base/timer.h - platform/external/libchrome - Gitiles

 // Copyright (c) 2006-2008 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.

 // OneShotTimer and RepeatingTimer provide a simple timer API.  As the names
 // suggest, OneShotTimer calls you back once after a time delay expires.
 // RepeatingTimer on the other hand calls you back periodically with the
 // prescribed time interval.
 //
 // OneShotTimer and RepeatingTimer both cancel the timer when they go out of
 // scope, which makes it easy to ensure that you do not get called when your
 // object has gone out of scope.  Just instantiate a OneShotTimer or
 // RepeatingTimer as a member variable of the class for which you wish to
 // receive timer events.
 //
 // Sample RepeatingTimer usage:
 //
 //   class MyClass {
 //    public:
 //     void StartDoingStuff() {
 //       timer_.Start(TimeDelta::FromSeconds(1), this, &MyClass::DoStuff);
 //     }
 //     void StopDoingStuff() {
 //       timer_.Stop();
 //     }
 //    private:
 //     void DoStuff() {
 //       // This method is called every second to do stuff.
 //       ...
 //     }
 //     base::RepeatingTimer<MyClass> timer_;
 //   };
 //
 // Both OneShotTimer and RepeatingTimer also support a Reset method, which
 // allows you to easily defer the timer event until the timer delay passes once
 // again.  So, in the above example, if 0.5 seconds have already passed,
 // calling Reset on timer_ would postpone DoStuff by another 1 second.  In
 // other words, Reset is shorthand for calling Stop and then Start again with
 // the same arguments.

 #ifndef BASE_TIMER_H_
 #define BASE_TIMER_H_

 // IMPORTANT: If you change timer code, make sure that all tests (including
 // disabled ones) from timer_unittests.cc pass locally. Some are disabled
 // because they're flaky on the buildbot, but when you run them locally you
 // should be able to tell the difference.

 #include "base/logging.h"
 #include "base/task.h"
 #include "base/time.h"

 class MessageLoop;

 namespace base {

 //-----------------------------------------------------------------------------
 // This class is an implementation detail of OneShotTimer and RepeatingTimer.
 // Please do not use this class directly.
 //
 // This class exists to share code between BaseTimer<T> template instantiations.
 //
 class BaseTimer_Helper {
  public:
   // Stops the timer.
   ~BaseTimer_Helper() {
     OrphanDelayedTask();
   }

   // Returns true if the timer is running (i.e., not stopped).
   bool IsRunning() const {
     return delayed_task_ != NULL;
   }

   // Returns the current delay for this timer.  May only call this method when
   // the timer is running!
   TimeDelta GetCurrentDelay() const {
     DCHECK(IsRunning());
     return delayed_task_->delay_;
   }

  protected:
   BaseTimer_Helper() : delayed_task_(NULL) {}

   // We have access to the timer_ member so we can orphan this task.
   class TimerTask : public Task {
    public:
     TimerTask(TimeDelta delay) : timer_(NULL), delay_(delay) {
     }
     virtual ~TimerTask() {}
     BaseTimer_Helper* timer_;
     TimeDelta delay_;
   };

   // Used to orphan delayed_task_ so that when it runs it does nothing.
   void OrphanDelayedTask();

   // Used to initiated a new delayed task.  This has the side-effect of
   // orphaning delayed_task_ if it is non-null.
   void InitiateDelayedTask(TimerTask* timer_task);

   TimerTask* delayed_task_;

   DISALLOW_COPY_AND_ASSIGN(BaseTimer_Helper);
 };

 //-----------------------------------------------------------------------------
 // This class is an implementation detail of OneShotTimer and RepeatingTimer.
 // Please do not use this class directly.
 template <class Receiver, bool kIsRepeating>
 class BaseTimer : public BaseTimer_Helper {
  public:
   typedef void (Receiver::*ReceiverMethod)();

   // Call this method to start the timer.  It is an error to call this method
   // while the timer is already running.
   void Start(TimeDelta delay, Receiver* receiver, ReceiverMethod method) {
     DCHECK(!IsRunning());
     InitiateDelayedTask(new TimerTask(delay, receiver, method));
   }

   // Call this method to stop the timer.  It is a no-op if the timer is not
   // running.
   void Stop() {
     OrphanDelayedTask();
   }

   // Call this method to reset the timer delay of an already running timer.
   void Reset() {
     DCHECK(IsRunning());
     InitiateDelayedTask(static_cast<TimerTask*>(delayed_task_)->Clone());
   }

  private:
   typedef BaseTimer<Receiver, kIsRepeating> SelfType;

   class TimerTask : public BaseTimer_Helper::TimerTask {
    public:
     TimerTask(TimeDelta delay, Receiver* receiver, ReceiverMethod method)
         : BaseTimer_Helper::TimerTask(delay),
           receiver_(receiver),
           method_(method) {
     }

     virtual ~TimerTask() {
       // This task may be getting cleared because the MessageLoop has been
       // destructed.  If so, don't leave the Timer with a dangling pointer
       // to this now-defunct task.
       ClearBaseTimer();
     }

     virtual void Run() {
       if (!timer_)  // timer_ is null if we were orphaned.
         return;
       if (kIsRepeating)
         ResetBaseTimer();
       else
         ClearBaseTimer();
       DispatchToMethod(receiver_, method_, Tuple0());
     }

     TimerTask* Clone() const {
       return new TimerTask(delay_, receiver_, method_);
     }

    private:
     // Inform the Base that the timer is no longer active.
     void ClearBaseTimer() {
       if (timer_) {
         SelfType* self = static_cast<SelfType*>(timer_);
         // It is possible that the Timer has already been reset, and that this
         // Task is old.  So, if the Timer points to a different task, assume
         // that the Timer has already taken care of properly setting the task.
         if (self->delayed_task_ == this)
           self->delayed_task_ = NULL;
         // By now the delayed_task_ in the Timer does not point to us anymore.
         // We should reset our own timer_ because the Timer can not do this
         // for us in its destructor.
         timer_ = NULL;
       }
     }

     // Inform the Base that we're resetting the timer.
     void ResetBaseTimer() {
       DCHECK(timer_);
       DCHECK(kIsRepeating);
       SelfType* self = static_cast<SelfType*>(timer_);
       self->Reset();
     }

     Receiver* receiver_;
     ReceiverMethod method_;
   };
 };

 //-----------------------------------------------------------------------------
 // A simple, one-shot timer.  See usage notes at the top of the file.
 template <class Receiver>
 class OneShotTimer : public BaseTimer<Receiver, false> {};

 //-----------------------------------------------------------------------------
 // A simple, repeating timer.  See usage notes at the top of the file.
 template <class Receiver>
 class RepeatingTimer : public BaseTimer<Receiver, true> {};

 //-----------------------------------------------------------------------------
 // A Delay timer is like The Button from Lost. Once started, you have to keep
 // calling Reset otherwise it will call the given method in the MessageLoop
 // thread.
 //
 // Once created, it is inactive until Reset is called. Once |delay| seconds have
 // passed since the last call to Reset, the callback is made. Once the callback
 // has been made, it's inactive until Reset is called again.
 //
 // If destroyed, the timeout is canceled and will not occur even if already
 // inflight.
 template <class Receiver>
 class DelayTimer {
  public:
   typedef void (Receiver::*ReceiverMethod)();

   DelayTimer(TimeDelta delay, Receiver* receiver, ReceiverMethod method)
       : receiver_(receiver),
         method_(method),
         delay_(delay) {
   }

   void Reset() {
     DelayFor(delay_);
   }

  private:
   void DelayFor(TimeDelta delay) {
     trigger_time_ = Time::Now() + delay;

     // If we already have a timer that will expire at or before the given delay,
     // then we have nothing more to do now.
     if (timer_.IsRunning() && timer_.GetCurrentDelay() <= delay)
       return;

     // The timer isn't running, or will expire too late, so restart it.
     timer_.Stop();
     timer_.Start(delay, this, &DelayTimer<Receiver>::Check);
   }

   void Check() {
     if (trigger_time_.is_null())
       return;

     // If we have not waited long enough, then wait some more.
     const Time now = Time::Now();
     if (now < trigger_time_) {
       DelayFor(trigger_time_ - now);
       return;
     }

     (receiver_->*method_)();
   }

   Receiver *const receiver_;
   const ReceiverMethod method_;
   const TimeDelta delay_;

   OneShotTimer<DelayTimer<Receiver> > timer_;
   Time trigger_time_;
 };

 }  // namespace base

 #endif  // BASE_TIMER_H_
	// Copyright (c) 2006-2008 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.

	// OneShotTimer and RepeatingTimer provide a simple timer API. As the names
	// suggest, OneShotTimer calls you back once after a time delay expires.
	// RepeatingTimer on the other hand calls you back periodically with the
	// prescribed time interval.
	//
	// OneShotTimer and RepeatingTimer both cancel the timer when they go out of
	// scope, which makes it easy to ensure that you do not get called when your
	// object has gone out of scope. Just instantiate a OneShotTimer or
	// RepeatingTimer as a member variable of the class for which you wish to
	// receive timer events.
	//
	// Sample RepeatingTimer usage:
	//
	// class MyClass {
	// public:
	// void StartDoingStuff() {
	// timer_.Start(TimeDelta::FromSeconds(1), this, &MyClass::DoStuff);
	// }
	// void StopDoingStuff() {
	// timer_.Stop();
	// }
	// private:
	// void DoStuff() {
	// // This method is called every second to do stuff.
	// ...
	// }
	// base::RepeatingTimer<MyClass> timer_;
	// };
	//
	// Both OneShotTimer and RepeatingTimer also support a Reset method, which
	// allows you to easily defer the timer event until the timer delay passes once
	// again. So, in the above example, if 0.5 seconds have already passed,
	// calling Reset on timer_ would postpone DoStuff by another 1 second. In
	// other words, Reset is shorthand for calling Stop and then Start again with
	// the same arguments.

	#ifndef BASE_TIMER_H_
	#define BASE_TIMER_H_

	// IMPORTANT: If you change timer code, make sure that all tests (including
	// disabled ones) from timer_unittests.cc pass locally. Some are disabled
	// because they're flaky on the buildbot, but when you run them locally you
	// should be able to tell the difference.

	#include "base/logging.h"
	#include "base/task.h"
	#include "base/time.h"

	class MessageLoop;

	namespace base {

	//-----------------------------------------------------------------------------
	// This class is an implementation detail of OneShotTimer and RepeatingTimer.
	// Please do not use this class directly.
	//
	// This class exists to share code between BaseTimer<T> template instantiations.
	//
	class BaseTimer_Helper {
	public:
	// Stops the timer.
	~BaseTimer_Helper() {
	OrphanDelayedTask();
	}

	// Returns true if the timer is running (i.e., not stopped).
	bool IsRunning() const {
	return delayed_task_ != NULL;
	}

	// Returns the current delay for this timer. May only call this method when
	// the timer is running!
	TimeDelta GetCurrentDelay() const {
	DCHECK(IsRunning());
	return delayed_task_->delay_;
	}

	protected:
	BaseTimer_Helper() : delayed_task_(NULL) {}

	// We have access to the timer_ member so we can orphan this task.
	class TimerTask : public Task {
	public:
	TimerTask(TimeDelta delay) : timer_(NULL), delay_(delay) {
	}
	virtual ~TimerTask() {}
	BaseTimer_Helper* timer_;
	TimeDelta delay_;
	};

	// Used to orphan delayed_task_ so that when it runs it does nothing.
	void OrphanDelayedTask();

	// Used to initiated a new delayed task. This has the side-effect of
	// orphaning delayed_task_ if it is non-null.
	void InitiateDelayedTask(TimerTask* timer_task);

	TimerTask* delayed_task_;

	DISALLOW_COPY_AND_ASSIGN(BaseTimer_Helper);
	};

	//-----------------------------------------------------------------------------
	// This class is an implementation detail of OneShotTimer and RepeatingTimer.
	// Please do not use this class directly.
	template <class Receiver, bool kIsRepeating>
	class BaseTimer : public BaseTimer_Helper {
	public:
	typedef void (Receiver::*ReceiverMethod)();

	// Call this method to start the timer. It is an error to call this method
	// while the timer is already running.
	void Start(TimeDelta delay, Receiver* receiver, ReceiverMethod method) {
	DCHECK(!IsRunning());
	InitiateDelayedTask(new TimerTask(delay, receiver, method));
	}

	// Call this method to stop the timer. It is a no-op if the timer is not
	// running.
	void Stop() {
	OrphanDelayedTask();
	}

	// Call this method to reset the timer delay of an already running timer.
	void Reset() {
	DCHECK(IsRunning());
	InitiateDelayedTask(static_cast<TimerTask*>(delayed_task_)->Clone());
	}

	private:
	typedef BaseTimer<Receiver, kIsRepeating> SelfType;

	class TimerTask : public BaseTimer_Helper::TimerTask {
	public:
	TimerTask(TimeDelta delay, Receiver* receiver, ReceiverMethod method)
	: BaseTimer_Helper::TimerTask(delay),
	receiver_(receiver),
	method_(method) {
	}

	virtual ~TimerTask() {
	// This task may be getting cleared because the MessageLoop has been
	// destructed. If so, don't leave the Timer with a dangling pointer
	// to this now-defunct task.
	ClearBaseTimer();
	}

	virtual void Run() {
	if (!timer_) // timer_ is null if we were orphaned.
	return;
	if (kIsRepeating)
	ResetBaseTimer();
	else
	ClearBaseTimer();
	DispatchToMethod(receiver_, method_, Tuple0());
	}

	TimerTask* Clone() const {
	return new TimerTask(delay_, receiver_, method_);
	}

	private:
	// Inform the Base that the timer is no longer active.
	void ClearBaseTimer() {
	if (timer_) {
	SelfType* self = static_cast<SelfType*>(timer_);
	// It is possible that the Timer has already been reset, and that this
	// Task is old. So, if the Timer points to a different task, assume
	// that the Timer has already taken care of properly setting the task.
	if (self->delayed_task_ == this)
	self->delayed_task_ = NULL;
	// By now the delayed_task_ in the Timer does not point to us anymore.
	// We should reset our own timer_ because the Timer can not do this
	// for us in its destructor.
	timer_ = NULL;
	}
	}

	// Inform the Base that we're resetting the timer.
	void ResetBaseTimer() {
	DCHECK(timer_);
	DCHECK(kIsRepeating);
	SelfType* self = static_cast<SelfType*>(timer_);
	self->Reset();
	}

	Receiver* receiver_;
	ReceiverMethod method_;
	};
	};

	//-----------------------------------------------------------------------------
	// A simple, one-shot timer. See usage notes at the top of the file.
	template <class Receiver>
	class OneShotTimer : public BaseTimer<Receiver, false> {};

	//-----------------------------------------------------------------------------
	// A simple, repeating timer. See usage notes at the top of the file.
	template <class Receiver>
	class RepeatingTimer : public BaseTimer<Receiver, true> {};

	//-----------------------------------------------------------------------------
	// A Delay timer is like The Button from Lost. Once started, you have to keep
	// calling Reset otherwise it will call the given method in the MessageLoop
	// thread.
	//
	// Once created, it is inactive until Reset is called. Once \|delay\| seconds have
	// passed since the last call to Reset, the callback is made. Once the callback
	// has been made, it's inactive until Reset is called again.
	//
	// If destroyed, the timeout is canceled and will not occur even if already
	// inflight.
	template <class Receiver>
	class DelayTimer {
	public:
	typedef void (Receiver::*ReceiverMethod)();

	DelayTimer(TimeDelta delay, Receiver* receiver, ReceiverMethod method)
	: receiver_(receiver),
	method_(method),
	delay_(delay) {
	}

	void Reset() {
	DelayFor(delay_);
	}

	private:
	void DelayFor(TimeDelta delay) {
	trigger_time_ = Time::Now() + delay;

	// If we already have a timer that will expire at or before the given delay,
	// then we have nothing more to do now.
	if (timer_.IsRunning() && timer_.GetCurrentDelay() <= delay)
	return;

	// The timer isn't running, or will expire too late, so restart it.
	timer_.Stop();
	timer_.Start(delay, this, &DelayTimer<Receiver>::Check);
	}

	void Check() {
	if (trigger_time_.is_null())
	return;

	// If we have not waited long enough, then wait some more.
	const Time now = Time::Now();
	if (now < trigger_time_) {
	DelayFor(trigger_time_ - now);
	return;
	}

	(receiver_->*method_)();
	}

	Receiver *const receiver_;
	const ReceiverMethod method_;
	const TimeDelta delay_;

	OneShotTimer<DelayTimer<Receiver> > timer_;
	Time trigger_time_;
	};

	} // namespace base

	#endif // BASE_TIMER_H_