/* Copyright Joyent, Inc. and other Node contributors. All rights reserved. * * 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 "uv.h" #include "internal.h" #include "handle-inl.h" #include "stream-inl.h" #include "req-inl.h" /* * Threshold of active tcp streams for which to preallocate tcp read buffers. * (Due to node slab allocator performing poorly under this pattern, * the optimization is temporarily disabled (threshold=0). This will be * revisited once node allocator is improved.) */ const unsigned int uv_active_tcp_streams_threshold = 0; /* * Number of simultaneous pending AcceptEx calls. */ const unsigned int uv_simultaneous_server_accepts = 32; /* A zero-size buffer for use by uv_tcp_read */ static char uv_zero_[] = ""; static int uv__tcp_nodelay(uv_tcp_t* handle, SOCKET socket, int enable) { if (setsockopt(socket, IPPROTO_TCP, TCP_NODELAY, (const char*)&enable, sizeof enable) == -1) { return WSAGetLastError(); } return 0; } static int uv__tcp_keepalive(uv_tcp_t* handle, SOCKET socket, int enable, unsigned int delay) { if (setsockopt(socket, SOL_SOCKET, SO_KEEPALIVE, (const char*)&enable, sizeof enable) == -1) { return WSAGetLastError(); } if (enable && setsockopt(socket, IPPROTO_TCP, TCP_KEEPALIVE, (const char*)&delay, sizeof delay) == -1) { return WSAGetLastError(); } return 0; } static int uv_tcp_set_socket(uv_loop_t* loop, uv_tcp_t* handle, SOCKET socket, int family, int imported) { DWORD yes = 1; int non_ifs_lsp; int err; assert(handle->socket == INVALID_SOCKET); /* Set the socket to nonblocking mode */ if (ioctlsocket(socket, FIONBIO, &yes) == SOCKET_ERROR) { return WSAGetLastError(); } /* Associate it with the I/O completion port. */ /* Use uv_handle_t pointer as completion key. */ if (CreateIoCompletionPort((HANDLE)socket, loop->iocp, (ULONG_PTR)socket, 0) == NULL) { if (imported) { handle->flags |= UV_HANDLE_EMULATE_IOCP; } else { return GetLastError(); } } if (family == AF_INET6) { non_ifs_lsp = uv_tcp_non_ifs_lsp_ipv6; } else { non_ifs_lsp = uv_tcp_non_ifs_lsp_ipv4; } if (pSetFileCompletionNotificationModes && !(handle->flags & UV_HANDLE_EMULATE_IOCP) && !non_ifs_lsp) { if (pSetFileCompletionNotificationModes((HANDLE) socket, FILE_SKIP_SET_EVENT_ON_HANDLE | FILE_SKIP_COMPLETION_PORT_ON_SUCCESS)) { handle->flags |= UV_HANDLE_SYNC_BYPASS_IOCP; } else if (GetLastError() != ERROR_INVALID_FUNCTION) { return GetLastError(); } } if (handle->flags & UV_HANDLE_TCP_NODELAY) { err = uv__tcp_nodelay(handle, socket, 1); if (err) return err; } /* TODO: Use stored delay. */ if (handle->flags & UV_HANDLE_TCP_KEEPALIVE) { err = uv__tcp_keepalive(handle, socket, 1, 60); if (err) return err; } handle->socket = socket; if (family == AF_INET6) { handle->flags |= UV_HANDLE_IPV6; } else { assert(!(handle->flags & UV_HANDLE_IPV6)); } return 0; } int uv_tcp_init(uv_loop_t* loop, uv_tcp_t* handle) { uv_stream_init(loop, (uv_stream_t*) handle, UV_TCP); handle->accept_reqs = NULL; handle->pending_accepts = NULL; handle->socket = INVALID_SOCKET; handle->reqs_pending = 0; handle->func_acceptex = NULL; handle->func_connectex = NULL; handle->processed_accepts = 0; return 0; } void uv_tcp_endgame(uv_loop_t* loop, uv_tcp_t* handle) { int err; unsigned int i; uv_tcp_accept_t* req; if (handle->flags & UV_HANDLE_CONNECTION && handle->shutdown_req != NULL && handle->write_reqs_pending == 0) { UNREGISTER_HANDLE_REQ(loop, handle, handle->shutdown_req); err = 0; if (handle->flags & UV__HANDLE_CLOSING) { err = ERROR_OPERATION_ABORTED; } else if (shutdown(handle->socket, SD_SEND) == SOCKET_ERROR) { err = WSAGetLastError(); } if (handle->shutdown_req->cb) { handle->shutdown_req->cb(handle->shutdown_req, uv_translate_sys_error(err)); } handle->shutdown_req = NULL; DECREASE_PENDING_REQ_COUNT(handle); return; } if (handle->flags & UV__HANDLE_CLOSING && handle->reqs_pending == 0) { assert(!(handle->flags & UV_HANDLE_CLOSED)); if (!(handle->flags & UV_HANDLE_TCP_SOCKET_CLOSED)) { closesocket(handle->socket); handle->flags |= UV_HANDLE_TCP_SOCKET_CLOSED; } if (!(handle->flags & UV_HANDLE_CONNECTION) && handle->accept_reqs) { if (handle->flags & UV_HANDLE_EMULATE_IOCP) { for (i = 0; i < uv_simultaneous_server_accepts; i++) { req = &handle->accept_reqs[i]; if (req->wait_handle != INVALID_HANDLE_VALUE) { UnregisterWait(req->wait_handle); req->wait_handle = INVALID_HANDLE_VALUE; } if (req->event_handle) { CloseHandle(req->event_handle); req->event_handle = NULL; } } } free(handle->accept_reqs); handle->accept_reqs = NULL; } if (handle->flags & UV_HANDLE_CONNECTION && handle->flags & UV_HANDLE_EMULATE_IOCP) { if (handle->read_req.wait_handle != INVALID_HANDLE_VALUE) { UnregisterWait(handle->read_req.wait_handle); handle->read_req.wait_handle = INVALID_HANDLE_VALUE; } if (handle->read_req.event_handle) { CloseHandle(handle->read_req.event_handle); handle->read_req.event_handle = NULL; } } uv__handle_close(handle); loop->active_tcp_streams--; } } static int uv_tcp_try_bind(uv_tcp_t* handle, const struct sockaddr* addr, unsigned int addrlen, unsigned int flags) { DWORD err; int r; if (handle->socket == INVALID_SOCKET) { SOCKET sock = socket(addr->sa_family, SOCK_STREAM, 0); if (sock == INVALID_SOCKET) { return WSAGetLastError(); } /* Make the socket non-inheritable */ if (!SetHandleInformation((HANDLE) sock, HANDLE_FLAG_INHERIT, 0)) { err = GetLastError(); closesocket(sock); return err; } err = uv_tcp_set_socket(handle->loop, handle, sock, addr->sa_family, 0); if (err) { closesocket(sock); return err; } } #ifdef IPV6_V6ONLY if (addr->sa_family == AF_INET6) { int on; on = (flags & UV_TCP_IPV6ONLY) != 0; /* TODO: how to handle errors? This may fail if there is no ipv4 stack */ /* available, or when run on XP/2003 which have no support for dualstack */ /* sockets. For now we're silently ignoring the error. */ setsockopt(handle->socket, IPPROTO_IPV6, IPV6_V6ONLY, &on, sizeof on); } #endif r = bind(handle->socket, addr, addrlen); if (r == SOCKET_ERROR) { err = WSAGetLastError(); if (err == WSAEADDRINUSE) { /* Some errors are not to be reported until connect() or listen() */ handle->bind_error = err; handle->flags |= UV_HANDLE_BIND_ERROR; } else { return err; } } handle->flags |= UV_HANDLE_BOUND; return 0; } static void CALLBACK post_completion(void* context, BOOLEAN timed_out) { uv_req_t* req; uv_tcp_t* handle; req = (uv_req_t*) context; assert(req != NULL); handle = (uv_tcp_t*)req->data; assert(handle != NULL); assert(!timed_out); if (!PostQueuedCompletionStatus(handle->loop->iocp, req->overlapped.InternalHigh, 0, &req->overlapped)) { uv_fatal_error(GetLastError(), "PostQueuedCompletionStatus"); } } static void CALLBACK post_write_completion(void* context, BOOLEAN timed_out) { uv_write_t* req; uv_tcp_t* handle; req = (uv_write_t*) context; assert(req != NULL); handle = (uv_tcp_t*)req->handle; assert(handle != NULL); assert(!timed_out); if (!PostQueuedCompletionStatus(handle->loop->iocp, req->overlapped.InternalHigh, 0, &req->overlapped)) { uv_fatal_error(GetLastError(), "PostQueuedCompletionStatus"); } } static void uv_tcp_queue_accept(uv_tcp_t* handle, uv_tcp_accept_t* req) { uv_loop_t* loop = handle->loop; BOOL success; DWORD bytes; SOCKET accept_socket; short family; assert(handle->flags & UV_HANDLE_LISTENING); assert(req->accept_socket == INVALID_SOCKET); /* choose family and extension function */ if (handle->flags & UV_HANDLE_IPV6) { family = AF_INET6; } else { family = AF_INET; } /* Open a socket for the accepted connection. */ accept_socket = socket(family, SOCK_STREAM, 0); if (accept_socket == INVALID_SOCKET) { SET_REQ_ERROR(req, WSAGetLastError()); uv_insert_pending_req(loop, (uv_req_t*)req); handle->reqs_pending++; return; } /* Make the socket non-inheritable */ if (!SetHandleInformation((HANDLE) accept_socket, HANDLE_FLAG_INHERIT, 0)) { SET_REQ_ERROR(req, GetLastError()); uv_insert_pending_req(loop, (uv_req_t*)req); handle->reqs_pending++; closesocket(accept_socket); return; } /* Prepare the overlapped structure. */ memset(&(req->overlapped), 0, sizeof(req->overlapped)); if (handle->flags & UV_HANDLE_EMULATE_IOCP) { req->overlapped.hEvent = (HANDLE) ((ULONG_PTR) req->event_handle | 1); } success = handle->func_acceptex(handle->socket, accept_socket, (void*)req->accept_buffer, 0, sizeof(struct sockaddr_storage), sizeof(struct sockaddr_storage), &bytes, &req->overlapped); if (UV_SUCCEEDED_WITHOUT_IOCP(success)) { /* Process the req without IOCP. */ req->accept_socket = accept_socket; handle->reqs_pending++; uv_insert_pending_req(loop, (uv_req_t*)req); } else if (UV_SUCCEEDED_WITH_IOCP(success)) { /* The req will be processed with IOCP. */ req->accept_socket = accept_socket; handle->reqs_pending++; if (handle->flags & UV_HANDLE_EMULATE_IOCP && req->wait_handle == INVALID_HANDLE_VALUE && !RegisterWaitForSingleObject(&req->wait_handle, req->event_handle, post_completion, (void*) req, INFINITE, WT_EXECUTEINWAITTHREAD)) { SET_REQ_ERROR(req, GetLastError()); uv_insert_pending_req(loop, (uv_req_t*)req); handle->reqs_pending++; return; } } else { /* Make this req pending reporting an error. */ SET_REQ_ERROR(req, WSAGetLastError()); uv_insert_pending_req(loop, (uv_req_t*)req); handle->reqs_pending++; /* Destroy the preallocated client socket. */ closesocket(accept_socket); /* Destroy the event handle */ if (handle->flags & UV_HANDLE_EMULATE_IOCP) { CloseHandle(req->overlapped.hEvent); req->event_handle = NULL; } } } static void uv_tcp_queue_read(uv_loop_t* loop, uv_tcp_t* handle) { uv_read_t* req; uv_buf_t buf; int result; DWORD bytes, flags; assert(handle->flags & UV_HANDLE_READING); assert(!(handle->flags & UV_HANDLE_READ_PENDING)); req = &handle->read_req; memset(&req->overlapped, 0, sizeof(req->overlapped)); /* * Preallocate a read buffer if the number of active streams is below * the threshold. */ if (loop->active_tcp_streams < uv_active_tcp_streams_threshold) { handle->flags &= ~UV_HANDLE_ZERO_READ; handle->alloc_cb((uv_handle_t*) handle, 65536, &handle->read_buffer); if (handle->read_buffer.len == 0) { handle->read_cb((uv_stream_t*) handle, UV_ENOBUFS, &handle->read_buffer); return; } assert(handle->read_buffer.base != NULL); buf = handle->read_buffer; } else { handle->flags |= UV_HANDLE_ZERO_READ; buf.base = (char*) &uv_zero_; buf.len = 0; } /* Prepare the overlapped structure. */ memset(&(req->overlapped), 0, sizeof(req->overlapped)); if (handle->flags & UV_HANDLE_EMULATE_IOCP) { assert(req->event_handle); req->overlapped.hEvent = (HANDLE) ((ULONG_PTR) req->event_handle | 1); } flags = 0; result = WSARecv(handle->socket, (WSABUF*)&buf, 1, &bytes, &flags, &req->overlapped, NULL); if (UV_SUCCEEDED_WITHOUT_IOCP(result == 0)) { /* Process the req without IOCP. */ handle->flags |= UV_HANDLE_READ_PENDING; req->overlapped.InternalHigh = bytes; handle->reqs_pending++; uv_insert_pending_req(loop, (uv_req_t*)req); } else if (UV_SUCCEEDED_WITH_IOCP(result == 0)) { /* The req will be processed with IOCP. */ handle->flags |= UV_HANDLE_READ_PENDING; handle->reqs_pending++; if (handle->flags & UV_HANDLE_EMULATE_IOCP && req->wait_handle == INVALID_HANDLE_VALUE && !RegisterWaitForSingleObject(&req->wait_handle, req->event_handle, post_completion, (void*) req, INFINITE, WT_EXECUTEINWAITTHREAD)) { SET_REQ_ERROR(req, GetLastError()); uv_insert_pending_req(loop, (uv_req_t*)req); } } else { /* Make this req pending reporting an error. */ SET_REQ_ERROR(req, WSAGetLastError()); uv_insert_pending_req(loop, (uv_req_t*)req); handle->reqs_pending++; } } int uv_tcp_listen(uv_tcp_t* handle, int backlog, uv_connection_cb cb) { uv_loop_t* loop = handle->loop; unsigned int i, simultaneous_accepts; uv_tcp_accept_t* req; int err; assert(backlog > 0); if (handle->flags & UV_HANDLE_LISTENING) { handle->connection_cb = cb; } if (handle->flags & UV_HANDLE_READING) { return WSAEISCONN; } if (handle->flags & UV_HANDLE_BIND_ERROR) { return handle->bind_error; } if (!(handle->flags & UV_HANDLE_BOUND)) { err = uv_tcp_try_bind(handle, (const struct sockaddr*) &uv_addr_ip4_any_, sizeof(uv_addr_ip4_any_), 0); if (err) return err; } if (!handle->func_acceptex) { if (!uv_get_acceptex_function(handle->socket, &handle->func_acceptex)) { return WSAEAFNOSUPPORT; } } if (!(handle->flags & UV_HANDLE_SHARED_TCP_SOCKET) && listen(handle->socket, backlog) == SOCKET_ERROR) { return WSAGetLastError(); } handle->flags |= UV_HANDLE_LISTENING; handle->connection_cb = cb; INCREASE_ACTIVE_COUNT(loop, handle); simultaneous_accepts = handle->flags & UV_HANDLE_TCP_SINGLE_ACCEPT ? 1 : uv_simultaneous_server_accepts; if(!handle->accept_reqs) { handle->accept_reqs = (uv_tcp_accept_t*) malloc(uv_simultaneous_server_accepts * sizeof(uv_tcp_accept_t)); if (!handle->accept_reqs) { uv_fatal_error(ERROR_OUTOFMEMORY, "malloc"); } for (i = 0; i < simultaneous_accepts; i++) { req = &handle->accept_reqs[i]; uv_req_init(loop, (uv_req_t*)req); req->type = UV_ACCEPT; req->accept_socket = INVALID_SOCKET; req->data = handle; req->wait_handle = INVALID_HANDLE_VALUE; if (handle->flags & UV_HANDLE_EMULATE_IOCP) { req->event_handle = CreateEvent(NULL, 0, 0, NULL); if (!req->event_handle) { uv_fatal_error(GetLastError(), "CreateEvent"); } } else { req->event_handle = NULL; } uv_tcp_queue_accept(handle, req); } /* Initialize other unused requests too, because uv_tcp_endgame */ /* doesn't know how how many requests were intialized, so it will */ /* try to clean up {uv_simultaneous_server_accepts} requests. */ for (i = simultaneous_accepts; i < uv_simultaneous_server_accepts; i++) { req = &handle->accept_reqs[i]; uv_req_init(loop, (uv_req_t*) req); req->type = UV_ACCEPT; req->accept_socket = INVALID_SOCKET; req->data = handle; req->wait_handle = INVALID_HANDLE_VALUE; } } return 0; } int uv_tcp_accept(uv_tcp_t* server, uv_tcp_t* client) { uv_loop_t* loop = server->loop; int err = 0; int family; uv_tcp_accept_t* req = server->pending_accepts; if (!req) { /* No valid connections found, so we error out. */ return WSAEWOULDBLOCK; } if (req->accept_socket == INVALID_SOCKET) { return WSAENOTCONN; } if (server->flags & UV_HANDLE_IPV6) { family = AF_INET6; } else { family = AF_INET; } err = uv_tcp_set_socket(client->loop, client, req->accept_socket, family, 0); if (err) { closesocket(req->accept_socket); } else { uv_connection_init((uv_stream_t*) client); /* AcceptEx() implicitly binds the accepted socket. */ client->flags |= UV_HANDLE_BOUND | UV_HANDLE_READABLE | UV_HANDLE_WRITABLE; } /* Prepare the req to pick up a new connection */ server->pending_accepts = req->next_pending; req->next_pending = NULL; req->accept_socket = INVALID_SOCKET; if (!(server->flags & UV__HANDLE_CLOSING)) { /* Check if we're in a middle of changing the number of pending accepts. */ if (!(server->flags & UV_HANDLE_TCP_ACCEPT_STATE_CHANGING)) { uv_tcp_queue_accept(server, req); } else { /* We better be switching to a single pending accept. */ assert(server->flags & UV_HANDLE_TCP_SINGLE_ACCEPT); server->processed_accepts++; if (server->processed_accepts >= uv_simultaneous_server_accepts) { server->processed_accepts = 0; /* * All previously queued accept requests are now processed. * We now switch to queueing just a single accept. */ uv_tcp_queue_accept(server, &server->accept_reqs[0]); server->flags &= ~UV_HANDLE_TCP_ACCEPT_STATE_CHANGING; server->flags |= UV_HANDLE_TCP_SINGLE_ACCEPT; } } } loop->active_tcp_streams++; return err; } int uv_tcp_read_start(uv_tcp_t* handle, uv_alloc_cb alloc_cb, uv_read_cb read_cb) { uv_loop_t* loop = handle->loop; handle->flags |= UV_HANDLE_READING; handle->read_cb = read_cb; handle->alloc_cb = alloc_cb; INCREASE_ACTIVE_COUNT(loop, handle); /* If reading was stopped and then started again, there could still be a */ /* read request pending. */ if (!(handle->flags & UV_HANDLE_READ_PENDING)) { if (handle->flags & UV_HANDLE_EMULATE_IOCP && !handle->read_req.event_handle) { handle->read_req.event_handle = CreateEvent(NULL, 0, 0, NULL); if (!handle->read_req.event_handle) { uv_fatal_error(GetLastError(), "CreateEvent"); } } uv_tcp_queue_read(loop, handle); } return 0; } static int uv_tcp_try_connect(uv_connect_t* req, uv_tcp_t* handle, const struct sockaddr* addr, unsigned int addrlen, uv_connect_cb cb) { uv_loop_t* loop = handle->loop; const struct sockaddr* bind_addr; BOOL success; DWORD bytes; int err; if (handle->flags & UV_HANDLE_BIND_ERROR) { return handle->bind_error; } if (!(handle->flags & UV_HANDLE_BOUND)) { if (addrlen == sizeof(uv_addr_ip4_any_)) { bind_addr = (const struct sockaddr*) &uv_addr_ip4_any_; } else if (addrlen == sizeof(uv_addr_ip6_any_)) { bind_addr = (const struct sockaddr*) &uv_addr_ip6_any_; } else { abort(); } err = uv_tcp_try_bind(handle, bind_addr, addrlen, 0); if (err) return err; } if (!handle->func_connectex) { if (!uv_get_connectex_function(handle->socket, &handle->func_connectex)) { return WSAEAFNOSUPPORT; } } uv_req_init(loop, (uv_req_t*) req); req->type = UV_CONNECT; req->handle = (uv_stream_t*) handle; req->cb = cb; memset(&req->overlapped, 0, sizeof(req->overlapped)); success = handle->func_connectex(handle->socket, addr, addrlen, NULL, 0, &bytes, &req->overlapped); if (UV_SUCCEEDED_WITHOUT_IOCP(success)) { /* Process the req without IOCP. */ handle->reqs_pending++; REGISTER_HANDLE_REQ(loop, handle, req); uv_insert_pending_req(loop, (uv_req_t*)req); } else if (UV_SUCCEEDED_WITH_IOCP(success)) { /* The req will be processed with IOCP. */ handle->reqs_pending++; REGISTER_HANDLE_REQ(loop, handle, req); } else { return WSAGetLastError(); } return 0; } int uv_tcp_getsockname(uv_tcp_t* handle, struct sockaddr* name, int* namelen) { int result; if (!(handle->flags & UV_HANDLE_BOUND)) { return UV_EINVAL; } if (handle->flags & UV_HANDLE_BIND_ERROR) { return uv_translate_sys_error(handle->bind_error); } result = getsockname(handle->socket, name, namelen); if (result != 0) { return uv_translate_sys_error(WSAGetLastError()); } return 0; } int uv_tcp_getpeername(uv_tcp_t* handle, struct sockaddr* name, int* namelen) { int result; if (!(handle->flags & UV_HANDLE_BOUND)) { return UV_EINVAL; } if (handle->flags & UV_HANDLE_BIND_ERROR) { return uv_translate_sys_error(handle->bind_error); } result = getpeername(handle->socket, name, namelen); if (result != 0) { return uv_translate_sys_error(WSAGetLastError()); } return 0; } int uv_tcp_write(uv_loop_t* loop, uv_write_t* req, uv_tcp_t* handle, const uv_buf_t bufs[], unsigned int nbufs, uv_write_cb cb) { int result; DWORD bytes; uv_req_init(loop, (uv_req_t*) req); req->type = UV_WRITE; req->handle = (uv_stream_t*) handle; req->cb = cb; memset(&req->overlapped, 0, sizeof(req->overlapped)); /* Prepare the overlapped structure. */ memset(&(req->overlapped), 0, sizeof(req->overlapped)); if (handle->flags & UV_HANDLE_EMULATE_IOCP) { req->event_handle = CreateEvent(NULL, 0, 0, NULL); if (!req->event_handle) { uv_fatal_error(GetLastError(), "CreateEvent"); } req->overlapped.hEvent = (HANDLE) ((ULONG_PTR) req->event_handle | 1); req->wait_handle = INVALID_HANDLE_VALUE; } result = WSASend(handle->socket, (WSABUF*) bufs, nbufs, &bytes, 0, &req->overlapped, NULL); if (UV_SUCCEEDED_WITHOUT_IOCP(result == 0)) { /* Request completed immediately. */ req->queued_bytes = 0; handle->reqs_pending++; handle->write_reqs_pending++; REGISTER_HANDLE_REQ(loop, handle, req); uv_insert_pending_req(loop, (uv_req_t*) req); } else if (UV_SUCCEEDED_WITH_IOCP(result == 0)) { /* Request queued by the kernel. */ req->queued_bytes = uv_count_bufs(bufs, nbufs); handle->reqs_pending++; handle->write_reqs_pending++; REGISTER_HANDLE_REQ(loop, handle, req); handle->write_queue_size += req->queued_bytes; if (handle->flags & UV_HANDLE_EMULATE_IOCP && !RegisterWaitForSingleObject(&req->wait_handle, req->event_handle, post_write_completion, (void*) req, INFINITE, WT_EXECUTEINWAITTHREAD | WT_EXECUTEONLYONCE)) { SET_REQ_ERROR(req, GetLastError()); uv_insert_pending_req(loop, (uv_req_t*)req); } } else { /* Send failed due to an error. */ return WSAGetLastError(); } return 0; } void uv_process_tcp_read_req(uv_loop_t* loop, uv_tcp_t* handle, uv_req_t* req) { DWORD bytes, flags, err; uv_buf_t buf; assert(handle->type == UV_TCP); handle->flags &= ~UV_HANDLE_READ_PENDING; if (!REQ_SUCCESS(req)) { /* An error occurred doing the read. */ if ((handle->flags & UV_HANDLE_READING) || !(handle->flags & UV_HANDLE_ZERO_READ)) { handle->flags &= ~UV_HANDLE_READING; DECREASE_ACTIVE_COUNT(loop, handle); buf = (handle->flags & UV_HANDLE_ZERO_READ) ? uv_buf_init(NULL, 0) : handle->read_buffer; err = GET_REQ_SOCK_ERROR(req); if (err == WSAECONNABORTED) { /* * Turn WSAECONNABORTED into UV_ECONNRESET to be consistent with Unix. */ err = WSAECONNRESET; } handle->read_cb((uv_stream_t*)handle, uv_translate_sys_error(err), &buf); } } else { if (!(handle->flags & UV_HANDLE_ZERO_READ)) { /* The read was done with a non-zero buffer length. */ if (req->overlapped.InternalHigh > 0) { /* Successful read */ handle->read_cb((uv_stream_t*)handle, req->overlapped.InternalHigh, &handle->read_buffer); /* Read again only if bytes == buf.len */ if (req->overlapped.InternalHigh < handle->read_buffer.len) { goto done; } } else { /* Connection closed */ if (handle->flags & UV_HANDLE_READING) { handle->flags &= ~UV_HANDLE_READING; DECREASE_ACTIVE_COUNT(loop, handle); } handle->flags &= ~UV_HANDLE_READABLE; buf.base = 0; buf.len = 0; handle->read_cb((uv_stream_t*)handle, UV_EOF, &handle->read_buffer); goto done; } } /* Do nonblocking reads until the buffer is empty */ while (handle->flags & UV_HANDLE_READING) { handle->alloc_cb((uv_handle_t*) handle, 65536, &buf); if (buf.len == 0) { handle->read_cb((uv_stream_t*) handle, UV_ENOBUFS, &buf); break; } assert(buf.base != NULL); flags = 0; if (WSARecv(handle->socket, (WSABUF*)&buf, 1, &bytes, &flags, NULL, NULL) != SOCKET_ERROR) { if (bytes > 0) { /* Successful read */ handle->read_cb((uv_stream_t*)handle, bytes, &buf); /* Read again only if bytes == buf.len */ if (bytes < buf.len) { break; } } else { /* Connection closed */ handle->flags &= ~(UV_HANDLE_READING | UV_HANDLE_READABLE); DECREASE_ACTIVE_COUNT(loop, handle); handle->read_cb((uv_stream_t*)handle, UV_EOF, &buf); break; } } else { err = WSAGetLastError(); if (err == WSAEWOULDBLOCK) { /* Read buffer was completely empty, report a 0-byte read. */ handle->read_cb((uv_stream_t*)handle, 0, &buf); } else { /* Ouch! serious error. */ handle->flags &= ~UV_HANDLE_READING; DECREASE_ACTIVE_COUNT(loop, handle); if (err == WSAECONNABORTED) { /* Turn WSAECONNABORTED into UV_ECONNRESET to be consistent with */ /* Unix. */ err = WSAECONNRESET; } handle->read_cb((uv_stream_t*)handle, uv_translate_sys_error(err), &buf); } break; } } done: /* Post another read if still reading and not closing. */ if ((handle->flags & UV_HANDLE_READING) && !(handle->flags & UV_HANDLE_READ_PENDING)) { uv_tcp_queue_read(loop, handle); } } DECREASE_PENDING_REQ_COUNT(handle); } void uv_process_tcp_write_req(uv_loop_t* loop, uv_tcp_t* handle, uv_write_t* req) { int err; assert(handle->type == UV_TCP); assert(handle->write_queue_size >= req->queued_bytes); handle->write_queue_size -= req->queued_bytes; UNREGISTER_HANDLE_REQ(loop, handle, req); if (handle->flags & UV_HANDLE_EMULATE_IOCP) { if (req->wait_handle != INVALID_HANDLE_VALUE) { UnregisterWait(req->wait_handle); } if (req->event_handle) { CloseHandle(req->event_handle); } } if (req->cb) { err = GET_REQ_SOCK_ERROR(req); req->cb(req, uv_translate_sys_error(err)); } handle->write_reqs_pending--; if (handle->shutdown_req != NULL && handle->write_reqs_pending == 0) { uv_want_endgame(loop, (uv_handle_t*)handle); } DECREASE_PENDING_REQ_COUNT(handle); } void uv_process_tcp_accept_req(uv_loop_t* loop, uv_tcp_t* handle, uv_req_t* raw_req) { uv_tcp_accept_t* req = (uv_tcp_accept_t*) raw_req; int err; assert(handle->type == UV_TCP); /* If handle->accepted_socket is not a valid socket, then */ /* uv_queue_accept must have failed. This is a serious error. We stop */ /* accepting connections and report this error to the connection */ /* callback. */ if (req->accept_socket == INVALID_SOCKET) { if (handle->flags & UV_HANDLE_LISTENING) { handle->flags &= ~UV_HANDLE_LISTENING; DECREASE_ACTIVE_COUNT(loop, handle); if (handle->connection_cb) { err = GET_REQ_SOCK_ERROR(req); handle->connection_cb((uv_stream_t*)handle, uv_translate_sys_error(err)); } } } else if (REQ_SUCCESS(req) && setsockopt(req->accept_socket, SOL_SOCKET, SO_UPDATE_ACCEPT_CONTEXT, (char*)&handle->socket, sizeof(handle->socket)) == 0) { req->next_pending = handle->pending_accepts; handle->pending_accepts = req; /* Accept and SO_UPDATE_ACCEPT_CONTEXT were successful. */ if (handle->connection_cb) { handle->connection_cb((uv_stream_t*)handle, 0); } } else { /* Error related to accepted socket is ignored because the server */ /* socket may still be healthy. If the server socket is broken */ /* uv_queue_accept will detect it. */ closesocket(req->accept_socket); req->accept_socket = INVALID_SOCKET; if (handle->flags & UV_HANDLE_LISTENING) { uv_tcp_queue_accept(handle, req); } } DECREASE_PENDING_REQ_COUNT(handle); } void uv_process_tcp_connect_req(uv_loop_t* loop, uv_tcp_t* handle, uv_connect_t* req) { int err; assert(handle->type == UV_TCP); UNREGISTER_HANDLE_REQ(loop, handle, req); err = 0; if (REQ_SUCCESS(req)) { if (setsockopt(handle->socket, SOL_SOCKET, SO_UPDATE_CONNECT_CONTEXT, NULL, 0) == 0) { uv_connection_init((uv_stream_t*)handle); handle->flags |= UV_HANDLE_READABLE | UV_HANDLE_WRITABLE; loop->active_tcp_streams++; } else { err = WSAGetLastError(); } } else { err = GET_REQ_SOCK_ERROR(req); } req->cb(req, uv_translate_sys_error(err)); DECREASE_PENDING_REQ_COUNT(handle); } int uv_tcp_import(uv_tcp_t* tcp, WSAPROTOCOL_INFOW* socket_protocol_info, int tcp_connection) { int err; SOCKET socket = WSASocketW(AF_INET, SOCK_STREAM, IPPROTO_IP, socket_protocol_info, 0, WSA_FLAG_OVERLAPPED); if (socket == INVALID_SOCKET) { return WSAGetLastError(); } if (!SetHandleInformation((HANDLE) socket, HANDLE_FLAG_INHERIT, 0)) { err = GetLastError(); closesocket(socket); return err; } err = uv_tcp_set_socket(tcp->loop, tcp, socket, socket_protocol_info->iAddressFamily, 1); if (err) { closesocket(socket); return err; } if (tcp_connection) { uv_connection_init((uv_stream_t*)tcp); tcp->flags |= UV_HANDLE_READABLE | UV_HANDLE_WRITABLE; } tcp->flags |= UV_HANDLE_BOUND; tcp->flags |= UV_HANDLE_SHARED_TCP_SOCKET; tcp->loop->active_tcp_streams++; return 0; } int uv_tcp_nodelay(uv_tcp_t* handle, int enable) { int err; if (handle->socket != INVALID_SOCKET) { err = uv__tcp_nodelay(handle, handle->socket, enable); if (err) return err; } if (enable) { handle->flags |= UV_HANDLE_TCP_NODELAY; } else { handle->flags &= ~UV_HANDLE_TCP_NODELAY; } return 0; } int uv_tcp_keepalive(uv_tcp_t* handle, int enable, unsigned int delay) { int err; if (handle->socket != INVALID_SOCKET) { err = uv__tcp_keepalive(handle, handle->socket, enable, delay); if (err) return err; } if (enable) { handle->flags |= UV_HANDLE_TCP_KEEPALIVE; } else { handle->flags &= ~UV_HANDLE_TCP_KEEPALIVE; } /* TODO: Store delay if handle->socket isn't created yet. */ return 0; } int uv_tcp_duplicate_socket(uv_tcp_t* handle, int pid, LPWSAPROTOCOL_INFOW protocol_info) { if (!(handle->flags & UV_HANDLE_CONNECTION)) { /* * We're about to share the socket with another process. Because * this is a listening socket, we assume that the other process will * be accepting connections on it. So, before sharing the socket * with another process, we call listen here in the parent process. */ if (!(handle->flags & UV_HANDLE_LISTENING)) { if (!(handle->flags & UV_HANDLE_BOUND)) { return ERROR_INVALID_PARAMETER; } /* Report any deferred bind errors now. */ if (handle->flags & UV_HANDLE_BIND_ERROR) { return handle->bind_error; } if (listen(handle->socket, SOMAXCONN) == SOCKET_ERROR) { return WSAGetLastError(); } } } if (WSADuplicateSocketW(handle->socket, pid, protocol_info)) { return WSAGetLastError(); } handle->flags |= UV_HANDLE_SHARED_TCP_SOCKET; return 0; } int uv_tcp_simultaneous_accepts(uv_tcp_t* handle, int enable) { if (handle->flags & UV_HANDLE_CONNECTION) { return UV_EINVAL; } /* Check if we're already in the desired mode. */ if ((enable && !(handle->flags & UV_HANDLE_TCP_SINGLE_ACCEPT)) || (!enable && handle->flags & UV_HANDLE_TCP_SINGLE_ACCEPT)) { return 0; } /* Don't allow switching from single pending accept to many. */ if (enable) { return UV_ENOTSUP; } /* Check if we're in a middle of changing the number of pending accepts. */ if (handle->flags & UV_HANDLE_TCP_ACCEPT_STATE_CHANGING) { return 0; } handle->flags |= UV_HANDLE_TCP_SINGLE_ACCEPT; /* Flip the changing flag if we have already queued multiple accepts. */ if (handle->flags & UV_HANDLE_LISTENING) { handle->flags |= UV_HANDLE_TCP_ACCEPT_STATE_CHANGING; } return 0; } static int uv_tcp_try_cancel_io(uv_tcp_t* tcp) { SOCKET socket = tcp->socket; int non_ifs_lsp; /* Check if we have any non-IFS LSPs stacked on top of TCP */ non_ifs_lsp = (tcp->flags & UV_HANDLE_IPV6) ? uv_tcp_non_ifs_lsp_ipv6 : uv_tcp_non_ifs_lsp_ipv4; /* If there are non-ifs LSPs then try to obtain a base handle for the */ /* socket. This will always fail on Windows XP/3k. */ if (non_ifs_lsp) { DWORD bytes; if (WSAIoctl(socket, SIO_BASE_HANDLE, NULL, 0, &socket, sizeof socket, &bytes, NULL, NULL) != 0) { /* Failed. We can't do CancelIo. */ return -1; } } assert(socket != 0 && socket != INVALID_SOCKET); if (!CancelIo((HANDLE) socket)) { return GetLastError(); } /* It worked. */ return 0; } void uv_tcp_close(uv_loop_t* loop, uv_tcp_t* tcp) { int close_socket = 1; if (tcp->flags & UV_HANDLE_READ_PENDING) { /* In order for winsock to do a graceful close there must not be any */ /* any pending reads, or the socket must be shut down for writing */ if (!(tcp->flags & UV_HANDLE_SHARED_TCP_SOCKET)) { /* Just do shutdown on non-shared sockets, which ensures graceful close. */ shutdown(tcp->socket, SD_SEND); } else if (uv_tcp_try_cancel_io(tcp) == 0) { /* In case of a shared socket, we try to cancel all outstanding I/O, */ /* If that works, don't close the socket yet - wait for the read req to */ /* return and close the socket in uv_tcp_endgame. */ close_socket = 0; } else { /* When cancelling isn't possible - which could happen when an LSP is */ /* present on an old Windows version, we will have to close the socket */ /* with a read pending. That is not nice because trailing sent bytes */ /* may not make it to the other side. */ } } else if ((tcp->flags & UV_HANDLE_SHARED_TCP_SOCKET) && tcp->accept_reqs != NULL) { /* Under normal circumstances closesocket() will ensure that all pending */ /* accept reqs are canceled. However, when the socket is shared the */ /* presence of another reference to the socket in another process will */ /* keep the accept reqs going, so we have to ensure that these are */ /* canceled. */ if (uv_tcp_try_cancel_io(tcp) != 0) { /* When cancellation is not possible, there is another option: we can */ /* close the incoming sockets, which will also cancel the accept */ /* operations. However this is not cool because we might inadvertedly */ /* close a socket that just accepted a new connection, which will */ /* cause the connection to be aborted. */ unsigned int i; for (i = 0; i < uv_simultaneous_server_accepts; i++) { uv_tcp_accept_t* req = &tcp->accept_reqs[i]; if (req->accept_socket != INVALID_SOCKET && !HasOverlappedIoCompleted(&req->overlapped)) { closesocket(req->accept_socket); req->accept_socket = INVALID_SOCKET; } } } } if (tcp->flags & UV_HANDLE_READING) { tcp->flags &= ~UV_HANDLE_READING; DECREASE_ACTIVE_COUNT(loop, tcp); } if (tcp->flags & UV_HANDLE_LISTENING) { tcp->flags &= ~UV_HANDLE_LISTENING; DECREASE_ACTIVE_COUNT(loop, tcp); } if (close_socket) { closesocket(tcp->socket); tcp->flags |= UV_HANDLE_TCP_SOCKET_CLOSED; } tcp->flags &= ~(UV_HANDLE_READABLE | UV_HANDLE_WRITABLE); uv__handle_closing(tcp); if (tcp->reqs_pending == 0) { uv_want_endgame(tcp->loop, (uv_handle_t*)tcp); } } int uv_tcp_open(uv_tcp_t* handle, uv_os_sock_t sock) { WSAPROTOCOL_INFOW protocol_info; int opt_len; int err; /* Detect the address family of the socket. */ opt_len = (int) sizeof protocol_info; if (getsockopt(sock, SOL_SOCKET, SO_PROTOCOL_INFOW, (char*) &protocol_info, &opt_len) == SOCKET_ERROR) { return uv_translate_sys_error(GetLastError()); } /* Make the socket non-inheritable */ if (!SetHandleInformation((HANDLE) sock, HANDLE_FLAG_INHERIT, 0)) { return uv_translate_sys_error(GetLastError()); } err = uv_tcp_set_socket(handle->loop, handle, sock, protocol_info.iAddressFamily, 1); if (err) { return uv_translate_sys_error(err); } return 0; } /* This function is an egress point, i.e. it returns libuv errors rather than * system errors. */ int uv__tcp_bind(uv_tcp_t* handle, const struct sockaddr* addr, unsigned int addrlen, unsigned int flags) { int err; err = uv_tcp_try_bind(handle, addr, addrlen, flags); if (err) return uv_translate_sys_error(err); return 0; } /* This function is an egress point, i.e. it returns libuv errors rather than * system errors. */ int uv__tcp_connect(uv_connect_t* req, uv_tcp_t* handle, const struct sockaddr* addr, unsigned int addrlen, uv_connect_cb cb) { int err; err = uv_tcp_try_connect(req, handle, addr, addrlen, cb); if (err) return uv_translate_sys_error(err); return 0; }