/* * Copyright 2013 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. */ // This file contains Macros for creating proxies for webrtc MediaStream and // PeerConnection classes. // TODO(deadbeef): Move this to pc/; this is part of the implementation. // // Example usage: // // class TestInterface : public rtc::RefCountInterface { // public: // std::string FooA() = 0; // std::string FooB(bool arg1) const = 0; // std::string FooC(bool arg1) = 0; // }; // // Note that return types can not be a const reference. // // class Test : public TestInterface { // ... implementation of the interface. // }; // // BEGIN_PROXY_MAP(Test) // PROXY_SIGNALING_THREAD_DESTRUCTOR() // PROXY_METHOD0(std::string, FooA) // PROXY_CONSTMETHOD1(std::string, FooB, arg1) // PROXY_WORKER_METHOD1(std::string, FooC, arg1) // END_PROXY_MAP() // // Where the destructor and first two methods are invoked on the signaling // thread, and the third is invoked on the worker thread. // // The proxy can be created using // // TestProxy::Create(Thread* signaling_thread, Thread* worker_thread, // TestInterface*). // // The variant defined with BEGIN_SIGNALING_PROXY_MAP is unaware of // the worker thread, and invokes all methods on the signaling thread. // // The variant defined with BEGIN_OWNED_PROXY_MAP does not use // refcounting, and instead just takes ownership of the object being proxied. #ifndef API_PROXY_H_ #define API_PROXY_H_ #include #include #include "rtc_base/event.h" #include "rtc_base/refcountedobject.h" #include "rtc_base/thread.h" namespace webrtc { template class ReturnType { public: template void Invoke(C* c, M m) { r_ = (c->*m)(); } template void Invoke(C* c, M m, T1 a1) { r_ = (c->*m)(std::move(a1)); } template void Invoke(C* c, M m, T1 a1, T2 a2) { r_ = (c->*m)(std::move(a1), std::move(a2)); } template void Invoke(C* c, M m, T1 a1, T2 a2, T3 a3) { r_ = (c->*m)(std::move(a1), std::move(a2), std::move(a3)); } template void Invoke(C* c, M m, T1 a1, T2 a2, T3 a3, T4 a4) { r_ = (c->*m)(std::move(a1), std::move(a2), std::move(a3), std::move(a4)); } template void Invoke(C* c, M m, T1 a1, T2 a2, T3 a3, T4 a4, T5 a5) { r_ = (c->*m)(std::move(a1), std::move(a2), std::move(a3), std::move(a4), std::move(a5)); } R moved_result() { return std::move(r_); } private: R r_; }; template <> class ReturnType { public: template void Invoke(C* c, M m) { (c->*m)(); } template void Invoke(C* c, M m, T1 a1) { (c->*m)(std::move(a1)); } template void Invoke(C* c, M m, T1 a1, T2 a2) { (c->*m)(std::move(a1), std::move(a2)); } template void Invoke(C* c, M m, T1 a1, T2 a2, T3 a3) { (c->*m)(std::move(a1), std::move(a2), std::move(a3)); } void moved_result() {} }; namespace internal { class SynchronousMethodCall : public rtc::MessageData, public rtc::MessageHandler { public: explicit SynchronousMethodCall(rtc::MessageHandler* proxy); ~SynchronousMethodCall() override; void Invoke(const rtc::Location& posted_from, rtc::Thread* t); private: void OnMessage(rtc::Message*) override; std::unique_ptr e_; rtc::MessageHandler* proxy_; }; } // namespace internal template class MethodCall0 : public rtc::Message, public rtc::MessageHandler { public: typedef R (C::*Method)(); MethodCall0(C* c, Method m) : c_(c), m_(m) {} R Marshal(const rtc::Location& posted_from, rtc::Thread* t) { internal::SynchronousMethodCall(this).Invoke(posted_from, t); return r_.moved_result(); } private: void OnMessage(rtc::Message*) { r_.Invoke(c_, m_); } C* c_; Method m_; ReturnType r_; }; template class ConstMethodCall0 : public rtc::Message, public rtc::MessageHandler { public: typedef R (C::*Method)() const; ConstMethodCall0(C* c, Method m) : c_(c), m_(m) {} R Marshal(const rtc::Location& posted_from, rtc::Thread* t) { internal::SynchronousMethodCall(this).Invoke(posted_from, t); return r_.moved_result(); } private: void OnMessage(rtc::Message*) { r_.Invoke(c_, m_); } C* c_; Method m_; ReturnType r_; }; template class MethodCall1 : public rtc::Message, public rtc::MessageHandler { public: typedef R (C::*Method)(T1 a1); MethodCall1(C* c, Method m, T1 a1) : c_(c), m_(m), a1_(std::move(a1)) {} R Marshal(const rtc::Location& posted_from, rtc::Thread* t) { internal::SynchronousMethodCall(this).Invoke(posted_from, t); return r_.moved_result(); } private: void OnMessage(rtc::Message*) { r_.Invoke(c_, m_, std::move(a1_)); } C* c_; Method m_; ReturnType r_; T1 a1_; }; template class ConstMethodCall1 : public rtc::Message, public rtc::MessageHandler { public: typedef R (C::*Method)(T1 a1) const; ConstMethodCall1(C* c, Method m, T1 a1) : c_(c), m_(m), a1_(std::move(a1)) {} R Marshal(const rtc::Location& posted_from, rtc::Thread* t) { internal::SynchronousMethodCall(this).Invoke(posted_from, t); return r_.moved_result(); } private: void OnMessage(rtc::Message*) { r_.Invoke(c_, m_, std::move(a1_)); } C* c_; Method m_; ReturnType r_; T1 a1_; }; template class MethodCall2 : public rtc::Message, public rtc::MessageHandler { public: typedef R (C::*Method)(T1 a1, T2 a2); MethodCall2(C* c, Method m, T1 a1, T2 a2) : c_(c), m_(m), a1_(std::move(a1)), a2_(std::move(a2)) {} R Marshal(const rtc::Location& posted_from, rtc::Thread* t) { internal::SynchronousMethodCall(this).Invoke(posted_from, t); return r_.moved_result(); } private: void OnMessage(rtc::Message*) { r_.Invoke(c_, m_, std::move(a1_), std::move(a2_)); } C* c_; Method m_; ReturnType r_; T1 a1_; T2 a2_; }; template class MethodCall3 : public rtc::Message, public rtc::MessageHandler { public: typedef R (C::*Method)(T1 a1, T2 a2, T3 a3); MethodCall3(C* c, Method m, T1 a1, T2 a2, T3 a3) : c_(c), m_(m), a1_(std::move(a1)), a2_(std::move(a2)), a3_(std::move(a3)) {} R Marshal(const rtc::Location& posted_from, rtc::Thread* t) { internal::SynchronousMethodCall(this).Invoke(posted_from, t); return r_.moved_result(); } private: void OnMessage(rtc::Message*) { r_.Invoke(c_, m_, std::move(a1_), std::move(a2_), std::move(a3_)); } C* c_; Method m_; ReturnType r_; T1 a1_; T2 a2_; T3 a3_; }; template class MethodCall4 : public rtc::Message, public rtc::MessageHandler { public: typedef R (C::*Method)(T1 a1, T2 a2, T3 a3, T4 a4); MethodCall4(C* c, Method m, T1 a1, T2 a2, T3 a3, T4 a4) : c_(c), m_(m), a1_(std::move(a1)), a2_(std::move(a2)), a3_(std::move(a3)), a4_(std::move(a4)) {} R Marshal(const rtc::Location& posted_from, rtc::Thread* t) { internal::SynchronousMethodCall(this).Invoke(posted_from, t); return r_.moved_result(); } private: void OnMessage(rtc::Message*) { r_.Invoke(c_, m_, std::move(a1_), std::move(a2_), std::move(a3_), std::move(a4_)); } C* c_; Method m_; ReturnType r_; T1 a1_; T2 a2_; T3 a3_; T4 a4_; }; template class MethodCall5 : public rtc::Message, public rtc::MessageHandler { public: typedef R (C::*Method)(T1 a1, T2 a2, T3 a3, T4 a4, T5 a5); MethodCall5(C* c, Method m, T1 a1, T2 a2, T3 a3, T4 a4, T5 a5) : c_(c), m_(m), a1_(std::move(a1)), a2_(std::move(a2)), a3_(std::move(a3)), a4_(std::move(a4)), a5_(std::move(a5)) {} R Marshal(const rtc::Location& posted_from, rtc::Thread* t) { internal::SynchronousMethodCall(this).Invoke(posted_from, t); return r_.moved_result(); } private: void OnMessage(rtc::Message*) { r_.Invoke(c_, m_, std::move(a1_), std::move(a2_), std::move(a3_), std::move(a4_), std::move(a5_)); } C* c_; Method m_; ReturnType r_; T1 a1_; T2 a2_; T3 a3_; T4 a4_; T5 a5_; }; // Helper macros to reduce code duplication. #define PROXY_MAP_BOILERPLATE(c) \ template \ class c##ProxyWithInternal; \ typedef c##ProxyWithInternal c##Proxy; \ template \ class c##ProxyWithInternal : public c##Interface { \ protected: \ typedef c##Interface C; \ \ public: \ const INTERNAL_CLASS* internal() const { return c_; } \ INTERNAL_CLASS* internal() { return c_; } // clang-format off // clang-format would put the semicolon alone, // leading to a presubmit error (cpplint.py) #define END_PROXY_MAP() \ }; // clang-format on #define SIGNALING_PROXY_MAP_BOILERPLATE(c) \ protected: \ c##ProxyWithInternal(rtc::Thread* signaling_thread, INTERNAL_CLASS* c) \ : signaling_thread_(signaling_thread), c_(c) {} \ \ private: \ mutable rtc::Thread* signaling_thread_; #define WORKER_PROXY_MAP_BOILERPLATE(c) \ protected: \ c##ProxyWithInternal(rtc::Thread* signaling_thread, \ rtc::Thread* worker_thread, INTERNAL_CLASS* c) \ : signaling_thread_(signaling_thread), \ worker_thread_(worker_thread), \ c_(c) {} \ \ private: \ mutable rtc::Thread* signaling_thread_; \ mutable rtc::Thread* worker_thread_; // Note that the destructor is protected so that the proxy can only be // destroyed via RefCountInterface. #define REFCOUNTED_PROXY_MAP_BOILERPLATE(c) \ protected: \ ~c##ProxyWithInternal() { \ MethodCall0 call( \ this, &c##ProxyWithInternal::DestroyInternal); \ call.Marshal(RTC_FROM_HERE, destructor_thread()); \ } \ \ private: \ void DestroyInternal() { c_ = nullptr; } \ rtc::scoped_refptr c_; // Note: This doesn't use a unique_ptr, because it intends to handle a corner // case where an object's deletion triggers a callback that calls back into // this proxy object. If relying on a unique_ptr to delete the object, its // inner pointer would be set to null before this reentrant callback would have // a chance to run, resulting in a segfault. #define OWNED_PROXY_MAP_BOILERPLATE(c) \ public: \ ~c##ProxyWithInternal() { \ MethodCall0 call( \ this, &c##ProxyWithInternal::DestroyInternal); \ call.Marshal(RTC_FROM_HERE, destructor_thread()); \ } \ \ private: \ void DestroyInternal() { delete c_; } \ INTERNAL_CLASS* c_; #define BEGIN_SIGNALING_PROXY_MAP(c) \ PROXY_MAP_BOILERPLATE(c) \ SIGNALING_PROXY_MAP_BOILERPLATE(c) \ REFCOUNTED_PROXY_MAP_BOILERPLATE(c) \ public: \ static rtc::scoped_refptr Create( \ rtc::Thread* signaling_thread, INTERNAL_CLASS* c) { \ return new rtc::RefCountedObject(signaling_thread, \ c); \ } #define BEGIN_PROXY_MAP(c) \ PROXY_MAP_BOILERPLATE(c) \ WORKER_PROXY_MAP_BOILERPLATE(c) \ REFCOUNTED_PROXY_MAP_BOILERPLATE(c) \ public: \ static rtc::scoped_refptr Create( \ rtc::Thread* signaling_thread, rtc::Thread* worker_thread, \ INTERNAL_CLASS* c) { \ return new rtc::RefCountedObject(signaling_thread, \ worker_thread, c); \ } #define BEGIN_OWNED_PROXY_MAP(c) \ PROXY_MAP_BOILERPLATE(c) \ WORKER_PROXY_MAP_BOILERPLATE(c) \ OWNED_PROXY_MAP_BOILERPLATE(c) \ public: \ static std::unique_ptr Create( \ rtc::Thread* signaling_thread, rtc::Thread* worker_thread, \ std::unique_ptr c) { \ return std::unique_ptr(new c##ProxyWithInternal( \ signaling_thread, worker_thread, c.release())); \ } #define PROXY_SIGNALING_THREAD_DESTRUCTOR() \ private: \ rtc::Thread* destructor_thread() const { return signaling_thread_; } \ \ public: // NOLINTNEXTLINE #define PROXY_WORKER_THREAD_DESTRUCTOR() \ private: \ rtc::Thread* destructor_thread() const { return worker_thread_; } \ \ public: // NOLINTNEXTLINE #define PROXY_METHOD0(r, method) \ r method() override { \ MethodCall0 call(c_, &C::method); \ return call.Marshal(RTC_FROM_HERE, signaling_thread_); \ } #define PROXY_CONSTMETHOD0(r, method) \ r method() const override { \ ConstMethodCall0 call(c_, &C::method); \ return call.Marshal(RTC_FROM_HERE, signaling_thread_); \ } #define PROXY_METHOD1(r, method, t1) \ r method(t1 a1) override { \ MethodCall1 call(c_, &C::method, std::move(a1)); \ return call.Marshal(RTC_FROM_HERE, signaling_thread_); \ } #define PROXY_CONSTMETHOD1(r, method, t1) \ r method(t1 a1) const override { \ ConstMethodCall1 call(c_, &C::method, std::move(a1)); \ return call.Marshal(RTC_FROM_HERE, signaling_thread_); \ } #define PROXY_METHOD2(r, method, t1, t2) \ r method(t1 a1, t2 a2) override { \ MethodCall2 call(c_, &C::method, std::move(a1), \ std::move(a2)); \ return call.Marshal(RTC_FROM_HERE, signaling_thread_); \ } #define PROXY_METHOD3(r, method, t1, t2, t3) \ r method(t1 a1, t2 a2, t3 a3) override { \ MethodCall3 call(c_, &C::method, std::move(a1), \ std::move(a2), std::move(a3)); \ return call.Marshal(RTC_FROM_HERE, signaling_thread_); \ } #define PROXY_METHOD4(r, method, t1, t2, t3, t4) \ r method(t1 a1, t2 a2, t3 a3, t4 a4) override { \ MethodCall4 call(c_, &C::method, std::move(a1), \ std::move(a2), std::move(a3), \ std::move(a4)); \ return call.Marshal(RTC_FROM_HERE, signaling_thread_); \ } #define PROXY_METHOD5(r, method, t1, t2, t3, t4, t5) \ r method(t1 a1, t2 a2, t3 a3, t4 a4, t5 a5) override { \ MethodCall5 call(c_, &C::method, std::move(a1), \ std::move(a2), std::move(a3), \ std::move(a4), std::move(a5)); \ return call.Marshal(RTC_FROM_HERE, signaling_thread_); \ } // Define methods which should be invoked on the worker thread. #define PROXY_WORKER_METHOD0(r, method) \ r method() override { \ MethodCall0 call(c_, &C::method); \ return call.Marshal(RTC_FROM_HERE, worker_thread_); \ } #define PROXY_WORKER_CONSTMETHOD0(r, method) \ r method() const override { \ ConstMethodCall0 call(c_, &C::method); \ return call.Marshal(RTC_FROM_HERE, worker_thread_); \ } #define PROXY_WORKER_METHOD1(r, method, t1) \ r method(t1 a1) override { \ MethodCall1 call(c_, &C::method, std::move(a1)); \ return call.Marshal(RTC_FROM_HERE, worker_thread_); \ } #define PROXY_WORKER_CONSTMETHOD1(r, method, t1) \ r method(t1 a1) const override { \ ConstMethodCall1 call(c_, &C::method, std::move(a1)); \ return call.Marshal(RTC_FROM_HERE, worker_thread_); \ } #define PROXY_WORKER_METHOD2(r, method, t1, t2) \ r method(t1 a1, t2 a2) override { \ MethodCall2 call(c_, &C::method, std::move(a1), \ std::move(a2)); \ return call.Marshal(RTC_FROM_HERE, worker_thread_); \ } #define PROXY_WORKER_CONSTMETHOD2(r, method, t1, t2) \ r method(t1 a1, t2 a2) const override { \ ConstMethodCall2 call(c_, &C::method, std::move(a1), \ std::move(a2)); \ return call.Marshal(RTC_FROM_HERE, worker_thread_); \ } #define PROXY_WORKER_METHOD3(r, method, t1, t2, t3) \ r method(t1 a1, t2 a2, t3 a3) override { \ MethodCall3 call(c_, &C::method, std::move(a1), \ std::move(a2), std::move(a3)); \ return call.Marshal(RTC_FROM_HERE, worker_thread_); \ } #define PROXY_WORKER_CONSTMETHOD3(r, method, t1, t2) \ r method(t1 a1, t2 a2, t3 a3) const override { \ ConstMethodCall3 call(c_, &C::method, std::move(a1), \ std::move(a2), std::move(a3)); \ return call.Marshal(RTC_FROM_HERE, worker_thread_); \ } } // namespace webrtc #endif // API_PROXY_H_