src/base/timer.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.

 // 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(FROM_HERE, 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.
 //
 // NOTE: These APIs are not thread safe. Always call from the same thread.

 #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/base_export.h"
 #include "base/bind.h"
 #include "base/bind_helpers.h"
 #include "base/callback.h"
 #include "base/location.h"
 #include "base/time.h"

 #if defined(__LB_SHELL_DEBUG_TASKS__)
 #include <stdio.h>
 #include <string>
 #endif

 class MessageLoop;

 namespace base {

 class BaseTimerTaskInternal;

 //-----------------------------------------------------------------------------
 // This class wraps MessageLoop::PostDelayedTask to manage delayed and repeating
 // tasks. It must be destructed on the same thread that starts tasks. There are
 // DCHECKs in place to verify this.
 // For a Timer with repeating task, the user can choose whether the Timer
 // should post the next task T(n+1) before or after running the current task
 // T(n).  As tasks are run in sequence, in the first case T(n+1) is likely to
 // run before other tasks scheduled while the T(n) is running. In the second
 // case T(n+1) will be run after other tasks scheduled while T(n) is running.
 // By default Timer uses the behavior but the user should use the second
 // behavior if the repeating task can be lengthy and is intended to be run at a
 // slightly lower priority.
 class BASE_EXPORT Timer {
  public:
   // Construct a timer in repeating or one-shot mode. Start or SetTaskInfo must
   // be called later to set task info. |retain_user_task| determines whether the
   // user_task is retained or reset when it runs or stops.  When
   // |is_task_run_before_scheduling_next| is true, the next task will be posted
   // after the current one is finished.
   Timer(bool retain_user_task,
         bool is_repeating,
         bool is_task_run_before_scheduling_next = false);

   // Construct a timer with retained task info.    When
   // |is_task_run_before_scheduling_next| is true, the next task will be posted
   // after the current one is finished.
   Timer(const tracked_objects::Location& posted_from,
         TimeDelta delay,
         const base::Closure& user_task,
         bool is_repeating,
         bool is_task_run_before_scheduling_next = false);

   virtual ~Timer();

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

   // Returns the current delay for this timer.
   TimeDelta GetCurrentDelay() const {
     return delay_;
   }

   // Start the timer to run at the given |delay| from now. If the timer is
   // already running, it will be replaced to call the given |user_task|.
   void Start(const tracked_objects::Location& posted_from,
              TimeDelta delay,
              const base::Closure& user_task);

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

   // Call this method to reset the timer delay. The user_task_ must be set. If
   // the timer is not running, this will start it by posting a task.
   void Reset();

   const base::Closure& user_task() const { return user_task_; }
   const TimeTicks& desired_run_time() const { return desired_run_time_; }

  protected:
   // Used to initiate a new delayed task.  This has the side-effect of disabling
   // scheduled_task_ if it is non-null.
   void SetTaskInfo(const tracked_objects::Location& posted_from,
                    TimeDelta delay,
                    const base::Closure& user_task);

  private:
   struct NewScheduledTaskInfo {
     tracked_objects::Location posted_from;
     base::Closure task;
   };

   friend class BaseTimerTaskInternal;

   // Allocates a new scheduled_task_ and posts it on the current MessageLoop
   // with the given |delay|. scheduled_task_ must be NULL. scheduled_run_time_
   // and desired_run_time_ are reset to Now() + delay.
   void PostNewScheduledTask(TimeDelta delay);
   // Allocates a new scheduled_task_ so it can be posted on the current
   // MessageLoop later.  scheduled_task_ must be NULL. scheduled_run_time_ and
   // desired_run_time_ are reset to Now() + delay.
   NewScheduledTaskInfo SetupNewScheduledTask(TimeDelta expected_delay);
   // Post the task on the current MessageLoop.  Note that the delay isn't the
   // same as the expected_delay in the above function.  It has been adjusted
   // according to the duration of the current task.
   void PostNewScheduledTask(NewScheduledTaskInfo task_info, TimeDelta delay);

   // Disable scheduled_task_ and abandon it so that it no longer refers back to
   // this object.
   void AbandonScheduledTask();

   // Called by BaseTimerTaskInternal when the MessageLoop runs it.
   void RunScheduledTask();

   // Stop running task (if any) and abandon scheduled task (if any).
   void StopAndAbandon() {
     Stop();
     AbandonScheduledTask();
   }

   // When non-NULL, the scheduled_task_ is waiting in the MessageLoop to call
   // RunScheduledTask() at scheduled_run_time_.
   BaseTimerTaskInternal* scheduled_task_;

   // Location in user code.
   tracked_objects::Location posted_from_;
   // Delay requested by user.
   TimeDelta delay_;
   // user_task_ is what the user wants to be run at desired_run_time_.
   base::Closure user_task_;

   // The estimated time that the MessageLoop will run the scheduled_task_ that
   // will call RunScheduledTask().
   TimeTicks scheduled_run_time_;

   // The desired run time of user_task_. The user may update this at any time,
   // even if their previous request has not run yet. If desired_run_time_ is
   // greater than scheduled_run_time_, a continuation task will be posted to
   // wait for the remaining time. This allows us to reuse the pending task so as
   // not to flood the MessageLoop with orphaned tasks when the user code
   // excessively Stops and Starts the timer.
   TimeTicks desired_run_time_;

   // Thread ID of current MessageLoop for verifying single-threaded usage.
   int thread_id_;

   // Repeating timers automatically post the task again before calling the task
   // callback.
   const bool is_repeating_;

   // The next task will be scheduled after the current one is finished.  Can
   // only be true when is_repeating_ is true.
   const bool is_task_run_before_scheduling_next_;

   // If true, hold on to the user_task_ closure object for reuse.
   const bool retain_user_task_;

   // If true, user_task_ is scheduled to run sometime in the future.
   bool is_running_;

   DISALLOW_COPY_AND_ASSIGN(Timer);
 };

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

   // This is here to work around the fact that Timer::Start is "hidden" by the
   // Start definition below, rather than being overloaded.
   // TODO(tim): We should remove uses of BaseTimerMethodPointer::Start below
   // and convert callers to use the base::Closure version in Timer::Start,
   // see bug 148832.
   using Timer::Start;

   BaseTimerMethodPointer() : Timer(kIsRepeating, kIsRepeating) {}

   // Start the timer to run at the given |delay| from now. If the timer is
   // already running, it will be replaced to call a task formed from
   // |reviewer->*method|.
   void Start(const tracked_objects::Location& posted_from,
              TimeDelta delay,
              Receiver* receiver,
              ReceiverMethod method) {
     Timer::Start(posted_from, delay,
                  base::Bind(method, base::Unretained(receiver)));
   }
 };

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

 //-----------------------------------------------------------------------------
 // A simple, repeating timer.  See usage notes at the top of the file.
 template <class Receiver>
 class RepeatingTimer : public BaseTimerMethodPointer<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 : protected Timer {
  public:
   typedef void (Receiver::*ReceiverMethod)();

   DelayTimer(const tracked_objects::Location& posted_from,
              TimeDelta delay,
              Receiver* receiver,
              ReceiverMethod method)
       : Timer(posted_from, delay,
               base::Bind(method, base::Unretained(receiver)),
               false) {}

   void Reset() { Timer::Reset(); }
 };

 }  // namespace base

 #endif  // BASE_TIMER_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.

	// 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(FROM_HERE, 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.
	//
	// NOTE: These APIs are not thread safe. Always call from the same thread.

	#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/base_export.h"
	#include "base/bind.h"
	#include "base/bind_helpers.h"
	#include "base/callback.h"
	#include "base/location.h"
	#include "base/time.h"

	#if defined(__LB_SHELL_DEBUG_TASKS__)
	#include <stdio.h>
	#include <string>
	#endif

	class MessageLoop;

	namespace base {

	class BaseTimerTaskInternal;

	//-----------------------------------------------------------------------------
	// This class wraps MessageLoop::PostDelayedTask to manage delayed and repeating
	// tasks. It must be destructed on the same thread that starts tasks. There are
	// DCHECKs in place to verify this.
	// For a Timer with repeating task, the user can choose whether the Timer
	// should post the next task T(n+1) before or after running the current task
	// T(n). As tasks are run in sequence, in the first case T(n+1) is likely to
	// run before other tasks scheduled while the T(n) is running. In the second
	// case T(n+1) will be run after other tasks scheduled while T(n) is running.
	// By default Timer uses the behavior but the user should use the second
	// behavior if the repeating task can be lengthy and is intended to be run at a
	// slightly lower priority.
	class BASE_EXPORT Timer {
	public:
	// Construct a timer in repeating or one-shot mode. Start or SetTaskInfo must
	// be called later to set task info. \|retain_user_task\| determines whether the
	// user_task is retained or reset when it runs or stops. When
	// \|is_task_run_before_scheduling_next\| is true, the next task will be posted
	// after the current one is finished.
	Timer(bool retain_user_task,
	bool is_repeating,
	bool is_task_run_before_scheduling_next = false);

	// Construct a timer with retained task info. When
	// \|is_task_run_before_scheduling_next\| is true, the next task will be posted
	// after the current one is finished.
	Timer(const tracked_objects::Location& posted_from,
	TimeDelta delay,
	const base::Closure& user_task,
	bool is_repeating,
	bool is_task_run_before_scheduling_next = false);

	virtual ~Timer();

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

	// Returns the current delay for this timer.
	TimeDelta GetCurrentDelay() const {
	return delay_;
	}

	// Start the timer to run at the given \|delay\| from now. If the timer is
	// already running, it will be replaced to call the given \|user_task\|.
	void Start(const tracked_objects::Location& posted_from,
	TimeDelta delay,
	const base::Closure& user_task);

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

	// Call this method to reset the timer delay. The user_task_ must be set. If
	// the timer is not running, this will start it by posting a task.
	void Reset();

	const base::Closure& user_task() const { return user_task_; }
	const TimeTicks& desired_run_time() const { return desired_run_time_; }

	protected:
	// Used to initiate a new delayed task. This has the side-effect of disabling
	// scheduled_task_ if it is non-null.
	void SetTaskInfo(const tracked_objects::Location& posted_from,
	TimeDelta delay,
	const base::Closure& user_task);

	private:
	struct NewScheduledTaskInfo {
	tracked_objects::Location posted_from;
	base::Closure task;
	};

	friend class BaseTimerTaskInternal;

	// Allocates a new scheduled_task_ and posts it on the current MessageLoop
	// with the given \|delay\|. scheduled_task_ must be NULL. scheduled_run_time_
	// and desired_run_time_ are reset to Now() + delay.
	void PostNewScheduledTask(TimeDelta delay);
	// Allocates a new scheduled_task_ so it can be posted on the current
	// MessageLoop later. scheduled_task_ must be NULL. scheduled_run_time_ and
	// desired_run_time_ are reset to Now() + delay.
	NewScheduledTaskInfo SetupNewScheduledTask(TimeDelta expected_delay);
	// Post the task on the current MessageLoop. Note that the delay isn't the
	// same as the expected_delay in the above function. It has been adjusted
	// according to the duration of the current task.
	void PostNewScheduledTask(NewScheduledTaskInfo task_info, TimeDelta delay);

	// Disable scheduled_task_ and abandon it so that it no longer refers back to
	// this object.
	void AbandonScheduledTask();

	// Called by BaseTimerTaskInternal when the MessageLoop runs it.
	void RunScheduledTask();

	// Stop running task (if any) and abandon scheduled task (if any).
	void StopAndAbandon() {
	Stop();
	AbandonScheduledTask();
	}

	// When non-NULL, the scheduled_task_ is waiting in the MessageLoop to call
	// RunScheduledTask() at scheduled_run_time_.
	BaseTimerTaskInternal* scheduled_task_;

	// Location in user code.
	tracked_objects::Location posted_from_;
	// Delay requested by user.
	TimeDelta delay_;
	// user_task_ is what the user wants to be run at desired_run_time_.
	base::Closure user_task_;

	// The estimated time that the MessageLoop will run the scheduled_task_ that
	// will call RunScheduledTask().
	TimeTicks scheduled_run_time_;

	// The desired run time of user_task_. The user may update this at any time,
	// even if their previous request has not run yet. If desired_run_time_ is
	// greater than scheduled_run_time_, a continuation task will be posted to
	// wait for the remaining time. This allows us to reuse the pending task so as
	// not to flood the MessageLoop with orphaned tasks when the user code
	// excessively Stops and Starts the timer.
	TimeTicks desired_run_time_;

	// Thread ID of current MessageLoop for verifying single-threaded usage.
	int thread_id_;

	// Repeating timers automatically post the task again before calling the task
	// callback.
	const bool is_repeating_;

	// The next task will be scheduled after the current one is finished. Can
	// only be true when is_repeating_ is true.
	const bool is_task_run_before_scheduling_next_;

	// If true, hold on to the user_task_ closure object for reuse.
	const bool retain_user_task_;

	// If true, user_task_ is scheduled to run sometime in the future.
	bool is_running_;

	DISALLOW_COPY_AND_ASSIGN(Timer);
	};

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

	// This is here to work around the fact that Timer::Start is "hidden" by the
	// Start definition below, rather than being overloaded.
	// TODO(tim): We should remove uses of BaseTimerMethodPointer::Start below
	// and convert callers to use the base::Closure version in Timer::Start,
	// see bug 148832.
	using Timer::Start;

	BaseTimerMethodPointer() : Timer(kIsRepeating, kIsRepeating) {}

	// Start the timer to run at the given \|delay\| from now. If the timer is
	// already running, it will be replaced to call a task formed from
	// \|reviewer->*method\|.
	void Start(const tracked_objects::Location& posted_from,
	TimeDelta delay,
	Receiver* receiver,
	ReceiverMethod method) {
	Timer::Start(posted_from, delay,
	base::Bind(method, base::Unretained(receiver)));
	}
	};

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

	//-----------------------------------------------------------------------------
	// A simple, repeating timer. See usage notes at the top of the file.
	template <class Receiver>
	class RepeatingTimer : public BaseTimerMethodPointer<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 : protected Timer {
	public:
	typedef void (Receiver::*ReceiverMethod)();

	DelayTimer(const tracked_objects::Location& posted_from,
	TimeDelta delay,
	Receiver* receiver,
	ReceiverMethod method)
	: Timer(posted_from, delay,
	base::Bind(method, base::Unretained(receiver)),
	false) {}

	void Reset() { Timer::Reset(); }
	};

	} // namespace base

	#endif // BASE_TIMER_H_