rtc_base/message_queue.h - src - Git at Google

 /*
  *  Copyright 2004 The WebRTC Project Authors. All rights reserved.
  *
  *  Use of this source code is governed by a BSD-style license
  *  that can be found in the LICENSE file in the root of the source
  *  tree. An additional intellectual property rights grant can be found
  *  in the file PATENTS.  All contributing project authors may
  *  be found in the AUTHORS file in the root of the source tree.
  */

 #ifndef RTC_BASE_MESSAGE_QUEUE_H_
 #define RTC_BASE_MESSAGE_QUEUE_H_

 #include <string.h>

 #include <algorithm>
 #include <list>
 #include <memory>
 #include <queue>
 #include <vector>

 #include "api/scoped_refptr.h"
 #include "rtc_base/constructor_magic.h"
 #include "rtc_base/critical_section.h"
 #include "rtc_base/location.h"
 #include "rtc_base/message_handler.h"
 #include "rtc_base/socket_server.h"
 #include "rtc_base/third_party/sigslot/sigslot.h"
 #include "rtc_base/thread_annotations.h"

 namespace rtc {

 struct Message;
 class MessageQueue;

 // MessageQueueManager does cleanup of of message queues

 class MessageQueueManager {
  public:
   static void Add(MessageQueue* message_queue);
   static void Remove(MessageQueue* message_queue);
   static void Clear(MessageHandler* handler);

   // TODO(nisse): Delete alias, as soon as downstream code is updated.
   static void ProcessAllMessageQueues() { ProcessAllMessageQueuesForTesting(); }

   // For testing purposes, for use with a simulated clock.
   // Ensures that all message queues have processed delayed messages
   // up until the current point in time.
   static void ProcessAllMessageQueuesForTesting();

  private:
   static MessageQueueManager* Instance();

   MessageQueueManager();
   ~MessageQueueManager();

   void AddInternal(MessageQueue* message_queue);
   void RemoveInternal(MessageQueue* message_queue);
   void ClearInternal(MessageHandler* handler);
   void ProcessAllMessageQueuesInternal();

   // This list contains all live MessageQueues.
   std::vector<MessageQueue*> message_queues_ RTC_GUARDED_BY(crit_);

   // Methods that don't modify the list of message queues may be called in a
   // re-entrant fashion. "processing_" keeps track of the depth of re-entrant
   // calls.
   CriticalSection crit_;
   size_t processing_ RTC_GUARDED_BY(crit_);
 };

 // Derive from this for specialized data
 // App manages lifetime, except when messages are purged

 class MessageData {
  public:
   MessageData() {}
   virtual ~MessageData() {}
 };

 template <class T>
 class TypedMessageData : public MessageData {
  public:
   explicit TypedMessageData(const T& data) : data_(data) {}
   const T& data() const { return data_; }
   T& data() { return data_; }

  private:
   T data_;
 };

 // Like TypedMessageData, but for pointers that require a delete.
 template <class T>
 class ScopedMessageData : public MessageData {
  public:
   explicit ScopedMessageData(std::unique_ptr<T> data)
       : data_(std::move(data)) {}
   // Deprecated.
   // TODO(deadbeef): Remove this once downstream applications stop using it.
   explicit ScopedMessageData(T* data) : data_(data) {}
   // Deprecated.
   // TODO(deadbeef): Returning a reference to a unique ptr? Why. Get rid of
   // this once downstream applications stop using it, then rename inner_data to
   // just data.
   const std::unique_ptr<T>& data() const { return data_; }
   std::unique_ptr<T>& data() { return data_; }

   const T& inner_data() const { return *data_; }
   T& inner_data() { return *data_; }

  private:
   std::unique_ptr<T> data_;
 };

 // Like ScopedMessageData, but for reference counted pointers.
 template <class T>
 class ScopedRefMessageData : public MessageData {
  public:
   explicit ScopedRefMessageData(T* data) : data_(data) {}
   const scoped_refptr<T>& data() const { return data_; }
   scoped_refptr<T>& data() { return data_; }

  private:
   scoped_refptr<T> data_;
 };

 template <class T>
 inline MessageData* WrapMessageData(const T& data) {
   return new TypedMessageData<T>(data);
 }

 template <class T>
 inline const T& UseMessageData(MessageData* data) {
   return static_cast<TypedMessageData<T>*>(data)->data();
 }

 template <class T>
 class DisposeData : public MessageData {
  public:
   explicit DisposeData(T* data) : data_(data) {}
   virtual ~DisposeData() { delete data_; }

  private:
   T* data_;
 };

 const uint32_t MQID_ANY = static_cast<uint32_t>(-1);
 const uint32_t MQID_DISPOSE = static_cast<uint32_t>(-2);

 // No destructor

 struct Message {
   Message()
       : phandler(nullptr), message_id(0), pdata(nullptr), ts_sensitive(0) {}
   inline bool Match(MessageHandler* handler, uint32_t id) const {
     return (handler == nullptr || handler == phandler) &&
            (id == MQID_ANY || id == message_id);
   }
   Location posted_from;
   MessageHandler* phandler;
   uint32_t message_id;
   MessageData* pdata;
   int64_t ts_sensitive;
 };

 typedef std::list<Message> MessageList;

 // DelayedMessage goes into a priority queue, sorted by trigger time.  Messages
 // with the same trigger time are processed in num_ (FIFO) order.

 class DelayedMessage {
  public:
   DelayedMessage(int64_t delay,
                  int64_t trigger,
                  uint32_t num,
                  const Message& msg)
       : cmsDelay_(delay), msTrigger_(trigger), num_(num), msg_(msg) {}

   bool operator<(const DelayedMessage& dmsg) const {
     return (dmsg.msTrigger_ < msTrigger_) ||
            ((dmsg.msTrigger_ == msTrigger_) && (dmsg.num_ < num_));
   }

   int64_t cmsDelay_;  // for debugging
   int64_t msTrigger_;
   uint32_t num_;
   Message msg_;
 };

 class MessageQueue {
  public:
   static const int kForever = -1;

   // Create a new MessageQueue and optionally assign it to the passed
   // SocketServer. Subclasses that override Clear should pass false for
   // init_queue and call DoInit() from their constructor to prevent races
   // with the MessageQueueManager using the object while the vtable is still
   // being created.
   MessageQueue(SocketServer* ss, bool init_queue);
   MessageQueue(std::unique_ptr<SocketServer> ss, bool init_queue);

   // NOTE: SUBCLASSES OF MessageQueue THAT OVERRIDE Clear MUST CALL
   // DoDestroy() IN THEIR DESTRUCTORS! This is required to avoid a data race
   // between the destructor modifying the vtable, and the MessageQueueManager
   // calling Clear on the object from a different thread.
   virtual ~MessageQueue();

   SocketServer* socketserver();

   // Note: The behavior of MessageQueue has changed.  When a MQ is stopped,
   // futher Posts and Sends will fail.  However, any pending Sends and *ready*
   // Posts (as opposed to unexpired delayed Posts) will be delivered before
   // Get (or Peek) returns false.  By guaranteeing delivery of those messages,
   // we eliminate the race condition when an MessageHandler and MessageQueue
   // may be destroyed independently of each other.
   virtual void Quit();
   virtual bool IsQuitting();
   virtual void Restart();
   // Not all message queues actually process messages (such as SignalThread).
   // In those cases, it's important to know, before posting, that it won't be
   // Processed.  Normally, this would be true until IsQuitting() is true.
   virtual bool IsProcessingMessagesForTesting();

   // Get() will process I/O until:
   //  1) A message is available (returns true)
   //  2) cmsWait seconds have elapsed (returns false)
   //  3) Stop() is called (returns false)
   virtual bool Get(Message* pmsg,
                    int cmsWait = kForever,
                    bool process_io = true);
   virtual bool Peek(Message* pmsg, int cmsWait = 0);
   virtual void Post(const Location& posted_from,
                     MessageHandler* phandler,
                     uint32_t id = 0,
                     MessageData* pdata = nullptr,
                     bool time_sensitive = false);
   virtual void PostDelayed(const Location& posted_from,
                            int cmsDelay,
                            MessageHandler* phandler,
                            uint32_t id = 0,
                            MessageData* pdata = nullptr);
   virtual void PostAt(const Location& posted_from,
                       int64_t tstamp,
                       MessageHandler* phandler,
                       uint32_t id = 0,
                       MessageData* pdata = nullptr);
   // TODO(honghaiz): Remove this when all the dependencies are removed.
   virtual void PostAt(const Location& posted_from,
                       uint32_t tstamp,
                       MessageHandler* phandler,
                       uint32_t id = 0,
                       MessageData* pdata = nullptr);
   virtual void Clear(MessageHandler* phandler,
                      uint32_t id = MQID_ANY,
                      MessageList* removed = nullptr);
   virtual void Dispatch(Message* pmsg);
   virtual void ReceiveSends();

   // Amount of time until the next message can be retrieved
   virtual int GetDelay();

   bool empty() const { return size() == 0u; }
   size_t size() const {
     CritScope cs(&crit_);  // msgq_.size() is not thread safe.
     return msgq_.size() + dmsgq_.size() + (fPeekKeep_ ? 1u : 0u);
   }

   // Internally posts a message which causes the doomed object to be deleted
   template <class T>
   void Dispose(T* doomed) {
     if (doomed) {
       Post(RTC_FROM_HERE, nullptr, MQID_DISPOSE, new DisposeData<T>(doomed));
     }
   }

   // When this signal is sent out, any references to this queue should
   // no longer be used.
   sigslot::signal0<> SignalQueueDestroyed;

  protected:
   class PriorityQueue : public std::priority_queue<DelayedMessage> {
    public:
     container_type& container() { return c; }
     void reheap() { make_heap(c.begin(), c.end(), comp); }
   };

   void DoDelayPost(const Location& posted_from,
                    int64_t cmsDelay,
                    int64_t tstamp,
                    MessageHandler* phandler,
                    uint32_t id,
                    MessageData* pdata);

   // Perform initialization, subclasses must call this from their constructor
   // if false was passed as init_queue to the MessageQueue constructor.
   void DoInit();

   // Does not take any lock. Must be called either while holding crit_, or by
   // the destructor (by definition, the latter has exclusive access).
   void ClearInternal(MessageHandler* phandler,
                      uint32_t id,
                      MessageList* removed) RTC_EXCLUSIVE_LOCKS_REQUIRED(&crit_);

   // Perform cleanup; subclasses must call this from the destructor,
   // and are not expected to actually hold the lock.
   void DoDestroy() RTC_EXCLUSIVE_LOCKS_REQUIRED(&crit_);

   void WakeUpSocketServer();

   bool fPeekKeep_;
   Message msgPeek_;
   MessageList msgq_ RTC_GUARDED_BY(crit_);
   PriorityQueue dmsgq_ RTC_GUARDED_BY(crit_);
   uint32_t dmsgq_next_num_ RTC_GUARDED_BY(crit_);
   CriticalSection crit_;
   bool fInitialized_;
   bool fDestroyed_;

  private:
   volatile int stop_;

   // The SocketServer might not be owned by MessageQueue.
   SocketServer* const ss_;
   // Used if SocketServer ownership lies with |this|.
   std::unique_ptr<SocketServer> own_ss_;

   RTC_DISALLOW_IMPLICIT_CONSTRUCTORS(MessageQueue);
 };

 }  // namespace rtc

 #endif  // RTC_BASE_MESSAGE_QUEUE_H_
	/*
	* Copyright 2004 The WebRTC Project Authors. All rights reserved.
	*
	* Use of this source code is governed by a BSD-style license
	* that can be found in the LICENSE file in the root of the source
	* tree. An additional intellectual property rights grant can be found
	* in the file PATENTS. All contributing project authors may
	* be found in the AUTHORS file in the root of the source tree.
	*/

	#ifndef RTC_BASE_MESSAGE_QUEUE_H_
	#define RTC_BASE_MESSAGE_QUEUE_H_

	#include <string.h>

	#include <algorithm>
	#include <list>
	#include <memory>
	#include <queue>
	#include <vector>

	#include "api/scoped_refptr.h"
	#include "rtc_base/constructor_magic.h"
	#include "rtc_base/critical_section.h"
	#include "rtc_base/location.h"
	#include "rtc_base/message_handler.h"
	#include "rtc_base/socket_server.h"
	#include "rtc_base/third_party/sigslot/sigslot.h"
	#include "rtc_base/thread_annotations.h"

	namespace rtc {

	struct Message;
	class MessageQueue;

	// MessageQueueManager does cleanup of of message queues

	class MessageQueueManager {
	public:
	static void Add(MessageQueue* message_queue);
	static void Remove(MessageQueue* message_queue);
	static void Clear(MessageHandler* handler);

	// TODO(nisse): Delete alias, as soon as downstream code is updated.
	static void ProcessAllMessageQueues() { ProcessAllMessageQueuesForTesting(); }

	// For testing purposes, for use with a simulated clock.
	// Ensures that all message queues have processed delayed messages
	// up until the current point in time.
	static void ProcessAllMessageQueuesForTesting();

	private:
	static MessageQueueManager* Instance();

	MessageQueueManager();
	~MessageQueueManager();

	void AddInternal(MessageQueue* message_queue);
	void RemoveInternal(MessageQueue* message_queue);
	void ClearInternal(MessageHandler* handler);
	void ProcessAllMessageQueuesInternal();

	// This list contains all live MessageQueues.
	std::vector<MessageQueue*> message_queues_ RTC_GUARDED_BY(crit_);

	// Methods that don't modify the list of message queues may be called in a
	// re-entrant fashion. "processing_" keeps track of the depth of re-entrant
	// calls.
	CriticalSection crit_;
	size_t processing_ RTC_GUARDED_BY(crit_);
	};

	// Derive from this for specialized data
	// App manages lifetime, except when messages are purged

	class MessageData {
	public:
	MessageData() {}
	virtual ~MessageData() {}
	};

	template <class T>
	class TypedMessageData : public MessageData {
	public:
	explicit TypedMessageData(const T& data) : data_(data) {}
	const T& data() const { return data_; }
	T& data() { return data_; }

	private:
	T data_;
	};

	// Like TypedMessageData, but for pointers that require a delete.
	template <class T>
	class ScopedMessageData : public MessageData {
	public:
	explicit ScopedMessageData(std::unique_ptr<T> data)
	: data_(std::move(data)) {}
	// Deprecated.
	// TODO(deadbeef): Remove this once downstream applications stop using it.
	explicit ScopedMessageData(T* data) : data_(data) {}
	// Deprecated.
	// TODO(deadbeef): Returning a reference to a unique ptr? Why. Get rid of
	// this once downstream applications stop using it, then rename inner_data to
	// just data.
	const std::unique_ptr<T>& data() const { return data_; }
	std::unique_ptr<T>& data() { return data_; }

	const T& inner_data() const { return *data_; }
	T& inner_data() { return *data_; }

	private:
	std::unique_ptr<T> data_;
	};

	// Like ScopedMessageData, but for reference counted pointers.
	template <class T>
	class ScopedRefMessageData : public MessageData {
	public:
	explicit ScopedRefMessageData(T* data) : data_(data) {}
	const scoped_refptr<T>& data() const { return data_; }
	scoped_refptr<T>& data() { return data_; }

	private:
	scoped_refptr<T> data_;
	};

	template <class T>
	inline MessageData* WrapMessageData(const T& data) {
	return new TypedMessageData<T>(data);
	}

	template <class T>
	inline const T& UseMessageData(MessageData* data) {
	return static_cast<TypedMessageData<T>*>(data)->data();
	}

	template <class T>
	class DisposeData : public MessageData {
	public:
	explicit DisposeData(T* data) : data_(data) {}
	virtual ~DisposeData() { delete data_; }

	private:
	T* data_;
	};

	const uint32_t MQID_ANY = static_cast<uint32_t>(-1);
	const uint32_t MQID_DISPOSE = static_cast<uint32_t>(-2);

	// No destructor

	struct Message {
	Message()
	: phandler(nullptr), message_id(0), pdata(nullptr), ts_sensitive(0) {}
	inline bool Match(MessageHandler* handler, uint32_t id) const {
	return (handler == nullptr \|\| handler == phandler) &&
	(id == MQID_ANY \|\| id == message_id);
	}
	Location posted_from;
	MessageHandler* phandler;
	uint32_t message_id;
	MessageData* pdata;
	int64_t ts_sensitive;
	};

	typedef std::list<Message> MessageList;

	// DelayedMessage goes into a priority queue, sorted by trigger time. Messages
	// with the same trigger time are processed in num_ (FIFO) order.

	class DelayedMessage {
	public:
	DelayedMessage(int64_t delay,
	int64_t trigger,
	uint32_t num,
	const Message& msg)
	: cmsDelay_(delay), msTrigger_(trigger), num_(num), msg_(msg) {}

	bool operator<(const DelayedMessage& dmsg) const {
	return (dmsg.msTrigger_ < msTrigger_) \|\|
	((dmsg.msTrigger_ == msTrigger_) && (dmsg.num_ < num_));
	}

	int64_t cmsDelay_; // for debugging
	int64_t msTrigger_;
	uint32_t num_;
	Message msg_;
	};

	class MessageQueue {
	public:
	static const int kForever = -1;

	// Create a new MessageQueue and optionally assign it to the passed
	// SocketServer. Subclasses that override Clear should pass false for
	// init_queue and call DoInit() from their constructor to prevent races
	// with the MessageQueueManager using the object while the vtable is still
	// being created.
	MessageQueue(SocketServer* ss, bool init_queue);
	MessageQueue(std::unique_ptr<SocketServer> ss, bool init_queue);

	// NOTE: SUBCLASSES OF MessageQueue THAT OVERRIDE Clear MUST CALL
	// DoDestroy() IN THEIR DESTRUCTORS! This is required to avoid a data race
	// between the destructor modifying the vtable, and the MessageQueueManager
	// calling Clear on the object from a different thread.
	virtual ~MessageQueue();

	SocketServer* socketserver();

	// Note: The behavior of MessageQueue has changed. When a MQ is stopped,
	// futher Posts and Sends will fail. However, any pending Sends and ready
	// Posts (as opposed to unexpired delayed Posts) will be delivered before
	// Get (or Peek) returns false. By guaranteeing delivery of those messages,
	// we eliminate the race condition when an MessageHandler and MessageQueue
	// may be destroyed independently of each other.
	virtual void Quit();
	virtual bool IsQuitting();
	virtual void Restart();
	// Not all message queues actually process messages (such as SignalThread).
	// In those cases, it's important to know, before posting, that it won't be
	// Processed. Normally, this would be true until IsQuitting() is true.
	virtual bool IsProcessingMessagesForTesting();

	// Get() will process I/O until:
	// 1) A message is available (returns true)
	// 2) cmsWait seconds have elapsed (returns false)
	// 3) Stop() is called (returns false)
	virtual bool Get(Message* pmsg,
	int cmsWait = kForever,
	bool process_io = true);
	virtual bool Peek(Message* pmsg, int cmsWait = 0);
	virtual void Post(const Location& posted_from,
	MessageHandler* phandler,
	uint32_t id = 0,
	MessageData* pdata = nullptr,
	bool time_sensitive = false);
	virtual void PostDelayed(const Location& posted_from,
	int cmsDelay,
	MessageHandler* phandler,
	uint32_t id = 0,
	MessageData* pdata = nullptr);
	virtual void PostAt(const Location& posted_from,
	int64_t tstamp,
	MessageHandler* phandler,
	uint32_t id = 0,
	MessageData* pdata = nullptr);
	// TODO(honghaiz): Remove this when all the dependencies are removed.
	virtual void PostAt(const Location& posted_from,
	uint32_t tstamp,
	MessageHandler* phandler,
	uint32_t id = 0,
	MessageData* pdata = nullptr);
	virtual void Clear(MessageHandler* phandler,
	uint32_t id = MQID_ANY,
	MessageList* removed = nullptr);
	virtual void Dispatch(Message* pmsg);
	virtual void ReceiveSends();

	// Amount of time until the next message can be retrieved
	virtual int GetDelay();

	bool empty() const { return size() == 0u; }
	size_t size() const {
	CritScope cs(&crit_); // msgq_.size() is not thread safe.
	return msgq_.size() + dmsgq_.size() + (fPeekKeep_ ? 1u : 0u);
	}

	// Internally posts a message which causes the doomed object to be deleted
	template <class T>
	void Dispose(T* doomed) {
	if (doomed) {
	Post(RTC_FROM_HERE, nullptr, MQID_DISPOSE, new DisposeData<T>(doomed));
	}
	}

	// When this signal is sent out, any references to this queue should
	// no longer be used.
	sigslot::signal0<> SignalQueueDestroyed;

	protected:
	class PriorityQueue : public std::priority_queue<DelayedMessage> {
	public:
	container_type& container() { return c; }
	void reheap() { make_heap(c.begin(), c.end(), comp); }
	};

	void DoDelayPost(const Location& posted_from,
	int64_t cmsDelay,
	int64_t tstamp,
	MessageHandler* phandler,
	uint32_t id,
	MessageData* pdata);

	// Perform initialization, subclasses must call this from their constructor
	// if false was passed as init_queue to the MessageQueue constructor.
	void DoInit();

	// Does not take any lock. Must be called either while holding crit_, or by
	// the destructor (by definition, the latter has exclusive access).
	void ClearInternal(MessageHandler* phandler,
	uint32_t id,
	MessageList* removed) RTC_EXCLUSIVE_LOCKS_REQUIRED(&crit_);

	// Perform cleanup; subclasses must call this from the destructor,
	// and are not expected to actually hold the lock.
	void DoDestroy() RTC_EXCLUSIVE_LOCKS_REQUIRED(&crit_);

	void WakeUpSocketServer();

	bool fPeekKeep_;
	Message msgPeek_;
	MessageList msgq_ RTC_GUARDED_BY(crit_);
	PriorityQueue dmsgq_ RTC_GUARDED_BY(crit_);
	uint32_t dmsgq_next_num_ RTC_GUARDED_BY(crit_);
	CriticalSection crit_;
	bool fInitialized_;
	bool fDestroyed_;

	private:
	volatile int stop_;

	// The SocketServer might not be owned by MessageQueue.
	SocketServer* const ss_;
	// Used if SocketServer ownership lies with \|this\|.
	std::unique_ptr<SocketServer> own_ss_;

	RTC_DISALLOW_IMPLICIT_CONSTRUCTORS(MessageQueue);
	};

	} // namespace rtc

	#endif // RTC_BASE_MESSAGE_QUEUE_H_