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

 // Copyright (c) 2006-2009 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_THREAD_H_
 #define BASE_THREAD_H_

 #include <string>

 #include "base/message_loop.h"
 #include "base/message_loop_proxy.h"
 #include "base/platform_thread.h"

 namespace base {

 // A simple thread abstraction that establishes a MessageLoop on a new thread.
 // The consumer uses the MessageLoop of the thread to cause code to execute on
 // the thread.  When this object is destroyed the thread is terminated.  All
 // pending tasks queued on the thread's message loop will run to completion
 // before the thread is terminated.
 //
 // After the thread is stopped, the destruction sequence is:
 //
 //  (1) Thread::CleanUp()
 //  (2) MessageLoop::~MessageLoop
 //  (3.b)    MessageLoop::DestructionObserver::WillDestroyCurrentMessageLoop
 //  (4) Thread::CleanUpAfterMessageLoopDestruction()
 class Thread : PlatformThread::Delegate {
  public:
   struct Options {
     // Specifies the type of message loop that will be allocated on the thread.
     MessageLoop::Type message_loop_type;

     // Specifies the maximum stack size that the thread is allowed to use.
     // This does not necessarily correspond to the thread's initial stack size.
     // A value of 0 indicates that the default maximum should be used.
     size_t stack_size;

     Options() : message_loop_type(MessageLoop::TYPE_DEFAULT), stack_size(0) {}
     Options(MessageLoop::Type type, size_t size)
         : message_loop_type(type), stack_size(size) {}
   };

   // Constructor.
   // name is a display string to identify the thread.
   explicit Thread(const char* name);

   // Destroys the thread, stopping it if necessary.
   //
   // NOTE: If you are subclassing from Thread, and you wish for your CleanUp
   // method to be called, then you need to call Stop() from your destructor.
   //
   virtual ~Thread();

   // Starts the thread.  Returns true if the thread was successfully started;
   // otherwise, returns false.  Upon successful return, the message_loop()
   // getter will return non-null.
   //
   // Note: This function can't be called on Windows with the loader lock held;
   // i.e. during a DllMain, global object construction or destruction, atexit()
   // callback.
   bool Start();

   // Starts the thread. Behaves exactly like Start in addition to allow to
   // override the default options.
   //
   // Note: This function can't be called on Windows with the loader lock held;
   // i.e. during a DllMain, global object construction or destruction, atexit()
   // callback.
   bool StartWithOptions(const Options& options);

   // Signals the thread to exit and returns once the thread has exited.  After
   // this method returns, the Thread object is completely reset and may be used
   // as if it were newly constructed (i.e., Start may be called again).
   //
   // Stop may be called multiple times and is simply ignored if the thread is
   // already stopped.
   //
   // NOTE: This method is optional.  It is not strictly necessary to call this
   // method as the Thread's destructor will take care of stopping the thread if
   // necessary.
   //
   void Stop();

   // Signals the thread to exit in the near future.
   //
   // WARNING: This function is not meant to be commonly used. Use at your own
   // risk. Calling this function will cause message_loop() to become invalid in
   // the near future. This function was created to workaround a specific
   // deadlock on Windows with printer worker thread. In any other case, Stop()
   // should be used.
   //
   // StopSoon should not be called multiple times as it is risky to do so. It
   // could cause a timing issue in message_loop() access. Call Stop() to reset
   // the thread object once it is known that the thread has quit.
   void StopSoon();

   // Returns the message loop for this thread.  Use the MessageLoop's
   // PostTask methods to execute code on the thread.  This only returns
   // non-null after a successful call to Start.  After Stop has been called,
   // this will return NULL.
   //
   // NOTE: You must not call this MessageLoop's Quit method directly.  Use
   // the Thread's Stop method instead.
   //
   MessageLoop* message_loop() const { return message_loop_; }

   // Returns a MessageLoopProxy for this thread.  Use the MessageLoopProxy's
   // PostTask methods to execute code on the thread.  This only returns
   // non-null after a successful call to Start. After Stop has been called,
   // this will return NULL. Callers can hold on to this even after the thread
   // is gone.
   // TODO(sanjeevr): Look into merging MessageLoop and MessageLoopProxy.
   scoped_refptr<MessageLoopProxy> message_loop_proxy() {
     return message_loop_proxy_;
   }

   // Set the name of this thread (for display in debugger too).
   const std::string &thread_name() { return name_; }

   // The native thread handle.
   PlatformThreadHandle thread_handle() { return thread_; }

   // The thread ID.
   PlatformThreadId thread_id() const { return thread_id_; }

   // Returns true if the thread has been started, and not yet stopped.
   // When a thread is running, the thread_id_ is non-zero.
   bool IsRunning() const { return thread_id_ != 0; }

  protected:
   // Called just prior to starting the message loop
   virtual void Init() {}

   // Called to start the message loop
   virtual void Run(MessageLoop* message_loop);

   // Called just after the message loop ends
   virtual void CleanUp() {}

   // Called after the message loop has been deleted. In general clients
   // should prefer to use CleanUp(). This method is used when code needs to
   // be run after all of the MessageLoop::DestructionObservers have completed.
   virtual void CleanUpAfterMessageLoopDestruction() {}

   static void SetThreadWasQuitProperly(bool flag);
   static bool GetThreadWasQuitProperly();

   void set_message_loop(MessageLoop* message_loop) {
     message_loop_ = message_loop;
   }

  private:
   // PlatformThread::Delegate methods:
   virtual void ThreadMain();

   // We piggy-back on the startup_data_ member to know if we successfully
   // started the thread.  This way we know that we need to call Join.
   bool thread_was_started() const { return startup_data_ != NULL; }

   // If true, we're in the middle of stopping, and shouldn't access
   // |message_loop_|. It may non-NULL and invalid.
   bool stopping_;

   // Used to pass data to ThreadMain.
   struct StartupData;
   StartupData* startup_data_;

   // The thread's handle.
   PlatformThreadHandle thread_;

   // The thread's message loop.  Valid only while the thread is alive.  Set
   // by the created thread.
   MessageLoop* message_loop_;

   // A MessageLoopProxy implementation that targets this thread. This can
   // outlive the thread.
   scoped_refptr<MessageLoopProxy> message_loop_proxy_;

   // Our thread's ID.
   PlatformThreadId thread_id_;

   // The name of the thread.  Used for debugging purposes.
   std::string name_;

   friend class ThreadQuitTask;

   DISALLOW_COPY_AND_ASSIGN(Thread);
 };

 }  // namespace base

 #endif  // BASE_THREAD_H_
	// Copyright (c) 2006-2009 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_THREAD_H_
	#define BASE_THREAD_H_

	#include <string>

	#include "base/message_loop.h"
	#include "base/message_loop_proxy.h"
	#include "base/platform_thread.h"

	namespace base {

	// A simple thread abstraction that establishes a MessageLoop on a new thread.
	// The consumer uses the MessageLoop of the thread to cause code to execute on
	// the thread. When this object is destroyed the thread is terminated. All
	// pending tasks queued on the thread's message loop will run to completion
	// before the thread is terminated.
	//
	// After the thread is stopped, the destruction sequence is:
	//
	// (1) Thread::CleanUp()
	// (2) MessageLoop::~MessageLoop
	// (3.b) MessageLoop::DestructionObserver::WillDestroyCurrentMessageLoop
	// (4) Thread::CleanUpAfterMessageLoopDestruction()
	class Thread : PlatformThread::Delegate {
	public:
	struct Options {
	// Specifies the type of message loop that will be allocated on the thread.
	MessageLoop::Type message_loop_type;

	// Specifies the maximum stack size that the thread is allowed to use.
	// This does not necessarily correspond to the thread's initial stack size.
	// A value of 0 indicates that the default maximum should be used.
	size_t stack_size;

	Options() : message_loop_type(MessageLoop::TYPE_DEFAULT), stack_size(0) {}
	Options(MessageLoop::Type type, size_t size)
	: message_loop_type(type), stack_size(size) {}
	};

	// Constructor.
	// name is a display string to identify the thread.
	explicit Thread(const char* name);

	// Destroys the thread, stopping it if necessary.
	//
	// NOTE: If you are subclassing from Thread, and you wish for your CleanUp
	// method to be called, then you need to call Stop() from your destructor.
	//
	virtual ~Thread();

	// Starts the thread. Returns true if the thread was successfully started;
	// otherwise, returns false. Upon successful return, the message_loop()
	// getter will return non-null.
	//
	// Note: This function can't be called on Windows with the loader lock held;
	// i.e. during a DllMain, global object construction or destruction, atexit()
	// callback.
	bool Start();

	// Starts the thread. Behaves exactly like Start in addition to allow to
	// override the default options.
	//
	// Note: This function can't be called on Windows with the loader lock held;
	// i.e. during a DllMain, global object construction or destruction, atexit()
	// callback.
	bool StartWithOptions(const Options& options);

	// Signals the thread to exit and returns once the thread has exited. After
	// this method returns, the Thread object is completely reset and may be used
	// as if it were newly constructed (i.e., Start may be called again).
	//
	// Stop may be called multiple times and is simply ignored if the thread is
	// already stopped.
	//
	// NOTE: This method is optional. It is not strictly necessary to call this
	// method as the Thread's destructor will take care of stopping the thread if
	// necessary.
	//
	void Stop();

	// Signals the thread to exit in the near future.
	//
	// WARNING: This function is not meant to be commonly used. Use at your own
	// risk. Calling this function will cause message_loop() to become invalid in
	// the near future. This function was created to workaround a specific
	// deadlock on Windows with printer worker thread. In any other case, Stop()
	// should be used.
	//
	// StopSoon should not be called multiple times as it is risky to do so. It
	// could cause a timing issue in message_loop() access. Call Stop() to reset
	// the thread object once it is known that the thread has quit.
	void StopSoon();

	// Returns the message loop for this thread. Use the MessageLoop's
	// PostTask methods to execute code on the thread. This only returns
	// non-null after a successful call to Start. After Stop has been called,
	// this will return NULL.
	//
	// NOTE: You must not call this MessageLoop's Quit method directly. Use
	// the Thread's Stop method instead.
	//
	MessageLoop* message_loop() const { return message_loop_; }

	// Returns a MessageLoopProxy for this thread. Use the MessageLoopProxy's
	// PostTask methods to execute code on the thread. This only returns
	// non-null after a successful call to Start. After Stop has been called,
	// this will return NULL. Callers can hold on to this even after the thread
	// is gone.
	// TODO(sanjeevr): Look into merging MessageLoop and MessageLoopProxy.
	scoped_refptr<MessageLoopProxy> message_loop_proxy() {
	return message_loop_proxy_;
	}

	// Set the name of this thread (for display in debugger too).
	const std::string &thread_name() { return name_; }

	// The native thread handle.
	PlatformThreadHandle thread_handle() { return thread_; }

	// The thread ID.
	PlatformThreadId thread_id() const { return thread_id_; }

	// Returns true if the thread has been started, and not yet stopped.
	// When a thread is running, the thread_id_ is non-zero.
	bool IsRunning() const { return thread_id_ != 0; }

	protected:
	// Called just prior to starting the message loop
	virtual void Init() {}

	// Called to start the message loop
	virtual void Run(MessageLoop* message_loop);

	// Called just after the message loop ends
	virtual void CleanUp() {}

	// Called after the message loop has been deleted. In general clients
	// should prefer to use CleanUp(). This method is used when code needs to
	// be run after all of the MessageLoop::DestructionObservers have completed.
	virtual void CleanUpAfterMessageLoopDestruction() {}

	static void SetThreadWasQuitProperly(bool flag);
	static bool GetThreadWasQuitProperly();

	void set_message_loop(MessageLoop* message_loop) {
	message_loop_ = message_loop;
	}

	private:
	// PlatformThread::Delegate methods:
	virtual void ThreadMain();

	// We piggy-back on the startup_data_ member to know if we successfully
	// started the thread. This way we know that we need to call Join.
	bool thread_was_started() const { return startup_data_ != NULL; }

	// If true, we're in the middle of stopping, and shouldn't access
	// \|message_loop_\|. It may non-NULL and invalid.
	bool stopping_;

	// Used to pass data to ThreadMain.
	struct StartupData;
	StartupData* startup_data_;

	// The thread's handle.
	PlatformThreadHandle thread_;

	// The thread's message loop. Valid only while the thread is alive. Set
	// by the created thread.
	MessageLoop* message_loop_;

	// A MessageLoopProxy implementation that targets this thread. This can
	// outlive the thread.
	scoped_refptr<MessageLoopProxy> message_loop_proxy_;

	// Our thread's ID.
	PlatformThreadId thread_id_;

	// The name of the thread. Used for debugging purposes.
	std::string name_;

	friend class ThreadQuitTask;

	DISALLOW_COPY_AND_ASSIGN(Thread);
	};

	} // namespace base

	#endif // BASE_THREAD_H_