base/condition_variable.h - chromium/src - Git at Google

 // 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.

 // ConditionVariable wraps pthreads condition variable synchronization or, on
 // Windows, simulates it.  This functionality is very helpful for having
 // several threads wait for an event, as is common with a thread pool managed
 // by a master.  The meaning of such an event in the (worker) thread pool
 // scenario is that additional tasks are now available for processing.  It is
 // used in Chrome in the DNS prefetching system to notify worker threads that
 // a queue now has items (tasks) which need to be tended to.  A related use
 // would have a pool manager waiting on a ConditionVariable, waiting for a
 // thread in the pool to announce (signal) that there is now more room in a
 // (bounded size) communications queue for the manager to deposit tasks, or,
 // as a second example, that the queue of tasks is completely empty and all
 // workers are waiting.
 //
 // USAGE NOTE 1: spurious signal events are possible with this and
 // most implementations of condition variables.  As a result, be
 // *sure* to retest your condition before proceeding.  The following
 // is a good example of doing this correctly:
 //
 // while (!work_to_be_done()) Wait(...);
 //
 // In contrast do NOT do the following:
 //
 // if (!work_to_be_done()) Wait(...);  // Don't do this.
 //
 // Especially avoid the above if you are relying on some other thread only
 // issuing a signal up *if* there is work-to-do.  There can/will
 // be spurious signals.  Recheck state on waiting thread before
 // assuming the signal was intentional. Caveat caller ;-).
 //
 // USAGE NOTE 2: Broadcast() frees up all waiting threads at once,
 // which leads to contention for the locks they all held when they
 // called Wait().  This results in POOR performance.  A much better
 // approach to getting a lot of threads out of Wait() is to have each
 // thread (upon exiting Wait()) call Signal() to free up another
 // Wait'ing thread.  Look at condition_variable_unittest.cc for
 // both examples.
 //
 // Broadcast() can be used nicely during teardown, as it gets the job
 // done, and leaves no sleeping threads... and performance is less
 // critical at that point.
 //
 // The semantics of Broadcast() are carefully crafted so that *all*
 // threads that were waiting when the request was made will indeed
 // get signaled.  Some implementations mess up, and don't signal them
 // all, while others allow the wait to be effectively turned off (for
 // a while while waiting threads come around).  This implementation
 // appears correct, as it will not "lose" any signals, and will guarantee
 // that all threads get signaled by Broadcast().
 //
 // This implementation offers support for "performance" in its selection of
 // which thread to revive.  Performance, in direct contrast with "fairness,"
 // assures that the thread that most recently began to Wait() is selected by
 // Signal to revive.  Fairness would (if publicly supported) assure that the
 // thread that has Wait()ed the longest is selected. The default policy
 // may improve performance, as the selected thread may have a greater chance of
 // having some of its stack data in various CPU caches.
 //
 // For a discussion of the many very subtle implementation details, see the FAQ
 // at the end of condition_variable_win.cc.

 #ifndef BASE_CONDITION_VARIABLE_H_
 #define BASE_CONDITION_VARIABLE_H_
 #pragma once

 #include "build/build_config.h"

 #if defined(OS_WIN)
 #include <windows.h>
 #elif defined(OS_POSIX)
 #include <pthread.h>
 #endif

 #include "base/basictypes.h"
 #include "base/lock.h"

 namespace base {
   class TimeDelta;
 }

 class ConditionVariable {
  public:
   // Construct a cv for use with ONLY one user lock.
   explicit ConditionVariable(Lock* user_lock);

   ~ConditionVariable();

   // Wait() releases the caller's critical section atomically as it starts to
   // sleep, and the reacquires it when it is signaled.
   void Wait();
   void TimedWait(const base::TimeDelta& max_time);

   // Broadcast() revives all waiting threads.
   void Broadcast();
   // Signal() revives one waiting thread.
   void Signal();

  private:

 #if defined(OS_WIN)

   // Define Event class that is used to form circularly linked lists.
   // The list container is an element with NULL as its handle_ value.
   // The actual list elements have a non-zero handle_ value.
   // All calls to methods MUST be done under protection of a lock so that links
   // can be validated.  Without the lock, some links might asynchronously
   // change, and the assertions would fail (as would list change operations).
   class Event {
    public:
     // Default constructor with no arguments creates a list container.
     Event();
     ~Event();

     // InitListElement transitions an instance from a container, to an element.
     void InitListElement();

     // Methods for use on lists.
     bool IsEmpty() const;
     void PushBack(Event* other);
     Event* PopFront();
     Event* PopBack();

     // Methods for use on list elements.
     // Accessor method.
     HANDLE handle() const;
     // Pull an element from a list (if it's in one).
     Event* Extract();

     // Method for use on a list element or on a list.
     bool IsSingleton() const;

    private:
     // Provide pre/post conditions to validate correct manipulations.
     bool ValidateAsDistinct(Event* other) const;
     bool ValidateAsItem() const;
     bool ValidateAsList() const;
     bool ValidateLinks() const;

     HANDLE handle_;
     Event* next_;
     Event* prev_;
     DISALLOW_COPY_AND_ASSIGN(Event);
   };

   // Note that RUNNING is an unlikely number to have in RAM by accident.
   // This helps with defensive destructor coding in the face of user error.
   enum RunState { SHUTDOWN = 0, RUNNING = 64213 };

   // Internal implementation methods supporting Wait().
   Event* GetEventForWaiting();
   void RecycleEvent(Event* used_event);

   RunState run_state_;

   // Private critical section for access to member data.
   Lock internal_lock_;

   // Lock that is acquired before calling Wait().
   Lock& user_lock_;

   // Events that threads are blocked on.
   Event waiting_list_;

   // Free list for old events.
   Event recycling_list_;
   int recycling_list_size_;

   // The number of allocated, but not yet deleted events.
   int allocation_counter_;

 #elif defined(OS_POSIX)

   pthread_cond_t condition_;
   pthread_mutex_t* user_mutex_;
 #if !defined(NDEBUG)
   Lock* user_lock_;     // Needed to adjust shadow lock state on wait.
 #endif

 #endif

   DISALLOW_COPY_AND_ASSIGN(ConditionVariable);
 };

 #endif  // BASE_CONDITION_VARIABLE_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.

	// ConditionVariable wraps pthreads condition variable synchronization or, on
	// Windows, simulates it. This functionality is very helpful for having
	// several threads wait for an event, as is common with a thread pool managed
	// by a master. The meaning of such an event in the (worker) thread pool
	// scenario is that additional tasks are now available for processing. It is
	// used in Chrome in the DNS prefetching system to notify worker threads that
	// a queue now has items (tasks) which need to be tended to. A related use
	// would have a pool manager waiting on a ConditionVariable, waiting for a
	// thread in the pool to announce (signal) that there is now more room in a
	// (bounded size) communications queue for the manager to deposit tasks, or,
	// as a second example, that the queue of tasks is completely empty and all
	// workers are waiting.
	//
	// USAGE NOTE 1: spurious signal events are possible with this and
	// most implementations of condition variables. As a result, be
	// sure to retest your condition before proceeding. The following
	// is a good example of doing this correctly:
	//
	// while (!work_to_be_done()) Wait(...);
	//
	// In contrast do NOT do the following:
	//
	// if (!work_to_be_done()) Wait(...); // Don't do this.
	//
	// Especially avoid the above if you are relying on some other thread only
	// issuing a signal up if there is work-to-do. There can/will
	// be spurious signals. Recheck state on waiting thread before
	// assuming the signal was intentional. Caveat caller ;-).
	//
	// USAGE NOTE 2: Broadcast() frees up all waiting threads at once,
	// which leads to contention for the locks they all held when they
	// called Wait(). This results in POOR performance. A much better
	// approach to getting a lot of threads out of Wait() is to have each
	// thread (upon exiting Wait()) call Signal() to free up another
	// Wait'ing thread. Look at condition_variable_unittest.cc for
	// both examples.
	//
	// Broadcast() can be used nicely during teardown, as it gets the job
	// done, and leaves no sleeping threads... and performance is less
	// critical at that point.
	//
	// The semantics of Broadcast() are carefully crafted so that all
	// threads that were waiting when the request was made will indeed
	// get signaled. Some implementations mess up, and don't signal them
	// all, while others allow the wait to be effectively turned off (for
	// a while while waiting threads come around). This implementation
	// appears correct, as it will not "lose" any signals, and will guarantee
	// that all threads get signaled by Broadcast().
	//
	// This implementation offers support for "performance" in its selection of
	// which thread to revive. Performance, in direct contrast with "fairness,"
	// assures that the thread that most recently began to Wait() is selected by
	// Signal to revive. Fairness would (if publicly supported) assure that the
	// thread that has Wait()ed the longest is selected. The default policy
	// may improve performance, as the selected thread may have a greater chance of
	// having some of its stack data in various CPU caches.
	//
	// For a discussion of the many very subtle implementation details, see the FAQ
	// at the end of condition_variable_win.cc.

	#ifndef BASE_CONDITION_VARIABLE_H_
	#define BASE_CONDITION_VARIABLE_H_
	#pragma once

	#include "build/build_config.h"

	#if defined(OS_WIN)
	#include <windows.h>
	#elif defined(OS_POSIX)
	#include <pthread.h>
	#endif

	#include "base/basictypes.h"
	#include "base/lock.h"

	namespace base {
	class TimeDelta;
	}

	class ConditionVariable {
	public:
	// Construct a cv for use with ONLY one user lock.
	explicit ConditionVariable(Lock* user_lock);

	~ConditionVariable();

	// Wait() releases the caller's critical section atomically as it starts to
	// sleep, and the reacquires it when it is signaled.
	void Wait();
	void TimedWait(const base::TimeDelta& max_time);

	// Broadcast() revives all waiting threads.
	void Broadcast();
	// Signal() revives one waiting thread.
	void Signal();

	private:

	#if defined(OS_WIN)

	// Define Event class that is used to form circularly linked lists.
	// The list container is an element with NULL as its handle_ value.
	// The actual list elements have a non-zero handle_ value.
	// All calls to methods MUST be done under protection of a lock so that links
	// can be validated. Without the lock, some links might asynchronously
	// change, and the assertions would fail (as would list change operations).
	class Event {
	public:
	// Default constructor with no arguments creates a list container.
	Event();
	~Event();

	// InitListElement transitions an instance from a container, to an element.
	void InitListElement();

	// Methods for use on lists.
	bool IsEmpty() const;
	void PushBack(Event* other);
	Event* PopFront();
	Event* PopBack();

	// Methods for use on list elements.
	// Accessor method.
	HANDLE handle() const;
	// Pull an element from a list (if it's in one).
	Event* Extract();

	// Method for use on a list element or on a list.
	bool IsSingleton() const;

	private:
	// Provide pre/post conditions to validate correct manipulations.
	bool ValidateAsDistinct(Event* other) const;
	bool ValidateAsItem() const;
	bool ValidateAsList() const;
	bool ValidateLinks() const;

	HANDLE handle_;
	Event* next_;
	Event* prev_;
	DISALLOW_COPY_AND_ASSIGN(Event);
	};

	// Note that RUNNING is an unlikely number to have in RAM by accident.
	// This helps with defensive destructor coding in the face of user error.
	enum RunState { SHUTDOWN = 0, RUNNING = 64213 };

	// Internal implementation methods supporting Wait().
	Event* GetEventForWaiting();
	void RecycleEvent(Event* used_event);

	RunState run_state_;

	// Private critical section for access to member data.
	Lock internal_lock_;

	// Lock that is acquired before calling Wait().
	Lock& user_lock_;

	// Events that threads are blocked on.
	Event waiting_list_;

	// Free list for old events.
	Event recycling_list_;
	int recycling_list_size_;

	// The number of allocated, but not yet deleted events.
	int allocation_counter_;

	#elif defined(OS_POSIX)

	pthread_cond_t condition_;
	pthread_mutex_t* user_mutex_;
	#if !defined(NDEBUG)
	Lock* user_lock_; // Needed to adjust shadow lock state on wait.
	#endif

	#endif

	DISALLOW_COPY_AND_ASSIGN(ConditionVariable);
	};

	#endif // BASE_CONDITION_VARIABLE_H_