#pragma once #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #ifdef BRYNET_USE_OPENSSL #ifdef __cplusplus extern "C" { #endif #include #include #ifdef __cplusplus } #endif #endif namespace brynet { namespace net { class TcpConnection : public Channel, public brynet::base::NonCopyable, public std::enable_shared_from_this { public: using Ptr = std::shared_ptr; using EnterCallback = std::function; using DataCallback = std::function; using DisconnectedCallback = std::function; using PacketSendedCallback = std::function; using HighWaterCallback = std::function; public: Ptr static Create(TcpSocket::Ptr socket, size_t maxRecvBufferSize, EnterCallback&& enterCallback, const EventLoop::Ptr& eventLoop, const SSLHelper::Ptr& sslHelper = nullptr) { class make_shared_enabler : public TcpConnection { public: make_shared_enabler(TcpSocket::Ptr socket, size_t maxRecvBufferSize, EnterCallback&& enterCallback, EventLoop::Ptr eventLoop) : TcpConnection(std::move(socket), maxRecvBufferSize, std::move(enterCallback), std::move(eventLoop)) {} }; const auto isServerSide = socket->isServerSide(); auto session = std::make_shared( std::move(socket), maxRecvBufferSize, std::move(enterCallback), eventLoop); (void) isServerSide; #ifdef BRYNET_USE_OPENSSL if (sslHelper != nullptr) { if (isServerSide) { if (sslHelper->getOpenSSLCTX() == nullptr || !session->initAcceptSSL(sslHelper->getOpenSSLCTX())) { throw std::runtime_error("init ssl failed"); } } else { if (!session->initConnectSSL()) { throw std::runtime_error("init ssl failed"); } } } #else if (sslHelper != nullptr) { throw std::runtime_error("not enable ssl"); } #endif eventLoop->runAsyncFunctor([session]() { session->onEnterEventLoop(); }); return session; } const EventLoop::Ptr& getEventLoop() const { return mEventLoop; } //TODO::如果所属EventLoop已经没有工作,则可能导致内存无限大,因为所投递的请求都没有得到处理 void send(const SendableMsg::Ptr& msg, PacketSendedCallback&& callback = nullptr) { if (mEventLoop->isInLoopThread()) { sendInLoop(msg, std::move(callback)); } else { auto sharedThis = shared_from_this(); mEventLoop->runAsyncFunctor([sharedThis, msg, callback, this]() mutable { sendInLoop(msg, std::move(callback)); }); } } void send(const char* buffer, size_t len, PacketSendedCallback&& callback = nullptr) { send(MakeStringMsg(buffer, len), std::move(callback)); } void send(const std::string& buffer, PacketSendedCallback&& callback = nullptr) { send(MakeStringMsg(buffer), std::move(callback)); } void send(std::string&& buffer, PacketSendedCallback&& callback = nullptr) { send(MakeStringMsg(std::move(buffer)), std::move(callback)); } // setDataCallback(std::function) template void setDataCallback(Callback&& cb) { verifyArgType(cb, &Callback::operator()); auto sharedThis = shared_from_this(); mEventLoop->runAsyncFunctor([sharedThis, cb, this]() mutable { mDataCallback = cb; processRecvMessage(); }); } void setDisConnectCallback(DisconnectedCallback&& cb) { auto sharedThis = shared_from_this(); mEventLoop->runAsyncFunctor([sharedThis, cb, this]() mutable { mDisConnectCallback = std::move(cb); }); } /* if checkTime is zero, will cancel check heartbeat */ void setHeartBeat(std::chrono::nanoseconds checkTime) { auto sharedThis = shared_from_this(); mEventLoop->runAsyncFunctor([sharedThis, checkTime, this]() { if (mTimer.lock() != nullptr) { mTimer.lock()->cancel(); mTimer.reset(); } mCheckTime = checkTime; startPingCheckTimer(); }); } void setHighWaterCallback(HighWaterCallback cb, size_t size) { auto sharedThis = shared_from_this(); mEventLoop->runAsyncFunctor([=]() mutable { mHighWaterCallback = std::move(cb); mHighWaterSize = size; }); } void postShrinkReceiveBuffer() { auto sharedThis = shared_from_this(); mEventLoop->runAsyncFunctor([sharedThis, this]() { mEventLoop->runFunctorAfterLoop([sharedThis, this]() { shrinkReceiveBuffer(); }); }); } void postDisConnect() { auto sharedThis = shared_from_this(); mEventLoop->runAsyncFunctor([sharedThis, this]() { procCloseInLoop(); }); } void postShutdown() { auto sharedThis = shared_from_this(); mEventLoop->runAsyncFunctor([sharedThis, this]() { mEventLoop->runFunctorAfterLoop([sharedThis, this]() { procShutdownInLoop(); }); }); } const std::string& getIP() const { return mIP; } protected: TcpConnection(TcpSocket::Ptr socket, size_t maxRecvBufferSize, EnterCallback&& enterCallback, EventLoop::Ptr eventLoop) BRYNET_NOEXCEPT : #ifdef BRYNET_PLATFORM_WINDOWS mOvlRecv(port::Win::OverlappedType::OverlappedRecv), mOvlSend(port::Win::OverlappedType::OverlappedSend), mPostClose(false), #endif mIP(socket->getRemoteIP()), mSocket(std::move(socket)), mEventLoop(std::move(eventLoop)), mAlreadyClose(false), mMaxRecvBufferSize(maxRecvBufferSize), mSendingMsgSize(0), mEnterCallback(std::move(enterCallback)), mHighWaterSize(0) { mRecvData = false; mCheckTime = std::chrono::steady_clock::duration::zero(); mIsPostFlush = false; mCanWrite = true; #ifdef BRYNET_PLATFORM_WINDOWS mPostRecvCheck = false; mPostWriteCheck = false; #endif growRecvBuffer(); #ifdef BRYNET_USE_OPENSSL mSSLCtx = nullptr; mSSL = nullptr; mIsHandsharked = false; #endif } ~TcpConnection() BRYNET_NOEXCEPT override { #ifdef BRYNET_USE_OPENSSL if (mSSL != nullptr) { SSL_free(mSSL); mSSL = nullptr; } if (mSSLCtx != nullptr) { SSL_CTX_free(mSSLCtx); mSSLCtx = nullptr; } #endif if (mTimer.lock()) { mTimer.lock()->cancel(); } } private: void sendInLoop(const SendableMsg::Ptr& msg, PacketSendedCallback&& callback = nullptr) { if (mAlreadyClose) { return; } const auto len = msg->size(); mSendingMsgSize += len; mSendList.emplace_back(PendingPacket{ msg, len, std::move(callback)}); runAfterFlush(); if (mSendingMsgSize > mHighWaterSize && mHighWaterCallback != nullptr) { mHighWaterCallback(); } } void growRecvBuffer() { if (mRecvBuffer == nullptr) { mRecvBuffer.reset(brynet::base::buffer_new(std::min(16 * 1024, mMaxRecvBufferSize))); mRecvBuffOriginSize = buffer_getsize(mRecvBuffer.get()); } else { if (buffer_getsize(mRecvBuffer.get()) >= mMaxRecvBufferSize) { return; } mCurrentTanhXDiff += 0.2; const auto newTanh = std::tanh(mCurrentTanhXDiff); const auto maxSizeDiff = mMaxRecvBufferSize - mRecvBuffOriginSize; const auto NewSize = mRecvBuffOriginSize + (maxSizeDiff * newTanh); assert(NewSize <= mMaxRecvBufferSize); std::unique_ptr newBuffer(brynet::base::buffer_new(NewSize)); buffer_write(newBuffer.get(), buffer_getreadptr(mRecvBuffer.get()), buffer_getreadvalidcount(mRecvBuffer.get())); mRecvBuffer = std::move(newBuffer); } } void shrinkReceiveBuffer() { auto newSize = buffer_getreadvalidcount(mRecvBuffer.get()); if (newSize == 0) { newSize = std::min(16 * 1024, mMaxRecvBufferSize); } if (newSize == buffer_getsize(mRecvBuffer.get())) { return; } std::unique_ptr newBuffer(brynet::base::buffer_new(newSize)); buffer_write(newBuffer.get(), buffer_getreadptr(mRecvBuffer.get()), buffer_getreadvalidcount(mRecvBuffer.get())); mRecvBuffer = std::move(newBuffer); mCurrentTanhXDiff = 0; mRecvBuffOriginSize = newSize; } /* must called in network thread */ bool onEnterEventLoop() { assert(mEventLoop->isInLoopThread()); if (!mEventLoop->isInLoopThread()) { return false; } if (!brynet::net::base::SocketNonblock(mSocket->getFD()) || !mEventLoop->linkChannel(mSocket->getFD(), this)) { return false; } const auto findRet = mEventLoop->getTcpConnection(mSocket->getFD()); (void) findRet; assert(findRet == nullptr); #ifdef BRYNET_USE_OPENSSL if (mSSL != nullptr) { mEventLoop->addTcpConnection(mSocket->getFD(), shared_from_this()); processSSLHandshake(); return true; } #endif if (!checkRead()) { return false; } mEventLoop->addTcpConnection(mSocket->getFD(), shared_from_this()); causeEnterCallback(); return true; } #ifdef BRYNET_USE_OPENSSL bool initAcceptSSL(SSL_CTX* ctx) { if (mSSL != nullptr) { return false; } mSSL = SSL_new(ctx); if (SSL_set_fd(mSSL, mSocket->getFD()) != 1) { ERR_print_errors_fp(stdout); ::fflush(stdout); return false; } return true; } bool initConnectSSL() { if (mSSLCtx != nullptr) { return false; } mSSLCtx = SSL_CTX_new(SSLv23_client_method()); mSSL = SSL_new(mSSLCtx); if (SSL_set_fd(mSSL, mSocket->getFD()) != 1) { ERR_print_errors_fp(stdout); ::fflush(stdout); return false; } return true; } #endif void pingCheck() { mTimer.reset(); if (mRecvData) { mRecvData = false; startPingCheckTimer(); } else { procCloseInLoop(); } } void startPingCheckTimer() { if (!mTimer.lock() && mCheckTime != std::chrono::steady_clock::duration::zero()) { std::weak_ptr weakThis = shared_from_this(); mTimer = mEventLoop->runAfter(mCheckTime, [weakThis]() { auto sharedThis = weakThis.lock(); if (sharedThis != nullptr) { sharedThis->pingCheck(); } }); } } void canRecv(const bool willClose) override { #ifdef BRYNET_PLATFORM_WINDOWS mPostRecvCheck = false; if (mPostClose) { if (!mPostWriteCheck) { onClose(); } return; } #elif defined BRYNET_PLATFORM_LINUX || defined BRYNET_PLATFORM_DARWIN if (mAlreadyClose) { return; } #endif #ifdef BRYNET_USE_OPENSSL if (mSSL != nullptr && !mIsHandsharked && (!processSSLHandshake() || !mIsHandsharked)) { return; } #endif do { recv(); adjustReceiveBuffer(); } while (willClose && !mAlreadyClose && mRecvBuffer != nullptr && buffer_getwritevalidcount(mRecvBuffer.get()) > 0); } void canSend() override { #ifdef BRYNET_PLATFORM_WINDOWS mPostWriteCheck = false; if (mPostClose) { if (!mPostRecvCheck) { onClose(); } return; } #elif defined BRYNET_PLATFORM_LINUX || defined BRYNET_PLATFORM_DARWIN if (mAlreadyClose) { return; } #endif mCanWrite = true; #ifdef BRYNET_USE_OPENSSL if (mSSL != nullptr && !mIsHandsharked && (!processSSLHandshake() || !mIsHandsharked)) { return; } #endif runAfterFlush(); } bool checkRead() { bool check_ret = true; #ifdef BRYNET_PLATFORM_WINDOWS static CHAR temp[] = {0}; static WSABUF in_buf = {0, temp}; if (mPostRecvCheck) { return check_ret; } DWORD dwBytes = 0; DWORD flag = 0; const int ret = WSARecv(mSocket->getFD(), &in_buf, 1, &dwBytes, &flag, &(mOvlRecv.base), 0); if (ret == BRYNET_SOCKET_ERROR) { check_ret = (BRYNET_ERRNO == WSA_IO_PENDING); } if (check_ret) { mPostRecvCheck = true; } #endif return check_ret; } bool checkWrite() { bool check_ret = true; #ifdef BRYNET_PLATFORM_WINDOWS static WSABUF wsendbuf[1] = {{ NULL, 0 }}; if (mPostWriteCheck) { return check_ret; } DWORD send_len = 0; const int ret = WSASend(mSocket->getFD(), wsendbuf, 1, &send_len, 0, &(mOvlSend.base), 0); if (ret == BRYNET_SOCKET_ERROR) { check_ret = (BRYNET_ERRNO == WSA_IO_PENDING); } if (check_ret) { mPostWriteCheck = true; } #endif return check_ret; } void adjustReceiveBuffer() { if (!mRecvBuffer) { return; } if (buffer_getwritevalidcount(mRecvBuffer.get()) == 0 || buffer_getreadvalidcount(mRecvBuffer.get()) == 0) { buffer_adjustto_head(mRecvBuffer.get()); } if (buffer_getreadvalidcount(mRecvBuffer.get()) == buffer_getsize(mRecvBuffer.get())) { growRecvBuffer(); } } void recv() { bool must_close = false; #ifdef BRYNET_USE_OPENSSL const bool notInSSL = (mSSL == nullptr); #else const bool notInSSL = false; #endif while (true) { adjustReceiveBuffer(); const auto tryRecvLen = buffer_getwritevalidcount(mRecvBuffer.get()); if (tryRecvLen == 0) { #ifdef BRYNET_PLATFORM_WINDOWS checkRead(); #elif defined BRYNET_PLATFORM_LINUX || defined BRYNET_PLATFORM_DARWIN //force recheck IN-OUT Event recheckEvent(); #endif break; } int retlen = 0; #ifdef BRYNET_USE_OPENSSL if (mSSL != nullptr) { retlen = SSL_read(mSSL, buffer_getwriteptr(mRecvBuffer.get()), tryRecvLen); } else { retlen = ::recv(mSocket->getFD(), buffer_getwriteptr(mRecvBuffer.get()), tryRecvLen, 0); } #else retlen = ::recv(mSocket->getFD(), buffer_getwriteptr(mRecvBuffer.get()), static_cast(tryRecvLen), 0); #endif if (retlen == 0) { must_close = true; break; } else if (retlen < 0) { #ifdef BRYNET_USE_OPENSSL if ((mSSL != nullptr && SSL_get_error(mSSL, retlen) == SSL_ERROR_WANT_READ) || (BRYNET_ERRNO == BRYNET_EWOULDBLOCK)) { must_close = !checkRead(); } else { must_close = true; } #else if (BRYNET_ERRNO != BRYNET_EWOULDBLOCK) { must_close = true; } else { must_close = !checkRead(); } #endif break; } mRecvData = true; buffer_addwritepos(mRecvBuffer.get(), static_cast(retlen)); if (notInSSL && retlen < static_cast(tryRecvLen)) { must_close = !checkRead(); break; } } processRecvMessage(); if (must_close) { procCloseInLoop(); } } void flush() { #ifdef BRYNET_PLATFORM_WINDOWS normalFlush(); #elif defined BRYNET_PLATFORM_LINUX || defined BRYNET_PLATFORM_DARWIN #ifdef BRYNET_USE_OPENSSL if (mSSL != nullptr) { normalFlush(); } else { quickFlush(); } #else quickFlush(); #endif #endif } void normalFlush() { #ifdef BRYNET_PLATFORM_WINDOWS static __declspec(thread) char* threadLocalSendBuf = nullptr; #elif defined BRYNET_PLATFORM_LINUX || defined BRYNET_PLATFORM_DARWIN static __thread char* threadLocalSendBuf = nullptr; #endif static const int SENDBUF_SIZE = 1024 * 32; if (threadLocalSendBuf == nullptr) { threadLocalSendBuf = static_cast(malloc(SENDBUF_SIZE)); } #ifdef BRYNET_USE_OPENSSL const bool notInSSL = (mSSL == nullptr); #else const bool notInSSL = false; #endif bool must_close = false; while (!mSendList.empty() && mCanWrite) { auto sendptr = threadLocalSendBuf; size_t wait_send_size = 0; for (auto it = mSendList.begin(); it != mSendList.end(); ++it) { auto& packet = *it; auto packetLeftBuf = (char*) (packet.data->data()) + packet.data->size() - packet.left; const auto packetLeftLen = packet.left; if ((wait_send_size + packetLeftLen) > SENDBUF_SIZE) { if (it == mSendList.begin()) { sendptr = packetLeftBuf; wait_send_size = packetLeftLen; } break; } memcpy(static_cast(sendptr + wait_send_size), static_cast(packetLeftBuf), packetLeftLen); wait_send_size += packetLeftLen; } if (wait_send_size == 0) { break; } int send_retlen = 0; #ifdef BRYNET_USE_OPENSSL if (mSSL != nullptr) { send_retlen = SSL_write(mSSL, sendptr, wait_send_size); } else { send_retlen = ::send(mSocket->getFD(), sendptr, wait_send_size, 0); } #else send_retlen = ::send(mSocket->getFD(), sendptr, static_cast(wait_send_size), 0); #endif if (send_retlen <= 0) { #ifdef BRYNET_USE_OPENSSL if ((mSSL != nullptr && SSL_get_error(mSSL, send_retlen) == SSL_ERROR_WANT_WRITE) || (BRYNET_ERRNO == BRYNET_EWOULDBLOCK)) { mCanWrite = false; must_close = !checkWrite(); } else { must_close = true; } #else if (BRYNET_ERRNO == BRYNET_EWOULDBLOCK) { mCanWrite = false; must_close = !checkWrite(); } else { must_close = true; } #endif break; } auto tmp_len = static_cast(send_retlen); for (auto it = mSendList.begin(); it != mSendList.end();) { auto& packet = *it; if (packet.left > tmp_len) { packet.left -= tmp_len; break; } tmp_len -= packet.left; if (packet.mCompleteCallback != nullptr) { (packet.mCompleteCallback)(); } mSendingMsgSize -= packet.data->size(); it = mSendList.erase(it); } if (notInSSL && static_cast(send_retlen) != wait_send_size) { mCanWrite = false; must_close = !checkWrite(); break; } } if (must_close) { procCloseInLoop(); } } #if defined BRYNET_PLATFORM_LINUX || defined BRYNET_PLATFORM_DARWIN void quickFlush() { #ifndef MAX_IOVEC constexpr size_t MAX_IOVEC = 1024; #endif struct iovec iov[MAX_IOVEC]; bool must_close = false; while (!mSendList.empty() && mCanWrite) { size_t num = 0; size_t ready_send_len = 0; for (const auto& p : mSendList) { iov[num].iov_base = (void*) (static_cast(p.data->data()) + p.data->size() - p.left); iov[num].iov_len = p.left; ready_send_len += p.left; num++; if (num >= MAX_IOVEC) { break; } } if (num == 0) { break; } const int send_len = writev(mSocket->getFD(), iov, static_cast(num)); if (send_len <= 0) { if (BRYNET_ERRNO == BRYNET_EWOULDBLOCK) { mCanWrite = false; must_close = !checkWrite(); } else { must_close = true; } break; } auto tmp_len = static_cast(send_len); for (auto it = mSendList.begin(); it != mSendList.end();) { PendingPacket& b = *it; if (b.left > tmp_len) { b.left -= tmp_len; break; } tmp_len -= b.left; if (b.mCompleteCallback != nullptr) { b.mCompleteCallback(); } mSendingMsgSize -= b.data->size(); it = mSendList.erase(it); } if (static_cast(send_len) != ready_send_len) { mCanWrite = false; must_close = !checkWrite(); break; } } if (must_close) { procCloseInLoop(); } } #endif void onClose() override { if (mAlreadyClose) { return; } mAlreadyClose = true; #if defined BRYNET_PLATFORM_LINUX || defined BRYNET_PLATFORM_DARWIN unregisterPollerEvent(); #endif assert(mEnterCallback == nullptr); auto callBack = mDisConnectCallback; auto sharedThis = shared_from_this(); auto eventLoop = mEventLoop; std::shared_ptr socket = std::move(const_cast(mSocket)); mEventLoop->runFunctorAfterLoop([callBack, sharedThis, eventLoop, socket]() { if (callBack != nullptr) { callBack(sharedThis); } auto tmp = eventLoop->getTcpConnection(socket->getFD()); assert(tmp == sharedThis); if (tmp == sharedThis) { eventLoop->removeTcpConnection(socket->getFD()); } }); mCanWrite = false; mDataCallback = nullptr; mDisConnectCallback = nullptr; mHighWaterCallback = nullptr; mRecvBuffer = nullptr; mSendList.clear(); } void procCloseInLoop() { mCanWrite = false; #ifdef BRYNET_PLATFORM_WINDOWS if (mPostWriteCheck || mPostRecvCheck) { if (mPostClose) { return; } mPostClose = true; //windows下立即关闭socket可能导致fd被另外的TcpConnection重用,而导致此对象在IOCP返回相关完成结果时内存已经释放 if (mPostRecvCheck) { CancelIoEx(HANDLE(mSocket->getFD()), &mOvlRecv.base); } if (mPostWriteCheck) { CancelIoEx(HANDLE(mSocket->getFD()), &mOvlSend.base); } } else { onClose(); } #elif defined BRYNET_PLATFORM_LINUX onClose(); #elif defined BRYNET_PLATFORM_DARWIN onClose(); #endif } void procShutdownInLoop() { mCanWrite = false; if (mSocket != nullptr) { #ifdef BRYNET_PLATFORM_WINDOWS shutdown(mSocket->getFD(), SD_SEND); #elif defined BRYNET_PLATFORM_LINUX || defined BRYNET_PLATFORM_DARWIN shutdown(mSocket->getFD(), SHUT_WR); #endif } } void runAfterFlush() { if (!mIsPostFlush && !mSendList.empty() && mCanWrite) { auto sharedThis = shared_from_this(); mEventLoop->runFunctorAfterLoop([sharedThis, this]() { mIsPostFlush = false; flush(); }); mIsPostFlush = true; } } #if defined BRYNET_PLATFORM_LINUX || defined BRYNET_PLATFORM_DARWIN void recheckEvent() { #ifdef BRYNET_PLATFORM_LINUX struct epoll_event ev = {0, { nullptr }}; ev.events = EPOLLET | EPOLLIN | EPOLLOUT | EPOLLRDHUP; ev.data.ptr = (Channel*) (this); epoll_ctl(mEventLoop->getEpollHandle(), EPOLL_CTL_MOD, mSocket->getFD(), &ev); #elif defined BRYNET_PLATFORM_DARWIN struct kevent ev[2]; memset(&ev, 0, sizeof(ev)); int n = 0; EV_SET(&ev[n++], mSocket->getFD(), EVFILT_READ, EV_ENABLE, 0, 0, (Channel*) (this)); EV_SET(&ev[n++], mSocket->getFD(), EVFILT_WRITE, EV_ENABLE, 0, 0, (Channel*) (this)); struct timespec now = {0, 0}; kevent(mEventLoop->getKqueueHandle(), ev, n, NULL, 0, &now); #endif } void unregisterPollerEvent() { #ifdef BRYNET_PLATFORM_LINUX struct epoll_event ev = {0, { nullptr }}; epoll_ctl(mEventLoop->getEpollHandle(), EPOLL_CTL_DEL, mSocket->getFD(), &ev); #elif defined BRYNET_PLATFORM_DARWIN struct kevent ev[2]; memset(&ev, 0, sizeof(ev)); int n = 0; EV_SET(&ev[n++], mSocket->getFD(), EVFILT_READ, EV_DELETE, 0, 0, NULL); EV_SET(&ev[n++], mSocket->getFD(), EVFILT_WRITE, EV_DELETE, 0, 0, NULL); struct timespec now = {0, 0}; kevent(mEventLoop->getKqueueHandle(), ev, n, NULL, 0, &now); #endif } #endif #ifdef BRYNET_USE_OPENSSL bool processSSLHandshake() { if (mIsHandsharked) { return true; } bool mustClose = false; int ret = 0; if (mSSLCtx != nullptr) { ret = SSL_connect(mSSL); } else { ret = SSL_accept(mSSL); } if (ret == 1) { mIsHandsharked = true; if (checkRead()) { causeEnterCallback(); } else { mustClose = true; } } else if (ret == 0) { mustClose = true; } else if (ret < 0) { int err = SSL_get_error(mSSL, ret); if (err == SSL_ERROR_WANT_WRITE || err == SSL_ERROR_WANT_READ) { if (!checkRead()) { mustClose = true; } } else { mustClose = true; } } if (mustClose) { causeEnterCallback(); procCloseInLoop(); return false; } return true; } #endif void causeEnterCallback() { assert(mEventLoop->isInLoopThread()); if (mEventLoop->isInLoopThread() && mEnterCallback != nullptr) { auto tmp = mEnterCallback; mEnterCallback = nullptr; tmp(shared_from_this()); } } void processRecvMessage() { if (mDataCallback != nullptr && buffer_getreadvalidcount(mRecvBuffer.get()) > 0) { auto reader = brynet::base::BasePacketReader(buffer_getreadptr(mRecvBuffer.get()), buffer_getreadvalidcount(mRecvBuffer.get()), false); mDataCallback(reader); const auto consumedLen = reader.savedPos(); assert(consumedLen <= reader.size()); if (consumedLen <= reader.size()) { buffer_addreadpos(mRecvBuffer.get(), consumedLen); } } } template static void verifyArgType(const CallbackType&, void (CallbackType::*)(Arg&) const) { static_assert(std::is_reference::value, "arg must be reference type"); static_assert(!std::is_const::type>::value, "arg can't be const type"); } private: #ifdef BRYNET_PLATFORM_WINDOWS struct port::Win::OverlappedExt mOvlRecv; struct port::Win::OverlappedExt mOvlSend; bool mPostRecvCheck; bool mPostWriteCheck; bool mPostClose; #endif const std::string mIP; const TcpSocket::Ptr mSocket; const EventLoop::Ptr mEventLoop; bool mCanWrite; bool mAlreadyClose; class BufferDeleter { public: void operator()(struct brynet::base::buffer_s* ptr) const { brynet::base::buffer_delete(ptr); } }; std::unique_ptr mRecvBuffer; double mCurrentTanhXDiff = 0; size_t mRecvBuffOriginSize = 0; const size_t mMaxRecvBufferSize; struct PendingPacket { SendableMsg::Ptr data; size_t left; PacketSendedCallback mCompleteCallback; }; using PacketListType = std::deque; PacketListType mSendList; size_t mSendingMsgSize; EnterCallback mEnterCallback; DataCallback mDataCallback; DisconnectedCallback mDisConnectCallback; HighWaterCallback mHighWaterCallback; size_t mHighWaterSize; bool mIsPostFlush; #ifdef BRYNET_USE_OPENSSL SSL_CTX* mSSLCtx; SSL* mSSL; bool mIsHandsharked; #endif bool mRecvData; std::chrono::nanoseconds mCheckTime{}; brynet::base::Timer::WeakPtr mTimer; }; }}// namespace brynet::net