rtc_base/asyncinvoker.h - src.git - Git at Google

 /*
  *  Copyright 2014 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_ASYNCINVOKER_H_
 #define RTC_BASE_ASYNCINVOKER_H_

 #include <atomic>
 #include <memory>
 #include <utility>

 #include "rtc_base/asyncinvoker-inl.h"
 #include "rtc_base/bind.h"
 #include "rtc_base/constructormagic.h"
 #include "rtc_base/event.h"
 #include "rtc_base/refcountedobject.h"
 #include "rtc_base/scoped_ref_ptr.h"
 #include "rtc_base/sigslot.h"
 #include "rtc_base/thread.h"

 namespace rtc {

 // Invokes function objects (aka functors) asynchronously on a Thread, and
 // owns the lifetime of calls (ie, when this object is destroyed, calls in
 // flight are cancelled). AsyncInvoker can optionally execute a user-specified
 // function when the asynchronous call is complete, or operates in
 // fire-and-forget mode otherwise.
 //
 // AsyncInvoker does not own the thread it calls functors on.
 //
 // A note about async calls and object lifetimes: users should
 // be mindful of object lifetimes when calling functions asynchronously and
 // ensure objects used by the function _cannot_ be deleted between the
 // invocation and execution of the functor. AsyncInvoker is designed to
 // help: any calls in flight will be cancelled when the AsyncInvoker used to
 // make the call is destructed, and any calls executing will be allowed to
 // complete before AsyncInvoker destructs.
 //
 // The easiest way to ensure lifetimes are handled correctly is to create a
 // class that owns the Thread and AsyncInvoker objects, and then call its
 // methods asynchronously as needed.
 //
 // Example:
 //   class MyClass {
 //    public:
 //     void FireAsyncTaskWithResult(Thread* thread, int x) {
 //       // Specify a callback to get the result upon completion.
 //       invoker_.AsyncInvoke<int>(RTC_FROM_HERE,
 //           thread, Bind(&MyClass::AsyncTaskWithResult, this, x),
 //           &MyClass::OnTaskComplete, this);
 //     }
 //     void FireAnotherAsyncTask(Thread* thread) {
 //       // No callback specified means fire-and-forget.
 //       invoker_.AsyncInvoke<void>(RTC_FROM_HERE,
 //           thread, Bind(&MyClass::AnotherAsyncTask, this));
 //
 //    private:
 //     int AsyncTaskWithResult(int x) {
 //       // Some long running process...
 //       return x * x;
 //     }
 //     void AnotherAsyncTask() {
 //       // Some other long running process...
 //     }
 //     void OnTaskComplete(int result) { result_ = result; }
 //
 //     AsyncInvoker invoker_;
 //     int result_;
 //   };
 //
 // More details about threading:
 // - It's safe to construct/destruct AsyncInvoker on different threads.
 // - It's safe to call AsyncInvoke from different threads.
 // - It's safe to call AsyncInvoke recursively from *within* a functor that's
 //   being AsyncInvoked.
 // - However, it's *not* safe to call AsyncInvoke from *outside* a functor
 //   that's being AsyncInvoked while the AsyncInvoker is being destroyed on
 //   another thread. This is just inherently unsafe and there's no way to
 //   prevent that. So, the user of this class should ensure that the start of
 //   each "chain" of invocations is synchronized somehow with the AsyncInvoker's
 //   destruction. This can be done by starting each chain of invocations on the
 //   same thread on which it will be destroyed, or by using some other
 //   synchronization method.
 class AsyncInvoker : public MessageHandler {
  public:
   AsyncInvoker();
   ~AsyncInvoker() override;

   // Call |functor| asynchronously on |thread|, with no callback upon
   // completion. Returns immediately.
   template <class ReturnT, class FunctorT>
   void AsyncInvoke(const Location& posted_from,
                    Thread* thread,
                    const FunctorT& functor,
                    uint32_t id = 0) {
     std::unique_ptr<AsyncClosure> closure(
         new FireAndForgetAsyncClosure<FunctorT>(this, functor));
     DoInvoke(posted_from, thread, std::move(closure), id);
   }

   // Call |functor| asynchronously on |thread| with |delay_ms|, with no callback
   // upon completion. Returns immediately.
   template <class ReturnT, class FunctorT>
   void AsyncInvokeDelayed(const Location& posted_from,
                           Thread* thread,
                           const FunctorT& functor,
                           uint32_t delay_ms,
                           uint32_t id = 0) {
     std::unique_ptr<AsyncClosure> closure(
         new FireAndForgetAsyncClosure<FunctorT>(this, functor));
     DoInvokeDelayed(posted_from, thread, std::move(closure), delay_ms, id);
   }

   // Synchronously execute on |thread| all outstanding calls we own
   // that are pending on |thread|, and wait for calls to complete
   // before returning. Optionally filter by message id.
   // The destructor will not wait for outstanding calls, so if that
   // behavior is desired, call Flush() before destroying this object.
   void Flush(Thread* thread, uint32_t id = MQID_ANY);

  private:
   void OnMessage(Message* msg) override;
   void DoInvoke(const Location& posted_from,
                 Thread* thread,
                 std::unique_ptr<AsyncClosure> closure,
                 uint32_t id);
   void DoInvokeDelayed(const Location& posted_from,
                        Thread* thread,
                        std::unique_ptr<AsyncClosure> closure,
                        uint32_t delay_ms,
                        uint32_t id);

   // Used to keep track of how many invocations (AsyncClosures) are still
   // alive, so that the destructor can wait for them to finish, as described in
   // the class documentation.
   //
   // TODO(deadbeef): Using a raw std::atomic like this is prone to error and
   // difficult to maintain. We should try to wrap this functionality in a
   // separate class to reduce the chance of errors being introduced in the
   // future.
   std::atomic<int> pending_invocations_;

   // Reference counted so that if the AsyncInvoker destructor finishes before
   // an AsyncClosure's destructor that's about to call
   // "invocation_complete_->Set()", it's not dereferenced after being
   // destroyed.
   scoped_refptr<RefCountedObject<Event>> invocation_complete_;

   // This flag is used to ensure that if an application AsyncInvokes tasks that
   // recursively AsyncInvoke other tasks ad infinitum, the cycle eventually
   // terminates.
   std::atomic<bool> destroying_;

   friend class AsyncClosure;

   RTC_DISALLOW_COPY_AND_ASSIGN(AsyncInvoker);
 };

 // Similar to AsyncInvoker, but guards against the Thread being destroyed while
 // there are outstanding dangling pointers to it. It will connect to the current
 // thread in the constructor, and will get notified when that thread is
 // destroyed. After GuardedAsyncInvoker is constructed, it can be used from
 // other threads to post functors to the thread it was constructed on. If that
 // thread dies, any further calls to AsyncInvoke() will be safely ignored.
 class GuardedAsyncInvoker : public sigslot::has_slots<> {
  public:
   GuardedAsyncInvoker();
   ~GuardedAsyncInvoker() override;

   // Synchronously execute all outstanding calls we own, and wait for calls to
   // complete before returning. Optionally filter by message id. The destructor
   // will not wait for outstanding calls, so if that behavior is desired, call
   // Flush() first. Returns false if the thread has died.
   bool Flush(uint32_t id = MQID_ANY);

   // Call |functor| asynchronously with no callback upon completion. Returns
   // immediately. Returns false if the thread has died.
   template <class ReturnT, class FunctorT>
   bool AsyncInvoke(const Location& posted_from,
                    const FunctorT& functor,
                    uint32_t id = 0) {
     CritScope cs(&crit_);
     if (thread_ == nullptr)
       return false;
     invoker_.AsyncInvoke<ReturnT, FunctorT>(posted_from, thread_, functor, id);
     return true;
   }

   // Call |functor| asynchronously with |delay_ms|, with no callback upon
   // completion. Returns immediately. Returns false if the thread has died.
   template <class ReturnT, class FunctorT>
   bool AsyncInvokeDelayed(const Location& posted_from,
                           const FunctorT& functor,
                           uint32_t delay_ms,
                           uint32_t id = 0) {
     CritScope cs(&crit_);
     if (thread_ == nullptr)
       return false;
     invoker_.AsyncInvokeDelayed<ReturnT, FunctorT>(posted_from, thread_,
                                                    functor, delay_ms, id);
     return true;
   }

   // Call |functor| asynchronously, calling |callback| when done. Returns false
   // if the thread has died.
   template <class ReturnT, class FunctorT, class HostT>
   bool AsyncInvoke(const Location& posted_from,
                    const Location& callback_posted_from,
                    const FunctorT& functor,
                    void (HostT::*callback)(ReturnT),
                    HostT* callback_host,
                    uint32_t id = 0) {
     CritScope cs(&crit_);
     if (thread_ == nullptr)
       return false;
     invoker_.AsyncInvoke<ReturnT, FunctorT, HostT>(
         posted_from, callback_posted_from, thread_, functor, callback,
         callback_host, id);
     return true;
   }

   // Call |functor| asynchronously calling |callback| when done. Overloaded for
   // void return. Returns false if the thread has died.
   template <class ReturnT, class FunctorT, class HostT>
   bool AsyncInvoke(const Location& posted_from,
                    const Location& callback_posted_from,
                    const FunctorT& functor,
                    void (HostT::*callback)(),
                    HostT* callback_host,
                    uint32_t id = 0) {
     CritScope cs(&crit_);
     if (thread_ == nullptr)
       return false;
     invoker_.AsyncInvoke<ReturnT, FunctorT, HostT>(
         posted_from, callback_posted_from, thread_, functor, callback,
         callback_host, id);
     return true;
   }

  private:
   // Callback when |thread_| is destroyed.
   void ThreadDestroyed();

   CriticalSection crit_;
   Thread* thread_ RTC_GUARDED_BY(crit_);
   AsyncInvoker invoker_ RTC_GUARDED_BY(crit_);
 };

 }  // namespace rtc

 #endif  // RTC_BASE_ASYNCINVOKER_H_
	/*
	* Copyright 2014 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_ASYNCINVOKER_H_
	#define RTC_BASE_ASYNCINVOKER_H_

	#include <atomic>
	#include <memory>
	#include <utility>

	#include "rtc_base/asyncinvoker-inl.h"
	#include "rtc_base/bind.h"
	#include "rtc_base/constructormagic.h"
	#include "rtc_base/event.h"
	#include "rtc_base/refcountedobject.h"
	#include "rtc_base/scoped_ref_ptr.h"
	#include "rtc_base/sigslot.h"
	#include "rtc_base/thread.h"

	namespace rtc {

	// Invokes function objects (aka functors) asynchronously on a Thread, and
	// owns the lifetime of calls (ie, when this object is destroyed, calls in
	// flight are cancelled). AsyncInvoker can optionally execute a user-specified
	// function when the asynchronous call is complete, or operates in
	// fire-and-forget mode otherwise.
	//
	// AsyncInvoker does not own the thread it calls functors on.
	//
	// A note about async calls and object lifetimes: users should
	// be mindful of object lifetimes when calling functions asynchronously and
	// ensure objects used by the function _cannot_ be deleted between the
	// invocation and execution of the functor. AsyncInvoker is designed to
	// help: any calls in flight will be cancelled when the AsyncInvoker used to
	// make the call is destructed, and any calls executing will be allowed to
	// complete before AsyncInvoker destructs.
	//
	// The easiest way to ensure lifetimes are handled correctly is to create a
	// class that owns the Thread and AsyncInvoker objects, and then call its
	// methods asynchronously as needed.
	//
	// Example:
	// class MyClass {
	// public:
	// void FireAsyncTaskWithResult(Thread* thread, int x) {
	// // Specify a callback to get the result upon completion.
	// invoker_.AsyncInvoke<int>(RTC_FROM_HERE,
	// thread, Bind(&MyClass::AsyncTaskWithResult, this, x),
	// &MyClass::OnTaskComplete, this);
	// }
	// void FireAnotherAsyncTask(Thread* thread) {
	// // No callback specified means fire-and-forget.
	// invoker_.AsyncInvoke<void>(RTC_FROM_HERE,
	// thread, Bind(&MyClass::AnotherAsyncTask, this));
	//
	// private:
	// int AsyncTaskWithResult(int x) {
	// // Some long running process...
	// return x * x;
	// }
	// void AnotherAsyncTask() {
	// // Some other long running process...
	// }
	// void OnTaskComplete(int result) { result_ = result; }
	//
	// AsyncInvoker invoker_;
	// int result_;
	// };
	//
	// More details about threading:
	// - It's safe to construct/destruct AsyncInvoker on different threads.
	// - It's safe to call AsyncInvoke from different threads.
	// - It's safe to call AsyncInvoke recursively from within a functor that's
	// being AsyncInvoked.
	// - However, it's not safe to call AsyncInvoke from outside a functor
	// that's being AsyncInvoked while the AsyncInvoker is being destroyed on
	// another thread. This is just inherently unsafe and there's no way to
	// prevent that. So, the user of this class should ensure that the start of
	// each "chain" of invocations is synchronized somehow with the AsyncInvoker's
	// destruction. This can be done by starting each chain of invocations on the
	// same thread on which it will be destroyed, or by using some other
	// synchronization method.
	class AsyncInvoker : public MessageHandler {
	public:
	AsyncInvoker();
	~AsyncInvoker() override;

	// Call \|functor\| asynchronously on \|thread\|, with no callback upon
	// completion. Returns immediately.
	template <class ReturnT, class FunctorT>
	void AsyncInvoke(const Location& posted_from,
	Thread* thread,
	const FunctorT& functor,
	uint32_t id = 0) {
	std::unique_ptr<AsyncClosure> closure(
	new FireAndForgetAsyncClosure<FunctorT>(this, functor));
	DoInvoke(posted_from, thread, std::move(closure), id);
	}

	// Call \|functor\| asynchronously on \|thread\| with \|delay_ms\|, with no callback
	// upon completion. Returns immediately.
	template <class ReturnT, class FunctorT>
	void AsyncInvokeDelayed(const Location& posted_from,
	Thread* thread,
	const FunctorT& functor,
	uint32_t delay_ms,
	uint32_t id = 0) {
	std::unique_ptr<AsyncClosure> closure(
	new FireAndForgetAsyncClosure<FunctorT>(this, functor));
	DoInvokeDelayed(posted_from, thread, std::move(closure), delay_ms, id);
	}

	// Synchronously execute on \|thread\| all outstanding calls we own
	// that are pending on \|thread\|, and wait for calls to complete
	// before returning. Optionally filter by message id.
	// The destructor will not wait for outstanding calls, so if that
	// behavior is desired, call Flush() before destroying this object.
	void Flush(Thread* thread, uint32_t id = MQID_ANY);

	private:
	void OnMessage(Message* msg) override;
	void DoInvoke(const Location& posted_from,
	Thread* thread,
	std::unique_ptr<AsyncClosure> closure,
	uint32_t id);
	void DoInvokeDelayed(const Location& posted_from,
	Thread* thread,
	std::unique_ptr<AsyncClosure> closure,
	uint32_t delay_ms,
	uint32_t id);

	// Used to keep track of how many invocations (AsyncClosures) are still
	// alive, so that the destructor can wait for them to finish, as described in
	// the class documentation.
	//
	// TODO(deadbeef): Using a raw std::atomic like this is prone to error and
	// difficult to maintain. We should try to wrap this functionality in a
	// separate class to reduce the chance of errors being introduced in the
	// future.
	std::atomic<int> pending_invocations_;

	// Reference counted so that if the AsyncInvoker destructor finishes before
	// an AsyncClosure's destructor that's about to call
	// "invocation_complete_->Set()", it's not dereferenced after being
	// destroyed.
	scoped_refptr<RefCountedObject<Event>> invocation_complete_;

	// This flag is used to ensure that if an application AsyncInvokes tasks that
	// recursively AsyncInvoke other tasks ad infinitum, the cycle eventually
	// terminates.
	std::atomic<bool> destroying_;

	friend class AsyncClosure;

	RTC_DISALLOW_COPY_AND_ASSIGN(AsyncInvoker);
	};

	// Similar to AsyncInvoker, but guards against the Thread being destroyed while
	// there are outstanding dangling pointers to it. It will connect to the current
	// thread in the constructor, and will get notified when that thread is
	// destroyed. After GuardedAsyncInvoker is constructed, it can be used from
	// other threads to post functors to the thread it was constructed on. If that
	// thread dies, any further calls to AsyncInvoke() will be safely ignored.
	class GuardedAsyncInvoker : public sigslot::has_slots<> {
	public:
	GuardedAsyncInvoker();
	~GuardedAsyncInvoker() override;

	// Synchronously execute all outstanding calls we own, and wait for calls to
	// complete before returning. Optionally filter by message id. The destructor
	// will not wait for outstanding calls, so if that behavior is desired, call
	// Flush() first. Returns false if the thread has died.
	bool Flush(uint32_t id = MQID_ANY);

	// Call \|functor\| asynchronously with no callback upon completion. Returns
	// immediately. Returns false if the thread has died.
	template <class ReturnT, class FunctorT>
	bool AsyncInvoke(const Location& posted_from,
	const FunctorT& functor,
	uint32_t id = 0) {
	CritScope cs(&crit_);
	if (thread_ == nullptr)
	return false;
	invoker_.AsyncInvoke<ReturnT, FunctorT>(posted_from, thread_, functor, id);
	return true;
	}

	// Call \|functor\| asynchronously with \|delay_ms\|, with no callback upon
	// completion. Returns immediately. Returns false if the thread has died.
	template <class ReturnT, class FunctorT>
	bool AsyncInvokeDelayed(const Location& posted_from,
	const FunctorT& functor,
	uint32_t delay_ms,
	uint32_t id = 0) {
	CritScope cs(&crit_);
	if (thread_ == nullptr)
	return false;
	invoker_.AsyncInvokeDelayed<ReturnT, FunctorT>(posted_from, thread_,
	functor, delay_ms, id);
	return true;
	}

	// Call \|functor\| asynchronously, calling \|callback\| when done. Returns false
	// if the thread has died.
	template <class ReturnT, class FunctorT, class HostT>
	bool AsyncInvoke(const Location& posted_from,
	const Location& callback_posted_from,
	const FunctorT& functor,
	void (HostT::*callback)(ReturnT),
	HostT* callback_host,
	uint32_t id = 0) {
	CritScope cs(&crit_);
	if (thread_ == nullptr)
	return false;
	invoker_.AsyncInvoke<ReturnT, FunctorT, HostT>(
	posted_from, callback_posted_from, thread_, functor, callback,
	callback_host, id);
	return true;
	}

	// Call \|functor\| asynchronously calling \|callback\| when done. Overloaded for
	// void return. Returns false if the thread has died.
	template <class ReturnT, class FunctorT, class HostT>
	bool AsyncInvoke(const Location& posted_from,
	const Location& callback_posted_from,
	const FunctorT& functor,
	void (HostT::*callback)(),
	HostT* callback_host,
	uint32_t id = 0) {
	CritScope cs(&crit_);
	if (thread_ == nullptr)
	return false;
	invoker_.AsyncInvoke<ReturnT, FunctorT, HostT>(
	posted_from, callback_posted_from, thread_, functor, callback,
	callback_host, id);
	return true;
	}

	private:
	// Callback when \|thread_\| is destroyed.
	void ThreadDestroyed();

	CriticalSection crit_;
	Thread* thread_ RTC_GUARDED_BY(crit_);
	AsyncInvoker invoker_ RTC_GUARDED_BY(crit_);
	};

	} // namespace rtc

	#endif // RTC_BASE_ASYNCINVOKER_H_