base/timer/timer.cc - mirrors/engine - 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.

 #include "base/timer/timer.h"

 #include <stddef.h>

 #include "base/logging.h"
 #include "base/memory/ref_counted.h"
 #include "base/single_thread_task_runner.h"
 #include "base/thread_task_runner_handle.h"
 #include "base/threading/platform_thread.h"

 namespace base {

 // BaseTimerTaskInternal is a simple delegate for scheduling a callback to
 // Timer in the thread's default task runner. It also handles the following
 // edge cases:
 // - deleted by the task runner.
 // - abandoned (orphaned) by Timer.
 class BaseTimerTaskInternal {
  public:
   explicit BaseTimerTaskInternal(Timer* timer)
       : timer_(timer) {
   }

   ~BaseTimerTaskInternal() {
     // This task may be getting cleared because the task runner has been
     // destructed.  If so, don't leave Timer with a dangling pointer
     // to this.
     if (timer_)
       timer_->StopAndAbandon();
   }

   void Run() {
     // timer_ is NULL if we were abandoned.
     if (!timer_)
       return;

     // *this will be deleted by the task runner, so Timer needs to
     // forget us:
     timer_->scheduled_task_ = NULL;

     // Although Timer should not call back into *this, let's clear
     // the timer_ member first to be pedantic.
     Timer* timer = timer_;
     timer_ = NULL;
     timer->RunScheduledTask();
   }

   // The task remains in the MessageLoop queue, but nothing will happen when it
   // runs.
   void Abandon() {
     timer_ = NULL;
   }

  private:
   Timer* timer_;
 };

 Timer::Timer(bool retain_user_task, bool is_repeating)
     : scheduled_task_(NULL),
       thread_id_(0),
       is_repeating_(is_repeating),
       retain_user_task_(retain_user_task),
       is_running_(false) {
 }

 Timer::Timer(const tracked_objects::Location& posted_from,
              TimeDelta delay,
              const base::Closure& user_task,
              bool is_repeating)
     : scheduled_task_(NULL),
       posted_from_(posted_from),
       delay_(delay),
       user_task_(user_task),
       thread_id_(0),
       is_repeating_(is_repeating),
       retain_user_task_(true),
       is_running_(false) {
 }

 Timer::~Timer() {
   StopAndAbandon();
 }

 bool Timer::IsRunning() const {
   return is_running_;
 }

 TimeDelta Timer::GetCurrentDelay() const {
   return delay_;
 }

 void Timer::SetTaskRunner(scoped_refptr<SingleThreadTaskRunner> task_runner) {
   // Do not allow changing the task runner once something has been scheduled.
   DCHECK_EQ(thread_id_, 0);
   task_runner_.swap(task_runner);
 }

 void Timer::Start(const tracked_objects::Location& posted_from,
                   TimeDelta delay,
                   const base::Closure& user_task) {
   SetTaskInfo(posted_from, delay, user_task);
   Reset();
 }

 void Timer::Stop() {
   is_running_ = false;
   if (!retain_user_task_)
     user_task_.Reset();
 }

 void Timer::Reset() {
   DCHECK(!user_task_.is_null());

   // If there's no pending task, start one up and return.
   if (!scheduled_task_) {
     PostNewScheduledTask(delay_);
     return;
   }

   // Set the new desired_run_time_.
   if (delay_ > TimeDelta::FromMicroseconds(0))
     desired_run_time_ = TimeTicks::Now() + delay_;
   else
     desired_run_time_ = TimeTicks();

   // We can use the existing scheduled task if it arrives before the new
   // desired_run_time_.
   if (desired_run_time_ >= scheduled_run_time_) {
     is_running_ = true;
     return;
   }

   // We can't reuse the scheduled_task_, so abandon it and post a new one.
   AbandonScheduledTask();
   PostNewScheduledTask(delay_);
 }

 void Timer::SetTaskInfo(const tracked_objects::Location& posted_from,
                         TimeDelta delay,
                         const base::Closure& user_task) {
   posted_from_ = posted_from;
   delay_ = delay;
   user_task_ = user_task;
 }

 void Timer::PostNewScheduledTask(TimeDelta delay) {
   DCHECK(scheduled_task_ == NULL);
   is_running_ = true;
   scheduled_task_ = new BaseTimerTaskInternal(this);
   if (delay > TimeDelta::FromMicroseconds(0)) {
     GetTaskRunner()->PostDelayedTask(posted_from_,
         base::Bind(&BaseTimerTaskInternal::Run, base::Owned(scheduled_task_)),
         delay);
     scheduled_run_time_ = desired_run_time_ = TimeTicks::Now() + delay;
   } else {
     GetTaskRunner()->PostTask(posted_from_,
         base::Bind(&BaseTimerTaskInternal::Run, base::Owned(scheduled_task_)));
     scheduled_run_time_ = desired_run_time_ = TimeTicks();
   }
   // Remember the thread ID that posts the first task -- this will be verified
   // later when the task is abandoned to detect misuse from multiple threads.
   if (!thread_id_) {
     DCHECK(GetTaskRunner()->BelongsToCurrentThread());
     thread_id_ = static_cast<int>(PlatformThread::CurrentId());
   }
 }

 scoped_refptr<SingleThreadTaskRunner> Timer::GetTaskRunner() {
   return task_runner_.get() ? task_runner_ : ThreadTaskRunnerHandle::Get();
 }

 void Timer::AbandonScheduledTask() {
   DCHECK(thread_id_ == 0 ||
          thread_id_ == static_cast<int>(PlatformThread::CurrentId()));
   if (scheduled_task_) {
     scheduled_task_->Abandon();
     scheduled_task_ = NULL;
   }
 }

 void Timer::RunScheduledTask() {
   // Task may have been disabled.
   if (!is_running_)
     return;

   // First check if we need to delay the task because of a new target time.
   if (desired_run_time_ > scheduled_run_time_) {
     // TimeTicks::Now() can be expensive, so only call it if we know the user
     // has changed the desired_run_time_.
     TimeTicks now = TimeTicks::Now();
     // Task runner may have called us late anyway, so only post a continuation
     // task if the desired_run_time_ is in the future.
     if (desired_run_time_ > now) {
       // Post a new task to span the remaining time.
       PostNewScheduledTask(desired_run_time_ - now);
       return;
     }
   }

   // Make a local copy of the task to run. The Stop method will reset the
   // user_task_ member if retain_user_task_ is false.
   base::Closure task = user_task_;

   if (is_repeating_)
     PostNewScheduledTask(delay_);
   else
     Stop();

   task.Run();

   // No more member accesses here: *this could be deleted at this point.
 }

 }  // namespace base
	// 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.

	#include "base/timer/timer.h"

	#include <stddef.h>

	#include "base/logging.h"
	#include "base/memory/ref_counted.h"
	#include "base/single_thread_task_runner.h"
	#include "base/thread_task_runner_handle.h"
	#include "base/threading/platform_thread.h"

	namespace base {

	// BaseTimerTaskInternal is a simple delegate for scheduling a callback to
	// Timer in the thread's default task runner. It also handles the following
	// edge cases:
	// - deleted by the task runner.
	// - abandoned (orphaned) by Timer.
	class BaseTimerTaskInternal {
	public:
	explicit BaseTimerTaskInternal(Timer* timer)
	: timer_(timer) {
	}

	~BaseTimerTaskInternal() {
	// This task may be getting cleared because the task runner has been
	// destructed. If so, don't leave Timer with a dangling pointer
	// to this.
	if (timer_)
	timer_->StopAndAbandon();
	}

	void Run() {
	// timer_ is NULL if we were abandoned.
	if (!timer_)
	return;

	// *this will be deleted by the task runner, so Timer needs to
	// forget us:
	timer_->scheduled_task_ = NULL;

	// Although Timer should not call back into *this, let's clear
	// the timer_ member first to be pedantic.
	Timer* timer = timer_;
	timer_ = NULL;
	timer->RunScheduledTask();
	}

	// The task remains in the MessageLoop queue, but nothing will happen when it
	// runs.
	void Abandon() {
	timer_ = NULL;
	}

	private:
	Timer* timer_;
	};

	Timer::Timer(bool retain_user_task, bool is_repeating)
	: scheduled_task_(NULL),
	thread_id_(0),
	is_repeating_(is_repeating),
	retain_user_task_(retain_user_task),
	is_running_(false) {
	}

	Timer::Timer(const tracked_objects::Location& posted_from,
	TimeDelta delay,
	const base::Closure& user_task,
	bool is_repeating)
	: scheduled_task_(NULL),
	posted_from_(posted_from),
	delay_(delay),
	user_task_(user_task),
	thread_id_(0),
	is_repeating_(is_repeating),
	retain_user_task_(true),
	is_running_(false) {
	}

	Timer::~Timer() {
	StopAndAbandon();
	}

	bool Timer::IsRunning() const {
	return is_running_;
	}

	TimeDelta Timer::GetCurrentDelay() const {
	return delay_;
	}

	void Timer::SetTaskRunner(scoped_refptr<SingleThreadTaskRunner> task_runner) {
	// Do not allow changing the task runner once something has been scheduled.
	DCHECK_EQ(thread_id_, 0);
	task_runner_.swap(task_runner);
	}

	void Timer::Start(const tracked_objects::Location& posted_from,
	TimeDelta delay,
	const base::Closure& user_task) {
	SetTaskInfo(posted_from, delay, user_task);
	Reset();
	}

	void Timer::Stop() {
	is_running_ = false;
	if (!retain_user_task_)
	user_task_.Reset();
	}

	void Timer::Reset() {
	DCHECK(!user_task_.is_null());

	// If there's no pending task, start one up and return.
	if (!scheduled_task_) {
	PostNewScheduledTask(delay_);
	return;
	}

	// Set the new desired_run_time_.
	if (delay_ > TimeDelta::FromMicroseconds(0))
	desired_run_time_ = TimeTicks::Now() + delay_;
	else
	desired_run_time_ = TimeTicks();

	// We can use the existing scheduled task if it arrives before the new
	// desired_run_time_.
	if (desired_run_time_ >= scheduled_run_time_) {
	is_running_ = true;
	return;
	}

	// We can't reuse the scheduled_task_, so abandon it and post a new one.
	AbandonScheduledTask();
	PostNewScheduledTask(delay_);
	}

	void Timer::SetTaskInfo(const tracked_objects::Location& posted_from,
	TimeDelta delay,
	const base::Closure& user_task) {
	posted_from_ = posted_from;
	delay_ = delay;
	user_task_ = user_task;
	}

	void Timer::PostNewScheduledTask(TimeDelta delay) {
	DCHECK(scheduled_task_ == NULL);
	is_running_ = true;
	scheduled_task_ = new BaseTimerTaskInternal(this);
	if (delay > TimeDelta::FromMicroseconds(0)) {
	GetTaskRunner()->PostDelayedTask(posted_from_,
	base::Bind(&BaseTimerTaskInternal::Run, base::Owned(scheduled_task_)),
	delay);
	scheduled_run_time_ = desired_run_time_ = TimeTicks::Now() + delay;
	} else {
	GetTaskRunner()->PostTask(posted_from_,
	base::Bind(&BaseTimerTaskInternal::Run, base::Owned(scheduled_task_)));
	scheduled_run_time_ = desired_run_time_ = TimeTicks();
	}
	// Remember the thread ID that posts the first task -- this will be verified
	// later when the task is abandoned to detect misuse from multiple threads.
	if (!thread_id_) {
	DCHECK(GetTaskRunner()->BelongsToCurrentThread());
	thread_id_ = static_cast<int>(PlatformThread::CurrentId());
	}
	}

	scoped_refptr<SingleThreadTaskRunner> Timer::GetTaskRunner() {
	return task_runner_.get() ? task_runner_ : ThreadTaskRunnerHandle::Get();
	}

	void Timer::AbandonScheduledTask() {
	DCHECK(thread_id_ == 0 \|\|
	thread_id_ == static_cast<int>(PlatformThread::CurrentId()));
	if (scheduled_task_) {
	scheduled_task_->Abandon();
	scheduled_task_ = NULL;
	}
	}

	void Timer::RunScheduledTask() {
	// Task may have been disabled.
	if (!is_running_)
	return;

	// First check if we need to delay the task because of a new target time.
	if (desired_run_time_ > scheduled_run_time_) {
	// TimeTicks::Now() can be expensive, so only call it if we know the user
	// has changed the desired_run_time_.
	TimeTicks now = TimeTicks::Now();
	// Task runner may have called us late anyway, so only post a continuation
	// task if the desired_run_time_ is in the future.
	if (desired_run_time_ > now) {
	// Post a new task to span the remaining time.
	PostNewScheduledTask(desired_run_time_ - now);
	return;
	}
	}

	// Make a local copy of the task to run. The Stop method will reset the
	// user_task_ member if retain_user_task_ is false.
	base::Closure task = user_task_;

	if (is_repeating_)
	PostNewScheduledTask(delay_);
	else
	Stop();

	task.Run();

	// No more member accesses here: *this could be deleted at this point.
	}

	} // namespace base