src/base/message_pump.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_MESSAGE_PUMP_H_
 #define BASE_MESSAGE_PUMP_H_

 #include "base/base_export.h"
 #include "base/memory/ref_counted.h"

 namespace base {

 class TimeTicks;

 class BASE_EXPORT MessagePump : public RefCountedThreadSafe<MessagePump> {
  public:
   // Please see the comments above the Run method for an illustration of how
   // these delegate methods are used.
   class BASE_EXPORT Delegate {
    public:
     virtual ~Delegate() {}

     // Called from within Run in response to ScheduleWork or when the message
     // pump would otherwise call DoDelayedWork.  Returns true to indicate that
     // work was done.  DoDelayedWork will still be called if DoWork returns
     // true, but DoIdleWork will not.
     virtual bool DoWork() = 0;

     // Called from within Run in response to ScheduleDelayedWork or when the
     // message pump would otherwise sleep waiting for more work.  Returns true
     // to indicate that delayed work was done.  DoIdleWork will not be called
     // if DoDelayedWork returns true.  Upon return |next_delayed_work_time|
     // indicates the time when DoDelayedWork should be called again.  If
     // |next_delayed_work_time| is null (per Time::is_null), then the queue of
     // future delayed work (timer events) is currently empty, and no additional
     // calls to this function need to be scheduled.
     virtual bool DoDelayedWork(TimeTicks* next_delayed_work_time) = 0;

     // Called from within Run just before the message pump goes to sleep.
     // Returns true to indicate that idle work was done.
     virtual bool DoIdleWork() = 0;
   };

   MessagePump();

   // The Run method is called to enter the message pump's run loop.
   //
   // Within the method, the message pump is responsible for processing native
   // messages as well as for giving cycles to the delegate periodically.  The
   // message pump should take care to mix delegate callbacks with native
   // message processing so neither type of event starves the other of cycles.
   //
   // The anatomy of a typical run loop:
   //
   //   for (;;) {
   //     bool did_work = DoInternalWork();
   //     if (should_quit_)
   //       break;
   //
   //     did_work |= delegate_->DoWork();
   //     if (should_quit_)
   //       break;
   //
   //     TimeTicks next_time;
   //     did_work |= delegate_->DoDelayedWork(&next_time);
   //     if (should_quit_)
   //       break;
   //
   //     if (did_work)
   //       continue;
   //
   //     did_work = delegate_->DoIdleWork();
   //     if (should_quit_)
   //       break;
   //
   //     if (did_work)
   //       continue;
   //
   //     WaitForWork();
   //   }
   //
   // Here, DoInternalWork is some private method of the message pump that is
   // responsible for dispatching the next UI message or notifying the next IO
   // completion (for example).  WaitForWork is a private method that simply
   // blocks until there is more work of any type to do.
   //
   // Notice that the run loop cycles between calling DoInternalWork, DoWork,
   // and DoDelayedWork methods.  This helps ensure that none of these work
   // queues starve the others.  This is important for message pumps that are
   // used to drive animations, for example.
   //
   // Notice also that after each callout to foreign code, the run loop checks
   // to see if it should quit.  The Quit method is responsible for setting this
   // flag.  No further work is done once the quit flag is set.
   //
   // NOTE: Care must be taken to handle Run being called again from within any
   // of the callouts to foreign code.  Native message pumps may also need to
   // deal with other native message pumps being run outside their control
   // (e.g., the MessageBox API on Windows pumps UI messages!).  To be specific,
   // the callouts (DoWork and DoDelayedWork) MUST still be provided even in
   // nested sub-loops that are "seemingly" outside the control of this message
   // pump.  DoWork in particular must never be starved for time slices unless
   // it returns false (meaning it has run out of things to do).
   //
   virtual void Run(Delegate* delegate) = 0;

   // Quit immediately from the most recently entered run loop.  This method may
   // only be used on the thread that called Run.
   virtual void Quit() = 0;

   // Schedule a DoWork callback to happen reasonably soon.  Does nothing if a
   // DoWork callback is already scheduled.  This method may be called from any
   // thread.  Once this call is made, DoWork should not be "starved" at least
   // until it returns a value of false.
   virtual void ScheduleWork() = 0;

   // Schedule a DoDelayedWork callback to happen at the specified time,
   // cancelling any pending DoDelayedWork callback.  This method may only be
   // used on the thread that called Run.
   virtual void ScheduleDelayedWork(const TimeTicks& delayed_work_time) = 0;

  protected:
   virtual ~MessagePump();
   friend class RefCountedThreadSafe<MessagePump>;
 };

 }  // namespace base

 #endif  // BASE_MESSAGE_PUMP_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_MESSAGE_PUMP_H_
	#define BASE_MESSAGE_PUMP_H_

	#include "base/base_export.h"
	#include "base/memory/ref_counted.h"

	namespace base {

	class TimeTicks;

	class BASE_EXPORT MessagePump : public RefCountedThreadSafe<MessagePump> {
	public:
	// Please see the comments above the Run method for an illustration of how
	// these delegate methods are used.
	class BASE_EXPORT Delegate {
	public:
	virtual ~Delegate() {}

	// Called from within Run in response to ScheduleWork or when the message
	// pump would otherwise call DoDelayedWork. Returns true to indicate that
	// work was done. DoDelayedWork will still be called if DoWork returns
	// true, but DoIdleWork will not.
	virtual bool DoWork() = 0;

	// Called from within Run in response to ScheduleDelayedWork or when the
	// message pump would otherwise sleep waiting for more work. Returns true
	// to indicate that delayed work was done. DoIdleWork will not be called
	// if DoDelayedWork returns true. Upon return \|next_delayed_work_time\|
	// indicates the time when DoDelayedWork should be called again. If
	// \|next_delayed_work_time\| is null (per Time::is_null), then the queue of
	// future delayed work (timer events) is currently empty, and no additional
	// calls to this function need to be scheduled.
	virtual bool DoDelayedWork(TimeTicks* next_delayed_work_time) = 0;

	// Called from within Run just before the message pump goes to sleep.
	// Returns true to indicate that idle work was done.
	virtual bool DoIdleWork() = 0;
	};

	MessagePump();

	// The Run method is called to enter the message pump's run loop.
	//
	// Within the method, the message pump is responsible for processing native
	// messages as well as for giving cycles to the delegate periodically. The
	// message pump should take care to mix delegate callbacks with native
	// message processing so neither type of event starves the other of cycles.
	//
	// The anatomy of a typical run loop:
	//
	// for (;;) {
	// bool did_work = DoInternalWork();
	// if (should_quit_)
	// break;
	//
	// did_work \|= delegate_->DoWork();
	// if (should_quit_)
	// break;
	//
	// TimeTicks next_time;
	// did_work \|= delegate_->DoDelayedWork(&next_time);
	// if (should_quit_)
	// break;
	//
	// if (did_work)
	// continue;
	//
	// did_work = delegate_->DoIdleWork();
	// if (should_quit_)
	// break;
	//
	// if (did_work)
	// continue;
	//
	// WaitForWork();
	// }
	//
	// Here, DoInternalWork is some private method of the message pump that is
	// responsible for dispatching the next UI message or notifying the next IO
	// completion (for example). WaitForWork is a private method that simply
	// blocks until there is more work of any type to do.
	//
	// Notice that the run loop cycles between calling DoInternalWork, DoWork,
	// and DoDelayedWork methods. This helps ensure that none of these work
	// queues starve the others. This is important for message pumps that are
	// used to drive animations, for example.
	//
	// Notice also that after each callout to foreign code, the run loop checks
	// to see if it should quit. The Quit method is responsible for setting this
	// flag. No further work is done once the quit flag is set.
	//
	// NOTE: Care must be taken to handle Run being called again from within any
	// of the callouts to foreign code. Native message pumps may also need to
	// deal with other native message pumps being run outside their control
	// (e.g., the MessageBox API on Windows pumps UI messages!). To be specific,
	// the callouts (DoWork and DoDelayedWork) MUST still be provided even in
	// nested sub-loops that are "seemingly" outside the control of this message
	// pump. DoWork in particular must never be starved for time slices unless
	// it returns false (meaning it has run out of things to do).
	//
	virtual void Run(Delegate* delegate) = 0;

	// Quit immediately from the most recently entered run loop. This method may
	// only be used on the thread that called Run.
	virtual void Quit() = 0;

	// Schedule a DoWork callback to happen reasonably soon. Does nothing if a
	// DoWork callback is already scheduled. This method may be called from any
	// thread. Once this call is made, DoWork should not be "starved" at least
	// until it returns a value of false.
	virtual void ScheduleWork() = 0;

	// Schedule a DoDelayedWork callback to happen at the specified time,
	// cancelling any pending DoDelayedWork callback. This method may only be
	// used on the thread that called Run.
	virtual void ScheduleDelayedWork(const TimeTicks& delayed_work_time) = 0;

	protected:
	virtual ~MessagePump();
	friend class RefCountedThreadSafe<MessagePump>;
	};

	} // namespace base

	#endif // BASE_MESSAGE_PUMP_H_