/*! * Copyright (c) 2014-2019 by Contributors * \file socket.h * \brief this file aims to provide a wrapper of sockets * \author Tianqi Chen */ #ifndef RABIT_INTERNAL_SOCKET_H_ #define RABIT_INTERNAL_SOCKET_H_ #if defined(_WIN32) #include #include #ifdef _MSC_VER #pragma comment(lib, "Ws2_32.lib") #endif // _MSC_VER #else #include #include #include #include #include #include #include #include #endif // defined(_WIN32) #include #include #include #include #include "utils.h" #if defined(_WIN32) || defined(__MINGW32__) typedef int ssize_t; #endif // defined(_WIN32) || defined(__MINGW32__) #if defined(_WIN32) typedef int sock_size_t; static inline int poll(struct pollfd *pfd, int nfds, int timeout) { return WSAPoll ( pfd, nfds, timeout ); } #else #include typedef int SOCKET; typedef size_t sock_size_t; const int INVALID_SOCKET = -1; #endif // defined(_WIN32) namespace rabit { namespace utils { /*! \brief data structure for network address */ struct SockAddr { sockaddr_in addr; // constructor SockAddr(void) {} SockAddr(const char *url, int port) { this->Set(url, port); } inline static std::string GetHostName(void) { std::string buf; buf.resize(256); utils::Check(gethostname(&buf[0], 256) != -1, "fail to get host name"); return std::string(buf.c_str()); } /*! * \brief set the address * \param url the url of the address * \param port the port of address */ inline void Set(const char *host, int port) { addrinfo hints; memset(&hints, 0, sizeof(hints)); hints.ai_family = AF_INET; hints.ai_protocol = SOCK_STREAM; addrinfo *res = NULL; int sig = getaddrinfo(host, NULL, &hints, &res); Check(sig == 0 && res != NULL, "cannot obtain address of %s", host); Check(res->ai_family == AF_INET, "Does not support IPv6"); memcpy(&addr, res->ai_addr, res->ai_addrlen); addr.sin_port = htons(port); freeaddrinfo(res); } /*! \brief return port of the address*/ inline int port(void) const { return ntohs(addr.sin_port); } /*! \return a string representation of the address */ inline std::string AddrStr(void) const { std::string buf; buf.resize(256); #ifdef _WIN32 const char *s = inet_ntop(AF_INET, (PVOID)&addr.sin_addr, &buf[0], buf.length()); #else const char *s = inet_ntop(AF_INET, &addr.sin_addr, &buf[0], buf.length()); #endif // _WIN32 Assert(s != NULL, "cannot decode address"); return std::string(s); } }; /*! * \brief base class containing common operations of TCP and UDP sockets */ class Socket { public: /*! \brief the file descriptor of socket */ SOCKET sockfd; // default conversion to int inline operator SOCKET() const { return sockfd; } /*! * \return last error of socket operation */ inline static int GetLastError(void) { #ifdef _WIN32 return WSAGetLastError(); #else return errno; #endif // _WIN32 } /*! \return whether last error was would block */ inline static bool LastErrorWouldBlock(void) { int errsv = GetLastError(); #ifdef _WIN32 return errsv == WSAEWOULDBLOCK; #else return errsv == EAGAIN || errsv == EWOULDBLOCK; #endif // _WIN32 } /*! * \brief start up the socket module * call this before using the sockets */ inline static void Startup(void) { #ifdef _WIN32 WSADATA wsa_data; if (WSAStartup(MAKEWORD(2, 2), &wsa_data) == -1) { Socket::Error("Startup"); } if (LOBYTE(wsa_data.wVersion) != 2 || HIBYTE(wsa_data.wVersion) != 2) { WSACleanup(); utils::Error("Could not find a usable version of Winsock.dll\n"); } #endif // _WIN32 } /*! * \brief shutdown the socket module after use, all sockets need to be closed */ inline static void Finalize(void) { #ifdef _WIN32 WSACleanup(); #endif // _WIN32 } /*! * \brief set this socket to use non-blocking mode * \param non_block whether set it to be non-block, if it is false * it will set it back to block mode */ inline void SetNonBlock(bool non_block) { #ifdef _WIN32 u_long mode = non_block ? 1 : 0; if (ioctlsocket(sockfd, FIONBIO, &mode) != NO_ERROR) { Socket::Error("SetNonBlock"); } #else int flag = fcntl(sockfd, F_GETFL, 0); if (flag == -1) { Socket::Error("SetNonBlock-1"); } if (non_block) { flag |= O_NONBLOCK; } else { flag &= ~O_NONBLOCK; } if (fcntl(sockfd, F_SETFL, flag) == -1) { Socket::Error("SetNonBlock-2"); } #endif // _WIN32 } /*! * \brief bind the socket to an address * \param addr */ inline void Bind(const SockAddr &addr) { if (bind(sockfd, reinterpret_cast(&addr.addr), sizeof(addr.addr)) == -1) { Socket::Error("Bind"); } } /*! * \brief try bind the socket to host, from start_port to end_port * \param start_port starting port number to try * \param end_port ending port number to try * \return the port successfully bind to, return -1 if failed to bind any port */ inline int TryBindHost(int start_port, int end_port) { // TODO(tqchen) add prefix check for (int port = start_port; port < end_port; ++port) { SockAddr addr("0.0.0.0", port); if (bind(sockfd, reinterpret_cast(&addr.addr), sizeof(addr.addr)) == 0) { return port; } #if defined(_WIN32) if (WSAGetLastError() != WSAEADDRINUSE) { Socket::Error("TryBindHost"); } #else if (errno != EADDRINUSE) { Socket::Error("TryBindHost"); } #endif // defined(_WIN32) } return -1; } /*! \brief get last error code if any */ inline int GetSockError(void) const { int error = 0; socklen_t len = sizeof(error); if (getsockopt(sockfd, SOL_SOCKET, SO_ERROR, reinterpret_cast(&error), &len) != 0) { Error("GetSockError"); } return error; } /*! \brief check if anything bad happens */ inline bool BadSocket(void) const { if (IsClosed()) return true; int err = GetSockError(); if (err == EBADF || err == EINTR) return true; return false; } /*! \brief check if socket is already closed */ inline bool IsClosed(void) const { return sockfd == INVALID_SOCKET; } /*! \brief close the socket */ inline void Close(void) { if (sockfd != INVALID_SOCKET) { #ifdef _WIN32 closesocket(sockfd); #else close(sockfd); #endif sockfd = INVALID_SOCKET; } else { Error("Socket::Close double close the socket or close without create"); } } // report an socket error inline static void Error(const char *msg) { int errsv = GetLastError(); #ifdef _WIN32 utils::Error("Socket %s Error:WSAError-code=%d", msg, errsv); #else utils::Error("Socket %s Error:%s", msg, strerror(errsv)); #endif } protected: explicit Socket(SOCKET sockfd) : sockfd(sockfd) { } }; /*! * \brief a wrapper of TCP socket that hopefully be cross platform */ class TCPSocket : public Socket{ public: // constructor TCPSocket(void) : Socket(INVALID_SOCKET) { } explicit TCPSocket(SOCKET sockfd) : Socket(sockfd) { } /*! * \brief enable/disable TCP keepalive * \param keepalive whether to set the keep alive option on */ void SetKeepAlive(bool keepalive) { int opt = static_cast(keepalive); if (setsockopt(sockfd, SOL_SOCKET, SO_KEEPALIVE, reinterpret_cast(&opt), sizeof(opt)) < 0) { Socket::Error("SetKeepAlive"); } } inline void SetLinger(int timeout = 0) { struct linger sl; sl.l_onoff = 1; /* non-zero value enables linger option in kernel */ sl.l_linger = timeout; /* timeout interval in seconds */ if (setsockopt(sockfd, SOL_SOCKET, SO_LINGER, reinterpret_cast(&sl), sizeof(sl)) == -1) { Socket::Error("SO_LINGER"); } } /*! * \brief create the socket, call this before using socket * \param af domain */ inline void Create(int af = PF_INET) { sockfd = socket(PF_INET, SOCK_STREAM, 0); if (sockfd == INVALID_SOCKET) { Socket::Error("Create"); } } /*! * \brief perform listen of the socket * \param backlog backlog parameter */ inline void Listen(int backlog = 16) { listen(sockfd, backlog); } /*! \brief get a new connection */ TCPSocket Accept(void) { SOCKET newfd = accept(sockfd, NULL, NULL); if (newfd == INVALID_SOCKET) { Socket::Error("Accept"); } return TCPSocket(newfd); } /*! * \brief decide whether the socket is at OOB mark * \return 1 if at mark, 0 if not, -1 if an error occured */ inline int AtMark(void) const { #ifdef _WIN32 unsigned long atmark; // NOLINT(*) if (ioctlsocket(sockfd, SIOCATMARK, &atmark) != NO_ERROR) return -1; #else int atmark; if (ioctl(sockfd, SIOCATMARK, &atmark) == -1) return -1; #endif // _WIN32 return static_cast(atmark); } /*! * \brief connect to an address * \param addr the address to connect to * \return whether connect is successful */ inline bool Connect(const SockAddr &addr) { return connect(sockfd, reinterpret_cast(&addr.addr), sizeof(addr.addr)) == 0; } /*! * \brief send data using the socket * \param buf the pointer to the buffer * \param len the size of the buffer * \param flags extra flags * \return size of data actually sent * return -1 if error occurs */ inline ssize_t Send(const void *buf_, size_t len, int flag = 0) { const char *buf = reinterpret_cast(buf_); return send(sockfd, buf, static_cast(len), flag); } /*! * \brief receive data using the socket * \param buf_ the pointer to the buffer * \param len the size of the buffer * \param flags extra flags * \return size of data actually received * return -1 if error occurs */ inline ssize_t Recv(void *buf_, size_t len, int flags = 0) { char *buf = reinterpret_cast(buf_); return recv(sockfd, buf, static_cast(len), flags); } /*! * \brief peform block write that will attempt to send all data out * can still return smaller than request when error occurs * \param buf the pointer to the buffer * \param len the size of the buffer * \return size of data actually sent */ inline size_t SendAll(const void *buf_, size_t len) { const char *buf = reinterpret_cast(buf_); size_t ndone = 0; while (ndone < len) { ssize_t ret = send(sockfd, buf, static_cast(len - ndone), 0); if (ret == -1) { if (LastErrorWouldBlock()) return ndone; Socket::Error("SendAll"); } buf += ret; ndone += ret; } return ndone; } /*! * \brief peforma block read that will attempt to read all data * can still return smaller than request when error occurs * \param buf_ the buffer pointer * \param len length of data to recv * \return size of data actually sent */ inline size_t RecvAll(void *buf_, size_t len) { char *buf = reinterpret_cast(buf_); size_t ndone = 0; while (ndone < len) { ssize_t ret = recv(sockfd, buf, static_cast(len - ndone), MSG_WAITALL); if (ret == -1) { if (LastErrorWouldBlock()) return ndone; Socket::Error("RecvAll"); } if (ret == 0) return ndone; buf += ret; ndone += ret; } return ndone; } /*! * \brief send a string over network * \param str the string to be sent */ inline void SendStr(const std::string &str) { int len = static_cast(str.length()); utils::Assert(this->SendAll(&len, sizeof(len)) == sizeof(len), "error during send SendStr"); if (len != 0) { utils::Assert(this->SendAll(str.c_str(), str.length()) == str.length(), "error during send SendStr"); } } /*! * \brief recv a string from network * \param out_str the string to receive */ inline void RecvStr(std::string *out_str) { int len; utils::Assert(this->RecvAll(&len, sizeof(len)) == sizeof(len), "error during send RecvStr"); out_str->resize(len); if (len != 0) { utils::Assert(this->RecvAll(&(*out_str)[0], len) == out_str->length(), "error during send SendStr"); } } }; /*! \brief helper data structure to perform poll */ struct PollHelper { public: /*! * \brief add file descriptor to watch for read * \param fd file descriptor to be watched */ inline void WatchRead(SOCKET fd) { auto& pfd = fds[fd]; pfd.fd = fd; pfd.events |= POLLIN; } /*! * \brief add file descriptor to watch for write * \param fd file descriptor to be watched */ inline void WatchWrite(SOCKET fd) { auto& pfd = fds[fd]; pfd.fd = fd; pfd.events |= POLLOUT; } /*! * \brief add file descriptor to watch for exception * \param fd file descriptor to be watched */ inline void WatchException(SOCKET fd) { auto& pfd = fds[fd]; pfd.fd = fd; pfd.events |= POLLPRI; } /*! * \brief Check if the descriptor is ready for read * \param fd file descriptor to check status */ inline bool CheckRead(SOCKET fd) const { const auto& pfd = fds.find(fd); return pfd != fds.end() && ((pfd->second.events & POLLIN) != 0); } /*! * \brief Check if the descriptor is ready for write * \param fd file descriptor to check status */ inline bool CheckWrite(SOCKET fd) const { const auto& pfd = fds.find(fd); return pfd != fds.end() && ((pfd->second.events & POLLOUT) != 0); } /*! * \brief Check if the descriptor has any exception * \param fd file descriptor to check status */ inline bool CheckExcept(SOCKET fd) const { const auto& pfd = fds.find(fd); return pfd != fds.end() && ((pfd->second.events & POLLPRI) != 0); } /*! * \brief wait for exception event on a single descriptor * \param fd the file descriptor to wait the event for * \param timeout the timeout counter, can be negative, which means wait until the event happen * \return 1 if success, 0 if timeout, and -1 if error occurs */ inline static int WaitExcept(SOCKET fd, long timeout = -1) { // NOLINT(*) pollfd pfd; pfd.fd = fd; pfd.events = POLLPRI; return poll(&pfd, 1, timeout); } /*! * \brief peform poll on the set defined, read, write, exception * \param timeout specify timeout in milliseconds(ms) if negative, means poll will block * \return */ inline void Poll(long timeout = -1) { // NOLINT(*) std::vector fdset; fdset.reserve(fds.size()); for (auto kv : fds) { fdset.push_back(kv.second); } int ret = poll(fdset.data(), fdset.size(), timeout); if (ret == -1) { Socket::Error("Poll"); } else { for (auto& pfd : fdset) { auto revents = pfd.revents & pfd.events; if (!revents) { fds.erase(pfd.fd); } else { fds[pfd.fd].events = revents; } } } } std::unordered_map fds; }; } // namespace utils } // namespace rabit #endif // RABIT_INTERNAL_SOCKET_H_