// Copyright Joyent, Inc. and other Node contributors. // // Permission is hereby granted, free of charge, to any person obtaining a // copy of this software and associated documentation files (the // "Software"), to deal in the Software without restriction, including // without limitation the rights to use, copy, modify, merge, publish, // distribute, sublicense, and/or sell copies of the Software, and to permit // persons to whom the Software is furnished to do so, subject to the // following conditions: // // The above copyright notice and this permission notice shall be included // in all copies or substantial portions of the Software. // // THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS // OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF // MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN // NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, // DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR // OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE // USE OR OTHER DEALINGS IN THE SOFTWARE. #include #include #include #include #include #include #include #include #include #include #ifdef __MINGW32__ # include # include #endif #ifdef __POSIX__ # include # include # include # include /* inet_pton */ # include # include # include #endif #ifdef __linux__ # include /* For the SIOCINQ / FIONREAD ioctl */ #endif /* Non-linux platforms like OS X define this ioctl elsewhere */ #ifndef FIONREAD # include #endif #ifdef __OpenBSD__ # include #endif /* * HACK to use inet_pton/inet_ntop from c-ares because mingw32 doesn't have it * This trick is used in node_ares.cc as well * TODO fixme */ #ifdef __MINGW32__ extern "C" { # include # include } # define inet_pton ares_inet_pton # define inet_ntop ares_inet_ntop #endif // SHUT_* constants aren't available on windows but there are 1:1 equivalents #ifdef __MINGW32__ # define SHUT_RD SD_RECEIVE # define SHUT_WR SD_SEND # define SHUT_RDWR SD_BOTH #endif #define ARRAY_SIZE(a) (sizeof(a) / sizeof(*(a))) namespace node { using namespace v8; static Persistent errno_symbol; static Persistent syscall_symbol; static Persistent fd_symbol; static Persistent size_symbol; static Persistent address_symbol; static Persistent port_symbol; static Persistent type_symbol; static Persistent tcp_symbol; static Persistent unix_symbol; static Persistent recv_msg_template; #define FD_ARG(a) \ int fd; \ if (!(a)->IsInt32() || (fd = (a)->Int32Value()) < 0) { \ return ThrowException(Exception::TypeError( \ String::New("Bad file descriptor argument"))); \ } static inline bool SetCloseOnExec(int fd) { #ifdef __POSIX__ return (fcntl(fd, F_SETFD, FD_CLOEXEC) != -1); #else // __MINGW32__ return SetHandleInformation(reinterpret_cast(_get_osfhandle(fd)), HANDLE_FLAG_INHERIT, 0) != 0; #endif } static inline bool SetNonBlock(int fd) { #ifdef __MINGW32__ unsigned long value = 1; return (ioctlsocket(_get_osfhandle(fd), FIONBIO, &value) == 0); #else // __POSIX__ return (fcntl(fd, F_SETFL, O_NONBLOCK) != -1); #endif } static inline bool SetSockFlags(int fd) { #ifdef __MINGW32__ BOOL flags = TRUE; setsockopt(_get_osfhandle(fd), SOL_SOCKET, SO_REUSEADDR, (const char *)&flags, sizeof(flags)); #else // __POSIX__ int flags = 1; setsockopt(fd, SOL_SOCKET, SO_REUSEADDR, (void *)&flags, sizeof(flags)); #endif return SetNonBlock(fd) && SetCloseOnExec(fd); } #ifdef __POSIX__ // Creates nonblocking pipe static Handle Pipe(const Arguments& args) { HandleScope scope; int fds[2]; if (pipe(fds) < 0) return ThrowException(ErrnoException(errno, "pipe")); if (!SetSockFlags(fds[0]) || !SetSockFlags(fds[1])) { int fcntl_errno = errno; close(fds[0]); close(fds[1]); return ThrowException(ErrnoException(fcntl_errno, "fcntl")); } Local a = Array::New(2); a->Set(Integer::New(0), Integer::New(fds[0])); a->Set(Integer::New(1), Integer::New(fds[1])); return scope.Close(a); } // Creates nonblocking socket pair static Handle SocketPair(const Arguments& args) { HandleScope scope; int fds[2]; // XXX support SOCK_DGRAM? if (socketpair(AF_UNIX, SOCK_STREAM, 0, fds) < 0) { return ThrowException(ErrnoException(errno, "socketpair")); } if (!SetSockFlags(fds[0]) || !SetSockFlags(fds[1])) { int fcntl_errno = errno; close(fds[0]); close(fds[1]); return ThrowException(ErrnoException(fcntl_errno, "fcntl")); } Local a = Array::New(2); a->Set(Integer::New(0), Integer::New(fds[0])); a->Set(Integer::New(1), Integer::New(fds[1])); return scope.Close(a); } #endif // Creates a new non-blocking socket fd // t.socket("TCP"); // t.socket("UNIX"); // t.socket("UDP"); static Handle Socket(const Arguments& args) { HandleScope scope; // default to TCP int domain = PF_INET; int type = SOCK_STREAM; #ifdef SO_REUSEPORT bool set_reuseport = false; #endif if (args[0]->IsString()) { String::Utf8Value t(args[0]->ToString()); // FIXME optimize this cascade. if (0 == strcasecmp(*t, "TCP")) { domain = PF_INET; type = SOCK_STREAM; } else if (0 == strcasecmp(*t, "TCP4")) { domain = PF_INET; type = SOCK_STREAM; } else if (0 == strcasecmp(*t, "TCP6")) { domain = PF_INET6; type = SOCK_STREAM; } else if (0 == strcasecmp(*t, "UNIX")) { domain = PF_UNIX; type = SOCK_STREAM; } else if (0 == strcasecmp(*t, "UNIX_DGRAM")) { domain = PF_UNIX; type = SOCK_DGRAM; } else if (0 == strcasecmp(*t, "UDP")) { domain = PF_INET; type = SOCK_DGRAM; #ifdef SO_REUSEPORT set_reuseport = true; #endif } else if (0 == strcasecmp(*t, "UDP4")) { domain = PF_INET; type = SOCK_DGRAM; #ifdef SO_REUSEPORT set_reuseport = true; #endif } else if (0 == strcasecmp(*t, "UDP6")) { domain = PF_INET6; type = SOCK_DGRAM; #ifdef SO_REUSEPORT set_reuseport = true; #endif } else { return ThrowException(Exception::Error( String::New("Unknown socket type."))); } } #ifdef __POSIX__ int fd = socket(domain, type, 0); #else // __MINGW32__ int fd = _open_osfhandle(socket(domain, type, 0), 0); #endif if (fd < 0) return ThrowException(ErrnoException(errno, "socket")); if (!SetSockFlags(fd)) { int fcntl_errno = errno; close(fd); return ThrowException(ErrnoException(fcntl_errno, "fcntl")); } #ifdef SO_REUSEPORT // needed for datagrams to be able to have multiple processes listening to // e.g. broadcasted datagrams. if (set_reuseport) { int flags = 1; setsockopt(fd, SOL_SOCKET, SO_REUSEPORT, (const char *)&flags, sizeof(flags)); } #endif return scope.Close(Integer::New(fd)); } // NOT AT ALL THREAD SAFE - but that's okay for node.js // (yes this is all to avoid one small heap alloc) static struct sockaddr *addr; static socklen_t addrlen; static inline Handle ParseAddressArgs(Handle first, Handle second, bool is_bind) { static struct sockaddr_in in; static struct sockaddr_in6 in6; #ifdef __POSIX__ // No unix sockets on windows static struct sockaddr_un un; if (first->IsString() && !second->IsString()) { // UNIX String::Utf8Value path(first->ToString()); if ((size_t) path.length() >= ARRAY_SIZE(un.sun_path)) { return Exception::Error(String::New("Socket path too long")); } memset(&un, 0, sizeof un); un.sun_family = AF_UNIX; memcpy(un.sun_path, *path, path.length()); addr = (struct sockaddr*)&un; addrlen = sizeof(un) - sizeof(un.sun_path) + path.length() + 1; } else { #else // __MINGW32__ if (first->IsString() && !second->IsString()) { return ErrnoException(errno, "ParseAddressArgs", "Unix sockets are not supported on windows"); } else { #endif // TCP or UDP memset(&in, 0, sizeof in); memset(&in6, 0, sizeof in6); int port = first->Int32Value(); in.sin_port = in6.sin6_port = htons(port); in.sin_family = AF_INET; in6.sin6_family = AF_INET6; bool is_ipv4 = true; if (!second->IsString()) { in.sin_addr.s_addr = htonl(is_bind ? INADDR_ANY : INADDR_LOOPBACK); in6.sin6_addr = is_bind ? in6addr_any : in6addr_loopback; } else { String::Utf8Value ip(second->ToString()); if (inet_pton(AF_INET, *ip, &(in.sin_addr)) <= 0) { is_ipv4 = false; if (inet_pton(AF_INET6, *ip, &(in6.sin6_addr)) <= 0) { return ErrnoException(errno, "inet_pton", "Invalid IP Address"); } } } addr = is_ipv4 ? (struct sockaddr*)&in : (struct sockaddr*)&in6; addrlen = is_ipv4 ? sizeof in : sizeof in6; } return Handle(); } // Bind with UNIX // t.bind(fd, "/tmp/socket") // Bind with TCP // t.bind(fd, 80, "192.168.11.2") // t.bind(fd, 80) static Handle Bind(const Arguments& args) { HandleScope scope; if (args.Length() < 2) { return ThrowException(Exception::TypeError( String::New("Must have at least two args"))); } FD_ARG(args[0]) Handle error = ParseAddressArgs(args[1], args[2], true); if (!error.IsEmpty()) return ThrowException(error); int flags = 1; #ifdef __POSIX__ setsockopt(fd, SOL_SOCKET, SO_REUSEADDR, (void *)&flags, sizeof(flags)); if (0 > bind(fd, addr, addrlen)) { return ThrowException(ErrnoException(errno, "bind")); } #else // __MINGW32__ SOCKET handle = _get_osfhandle(fd); setsockopt(handle, SOL_SOCKET, SO_REUSEADDR, (char *)&flags, sizeof(flags)); if (SOCKET_ERROR == bind(handle, addr, addrlen)) { return ThrowException(ErrnoException(WSAGetLastError(), "bind")); } #endif // __MINGW32__ return Undefined(); } static Handle Close(const Arguments& args) { HandleScope scope; FD_ARG(args[0]) // Windows: this is not a winsock operation, don't use _get_osfhandle here! if (0 > close(fd)) { return ThrowException(ErrnoException(errno, "close")); } return Undefined(); } // t.shutdown(fd, "read"); -- SHUT_RD // t.shutdown(fd, "write"); -- SHUT_WR // t.shutdown(fd, "readwrite"); -- SHUT_RDWR // second arg defaults to "write". static Handle Shutdown(const Arguments& args) { HandleScope scope; FD_ARG(args[0]) int how = SHUT_WR; if (args[1]->IsString()) { String::Utf8Value t(args[1]->ToString()); if (0 == strcasecmp(*t, "write")) { how = SHUT_WR; } else if (0 == strcasecmp(*t, "read")) { how = SHUT_RD; } else if (0 == strcasecmp(*t, "readwrite")) { how = SHUT_RDWR; } else { return ThrowException(Exception::Error(String::New( "Unknown shutdown method. (Use 'read', 'write', or 'readwrite'.)"))); } } #ifdef __POSIX__ if (0 > shutdown(fd, how)) { return ThrowException(ErrnoException(errno, "shutdown")); } #else // __MINGW32__ if (SOCKET_ERROR == shutdown(_get_osfhandle(fd), how)) { return ThrowException(ErrnoException(WSAGetLastError(), "shutdown")); } #endif // __MINGW32__ return Undefined(); } // Connect with unix // t.connect(fd, "/tmp/socket") // // Connect with TCP or UDP // t.connect(fd, 80, "192.168.11.2") // t.connect(fd, 80, "::1") // t.connect(fd, 80) // the third argument defaults to "::1" static Handle Connect(const Arguments& args) { HandleScope scope; if (args.Length() < 2) { return ThrowException(Exception::TypeError( String::New("Must have at least two args"))); } FD_ARG(args[0]) Handle error = ParseAddressArgs(args[1], args[2], false); if (!error.IsEmpty()) return ThrowException(error); #ifdef __POSIX__ int r = connect(fd, addr, addrlen); if (r < 0 && errno != EINPROGRESS) { return ThrowException(ErrnoException(errno, "connect")); } #else // __MINGW32__ int r = connect(_get_osfhandle(fd), addr, addrlen); if (r == SOCKET_ERROR) { int wsaErrno = WSAGetLastError(); if (wsaErrno != WSAEWOULDBLOCK && wsaErrno != WSAEINPROGRESS) { return ThrowException(ErrnoException(wsaErrno, "connect")); } } #endif // __MINGW32__ return Undefined(); } #ifdef __POSIX__ #define ADDRESS_TO_JS(info, address_storage, addrlen) \ do { \ char ip[INET6_ADDRSTRLEN]; \ int port; \ struct sockaddr_in *a4; \ struct sockaddr_in6 *a6; \ struct sockaddr_un *au; \ if (addrlen == 0) { \ (info)->Set(address_symbol, String::Empty()); \ } else { \ switch ((address_storage).ss_family) { \ case AF_INET6: \ a6 = (struct sockaddr_in6*)&(address_storage); \ inet_ntop(AF_INET6, &(a6->sin6_addr), ip, INET6_ADDRSTRLEN); \ port = ntohs(a6->sin6_port); \ (info)->Set(address_symbol, String::New(ip)); \ (info)->Set(port_symbol, Integer::New(port)); \ break; \ case AF_INET: \ a4 = (struct sockaddr_in*)&(address_storage); \ inet_ntop(AF_INET, &(a4->sin_addr), ip, INET6_ADDRSTRLEN); \ port = ntohs(a4->sin_port); \ (info)->Set(address_symbol, String::New(ip)); \ (info)->Set(port_symbol, Integer::New(port)); \ break; \ case AF_UNIX: \ /* * Three types of addresses (see man 7 unix): * * unnamed: sizeof(sa_family_t) (sun_path should not be used) * * abstract (Linux extension): sizeof(struct sockaddr_un) * * pathname: sizeof(sa_family_t) + strlen(sun_path) + 1 */ \ au = (struct sockaddr_un*)&(address_storage); \ if (addrlen == sizeof(sa_family_t)) { \ (info)->Set(address_symbol, String::Empty()); \ } else if (addrlen == sizeof(struct sockaddr_un)) { \ /* first byte is '\0' and all remaining bytes are name; * it is not NUL-terminated and may contain embedded NULs */ \ (info)->Set(address_symbol, String::New(au->sun_path + 1, sizeof(au->sun_path - 1))); \ } else { \ (info)->Set(address_symbol, String::New(au->sun_path)); \ } \ break; \ default: \ (info)->Set(address_symbol, String::Empty()); \ } \ } \ } while (0) #else // __MINGW32__ #define ADDRESS_TO_JS(info, address_storage, addrlen) \ do { \ char ip[INET6_ADDRSTRLEN]; \ int port; \ struct sockaddr_in *a4; \ struct sockaddr_in6 *a6; \ if (addrlen == 0) { \ (info)->Set(address_symbol, String::Empty()); \ } else { \ switch ((address_storage).ss_family) { \ case AF_INET6: \ a6 = (struct sockaddr_in6*)&(address_storage); \ inet_ntop(AF_INET6, &(a6->sin6_addr), ip, INET6_ADDRSTRLEN); \ port = ntohs(a6->sin6_port); \ (info)->Set(address_symbol, String::New(ip)); \ (info)->Set(port_symbol, Integer::New(port)); \ break; \ case AF_INET: \ a4 = (struct sockaddr_in*)&(address_storage); \ inet_ntop(AF_INET, &(a4->sin_addr), ip, INET6_ADDRSTRLEN); \ port = ntohs(a4->sin_port); \ (info)->Set(address_symbol, String::New(ip)); \ (info)->Set(port_symbol, Integer::New(port)); \ break; \ default: \ (info)->Set(address_symbol, String::Empty()); \ } \ } \ } while (0) #endif // __MINGW32__ static Handle GetSockName(const Arguments& args) { HandleScope scope; FD_ARG(args[0]) struct sockaddr_storage address_storage; socklen_t len = sizeof(struct sockaddr_storage); #ifdef __POSIX__ if (0 > getsockname(fd, (struct sockaddr *) &address_storage, &len)) { return ThrowException(ErrnoException(errno, "getsockname")); } #else // __MINGW32__ if (SOCKET_ERROR == getsockname(_get_osfhandle(fd), (struct sockaddr *) &address_storage, &len)) { return ThrowException(ErrnoException(WSAGetLastError(), "getsockname")); } #endif // __MINGW32__ Local info = Object::New(); ADDRESS_TO_JS(info, address_storage, len); return scope.Close(info); } static Handle GetPeerName(const Arguments& args) { HandleScope scope; FD_ARG(args[0]) struct sockaddr_storage address_storage; socklen_t len = sizeof(struct sockaddr_storage); #ifdef __POSIX__ if (0 > getpeername(fd, (struct sockaddr *) &address_storage, &len)) { return ThrowException(ErrnoException(errno, "getpeername")); } #else // __MINGW32__ if (SOCKET_ERROR == getpeername(_get_osfhandle(fd), (struct sockaddr *) &address_storage, &len)) { return ThrowException(ErrnoException(WSAGetLastError(), "getpeername")); } #endif // __MINGW32__ Local info = Object::New(); ADDRESS_TO_JS(info, address_storage, len); return scope.Close(info); } static Handle Listen(const Arguments& args) { HandleScope scope; FD_ARG(args[0]) int backlog = args[1]->IsInt32() ? args[1]->Int32Value() : 128; #ifdef __POSIX__ if (0 > listen(fd, backlog)) { return ThrowException(ErrnoException(errno, "listen")); } #else // __MINGW32__ if (SOCKET_ERROR == listen(_get_osfhandle(fd), backlog)) { return ThrowException(ErrnoException(WSAGetLastError(), "listen")); } #endif return Undefined(); } // var peerInfo = t.accept(server_fd); // // peerInfo.fd // peerInfo.address // peerInfo.port // // Returns a new nonblocking socket fd. If the listen queue is empty the // function returns null (wait for server_fd to become readable and try // again) static Handle Accept(const Arguments& args) { HandleScope scope; FD_ARG(args[0]) struct sockaddr_storage address_storage; socklen_t len = sizeof(struct sockaddr_storage); #ifdef __POSIX__ int peer_fd = accept(fd, (struct sockaddr*) &address_storage, &len); if (peer_fd < 0) { if (errno == EAGAIN) return scope.Close(Null()); if (errno == ECONNABORTED) return scope.Close(Null()); return ThrowException(ErrnoException(errno, "accept")); } #else // __MINGW32__ SOCKET peer_handle = accept(_get_osfhandle(fd), (struct sockaddr*) &address_storage, &len); if (peer_handle == INVALID_SOCKET) { int wsaErrno = WSAGetLastError(); if (wsaErrno == WSAEWOULDBLOCK) return scope.Close(Null()); return ThrowException(ErrnoException(wsaErrno, "accept")); } int peer_fd = _open_osfhandle(peer_handle, 0); #endif // __MINGW32__ if (!SetSockFlags(peer_fd)) { #ifdef __POSIX__ int fcntl_errno = errno; #else // __MINGW32__ int fcntl_errno = WSAGetLastError(); #endif // __MINGW32__ close(peer_fd); return ThrowException(ErrnoException(fcntl_errno, "fcntl")); } Local peer_info = Object::New(); peer_info->Set(fd_symbol, Integer::New(peer_fd)); ADDRESS_TO_JS(peer_info, address_storage, len); return scope.Close(peer_info); } static Handle SocketError(const Arguments& args) { HandleScope scope; FD_ARG(args[0]) int error; socklen_t len = sizeof(int); #ifdef __POSIX__ int r = getsockopt(fd, SOL_SOCKET, SO_ERROR, &error, &len); if (r < 0) { return ThrowException(ErrnoException(errno, "getsockopt")); } #else // __MINGW32__ int r = getsockopt(_get_osfhandle(fd), SOL_SOCKET, SO_ERROR, (char*)&error, &len); if (r < 0) { return ThrowException(ErrnoException(WSAGetLastError(), "getsockopt")); } #endif return scope.Close(Integer::New(error)); } // var bytesRead = t.read(fd, buffer, offset, length); // returns null on EAGAIN or EINTR, raises an exception on all other errors // returns 0 on EOF. static Handle Read(const Arguments& args) { HandleScope scope; if (args.Length() < 4) { return ThrowException(Exception::TypeError( String::New("Takes 4 parameters"))); } FD_ARG(args[0]) if (!Buffer::HasInstance(args[1])) { return ThrowException(Exception::TypeError( String::New("Second argument should be a buffer"))); } Local buffer_obj = args[1]->ToObject(); char *buffer_data = Buffer::Data(buffer_obj); size_t buffer_length = Buffer::Length(buffer_obj); size_t off = args[2]->Int32Value(); if (off >= buffer_length) { return ThrowException(Exception::Error( String::New("Offset is out of bounds"))); } size_t len = args[3]->Int32Value(); if (off + len > buffer_length) { return ThrowException(Exception::Error( String::New("Length is extends beyond buffer"))); } #ifdef __POSIX__ ssize_t bytes_read = read(fd, (char*)buffer_data + off, len); if (bytes_read < 0) { if (errno == EAGAIN || errno == EINTR) return Null(); return ThrowException(ErrnoException(errno, "read")); } #else // __MINGW32__ // read() doesn't work for overlapped sockets (the only usable // type of sockets) so recv() is used here. ssize_t bytes_read = recv(_get_osfhandle(fd), (char*)buffer_data + off, len, 0); if (bytes_read < 0) { int wsaErrno = WSAGetLastError(); if (wsaErrno == WSAEWOULDBLOCK || wsaErrno == WSAEINTR) return Null(); return ThrowException(ErrnoException(wsaErrno, "read")); } #endif return scope.Close(Integer::New(bytes_read)); } // var info = t.recvfrom(fd, buffer, offset, length, flags); // info.size // bytes read // info.port // from port // info.address // from address // returns null on EAGAIN or EINTR, raises an exception on all other errors // returns object otherwise static Handle RecvFrom(const Arguments& args) { HandleScope scope; if (args.Length() < 5) { return ThrowException(Exception::TypeError( String::New("Takes 5 parameters"))); } FD_ARG(args[0]) if (!Buffer::HasInstance(args[1])) { return ThrowException(Exception::TypeError( String::New("Second argument should be a buffer"))); } Local buffer_obj = args[1]->ToObject(); char *buffer_data = Buffer::Data(buffer_obj); size_t buffer_length = Buffer::Length(buffer_obj); size_t off = args[2]->Int32Value(); if (off >= buffer_length) { return ThrowException(Exception::Error( String::New("Offset is out of bounds"))); } size_t len = args[3]->Int32Value(); if (off + len > buffer_length) { return ThrowException(Exception::Error( String::New("Length is extends beyond buffer"))); } int flags = args[4]->Int32Value(); struct sockaddr_storage address_storage; socklen_t addrlen = sizeof(struct sockaddr_storage); #ifdef __POSIX__ ssize_t bytes_read = recvfrom(fd, (char*)buffer_data + off, len, flags, (struct sockaddr*) &address_storage, &addrlen); if (bytes_read < 0) { if (errno == EAGAIN || errno == EINTR) return Null(); return ThrowException(ErrnoException(errno, "read")); } #else // __MINGW32__ ssize_t bytes_read = recvfrom(_get_osfhandle(fd), (char*)buffer_data + off, len, flags, (struct sockaddr*) &address_storage, &addrlen); if (bytes_read == SOCKET_ERROR) { int wsaErrno = WSAGetLastError(); if (wsaErrno == WSAEWOULDBLOCK || wsaErrno == WSAEINTR) return Null(); return ThrowException(ErrnoException(wsaErrno, "read")); } #endif Local info = Object::New(); info->Set(size_symbol, Integer::New(bytes_read)); ADDRESS_TO_JS(info, address_storage, addrlen); return scope.Close(info); } #ifdef __POSIX__ // bytesRead = t.recvMsg(fd, buffer, offset, length) // if (recvMsg.fd) { // receivedFd = recvMsg.fd; // } static Handle RecvMsg(const Arguments& args) { HandleScope scope; if (args.Length() < 4) { return ThrowException(Exception::TypeError( String::New("Takes 4 parameters"))); } FD_ARG(args[0]) if (!Buffer::HasInstance(args[1])) { return ThrowException(Exception::TypeError( String::New("Second argument should be a buffer"))); } Local buffer_obj = args[1]->ToObject(); char *buffer_data = Buffer::Data(buffer_obj); size_t buffer_length = Buffer::Length(buffer_obj); size_t off = args[2]->Int32Value(); if (off >= buffer_length) { return ThrowException(Exception::Error( String::New("Offset is out of bounds"))); } size_t len = args[3]->Int32Value(); if (off + len > buffer_length) { return ThrowException(Exception::Error( String::New("Length is extends beyond buffer"))); } struct iovec iov[1]; iov[0].iov_base = (char*)buffer_data + off; iov[0].iov_len = len; struct msghdr msg; msg.msg_flags = 0; msg.msg_iov = iov; msg.msg_iovlen = 1; msg.msg_name = NULL; msg.msg_namelen = 0; /* Set up to receive a descriptor even if one isn't in the message */ char cmsg_space[64]; // should be big enough msg.msg_controllen = 64; msg.msg_control = (void *) cmsg_space; ssize_t bytes_read = recvmsg(fd, &msg, 0); if (bytes_read < 0) { if (errno == EAGAIN || errno == EINTR) return Null(); return ThrowException(ErrnoException(errno, "recvMsg")); } // Why not return a two element array here [bytesRead, fd]? Because // creating an object for each recvmsg() action is heavy. Instead we just // assign the recved fd to a globalally accessable variable (recvMsg.fd) // that the wrapper can pick up. Since we're single threaded, this is not // a problem - just make sure to copy out that variable before the next // call to recvmsg(). // // XXX: Some implementations can send multiple file descriptors in a // single message. We should be using CMSG_NXTHDR() to walk the // chain to get at them all. This would require changing the // API to hand these back up the caller, is a pain. int received_fd = -1; for (struct cmsghdr *cmsg = CMSG_FIRSTHDR(&msg); msg.msg_controllen > 0 && cmsg != NULL; cmsg = CMSG_NXTHDR(&msg, cmsg)) { if (cmsg->cmsg_type == SCM_RIGHTS) { if (received_fd != -1) { fprintf(stderr, "ignoring extra FD received: %d\n", received_fd); } received_fd = *(int *) CMSG_DATA(cmsg); } else { fprintf(stderr, "ignoring non-SCM_RIGHTS ancillary data: %d\n", cmsg->cmsg_type ); } } recv_msg_template->GetFunction()->Set( fd_symbol, (received_fd != -1) ? Integer::New(received_fd) : Null() ); return scope.Close(Integer::New(bytes_read)); } #endif // __POSIX__ // var bytesWritten = t.write(fd, buffer, offset, length); // returns null on EAGAIN or EINTR, raises an exception on all other errors static Handle Write(const Arguments& args) { HandleScope scope; if (args.Length() < 4) { return ThrowException(Exception::TypeError( String::New("Takes 4 parameters"))); } FD_ARG(args[0]) if (!Buffer::HasInstance(args[1])) { return ThrowException(Exception::TypeError( String::New("Second argument should be a buffer"))); } Local buffer_obj = args[1]->ToObject(); char *buffer_data = Buffer::Data(buffer_obj); size_t buffer_length = Buffer::Length(buffer_obj); size_t off = args[2]->Int32Value(); if (off >= buffer_length) { return ThrowException(Exception::Error( String::New("Offset is out of bounds"))); } size_t len = args[3]->Int32Value(); if (off + len > buffer_length) { return ThrowException(Exception::Error( String::New("Length is extends beyond buffer"))); } #ifdef __POSIX__ ssize_t written = write(fd, buffer_data + off, len); if (written < 0) { if (errno == EAGAIN || errno == EINTR) { return scope.Close(Integer::New(0)); } return ThrowException(ErrnoException(errno, "write")); } #else // __MINGW32__ // write() doesn't work for overlapped sockets (the only usable // type of sockets) so send() is used. ssize_t written = send(_get_osfhandle(fd), buffer_data + off, len, 0); if (written < 0) { int wsaErrno = WSAGetLastError(); if (wsaErrno == WSAEWOULDBLOCK || wsaErrno == WSAEINTR) { return scope.Close(Integer::New(0)); } return ThrowException(ErrnoException(wsaErrno, "write")); } #endif // __MINGW32__ return scope.Close(Integer::New(written)); } #ifdef __POSIX__ // var bytes = sendmsg(fd, buf, off, len, fd, flags); // // Write a buffer with optional offset and length to the given file // descriptor. Note that we refuse to send 0 bytes. // // The 'fd' parameter is a numerical file descriptor, or the undefined value // to send none. // // The 'flags' parameter is a number representing a bitmask of MSG_* values. // This is passed directly to sendmsg(). // // Returns null on EAGAIN or EINTR, raises an exception on all other errors static Handle SendMsg(const Arguments& args) { HandleScope scope; struct iovec iov; if (args.Length() < 2) { return ThrowException(Exception::TypeError( String::New("Takes 2 parameters"))); } // The first argument should be a file descriptor FD_ARG(args[0]) // Grab the actul data to be written, stuffing it into iov if (!Buffer::HasInstance(args[1])) { return ThrowException(Exception::TypeError( String::New("Expected either a string or a buffer"))); } Local buffer_obj = args[1]->ToObject(); char *buffer_data = Buffer::Data(buffer_obj); size_t buffer_length = Buffer::Length(buffer_obj); size_t offset = 0; if (args.Length() >= 3 && !args[2]->IsUndefined()) { if (!args[2]->IsUint32()) { return ThrowException(Exception::TypeError( String::New("Expected unsigned integer for offset"))); } offset = args[2]->Uint32Value(); if (offset >= buffer_length) { return ThrowException(Exception::Error( String::New("Offset into buffer too large"))); } } size_t length = buffer_length - offset; if (args.Length() >= 4 && !args[3]->IsUndefined()) { if (!args[3]->IsUint32()) { return ThrowException(Exception::TypeError( String::New("Expected unsigned integer for length"))); } length = args[3]->Uint32Value(); if (offset + length > buffer_length) { return ThrowException(Exception::Error( String::New("offset + length beyond buffer length"))); } } iov.iov_base = buffer_data + offset; iov.iov_len = length; int fd_to_send = -1; if (args.Length() >= 5 && !args[4]->IsUndefined()) { if (!args[4]->IsUint32()) { return ThrowException(Exception::TypeError( String::New("Expected unsigned integer for a file descriptor"))); } fd_to_send = args[4]->Uint32Value(); } int flags = 0; if (args.Length() >= 6 && !args[5]->IsUndefined()) { if (!args[5]->IsUint32()) { return ThrowException(Exception::TypeError( String::New("Expected unsigned integer for a flags argument"))); } flags = args[5]->Uint32Value(); } struct msghdr msg; char scratch[64]; msg.msg_iov = &iov; msg.msg_iovlen = 1; msg.msg_name = NULL; msg.msg_namelen = 0; msg.msg_flags = 0; msg.msg_control = NULL; msg.msg_controllen = 0; if (fd_to_send >= 0) { struct cmsghdr *cmsg; msg.msg_control = (void *) scratch; msg.msg_controllen = CMSG_LEN(sizeof(fd_to_send)); cmsg = CMSG_FIRSTHDR(&msg); cmsg->cmsg_level = SOL_SOCKET; cmsg->cmsg_type = SCM_RIGHTS; cmsg->cmsg_len = msg.msg_controllen; *(int*) CMSG_DATA(cmsg) = fd_to_send; } ssize_t written = sendmsg(fd, &msg, flags); if (written < 0) { if (errno == EAGAIN || errno == EINTR) return Null(); return ThrowException(ErrnoException(errno, "sendmsg")); } /* Note that the FD isn't explicitly closed here, this * happens in the JS */ return scope.Close(Integer::New(written)); } #endif // __POSIX__ // var bytes = sendto(fd, buf, off, len, flags, destination port, desitnation address); // // Write a buffer with optional offset and length to the given file // descriptor. Note that we refuse to send 0 bytes. // // The 'fd' parameter is a numerical file descriptor, or the undefined value // to send none. // // The 'flags' parameter is a number representing a bitmask of MSG_* values. // This is passed directly to sendmsg(). // // The destination port can either be an int port, or a path. // // Returns null on EAGAIN or EINTR, raises an exception on all other errors static Handle SendTo(const Arguments& args) { HandleScope scope; if (args.Length() < 5) { return ThrowException(Exception::TypeError( String::New("Takes 5 or 6 parameters"))); } // The first argument should be a file descriptor FD_ARG(args[0]) // Grab the actul data to be written if (!Buffer::HasInstance(args[1])) { return ThrowException(Exception::TypeError( String::New("Expected either a string or a buffer"))); } Local buffer_obj = args[1]->ToObject(); char *buffer_data = Buffer::Data(buffer_obj); size_t buffer_length = Buffer::Length(buffer_obj); size_t offset = 0; if (args.Length() >= 3 && !args[2]->IsUndefined()) { if (!args[2]->IsUint32()) { return ThrowException(Exception::TypeError( String::New("Expected unsigned integer for offset"))); } offset = args[2]->Uint32Value(); if (offset >= buffer_length) { return ThrowException(Exception::Error( String::New("Offset into buffer too large"))); } } size_t length = buffer_length - offset; if (args.Length() >= 4 && !args[3]->IsUndefined()) { if (!args[3]->IsUint32()) { return ThrowException(Exception::TypeError( String::New("Expected unsigned integer for length"))); } length = args[3]->Uint32Value(); if (offset + length > buffer_length) { return ThrowException(Exception::Error( String::New("offset + length beyond buffer length"))); } } int flags = 0; if (args.Length() >= 5 && !args[4]->IsUndefined()) { if (!args[4]->IsUint32()) { return ThrowException(Exception::TypeError( String::New("Expected unsigned integer for a flags argument"))); } flags = args[4]->Uint32Value(); } Handle error = ParseAddressArgs(args[5], args[6], false); if (!error.IsEmpty()) return ThrowException(error); #ifdef __POSIX__ ssize_t written = sendto(fd, buffer_data + offset, length, flags, addr, addrlen); if (written < 0) { if (errno == EAGAIN || errno == EINTR) return Null(); return ThrowException(ErrnoException(errno, "sendto")); } #else // __MINGW32__ ssize_t written = sendto(_get_osfhandle(fd), buffer_data + offset, length, flags, addr, addrlen); if (written == SOCKET_ERROR) { int wsaErrno = WSAGetLastError(); if (wsaErrno == WSAEWOULDBLOCK || wsaErrno == WSAEINTR) return Null(); return ThrowException(ErrnoException(wsaErrno, "sendto")); } #endif // __MINGW32__ /* Note that the FD isn't explicitly closed here, this * happens in the JS */ return scope.Close(Integer::New(written)); } // Probably only works for Linux TCP sockets? // Returns the amount of data on the read queue. static Handle ToRead(const Arguments& args) { HandleScope scope; FD_ARG(args[0]) #ifdef __POSIX__ int value; if (0 > ioctl(fd, FIONREAD, &value)) { return ThrowException(ErrnoException(errno, "ioctl")); } #else // __MINGW32__ unsigned long value; if (SOCKET_ERROR == ioctlsocket(_get_osfhandle(fd), FIONREAD, &value)) { return ThrowException(ErrnoException(WSAGetLastError(), "ioctlsocket")); } #endif // __MINGW32__ return scope.Close(Integer::New(value)); } static Handle SetNoDelay(const Arguments& args) { HandleScope scope; FD_ARG(args[0]) #ifdef __POSIX__ int flags = args[1]->IsFalse() ? 0 : 1; if (0 > setsockopt(fd, IPPROTO_TCP, TCP_NODELAY, (void *)&flags, sizeof(flags))) { return ThrowException(ErrnoException(errno, "setsockopt")); } #else // __MINGW32__ BOOL flags = args[1]->IsFalse() ? FALSE : TRUE; if (SOCKET_ERROR == setsockopt(_get_osfhandle(fd), IPPROTO_TCP, TCP_NODELAY, (const char *)&flags, sizeof(flags))) { return ThrowException(ErrnoException(WSAGetLastError(), "setsockopt")); } #endif // __MINGW32__ return Undefined(); } static Handle SetKeepAlive(const Arguments& args) { int r; HandleScope scope; bool enable = false; int time = 0; FD_ARG(args[0]) if (args.Length() > 0) enable = args[1]->IsTrue(); if (enable == true) { time = args[2]->Int32Value(); } #ifdef __POSIX__ int flags = enable ? 1 : 0; r = setsockopt(fd, SOL_SOCKET, SO_KEEPALIVE, (void *)&flags, sizeof(flags)); if ((time > 0)&&(r >= 0)) { #if defined(__APPLE__) r = setsockopt(fd, IPPROTO_TCP, TCP_KEEPALIVE, (void *)&time, sizeof(time)); #elif defined(__linux__) r = setsockopt(fd, IPPROTO_TCP, TCP_KEEPIDLE, (void *)&time, sizeof(time)); #else // Solaris nor FreeBSD support TCP_KEEPIDLE, so do nothing here. #endif } if (r < 0) { return ThrowException(ErrnoException(errno, "setsockopt")); } #else // __MINGW32__ SOCKET handle = (SOCKET)_get_osfhandle(fd); BOOL flags = enable ? TRUE : FALSE; r = setsockopt(handle, SOL_SOCKET, SO_KEEPALIVE, (const char *)&flags, sizeof(flags)); // Could set the timeout here, using WSAIoctl(SIO_KEEPALIVE_VALS), // but ryah thinks it is not necessary, and mingw is missing mstcpip.h anyway. if (r == SOCKET_ERROR) { return ThrowException(ErrnoException(WSAGetLastError(), "setsockopt")); } #endif return Undefined(); } static Handle SetBroadcast(const Arguments& args) { HandleScope scope; FD_ARG(args[0]) #ifdef __POSIX__ int flags = args[1]->IsFalse() ? 0 : 1; if (0 > setsockopt(fd, SOL_SOCKET, SO_BROADCAST, (void *)&flags, sizeof(flags))) { return ThrowException(ErrnoException(errno, "setsockopt")); } #else // __MINGW32__ BOOL flags = args[1]->IsFalse() ? FALSE : TRUE; if (SOCKET_ERROR == setsockopt(_get_osfhandle(fd), SOL_SOCKET, SO_BROADCAST, (const char *)&flags, sizeof(flags))) { return ThrowException(ErrnoException(WSAGetLastError(), "setsockopt")); } #endif return Undefined(); } static Handle SetTTL(const Arguments& args) { HandleScope scope; #ifdef __POSIX__ int newttl; #else // __MINGW32__ DWORD newttl; #endif if (args.Length() != 2) { return ThrowException(Exception::TypeError( String::New("Takes exactly two arguments: fd, new TTL"))); } FD_ARG(args[0]); if (!args[1]->IsInt32()) { return ThrowException(Exception::TypeError( String::New("Argument must be a number"))); } newttl = args[1]->Int32Value(); if (newttl < 1 || newttl > 255) { return ThrowException(Exception::TypeError( String::New("new TTL must be between 1 and 255"))); } #ifdef __POSIX__ int r = setsockopt(fd, IPPROTO_IP, IP_TTL, reinterpret_cast(&newttl), sizeof(newttl)); if (r < 0) { return ThrowException(ErrnoException(errno, "setsockopt")); } #else // __MINGW32__ if (SOCKET_ERROR > setsockopt(_get_osfhandle(fd), IPPROTO_IP, IP_TTL, (const char *)&newttl, sizeof(newttl))) { return ThrowException(ErrnoException(WSAGetLastError(), "setsockopt")); } #endif // __MINGW32__ return scope.Close(Integer::New(newttl)); } #ifdef __POSIX__ static Handle SetMulticastTTL(const Arguments& args) { HandleScope scope; if (args.Length() != 2) { return ThrowException(Exception::TypeError( String::New("Takes exactly two arguments: fd, new MulticastTTL"))); } FD_ARG(args[0]); if (!args[1]->IsInt32()) { return ThrowException(Exception::TypeError( String::New("Argument must be a number"))); } int newttl = args[1]->Int32Value(); if (newttl < 0 || newttl > 255) { return ThrowException(Exception::TypeError( String::New("new MulticastTTL must be between 0 and 255"))); } int r = setsockopt(fd, IPPROTO_IP, IP_MULTICAST_TTL, reinterpret_cast(&newttl), sizeof(newttl)); if (r < 0) { return ThrowException(ErrnoException(errno, "setsockopt")); } else { return scope.Close(Integer::New(newttl)); } } static Handle SetMulticastLoopback(const Arguments& args) { int flags, r; HandleScope scope; FD_ARG(args[0]) flags = args[1]->IsFalse() ? 0 : 1; r = setsockopt(fd, IPPROTO_IP, IP_MULTICAST_LOOP, reinterpret_cast(&flags), sizeof(flags)); if (r < 0) { return ThrowException(ErrnoException(errno, "setsockopt")); } else { return scope.Close(Integer::New(flags)); } } static Handle SetMembership(const Arguments& args, int socketOption) { HandleScope scope; if (args.Length() < 2 || args.Length() > 3) { return ThrowException(Exception::TypeError( String::New("Takes arguments: fd, multicast group, multicast address"))); } FD_ARG(args[0]); struct ip_mreq mreq; memset(&mreq, 0, sizeof(mreq)); // Multicast address (arg[1]) String::Utf8Value multicast_address(args[1]->ToString()); if (inet_pton( AF_INET, *multicast_address, &(mreq.imr_multiaddr.s_addr)) <= 0) { return ErrnoException(errno, "inet_pton", "Invalid multicast address"); } // Interface address (arg[2] - optional, default:INADDR_ANY) if (args.Length() < 3 || !args[2]->IsString()) { mreq.imr_interface.s_addr = htonl(INADDR_ANY); } else { String::Utf8Value multicast_interface(args[2]->ToString()); if (inet_pton( AF_INET, *multicast_interface, &(mreq.imr_interface.s_addr)) <= 0) { return ErrnoException(errno, "inet_pton", "Invalid multicast interface"); } } int r = setsockopt(fd, IPPROTO_IP, socketOption, reinterpret_cast(&mreq), sizeof(mreq)); if (r < 0) { return ThrowException(ErrnoException(errno, "setsockopt")); } else { return Undefined(); } } static Handle AddMembership(const Arguments& args) { return SetMembership(args, IP_ADD_MEMBERSHIP); } static Handle DropMembership(const Arguments& args) { return SetMembership(args, IP_DROP_MEMBERSHIP); } #endif // __POSIX__ // // G E T A D D R I N F O // struct resolve_request { Persistent cb; struct addrinfo *address_list; int ai_family; // AF_INET or AF_INET6 char hostname[1]; }; #ifndef EAI_NODATA // EAI_NODATA is deprecated, FreeBSD already thrown it away in favor of EAI_NONAME #define EAI_NODATA EAI_NONAME #endif static int AfterResolve(eio_req *req) { ev_unref(EV_DEFAULT_UC); struct resolve_request * rreq = (struct resolve_request *)(req->data); HandleScope scope; Local argv[2]; if (req->result != 0) { argv[1] = Array::New(); if (req->result == EAI_NODATA) { argv[0] = Local::New(Null()); } else { argv[0] = ErrnoException(req->result, "getaddrinfo", gai_strerror(req->result)); } } else { struct addrinfo *address; int n = 0; for (address = rreq->address_list; address; address = address->ai_next) { n++; } Local results = Array::New(n); char ip[INET6_ADDRSTRLEN]; const char *addr; n = 0; address = rreq->address_list; while (address) { assert(address->ai_socktype == SOCK_STREAM); assert(address->ai_family == AF_INET || address->ai_family == AF_INET6); addr = ( address->ai_family == AF_INET ? (char *) &((struct sockaddr_in *) address->ai_addr)->sin_addr : (char *) &((struct sockaddr_in6 *) address->ai_addr)->sin6_addr ); const char *c = inet_ntop(address->ai_family, addr, ip, INET6_ADDRSTRLEN); Local s = String::New(c); results->Set(Integer::New(n), s); n++; address = address->ai_next; } argv[0] = Local::New(Null()); argv[1] = results; } TryCatch try_catch; rreq->cb->Call(Context::GetCurrent()->Global(), 2, argv); if (try_catch.HasCaught()) { FatalException(try_catch); } if (rreq->address_list) freeaddrinfo(rreq->address_list); rreq->cb.Dispose(); // Dispose of the persistent handle free(rreq); return 0; } static int Resolve(eio_req *req) { // Note: this function is executed in the thread pool! CAREFUL struct resolve_request * rreq = (struct resolve_request *) req->data; struct addrinfo hints; memset(&hints, 0, sizeof(struct addrinfo)); hints.ai_family = rreq->ai_family; hints.ai_socktype = SOCK_STREAM; req->result = getaddrinfo((char*)rreq->hostname, NULL, &hints, &(rreq->address_list)); return 0; } static Handle GetAddrInfo(const Arguments& args) { HandleScope scope; String::Utf8Value hostname(args[0]->ToString()); int type = args[1]->Int32Value(); int fam = AF_INET; switch (type) { case 4: fam = AF_INET; break; case 6: fam = AF_INET6; break; default: return ThrowException(Exception::TypeError( String::New("Second argument must be an integer 4 or 6"))); } if (!args[2]->IsFunction()) { return ThrowException(Exception::TypeError( String::New("Thrid argument must be a callback"))); } Local cb = Local::Cast(args[2]); struct resolve_request *rreq = (struct resolve_request *) calloc(1, sizeof(struct resolve_request) + hostname.length() + 1); if (!rreq) { V8::LowMemoryNotification(); return ThrowException(Exception::Error( String::New("Could not allocate enough memory"))); } strncpy(rreq->hostname, *hostname, hostname.length() + 1); rreq->cb = Persistent::New(cb); rreq->ai_family = fam; // For the moment I will do DNS lookups in the eio thread pool. This is // sub-optimal and cannot handle massive numbers of requests. // // (One particularly annoying problem is that the pthread stack size needs // to be increased dramatically to handle getaddrinfo() see X_STACKSIZE in // wscript ). // // In the future I will move to a system using c-ares: // http://lists.schmorp.de/pipermail/libev/2009q1/000632.html eio_custom(Resolve, EIO_PRI_DEFAULT, AfterResolve, rreq); // There will not be any active watchers from this object on the event // loop while getaddrinfo() runs. If the only thing happening in the // script was this hostname resolution, then the event loop would drop // out. Thus we need to add ev_ref() until AfterResolve(). ev_ref(EV_DEFAULT_UC); return Undefined(); } static Handle IsIP(const Arguments& args) { HandleScope scope; if (!args[0]->IsString()) { return scope.Close(Integer::New(4)); } String::Utf8Value s(args[0]->ToString()); // avoiding buffer overflows in the following strcat // 2001:0db8:85a3:08d3:1319:8a2e:0370:7334 // 39 = max ipv6 address. if (s.length() > INET6_ADDRSTRLEN) { return scope.Close(Integer::New(0)); } struct sockaddr_in6 a; if (inet_pton(AF_INET, *s, &(a.sin6_addr)) > 0) return scope.Close(Integer::New(4)); if (inet_pton(AF_INET6, *s, &(a.sin6_addr)) > 0) return scope.Close(Integer::New(6)); return scope.Close(Integer::New(0)); } static Handle CreateErrnoException(const Arguments& args) { HandleScope scope; int errorno = args[0]->Int32Value(); String::Utf8Value syscall(args[1]->ToString()); Local exception = ErrnoException(errorno, *syscall); return scope.Close(exception); } void InitNet(Handle target) { HandleScope scope; NODE_SET_METHOD(target, "write", Write); NODE_SET_METHOD(target, "read", Read); NODE_SET_METHOD(target, "sendto", SendTo); NODE_SET_METHOD(target, "recvfrom", RecvFrom); #ifdef __POSIX__ NODE_SET_METHOD(target, "sendMsg", SendMsg); recv_msg_template = Persistent::New(FunctionTemplate::New(RecvMsg)); target->Set(String::NewSymbol("recvMsg"), recv_msg_template->GetFunction()); #endif //__POSIX__ NODE_SET_METHOD(target, "socket", Socket); NODE_SET_METHOD(target, "close", Close); NODE_SET_METHOD(target, "shutdown", Shutdown); #ifdef __POSIX__ NODE_SET_METHOD(target, "pipe", Pipe); NODE_SET_METHOD(target, "socketpair", SocketPair); #endif // __POSIX__ NODE_SET_METHOD(target, "connect", Connect); NODE_SET_METHOD(target, "bind", Bind); NODE_SET_METHOD(target, "listen", Listen); NODE_SET_METHOD(target, "accept", Accept); NODE_SET_METHOD(target, "socketError", SocketError); NODE_SET_METHOD(target, "toRead", ToRead); NODE_SET_METHOD(target, "setNoDelay", SetNoDelay); NODE_SET_METHOD(target, "setBroadcast", SetBroadcast); NODE_SET_METHOD(target, "setTTL", SetTTL); NODE_SET_METHOD(target, "setKeepAlive", SetKeepAlive); #ifdef __POSIX__ NODE_SET_METHOD(target, "setMulticastTTL", SetMulticastTTL); NODE_SET_METHOD(target, "setMulticastLoopback", SetMulticastLoopback); NODE_SET_METHOD(target, "addMembership", AddMembership); NODE_SET_METHOD(target, "dropMembership", DropMembership); #endif // __POSIX__ NODE_SET_METHOD(target, "getsockname", GetSockName); NODE_SET_METHOD(target, "getpeername", GetPeerName); NODE_SET_METHOD(target, "getaddrinfo", GetAddrInfo); NODE_SET_METHOD(target, "isIP", IsIP); NODE_SET_METHOD(target, "errnoException", CreateErrnoException); errno_symbol = NODE_PSYMBOL("errno"); syscall_symbol = NODE_PSYMBOL("syscall"); fd_symbol = NODE_PSYMBOL("fd"); size_symbol = NODE_PSYMBOL("size"); address_symbol = NODE_PSYMBOL("address"); port_symbol = NODE_PSYMBOL("port"); } } // namespace node NODE_MODULE(node_net, node::InitNet);