFO order. (This is equivalent to the
 //     statement of the first guarantee above.)
 //
 // Some theoretical implementations of SequencedTaskRunner:
 //
 //   - A SequencedTaskRunner that wraps a regular TaskRunner but makes
 //     sure that only one task at a time is posted to the TaskRunner,
 //     with appropriate memory barriers in between tasks.
 //
 //   - A SequencedTaskRunner that, for each task, spawns a joinable
 //     thread to run that task and immediately quit, and then
 //     immediately joins that thread.
 //
 //   - A SequencedTaskRunner that stores the list of posted tasks and
 //     has a method Run() that runs each runnable task in FIFO order
 //     that can be called from any thread, but only if another
 //     (non-nested) Run() call isn't already happening.
 class BASE_EXPORT SequencedTaskRunner : public TaskRunner {
  public:
   // The two PostNonNestable*Task methods below are like their
   // nestable equivalents in TaskRunner, but they guarantee that the
   // posted task will not run nested within an already-running task.
   //
   // A simple corollary is that posting a task as non-nestable can
   // only delay when the task gets run.  That is, posting a task as
   // non-nestable may not affect when the task gets run, or it could
   // make it run later than it normally would, but it won't make it
   // run earlier than it normally would.

   // TODO(akalin): Get rid of the boolean return value for the methods
   // below.

   bool PostNonNestableTask(const Location& from_here, OnceClosure task);

   virtual bool PostNonNestableDelayedTask(const Location& from_here,
                                           OnceClosure task,
                                           base::TimeDelta delay) = 0;

   // Submits a non-nestable task to delete the given object.  Returns
   // true if the object may be deleted at some point in the future,
   // and false if the object definitely will not be deleted.
   template <class T>
   bool DeleteSoon(const Location& from_here, const T* object) {
     return DeleteOrReleaseSoonInternal(from_here, &DeleteHelper<T>::DoDelete,
                                        object);
   }

   template <class T>
   bool DeleteSoon(const Location& from_here, std::unique_ptr<T> object) {
     return DeleteSoon(from_here, object.release());
   }

   // Submits a non-nestable task to release the given object.  Returns
   // true if the object may be released at some point in the future,
   // and false if the object definitely will not be released.
   template <class T>
   bool ReleaseSoon(const Location& from_here, const T* object) {
     return DeleteOrReleaseSoonInternal(from_here, &ReleaseHelper<T>::DoRelease,
                                        object);
   }

  protected:
   ~SequencedTaskRunner() override = default;

  private:
   bool DeleteOrReleaseSoonInternal(const Location& from_here,
                                    void (*deleter)(const void*),
                                    const void* object);
 };

 // Sample usage with std::unique_ptr :
 // std::unique_ptr<Foo, base::OnTaskRunnerDeleter> ptr(
 //     new Foo, base::OnTaskRunnerDeleter(my_task_runner));
 //
 // For RefCounted see base::RefCountedDeleteOnSequence.
 struct BASE_EXPORT OnTaskRunnerDeleter {
   explicit OnTaskRunnerDeleter(scoped_refptr<SequencedTaskRunner> task_runner);
   ~OnTaskRunnerDeleter();

   OnTaskRunnerDeleter(OnTaskRunnerDeleter&&);
   OnTaskRunnerDeleter& operator=(OnTaskRunnerDeleter&&);
 #ifdef STARBOARD
   OnTaskRunnerDeleter(const OnTaskRunnerDeleter&) = default;
 #endif

   // For compatibility with std:: deleters.
   template <typename T>
   void operator()(const T* ptr) {
     if (ptr)
       task_runner_->DeleteSoon(FROM_HERE, ptr);
   }

   scoped_refptr<SequencedTaskRunner> task_runner_;
 };

 }  // namespace base

 #endif  // BASE_SEQUENCED_TASK_RUNNER_H_
	// Copyright (c) 2012 The Chromium 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 BASE_SEQUENCED_TASK_RUNNER_H_
	#define BASE_SEQUENCED_TASK_RUNNER_H_

	#include <memory>

	#include "base/base_export.h"
	#include "base/callback.h"
	#include "base/sequenced_task_runner_helpers.h"
	#include "base/task_runner.h"

	namespace base {

	// A SequencedTaskRunner is a subclass of TaskRunner that provides
	// additional guarantees on the order that tasks are started, as well
	// as guarantees on when tasks are in sequence, i.e. one task finishes
	// before the other one starts.
	//
	// Summary
	// -------
	// Non-nested tasks with the same delay will run one by one in FIFO
	// order.
	//
	// Detailed guarantees
	// -------------------
	//
	// SequencedTaskRunner also adds additional methods for posting
	// non-nestable tasks. In general, an implementation of TaskRunner
	// may expose task-running methods which are themselves callable from
	// within tasks. A non-nestable task is one that is guaranteed to not
	// be run from within an already-running task. Conversely, a nestable
	// task (the default) is a task that can be run from within an
	// already-running task.
	//
	// The guarantees of SequencedTaskRunner are as follows:
	//
	// - Given two tasks T2 and T1, T2 will start after T1 starts if:
	//
	// * T2 is posted after T1; and
	// * T2 has equal or higher delay than T1; and
	// * T2 is non-nestable or T1 is nestable.
	//
	// - If T2 will start after T1 starts by the above guarantee, then
	// T2 will start after T1 finishes and is destroyed if:
	//
	// * T2 is non-nestable, or
	// * T1 doesn't call any task-running methods.
	//
	// - If T2 will start after T1 finishes by the above guarantee, then
	// all memory changes in T1 and T1's destruction will be visible
	// to T2.
	//
	// - If T2 runs nested within T1 via a call to the task-running
	// method M, then all memory changes in T1 up to the call to M
	// will be visible to T2, and all memory changes in T2 will be
	// visible to T1 from the return from M.
	//
	// Note that SequencedTaskRunner does not guarantee that tasks are run
	// on a single dedicated thread, although the above guarantees provide
	// most (but not all) of the same guarantees. If you do need to
	// guarantee that tasks are run on a single dedicated thread, see
	// SingleThreadTaskRunner (in single_thread_task_runner.h).
	//
	// Some corollaries to the above guarantees, assuming the tasks in
	// question don't call any task-running methods:
	//
	// - Tasks posted via PostTask are run in FIFO order.
	//
	// - Tasks posted via PostNonNestableTask are run in FIFO order.
	//
	// - Tasks posted with the same delay and the same nestable state
	// are run in FIFO order.
	//
	// - A list of tasks with the same nestable state posted in order of
	// non-decreasing delay is run in FIFO order.
	//
	// - A list of tasks posted in order of non-decreasing delay with at
	// most a single change in nestable state from nestable to
	// non-nestable is run in FIFO order. (This is equivalent to the
	// statement of the first guarantee above.)
	//
	// Some theoretical implementations of SequencedTaskRunner:
	//
	// - A SequencedTaskRunner that wraps a regular TaskRunner but makes
	// sure that only one task at a time is posted to the TaskRunner,
	// with appropriate memory barriers in between tasks.
	//
	// - A SequencedTaskRunner that, for each task, spawns a joinable
	// thread to run that task and immediately quit, and then
	// immediately joins that thread.
	//
	// - A SequencedTaskRunner that stores the list of posted tasks and
	// has a method Run() that runs each runnable task in FIFO order
	// that can be called from any thread, but only if another
	// (non-nested) Run() call isn't already happening.
	class BASE_EXPORT SequencedTaskRunner : public TaskRunner {
	public:
	// The two PostNonNestable*Task methods below are like their
	// nestable equivalents in TaskRunner, but they guarantee that the
	// posted task will not run nested within an already-running task.
	//
	// A simple corollary is that posting a task as non-nestable can
	// only delay when the task gets run. That is, posting a task as
	// non-nestable may not affect when the task gets run, or it could
	// make it run later than it normally would, but it won't make it
	// run earlier than it normally would.

	// TODO(akalin): Get rid of the boolean return value for the methods
	// below.

	bool PostNonNestableTask(const Location& from_here, OnceClosure task);

	virtual bool PostNonNestableDelayedTask(const Location& from_here,
	OnceClosure task,
	base::TimeDelta delay) = 0;

	// Submits a non-nestable task to delete the given object. Returns
	// true if the object may be deleted at some point in the future,
	// and false if the object definitely will not be deleted.
	template <class T>
	bool DeleteSoon(const Location& from_here, const T* object) {
	return DeleteOrReleaseSoonInternal(from_here, &DeleteHelper<T>::DoDelete,
	object);
	}

	template <class T>
	bool DeleteSoon(const Location& from_here, std::unique_ptr<T> object) {
	return DeleteSoon(from_here, object.release());
	}

	// Submits a non-nestable task to release the given object. Returns
	// true if the object may be released at some point in the future,
	// and false if the object definitely will not be released.
	template <class T>
	bool ReleaseSoon(const Location& from_here, const T* object) {
	return DeleteOrReleaseSoonInternal(from_here, &ReleaseHelper<T>::DoRelease,
	object);
	}

	protected:
	~SequencedTaskRunner() override = default;

	private:
	bool DeleteOrReleaseSoonInternal(const Location& from_here,
	void (deleter)(const void),
	const void* object);
	};

	// Sample usage with std::unique_ptr :
	// std::unique_ptr<Foo, base::OnTaskRunnerDeleter> ptr(
	// new Foo, base::OnTaskRunnerDeleter(my_task_runner));
	//
	// For RefCounted see base::RefCountedDeleteOnSequence.
	struct BASE_EXPORT OnTaskRunnerDeleter {
	explicit OnTaskRunnerDeleter(scoped_refptr<SequencedTaskRunner> task_runner);
	~OnTaskRunnerDeleter();

	OnTaskRunnerDeleter(OnTaskRunnerDeleter&&);
	OnTaskRunnerDeleter& operator=(OnTaskRunnerDeleter&&);
	#ifdef STARBOARD
	OnTaskRunnerDeleter(const OnTaskRunnerDeleter&) = default;
	#endif

	// For compatibility with std:: deleters.
	template <typename T>
	void operator()(const T* ptr) {
	if (ptr)
	task_runner_->DeleteSoon(FROM_HERE, ptr);
	}

	scoped_refptr<SequencedTaskRunner> task_runner_;
	};

	} // namespace base

	#endif // BASE_SEQUENCED_TASK_RUNNER_H_