/* Copyright (c) 2016 PaddlePaddle Authors. All Rights Reserve. Licensed under the Apache License, Version 2.0 (the "License"); you may not use this file except in compliance with the License. You may obtain a copy of the License at http://www.apache.org/licenses/LICENSE-2.0 Unless required by applicable law or agreed to in writing, software distributed under the License is distributed on an "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the License for the specific language governing permissions and limitations under the License. */ #include #include #include #include #include #include #include #include #include #include #include #include "LightNetwork.h" #include "RDMANetwork.h" #include "paddle/utils/StringUtil.h" #include "paddle/utils/Util.h" /// quick ack can reduce the latency of small message DEFINE_bool(small_messages, false, "if message size is small, recommend set it True to enable quick " "ack and no delay"); /// reasonable sock_send_buf_size can control the traffic injected into switch /// network. Injecting too many data into traffic could cause packets loss which /// cause long latency and degrade the efficiency of communication. DEFINE_int32(sock_send_buf_size, 1024 * 1024 * 40, "restrict sock send buff size, can reduce network congestion if " "set carefully"); /// reasonable size can hold bursted packets and reduce packets loss DEFINE_int32(sock_recv_buf_size, 1024 * 1024 * 40, "restrict sock recv buff size"); namespace paddle { /** * @brief get ip address from interface name * * @param[in] device device interface name */ std::string getIpAddr(std::string &device) { int sock; struct sockaddr_in sin; struct ifreq ifr; sock = socket(AF_INET, SOCK_DGRAM, 0); CHECK(sock >= 0) << "Create socket error."; strncpy(ifr.ifr_name, device.c_str(), IFNAMSIZ); ifr.ifr_name[IFNAMSIZ - 1] = 0; CHECK_GE(ioctl(sock, SIOCGIFADDR, &ifr), 0); memcpy(&sin, &ifr.ifr_addr, sizeof(sin)); close(sock); return std::string(inet_ntoa(sin.sin_addr)); } /** * @brief set sock option * * @param[in] sockfd sock file descriptor * * @note adjust some default sock option for better performance */ void setOption(int sockfd) { #if !defined(__APPLE__) && !defined(__OSX__) int sendSize = FLAGS_sock_send_buf_size; int recvSize = FLAGS_sock_recv_buf_size; CHECK_GE( setsockopt(sockfd, SOL_SOCKET, SO_RCVBUF, &recvSize, sizeof(recvSize)), 0); CHECK_GE( setsockopt(sockfd, SOL_SOCKET, SO_SNDBUF, &sendSize, sizeof(sendSize)), 0); #endif if (FLAGS_small_messages) { int optval = 1; CHECK_GE( setsockopt(sockfd, IPPROTO_TCP, TCP_NODELAY, &optval, sizeof(optval)), 0); #ifdef TCP_QUICKACK optval = 1; CHECK_GE( setsockopt(sockfd, IPPROTO_TCP, TCP_QUICKACK, &optval, sizeof(optval)), 0); #endif } int reuse = 1; CHECK_GE(setsockopt(sockfd, SOL_SOCKET, SO_REUSEADDR, &reuse, sizeof(reuse)), 0); } /** * @brief class constructor for SocketServer * @param[in] addr sock bind address * @param[in] port sock bind port * @param[in] rdmaCpu rdma sock bind cpu core * * @note start one socket server which hosts parameter server process. * rdmaCpu is passed to rdma deamon for better performance, and * start tcp socket instead of rdma socket if rdmaCpu is equal * to -1. Each trainer process starts one connection to one socket * server, and use --ports_num to build more connections to harness * fat communication channel if necessary. * each connection is controlled by single thread with blocking * read and write. */ SocketServer::SocketServer(const std::string &addr, int port, int rdmaCpu) : port_(port), addr_(addr), stopping_(false) { if (rdmaCpu == -1) { tcpRdma_ = F_TCP; socket_ = 0; maxPendingConnections_ = 100; } else { tcpRdma_ = F_RDMA; rdmaCpu_ = rdmaCpu; rdmaSocket_ = 0; std::stringstream ss; ss << port; rdmaUri_ = "rdma://" + addr + ":" + ss.str(); } /// trigger to initialize RDMA lib PCHECK(RdmaClientDaemons::get()) << "initilizate RDMA failed\n"; } SocketServer::~SocketServer() { stopping_ = true; /// trigger accept thread to stop { SocketClient trigger(addr_.empty() ? "127.0.0.1" : addr_, port_, tcpRdma_); } this->join(); } /** * @brief start one tcp server which hosts parameter server * * @note do tcp socket bind and listen. it will spawn one thread * for each connection */ void SocketServer::tcpServer() { int newsockfd; socklen_t clilen; struct sockaddr_in serv_addr, cli_addr; struct hostent *server; /// First call to socket() function socket_ = socket(AF_INET, SOCK_STREAM, 0); PCHECK(socket_ >= 0) << "ERROR opening socket"; /// Initialize socket structure bzero((char *)&serv_addr, sizeof(serv_addr)); serv_addr.sin_family = AF_INET; serv_addr.sin_port = htons(port_); if (!addr_.empty()) { server = gethostbyname(addr_.c_str()); PCHECK(server) << "ERROR, no such host: " << addr_; bcopy((char *)server->h_addr, (char *)&serv_addr.sin_addr.s_addr, server->h_length); } else { serv_addr.sin_addr.s_addr = INADDR_ANY; } setOption(socket_); /// Now bind the host address using bind() call. PCHECK(bind(socket_, (struct sockaddr *)&serv_addr, sizeof(serv_addr)) >= 0) << "ERROR on binding " << addr_; /// Now start listening for the clients, here process will /// go in sleep mode and will wait for the incoming connection listen(socket_, maxPendingConnections_); clilen = sizeof(cli_addr); while (true) { /// Accept actual connection from the client newsockfd = accept(socket_, (struct sockaddr *)&cli_addr, &clilen); if (stopping_) { break; } PCHECK(newsockfd >= 0) << "ERROR on accept"; constexpr int kPeerNameLen = 128; char peerName[kPeerNameLen]; CHECK(inet_ntop(AF_INET, &cli_addr.sin_addr, peerName, kPeerNameLen)); SocketWorker *worker = new SocketWorker(createChannel(newsockfd, std::string(peerName)), this); worker->start(); worker->detach(); } close(socket_); LOG(INFO) << "pserver accept thread finish, addr=" << addr_ << " port=" << port_; } /** * @brief start one rdma server which hosts parameter server * * @note do rdma bind and listen, which calling self-defined socket * like rdma library. it will spawn one thread for each connection */ void SocketServer::rdmaServer() { struct sxi_sock *newsock; /// First call to socket() function rdmaSocket_ = rdma::ssocket(rdmaCpu_); PCHECK(rdmaSocket_) << "ERROR opening RDMA socket"; PCHECK(rdma::bind(rdmaSocket_, rdmaUri_.c_str()) == 0) << "ERROR bind RDMA socket"; /// Now start listening for the clients, here process will /// go in sleep mode and will wait for the incoming connection PCHECK(rdma::listen(rdmaSocket_) == 0) << "ERROR listen RDMA socket"; while (true) { /// Accept actual connection from the client newsock = rdma::accept(rdmaSocket_); if (stopping_) { break; } PCHECK(newsock) << "ERROR on accept"; constexpr int kPeerNameLen = 128; char peerName[kPeerNameLen]; struct sockaddr_in *saddr = rdma::getSourceAddress(newsock); CHECK(inet_ntop(AF_INET, &saddr->sin_addr, peerName, kPeerNameLen)); SocketWorker *worker = new SocketWorker(createChannel(newsock, std::string(peerName)), this); worker->start(); worker->detach(); } rdma::close(rdmaSocket_); LOG(INFO) << "pserver accept thread finish, rdma uri=" << rdmaUri_; } /** * @brief start a socket server * * @note framework for starting socket server */ void SocketServer::run() { if (tcpRdma_ == F_TCP) { LOG(INFO) << "tcp server start "; tcpServer(); } else if (tcpRdma_ == F_RDMA) { LOG(INFO) << "rdma server start "; rdmaServer(); } } /** * @brief class constructor for rdma client deamons * * @note automatically start several client deamons for better performance */ std::unique_ptr RdmaClientDaemons::daemons_ = nullptr; std::once_flag RdmaClientDaemons::initDataFlag_; RdmaClientDaemons::RdmaClientDaemons() { if (FLAGS_rdma_tcp == "rdma") { rdma::init(); struct sxi_socket *socket; onlineCpus_ = rdma::numCpus(); for (auto i = 0; i < onlineCpus_; i++) { socket = rdma::csocket(i); PCHECK(socket) << "ERROR open client socket daemon"; rdmaClientSocket_.push_back(socket); } LOG(INFO) << "RDMA client daemons started, onlineCpus_:" << onlineCpus_; /// round robin scheduler for new connection curCpu_ = 0; /// wait daemons to start completely. sleep(2); } } RdmaClientDaemons::~RdmaClientDaemons() { if (FLAGS_rdma_tcp == "rdma") { for (auto i = 0; i < onlineCpus_; i++) { rdma::close(rdmaClientSocket_[i]); } LOG(INFO) << "RDMA client daemons is destoryed, onlineCpus_ " << onlineCpus_; } } /** * @brief worker thread main context * * @note each connection from client(trainer) is controlled by single worker * thread, which is for handling all parameter server requests */ void SocketWorker::run() { LOG(INFO) << "worker started, peer = " << channel_->getPeerName(); std::vector inputIovs; while (true) { std::unique_ptr msgReader = channel_->readMessage(); if (!msgReader) { break; } auto callback = [this](const std::vector &outputIovs) { channel_->writeMessage(outputIovs); }; server_->handleRequest(std::move(msgReader), callback); } LOG(INFO) << "worker begin to finish, peer = " << channel_->getPeerName(); delete this; } /** * @brief start one tcp connection to tcp server * @param[in] serverAddr tcp server ip * @param[in] serverPort tcp server port * * @note each object contains one channel which accept byte stream */ void SocketClient::TcpClient(const std::string &serverAddr, int serverPort) { struct sockaddr_in serv_addr; struct hostent *server; int errRet; // temp for gethostbyname_r /// Create a socket point int sockfd = socket(AF_INET, SOCK_STREAM, 0); PCHECK(sockfd >= 0) << "ERROR opening socket"; #if defined(__OSX__) || defined(__APPLE__) server = getipnodebyname(serverAddr.c_str(), AF_INET, AI_DEFAULT, &errRet); CHECK_NE(HOST_NOT_FOUND, errRet) << "ERROR, no such host: " << serverAddr << " ret = " << errRet; CHECK(server) << "getipnodebyname error!"; #else struct hostent hostinfo; char buf[1024]; // temp for gethostbyname_r CHECK_EQ( 0, gethostbyname_r( serverAddr.c_str(), &hostinfo, buf, sizeof(buf), &server, &errRet)) << "ERROR, no such host: " << serverAddr << " ret = " << errRet; CHECK(server) << "gethostbyname_r error!"; #endif bzero((char *)&serv_addr, sizeof(serv_addr)); serv_addr.sin_family = AF_INET; bcopy((char *)server->h_addr, (char *)&serv_addr.sin_addr.s_addr, server->h_length); serv_addr.sin_port = htons(serverPort); setOption(sockfd); /// Now connect to the server PCHECK(connect(sockfd, (sockaddr *)&serv_addr, sizeof(serv_addr)) >= 0) << "ERROR connecting to " << serverAddr; channel_.reset(new SocketChannel(sockfd, serverAddr)); tcpRdma_ = F_TCP; } /** * @brief start one RDMA connection to rdma server * @param[in] serverAddr rdma server ip * @param[in] serverPort rdma server port * * @note each object contains one channel which accept byte stream * for rdma, low level sock also provide byte stream api. */ void SocketClient::RdmaClient(const std::string &serverAddr, int serverPort) { struct sxi_sock *sock; std::stringstream ss; ss << serverPort; std::string rdmaUri = "rdma://" + serverAddr + ":" + ss.str(); RdmaClientDaemons *daemons = RdmaClientDaemons::daemons_->get(); socketDaemon_ = daemons->selectDaemon(); /// connect to server with socket daemon sock = rdma::connect(socketDaemon_, rdmaUri.c_str()); PCHECK(sock) << "ERROR connect to server" << rdmaUri; std::vector seg; str::split(rdmaUri, '/', &seg); std::string server = seg.at(seg.size() - 1); channel_.reset(new SocketChannel(sock, server)); tcpRdma_ = F_RDMA; } /** * @brief class constructor * @param[in] serverAddr pserver ip address * @param[in] serverPort pserver port * @param[in] ChannelType F_TCP or F_RDMA * * @note responsible for building one connection to specified pserver port */ SocketClient::SocketClient(const std::string &serverAddr, int serverPort, enum ChannelType channelType) { if (channelType == F_RDMA) RdmaClient(serverAddr, serverPort); else TcpClient(serverAddr, serverPort); } } // namespace paddle