/* 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 #include #include #include "handle-inl.h" #include "internal.h" #include "req-inl.h" #include "stream-inl.h" #include "uv-common.h" #include "uv.h" #include #include /* A zero-size buffer for use by uv_pipe_read */ static char uv_zero_[] = ""; /* Null uv_buf_t */ static const uv_buf_t uv_null_buf_ = { 0, NULL }; /* The timeout that the pipe will wait for the remote end to write data when * the local ends wants to shut it down. */ static const int64_t eof_timeout = 50; /* ms */ static const int default_pending_pipe_instances = 4; /* Pipe prefix */ static char pipe_prefix[] = "\\\\?\\pipe"; static const int pipe_prefix_len = sizeof(pipe_prefix) - 1; /* IPC incoming xfer queue item. */ typedef struct { uv__ipc_socket_xfer_type_t xfer_type; uv__ipc_socket_xfer_info_t xfer_info; struct uv__queue member; } uv__ipc_xfer_queue_item_t; /* IPC frame header flags. */ /* clang-format off */ enum { UV__IPC_FRAME_HAS_DATA = 0x01, UV__IPC_FRAME_HAS_SOCKET_XFER = 0x02, UV__IPC_FRAME_XFER_IS_TCP_CONNECTION = 0x04, /* These are combinations of the flags above. */ UV__IPC_FRAME_XFER_FLAGS = 0x06, UV__IPC_FRAME_VALID_FLAGS = 0x07 }; /* clang-format on */ /* IPC frame header. */ typedef struct { uint32_t flags; uint32_t reserved1; /* Ignored. */ uint32_t data_length; /* Must be zero if there is no data. */ uint32_t reserved2; /* Must be zero. */ } uv__ipc_frame_header_t; /* To implement the IPC protocol correctly, these structures must have exactly * the right size. */ STATIC_ASSERT(sizeof(uv__ipc_frame_header_t) == 16); STATIC_ASSERT(sizeof(uv__ipc_socket_xfer_info_t) == 632); /* Coalesced write request. */ typedef struct { uv_write_t req; /* Internal heap-allocated write request. */ uv_write_t* user_req; /* Pointer to user-specified uv_write_t. */ } uv__coalesced_write_t; static void eof_timer_init(uv_pipe_t* pipe); static void eof_timer_start(uv_pipe_t* pipe); static void eof_timer_stop(uv_pipe_t* pipe); static void eof_timer_cb(uv_timer_t* timer); static void eof_timer_destroy(uv_pipe_t* pipe); static void eof_timer_close_cb(uv_handle_t* handle); static void uv__unique_pipe_name(char* ptr, char* name, size_t size) { snprintf(name, size, "\\\\?\\pipe\\uv\\%p-%lu", ptr, GetCurrentProcessId()); } int uv_pipe_init(uv_loop_t* loop, uv_pipe_t* handle, int ipc) { uv__stream_init(loop, (uv_stream_t*)handle, UV_NAMED_PIPE); handle->reqs_pending = 0; handle->handle = INVALID_HANDLE_VALUE; handle->name = NULL; handle->pipe.conn.ipc_remote_pid = 0; handle->pipe.conn.ipc_data_frame.payload_remaining = 0; uv__queue_init(&handle->pipe.conn.ipc_xfer_queue); handle->pipe.conn.ipc_xfer_queue_length = 0; handle->ipc = ipc; handle->pipe.conn.non_overlapped_writes_tail = NULL; return 0; } static void uv__pipe_connection_init(uv_pipe_t* handle) { assert(!(handle->flags & UV_HANDLE_PIPESERVER)); uv__connection_init((uv_stream_t*) handle); handle->read_req.data = handle; handle->pipe.conn.eof_timer = NULL; } static HANDLE open_named_pipe(const WCHAR* name, DWORD* duplex_flags) { HANDLE pipeHandle; /* * Assume that we have a duplex pipe first, so attempt to * connect with GENERIC_READ | GENERIC_WRITE. */ pipeHandle = CreateFileW(name, GENERIC_READ | GENERIC_WRITE, 0, NULL, OPEN_EXISTING, FILE_FLAG_OVERLAPPED, NULL); if (pipeHandle != INVALID_HANDLE_VALUE) { *duplex_flags = UV_HANDLE_READABLE | UV_HANDLE_WRITABLE; return pipeHandle; } /* * If the pipe is not duplex CreateFileW fails with * ERROR_ACCESS_DENIED. In that case try to connect * as a read-only or write-only. */ if (GetLastError() == ERROR_ACCESS_DENIED) { pipeHandle = CreateFileW(name, GENERIC_READ | FILE_WRITE_ATTRIBUTES, 0, NULL, OPEN_EXISTING, FILE_FLAG_OVERLAPPED, NULL); if (pipeHandle != INVALID_HANDLE_VALUE) { *duplex_flags = UV_HANDLE_READABLE; return pipeHandle; } } if (GetLastError() == ERROR_ACCESS_DENIED) { pipeHandle = CreateFileW(name, GENERIC_WRITE | FILE_READ_ATTRIBUTES, 0, NULL, OPEN_EXISTING, FILE_FLAG_OVERLAPPED, NULL); if (pipeHandle != INVALID_HANDLE_VALUE) { *duplex_flags = UV_HANDLE_WRITABLE; return pipeHandle; } } return INVALID_HANDLE_VALUE; } static void close_pipe(uv_pipe_t* pipe) { assert(pipe->u.fd == -1 || pipe->u.fd > 2); if (pipe->u.fd == -1) CloseHandle(pipe->handle); else close(pipe->u.fd); pipe->u.fd = -1; pipe->handle = INVALID_HANDLE_VALUE; } static int uv__pipe_server( HANDLE* pipeHandle_ptr, DWORD access, char* name, size_t nameSize, char* random) { HANDLE pipeHandle; int err; for (;;) { uv__unique_pipe_name(random, name, nameSize); pipeHandle = CreateNamedPipeA(name, access | FILE_FLAG_FIRST_PIPE_INSTANCE, PIPE_TYPE_BYTE | PIPE_READMODE_BYTE | PIPE_WAIT, 1, 65536, 65536, 0, NULL); if (pipeHandle != INVALID_HANDLE_VALUE) { /* No name collisions. We're done. */ break; } err = GetLastError(); if (err != ERROR_PIPE_BUSY && err != ERROR_ACCESS_DENIED) { goto error; } /* Pipe name collision. Increment the random number and try again. */ random++; } *pipeHandle_ptr = pipeHandle; return 0; error: if (pipeHandle != INVALID_HANDLE_VALUE) CloseHandle(pipeHandle); return err; } static int uv__create_pipe_pair( HANDLE* server_pipe_ptr, HANDLE* client_pipe_ptr, unsigned int server_flags, unsigned int client_flags, int inherit_client, char* random) { /* allowed flags are: UV_READABLE_PIPE | UV_WRITABLE_PIPE | UV_NONBLOCK_PIPE */ char pipe_name[64]; SECURITY_ATTRIBUTES sa; DWORD server_access; DWORD client_access; HANDLE server_pipe; HANDLE client_pipe; int err; server_pipe = INVALID_HANDLE_VALUE; client_pipe = INVALID_HANDLE_VALUE; server_access = 0; if (server_flags & UV_READABLE_PIPE) server_access |= PIPE_ACCESS_INBOUND; if (server_flags & UV_WRITABLE_PIPE) server_access |= PIPE_ACCESS_OUTBOUND; if (server_flags & UV_NONBLOCK_PIPE) server_access |= FILE_FLAG_OVERLAPPED; server_access |= WRITE_DAC; client_access = 0; if (client_flags & UV_READABLE_PIPE) client_access |= GENERIC_READ; else client_access |= FILE_READ_ATTRIBUTES; if (client_flags & UV_WRITABLE_PIPE) client_access |= GENERIC_WRITE; else client_access |= FILE_WRITE_ATTRIBUTES; client_access |= WRITE_DAC; /* Create server pipe handle. */ err = uv__pipe_server(&server_pipe, server_access, pipe_name, sizeof(pipe_name), random); if (err) goto error; /* Create client pipe handle. */ sa.nLength = sizeof sa; sa.lpSecurityDescriptor = NULL; sa.bInheritHandle = inherit_client; client_pipe = CreateFileA(pipe_name, client_access, 0, &sa, OPEN_EXISTING, (client_flags & UV_NONBLOCK_PIPE) ? FILE_FLAG_OVERLAPPED : 0, NULL); if (client_pipe == INVALID_HANDLE_VALUE) { err = GetLastError(); goto error; } #ifndef NDEBUG /* Validate that the pipe was opened in the right mode. */ { DWORD mode; BOOL r; r = GetNamedPipeHandleState(client_pipe, &mode, NULL, NULL, NULL, NULL, 0); if (r == TRUE) { assert(mode == (PIPE_READMODE_BYTE | PIPE_WAIT)); } else { fprintf(stderr, "libuv assertion failure: GetNamedPipeHandleState failed\n"); } } #endif /* Do a blocking ConnectNamedPipe. This should not block because we have * both ends of the pipe created. */ if (!ConnectNamedPipe(server_pipe, NULL)) { if (GetLastError() != ERROR_PIPE_CONNECTED) { err = GetLastError(); goto error; } } *client_pipe_ptr = client_pipe; *server_pipe_ptr = server_pipe; return 0; error: if (server_pipe != INVALID_HANDLE_VALUE) CloseHandle(server_pipe); if (client_pipe != INVALID_HANDLE_VALUE) CloseHandle(client_pipe); return err; } int uv_pipe(uv_file fds[2], int read_flags, int write_flags) { uv_file temp[2]; int err; HANDLE readh; HANDLE writeh; /* Make the server side the inbound (read) end, */ /* so that both ends will have FILE_READ_ATTRIBUTES permission. */ /* TODO: better source of local randomness than &fds? */ read_flags |= UV_READABLE_PIPE; write_flags |= UV_WRITABLE_PIPE; err = uv__create_pipe_pair(&readh, &writeh, read_flags, write_flags, 0, (char*) &fds[0]); if (err != 0) return err; temp[0] = _open_osfhandle((intptr_t) readh, 0); if (temp[0] == -1) { if (errno == UV_EMFILE) err = UV_EMFILE; else err = UV_UNKNOWN; CloseHandle(readh); CloseHandle(writeh); return err; } temp[1] = _open_osfhandle((intptr_t) writeh, 0); if (temp[1] == -1) { if (errno == UV_EMFILE) err = UV_EMFILE; else err = UV_UNKNOWN; _close(temp[0]); CloseHandle(writeh); return err; } fds[0] = temp[0]; fds[1] = temp[1]; return 0; } int uv__create_stdio_pipe_pair(uv_loop_t* loop, uv_pipe_t* parent_pipe, HANDLE* child_pipe_ptr, unsigned int flags) { /* The parent_pipe is always the server_pipe and kept by libuv. * The child_pipe is always the client_pipe and is passed to the child. * The flags are specified with respect to their usage in the child. */ HANDLE server_pipe; HANDLE client_pipe; unsigned int server_flags; unsigned int client_flags; int err; uv__pipe_connection_init(parent_pipe); server_pipe = INVALID_HANDLE_VALUE; client_pipe = INVALID_HANDLE_VALUE; server_flags = 0; client_flags = 0; if (flags & UV_READABLE_PIPE) { /* The server needs inbound (read) access too, otherwise CreateNamedPipe() * won't give us the FILE_READ_ATTRIBUTES permission. We need that to probe * the state of the write buffer when we're trying to shutdown the pipe. */ server_flags |= UV_READABLE_PIPE | UV_WRITABLE_PIPE; client_flags |= UV_READABLE_PIPE; } if (flags & UV_WRITABLE_PIPE) { server_flags |= UV_READABLE_PIPE; client_flags |= UV_WRITABLE_PIPE; } server_flags |= UV_NONBLOCK_PIPE; if (flags & UV_NONBLOCK_PIPE || parent_pipe->ipc) { client_flags |= UV_NONBLOCK_PIPE; } err = uv__create_pipe_pair(&server_pipe, &client_pipe, server_flags, client_flags, 1, (char*) server_pipe); if (err) goto error; if (CreateIoCompletionPort(server_pipe, loop->iocp, (ULONG_PTR) parent_pipe, 0) == NULL) { err = GetLastError(); goto error; } parent_pipe->handle = server_pipe; *child_pipe_ptr = client_pipe; /* The server end is now readable and/or writable. */ if (flags & UV_READABLE_PIPE) parent_pipe->flags |= UV_HANDLE_WRITABLE; if (flags & UV_WRITABLE_PIPE) parent_pipe->flags |= UV_HANDLE_READABLE; return 0; error: if (server_pipe != INVALID_HANDLE_VALUE) CloseHandle(server_pipe); if (client_pipe != INVALID_HANDLE_VALUE) CloseHandle(client_pipe); return err; } static int uv__set_pipe_handle(uv_loop_t* loop, uv_pipe_t* handle, HANDLE pipeHandle, int fd, DWORD duplex_flags) { NTSTATUS nt_status; IO_STATUS_BLOCK io_status; FILE_MODE_INFORMATION mode_info; DWORD mode = PIPE_READMODE_BYTE | PIPE_WAIT; DWORD current_mode = 0; DWORD err = 0; assert(handle->flags & UV_HANDLE_CONNECTION); assert(!(handle->flags & UV_HANDLE_PIPESERVER)); if (handle->flags & UV_HANDLE_CLOSING) return UV_EINVAL; if (handle->handle != INVALID_HANDLE_VALUE) return UV_EBUSY; if (!SetNamedPipeHandleState(pipeHandle, &mode, NULL, NULL)) { err = GetLastError(); if (err == ERROR_ACCESS_DENIED) { /* * SetNamedPipeHandleState can fail if the handle doesn't have either * GENERIC_WRITE or FILE_WRITE_ATTRIBUTES. * But if the handle already has the desired wait and blocking modes * we can continue. */ if (!GetNamedPipeHandleState(pipeHandle, ¤t_mode, NULL, NULL, NULL, NULL, 0)) { return uv_translate_sys_error(GetLastError()); } else if (current_mode & PIPE_NOWAIT) { return UV_EACCES; } } else { /* If this returns ERROR_INVALID_PARAMETER we probably opened * something that is not a pipe. */ if (err == ERROR_INVALID_PARAMETER) { return UV_ENOTSOCK; } return uv_translate_sys_error(err); } } /* Check if the pipe was created with FILE_FLAG_OVERLAPPED. */ nt_status = pNtQueryInformationFile(pipeHandle, &io_status, &mode_info, sizeof(mode_info), FileModeInformation); if (nt_status != STATUS_SUCCESS) { return uv_translate_sys_error(err); } if (mode_info.Mode & FILE_SYNCHRONOUS_IO_ALERT || mode_info.Mode & FILE_SYNCHRONOUS_IO_NONALERT) { /* Non-overlapped pipe. */ handle->flags |= UV_HANDLE_NON_OVERLAPPED_PIPE; handle->pipe.conn.readfile_thread_handle = NULL; InitializeCriticalSection(&handle->pipe.conn.readfile_thread_lock); } else { /* Overlapped pipe. Try to associate with IOCP. */ if (CreateIoCompletionPort(pipeHandle, loop->iocp, (ULONG_PTR) handle, 0) == NULL) { handle->flags |= UV_HANDLE_EMULATE_IOCP; } } handle->handle = pipeHandle; handle->u.fd = fd; handle->flags |= duplex_flags; return 0; } static int pipe_alloc_accept(uv_loop_t* loop, uv_pipe_t* handle, uv_pipe_accept_t* req, BOOL firstInstance) { assert(req->pipeHandle == INVALID_HANDLE_VALUE); req->pipeHandle = CreateNamedPipeW(handle->name, PIPE_ACCESS_DUPLEX | FILE_FLAG_OVERLAPPED | WRITE_DAC | (firstInstance ? FILE_FLAG_FIRST_PIPE_INSTANCE : 0), PIPE_TYPE_BYTE | PIPE_READMODE_BYTE | PIPE_WAIT, PIPE_UNLIMITED_INSTANCES, 65536, 65536, 0, NULL); if (req->pipeHandle == INVALID_HANDLE_VALUE) { return 0; } /* Associate it with IOCP so we can get events. */ if (CreateIoCompletionPort(req->pipeHandle, loop->iocp, (ULONG_PTR) handle, 0) == NULL) { uv_fatal_error(GetLastError(), "CreateIoCompletionPort"); } /* Stash a handle in the server object for use from places such as * getsockname and chmod. As we transfer ownership of these to client * objects, we'll allocate new ones here. */ handle->handle = req->pipeHandle; return 1; } static DWORD WINAPI pipe_shutdown_thread_proc(void* parameter) { uv_loop_t* loop; uv_pipe_t* handle; uv_shutdown_t* req; req = (uv_shutdown_t*) parameter; assert(req); handle = (uv_pipe_t*) req->handle; assert(handle); loop = handle->loop; assert(loop); FlushFileBuffers(handle->handle); /* Post completed */ POST_COMPLETION_FOR_REQ(loop, req); return 0; } void uv__pipe_shutdown(uv_loop_t* loop, uv_pipe_t* handle, uv_shutdown_t *req) { DWORD result; NTSTATUS nt_status; IO_STATUS_BLOCK io_status; FILE_PIPE_LOCAL_INFORMATION pipe_info; assert(handle->flags & UV_HANDLE_CONNECTION); assert(req != NULL); assert(handle->stream.conn.write_reqs_pending == 0); SET_REQ_SUCCESS(req); if (handle->flags & UV_HANDLE_CLOSING) { uv__insert_pending_req(loop, (uv_req_t*) req); return; } /* Try to avoid flushing the pipe buffer in the thread pool. */ nt_status = pNtQueryInformationFile(handle->handle, &io_status, &pipe_info, sizeof pipe_info, FilePipeLocalInformation); if (nt_status != STATUS_SUCCESS) { SET_REQ_ERROR(req, pRtlNtStatusToDosError(nt_status)); handle->flags |= UV_HANDLE_WRITABLE; /* Questionable. */ uv__insert_pending_req(loop, (uv_req_t*) req); return; } if (pipe_info.OutboundQuota == pipe_info.WriteQuotaAvailable) { /* Short-circuit, no need to call FlushFileBuffers: * all writes have been read. */ uv__insert_pending_req(loop, (uv_req_t*) req); return; } /* Run FlushFileBuffers in the thread pool. */ result = QueueUserWorkItem(pipe_shutdown_thread_proc, req, WT_EXECUTELONGFUNCTION); if (!result) { SET_REQ_ERROR(req, GetLastError()); handle->flags |= UV_HANDLE_WRITABLE; /* Questionable. */ uv__insert_pending_req(loop, (uv_req_t*) req); return; } } void uv__pipe_endgame(uv_loop_t* loop, uv_pipe_t* handle) { uv__ipc_xfer_queue_item_t* xfer_queue_item; assert(handle->reqs_pending == 0); assert(handle->flags & UV_HANDLE_CLOSING); assert(!(handle->flags & UV_HANDLE_CLOSED)); if (handle->flags & UV_HANDLE_CONNECTION) { /* Free pending sockets */ while (!uv__queue_empty(&handle->pipe.conn.ipc_xfer_queue)) { struct uv__queue* q; SOCKET socket; q = uv__queue_head(&handle->pipe.conn.ipc_xfer_queue); uv__queue_remove(q); xfer_queue_item = uv__queue_data(q, uv__ipc_xfer_queue_item_t, member); /* Materialize socket and close it */ socket = WSASocketW(FROM_PROTOCOL_INFO, FROM_PROTOCOL_INFO, FROM_PROTOCOL_INFO, &xfer_queue_item->xfer_info.socket_info, 0, WSA_FLAG_OVERLAPPED); uv__free(xfer_queue_item); if (socket != INVALID_SOCKET) closesocket(socket); } handle->pipe.conn.ipc_xfer_queue_length = 0; if (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 != NULL) { CloseHandle(handle->read_req.event_handle); handle->read_req.event_handle = NULL; } } if (handle->flags & UV_HANDLE_NON_OVERLAPPED_PIPE) DeleteCriticalSection(&handle->pipe.conn.readfile_thread_lock); } if (handle->flags & UV_HANDLE_PIPESERVER) { assert(handle->pipe.serv.accept_reqs); uv__free(handle->pipe.serv.accept_reqs); handle->pipe.serv.accept_reqs = NULL; } uv__handle_close(handle); } void uv_pipe_pending_instances(uv_pipe_t* handle, int count) { if (handle->flags & UV_HANDLE_BOUND) return; handle->pipe.serv.pending_instances = count; handle->flags |= UV_HANDLE_PIPESERVER; } /* Creates a pipe server. */ int uv_pipe_bind(uv_pipe_t* handle, const char* name) { return uv_pipe_bind2(handle, name, strlen(name), 0); } int uv_pipe_bind2(uv_pipe_t* handle, const char* name, size_t namelen, unsigned int flags) { uv_loop_t* loop = handle->loop; int i, err, nameSize; uv_pipe_accept_t* req; if (flags & ~UV_PIPE_NO_TRUNCATE) { return UV_EINVAL; } if (name == NULL) { return UV_EINVAL; } if (namelen == 0) { return UV_EINVAL; } if (*name == '\0') { return UV_EINVAL; } if (flags & UV_PIPE_NO_TRUNCATE) { if (namelen > 256) { return UV_EINVAL; } } if (handle->flags & UV_HANDLE_BOUND) { return UV_EINVAL; } if (uv__is_closing(handle)) { return UV_EINVAL; } if (!(handle->flags & UV_HANDLE_PIPESERVER)) { handle->pipe.serv.pending_instances = default_pending_pipe_instances; } handle->pipe.serv.accept_reqs = (uv_pipe_accept_t*) uv__malloc(sizeof(uv_pipe_accept_t) * handle->pipe.serv.pending_instances); if (!handle->pipe.serv.accept_reqs) { uv_fatal_error(ERROR_OUTOFMEMORY, "uv__malloc"); } for (i = 0; i < handle->pipe.serv.pending_instances; i++) { req = &handle->pipe.serv.accept_reqs[i]; UV_REQ_INIT(req, UV_ACCEPT); req->data = handle; req->pipeHandle = INVALID_HANDLE_VALUE; req->next_pending = NULL; } /* Convert name to UTF16. */ nameSize = MultiByteToWideChar(CP_UTF8, 0, name, -1, NULL, 0) * sizeof(WCHAR); handle->name = uv__malloc(nameSize); if (!handle->name) { uv_fatal_error(ERROR_OUTOFMEMORY, "uv__malloc"); } if (!MultiByteToWideChar(CP_UTF8, 0, name, -1, handle->name, nameSize / sizeof(WCHAR))) { err = GetLastError(); goto error; } /* * Attempt to create the first pipe with FILE_FLAG_FIRST_PIPE_INSTANCE. * If this fails then there's already a pipe server for the given pipe name. */ if (!pipe_alloc_accept(loop, handle, &handle->pipe.serv.accept_reqs[0], TRUE)) { err = GetLastError(); if (err == ERROR_ACCESS_DENIED) { err = WSAEADDRINUSE; /* Translates to UV_EADDRINUSE. */ } else if (err == ERROR_PATH_NOT_FOUND || err == ERROR_INVALID_NAME) { err = WSAEACCES; /* Translates to UV_EACCES. */ } goto error; } handle->pipe.serv.pending_accepts = NULL; handle->flags |= UV_HANDLE_PIPESERVER; handle->flags |= UV_HANDLE_BOUND; return 0; error: if (handle->name) { uv__free(handle->name); handle->name = NULL; } return uv_translate_sys_error(err); } static DWORD WINAPI pipe_connect_thread_proc(void* parameter) { uv_loop_t* loop; uv_pipe_t* handle; uv_connect_t* req; HANDLE pipeHandle = INVALID_HANDLE_VALUE; DWORD duplex_flags; req = (uv_connect_t*) parameter; assert(req); handle = (uv_pipe_t*) req->handle; assert(handle); loop = handle->loop; assert(loop); /* We're here because CreateFile on a pipe returned ERROR_PIPE_BUSY. We wait * up to 30 seconds for the pipe to become available with WaitNamedPipe. */ while (WaitNamedPipeW(req->u.connect.name, 30000)) { /* The pipe is now available, try to connect. */ pipeHandle = open_named_pipe(req->u.connect.name, &duplex_flags); if (pipeHandle != INVALID_HANDLE_VALUE) break; SwitchToThread(); } uv__free(req->u.connect.name); req->u.connect.name = NULL; if (pipeHandle != INVALID_HANDLE_VALUE) { SET_REQ_SUCCESS(req); req->u.connect.pipeHandle = pipeHandle; req->u.connect.duplex_flags = duplex_flags; } else { SET_REQ_ERROR(req, GetLastError()); } /* Post completed */ POST_COMPLETION_FOR_REQ(loop, req); return 0; } void uv_pipe_connect(uv_connect_t* req, uv_pipe_t* handle, const char* name, uv_connect_cb cb) { uv_pipe_connect2(req, handle, name, strlen(name), 0, cb); } int uv_pipe_connect2(uv_connect_t* req, uv_pipe_t* handle, const char* name, size_t namelen, unsigned int flags, uv_connect_cb cb) { uv_loop_t* loop = handle->loop; int err, nameSize; HANDLE pipeHandle = INVALID_HANDLE_VALUE; DWORD duplex_flags; if (flags & ~UV_PIPE_NO_TRUNCATE) { return UV_EINVAL; } if (name == NULL) { return UV_EINVAL; } if (namelen == 0) { return UV_EINVAL; } if (*name == '\0') { return UV_EINVAL; } if (flags & UV_PIPE_NO_TRUNCATE) { if (namelen > 256) { return UV_EINVAL; } } UV_REQ_INIT(req, UV_CONNECT); req->handle = (uv_stream_t*) handle; req->cb = cb; req->u.connect.pipeHandle = INVALID_HANDLE_VALUE; req->u.connect.duplex_flags = 0; req->u.connect.name = NULL; if (handle->flags & UV_HANDLE_PIPESERVER) { err = ERROR_INVALID_PARAMETER; goto error; } if (handle->flags & UV_HANDLE_CONNECTION) { err = ERROR_PIPE_BUSY; goto error; } uv__pipe_connection_init(handle); /* Convert name to UTF16. */ nameSize = MultiByteToWideChar(CP_UTF8, 0, name, -1, NULL, 0) * sizeof(WCHAR); handle->name = uv__malloc(nameSize); if (!handle->name) { uv_fatal_error(ERROR_OUTOFMEMORY, "uv__malloc"); } if (!MultiByteToWideChar(CP_UTF8, 0, name, -1, handle->name, nameSize / sizeof(WCHAR))) { err = GetLastError(); goto error; } pipeHandle = open_named_pipe(handle->name, &duplex_flags); if (pipeHandle == INVALID_HANDLE_VALUE) { if (GetLastError() == ERROR_PIPE_BUSY) { req->u.connect.name = uv__malloc(nameSize); if (!req->u.connect.name) { uv_fatal_error(ERROR_OUTOFMEMORY, "uv__malloc"); } memcpy(req->u.connect.name, handle->name, nameSize); /* Wait for the server to make a pipe instance available. */ if (!QueueUserWorkItem(&pipe_connect_thread_proc, req, WT_EXECUTELONGFUNCTION)) { uv__free(req->u.connect.name); req->u.connect.name = NULL; err = GetLastError(); goto error; } REGISTER_HANDLE_REQ(loop, handle, req); handle->reqs_pending++; return 0; } err = GetLastError(); goto error; } req->u.connect.pipeHandle = pipeHandle; req->u.connect.duplex_flags = duplex_flags; SET_REQ_SUCCESS(req); uv__insert_pending_req(loop, (uv_req_t*) req); handle->reqs_pending++; REGISTER_HANDLE_REQ(loop, handle, req); return 0; error: if (handle->name) { uv__free(handle->name); handle->name = NULL; } if (pipeHandle != INVALID_HANDLE_VALUE) CloseHandle(pipeHandle); /* Make this req pending reporting an error. */ SET_REQ_ERROR(req, err); uv__insert_pending_req(loop, (uv_req_t*) req); handle->reqs_pending++; REGISTER_HANDLE_REQ(loop, handle, req); return 0; } void uv__pipe_interrupt_read(uv_pipe_t* handle) { BOOL r; if (!(handle->flags & UV_HANDLE_READ_PENDING)) return; /* No pending reads. */ if (handle->flags & UV_HANDLE_CANCELLATION_PENDING) return; /* Already cancelled. */ if (handle->handle == INVALID_HANDLE_VALUE) return; /* Pipe handle closed. */ if (!(handle->flags & UV_HANDLE_NON_OVERLAPPED_PIPE)) { /* Cancel asynchronous read. */ r = CancelIoEx(handle->handle, &handle->read_req.u.io.overlapped); assert(r || GetLastError() == ERROR_NOT_FOUND); (void) r; } else { /* Cancel synchronous read (which is happening in the thread pool). */ HANDLE thread; volatile HANDLE* thread_ptr = &handle->pipe.conn.readfile_thread_handle; EnterCriticalSection(&handle->pipe.conn.readfile_thread_lock); thread = *thread_ptr; if (thread == NULL) { /* The thread pool thread has not yet reached the point of blocking, we * can pre-empt it by setting thread_handle to INVALID_HANDLE_VALUE. */ *thread_ptr = INVALID_HANDLE_VALUE; } else { /* Spin until the thread has acknowledged (by setting the thread to * INVALID_HANDLE_VALUE) that it is past the point of blocking. */ while (thread != INVALID_HANDLE_VALUE) { r = CancelSynchronousIo(thread); assert(r || GetLastError() == ERROR_NOT_FOUND); SwitchToThread(); /* Yield thread. */ thread = *thread_ptr; } } LeaveCriticalSection(&handle->pipe.conn.readfile_thread_lock); } /* Set flag to indicate that read has been cancelled. */ handle->flags |= UV_HANDLE_CANCELLATION_PENDING; } void uv__pipe_read_stop(uv_pipe_t* handle) { handle->flags &= ~UV_HANDLE_READING; DECREASE_ACTIVE_COUNT(handle->loop, handle); uv__pipe_interrupt_read(handle); } /* Cleans up uv_pipe_t (server or connection) and all resources associated with * it. */ void uv__pipe_close(uv_loop_t* loop, uv_pipe_t* handle) { int i; HANDLE pipeHandle; if (handle->flags & UV_HANDLE_READING) { handle->flags &= ~UV_HANDLE_READING; DECREASE_ACTIVE_COUNT(loop, handle); } if (handle->flags & UV_HANDLE_LISTENING) { handle->flags &= ~UV_HANDLE_LISTENING; DECREASE_ACTIVE_COUNT(loop, handle); } handle->flags &= ~(UV_HANDLE_READABLE | UV_HANDLE_WRITABLE); uv__handle_closing(handle); uv__pipe_interrupt_read(handle); if (handle->name) { uv__free(handle->name); handle->name = NULL; } if (handle->flags & UV_HANDLE_PIPESERVER) { for (i = 0; i < handle->pipe.serv.pending_instances; i++) { pipeHandle = handle->pipe.serv.accept_reqs[i].pipeHandle; if (pipeHandle != INVALID_HANDLE_VALUE) { CloseHandle(pipeHandle); handle->pipe.serv.accept_reqs[i].pipeHandle = INVALID_HANDLE_VALUE; } } handle->handle = INVALID_HANDLE_VALUE; } if (handle->flags & UV_HANDLE_CONNECTION) { eof_timer_destroy(handle); } if ((handle->flags & UV_HANDLE_CONNECTION) && handle->handle != INVALID_HANDLE_VALUE) { /* This will eventually destroy the write queue for us too. */ close_pipe(handle); } if (handle->reqs_pending == 0) uv__want_endgame(loop, (uv_handle_t*) handle); } static void uv__pipe_queue_accept(uv_loop_t* loop, uv_pipe_t* handle, uv_pipe_accept_t* req, BOOL firstInstance) { assert(handle->flags & UV_HANDLE_LISTENING); if (!firstInstance && !pipe_alloc_accept(loop, handle, req, FALSE)) { SET_REQ_ERROR(req, GetLastError()); uv__insert_pending_req(loop, (uv_req_t*) req); handle->reqs_pending++; return; } assert(req->pipeHandle != INVALID_HANDLE_VALUE); /* Prepare the overlapped structure. */ memset(&(req->u.io.overlapped), 0, sizeof(req->u.io.overlapped)); if (!ConnectNamedPipe(req->pipeHandle, &req->u.io.overlapped) && GetLastError() != ERROR_IO_PENDING) { if (GetLastError() == ERROR_PIPE_CONNECTED) { SET_REQ_SUCCESS(req); } else { CloseHandle(req->pipeHandle); req->pipeHandle = INVALID_HANDLE_VALUE; /* Make this req pending reporting an error. */ SET_REQ_ERROR(req, GetLastError()); } uv__insert_pending_req(loop, (uv_req_t*) req); handle->reqs_pending++; return; } /* Wait for completion via IOCP */ handle->reqs_pending++; } int uv__pipe_accept(uv_pipe_t* server, uv_stream_t* client) { uv_loop_t* loop = server->loop; uv_pipe_t* pipe_client; uv_pipe_accept_t* req; struct uv__queue* q; uv__ipc_xfer_queue_item_t* item; int err; if (server->ipc) { if (uv__queue_empty(&server->pipe.conn.ipc_xfer_queue)) { /* No valid pending sockets. */ return WSAEWOULDBLOCK; } q = uv__queue_head(&server->pipe.conn.ipc_xfer_queue); uv__queue_remove(q); server->pipe.conn.ipc_xfer_queue_length--; item = uv__queue_data(q, uv__ipc_xfer_queue_item_t, member); err = uv__tcp_xfer_import( (uv_tcp_t*) client, item->xfer_type, &item->xfer_info); uv__free(item); if (err != 0) return err; } else { pipe_client = (uv_pipe_t*) client; uv__pipe_connection_init(pipe_client); /* Find a connection instance that has been connected, but not yet * accepted. */ req = server->pipe.serv.pending_accepts; if (!req) { /* No valid connections found, so we error out. */ return WSAEWOULDBLOCK; } /* Initialize the client handle and copy the pipeHandle to the client */ pipe_client->handle = req->pipeHandle; pipe_client->flags |= UV_HANDLE_READABLE | UV_HANDLE_WRITABLE; /* Prepare the req to pick up a new connection */ server->pipe.serv.pending_accepts = req->next_pending; req->next_pending = NULL; req->pipeHandle = INVALID_HANDLE_VALUE; server->handle = INVALID_HANDLE_VALUE; if (!(server->flags & UV_HANDLE_CLOSING)) { uv__pipe_queue_accept(loop, server, req, FALSE); } } return 0; } /* Starts listening for connections for the given pipe. */ int uv__pipe_listen(uv_pipe_t* handle, int backlog, uv_connection_cb cb) { uv_loop_t* loop = handle->loop; int i; if (handle->flags & UV_HANDLE_LISTENING) { handle->stream.serv.connection_cb = cb; } if (!(handle->flags & UV_HANDLE_BOUND)) { return WSAEINVAL; } if (handle->flags & UV_HANDLE_READING) { return WSAEISCONN; } if (!(handle->flags & UV_HANDLE_PIPESERVER)) { return ERROR_NOT_SUPPORTED; } if (handle->ipc) { return WSAEINVAL; } handle->flags |= UV_HANDLE_LISTENING; INCREASE_ACTIVE_COUNT(loop, handle); handle->stream.serv.connection_cb = cb; /* First pipe handle should have already been created in uv_pipe_bind */ assert(handle->pipe.serv.accept_reqs[0].pipeHandle != INVALID_HANDLE_VALUE); for (i = 0; i < handle->pipe.serv.pending_instances; i++) { uv__pipe_queue_accept(loop, handle, &handle->pipe.serv.accept_reqs[i], i == 0); } return 0; } static DWORD WINAPI uv_pipe_zero_readfile_thread_proc(void* arg) { uv_read_t* req = (uv_read_t*) arg; uv_pipe_t* handle = (uv_pipe_t*) req->data; uv_loop_t* loop = handle->loop; volatile HANDLE* thread_ptr = &handle->pipe.conn.readfile_thread_handle; CRITICAL_SECTION* lock = &handle->pipe.conn.readfile_thread_lock; HANDLE thread; DWORD bytes; DWORD err; assert(req->type == UV_READ); assert(handle->type == UV_NAMED_PIPE); err = 0; /* Create a handle to the current thread. */ if (!DuplicateHandle(GetCurrentProcess(), GetCurrentThread(), GetCurrentProcess(), &thread, 0, FALSE, DUPLICATE_SAME_ACCESS)) { err = GetLastError(); goto out1; } /* The lock needs to be held when thread handle is modified. */ EnterCriticalSection(lock); if (*thread_ptr == INVALID_HANDLE_VALUE) { /* uv__pipe_interrupt_read() cancelled reading before we got here. */ err = ERROR_OPERATION_ABORTED; } else { /* Let main thread know which worker thread is doing the blocking read. */ assert(*thread_ptr == NULL); *thread_ptr = thread; } LeaveCriticalSection(lock); if (err) goto out2; /* Block the thread until data is available on the pipe, or the read is * cancelled. */ if (!ReadFile(handle->handle, &uv_zero_, 0, &bytes, NULL)) err = GetLastError(); /* Let the main thread know the worker is past the point of blocking. */ assert(thread == *thread_ptr); *thread_ptr = INVALID_HANDLE_VALUE; /* Briefly acquire the mutex. Since the main thread holds the lock while it * is spinning trying to cancel this thread's I/O, we will block here until * it stops doing that. */ EnterCriticalSection(lock); LeaveCriticalSection(lock); out2: /* Close the handle to the current thread. */ CloseHandle(thread); out1: /* Set request status and post a completion record to the IOCP. */ if (err) SET_REQ_ERROR(req, err); else SET_REQ_SUCCESS(req); POST_COMPLETION_FOR_REQ(loop, req); return 0; } static DWORD WINAPI uv_pipe_writefile_thread_proc(void* parameter) { int result; DWORD bytes; uv_write_t* req = (uv_write_t*) parameter; uv_pipe_t* handle = (uv_pipe_t*) req->handle; uv_loop_t* loop = handle->loop; assert(req != NULL); assert(req->type == UV_WRITE); assert(handle->type == UV_NAMED_PIPE); result = WriteFile(handle->handle, req->write_buffer.base, req->write_buffer.len, &bytes, NULL); if (!result) { SET_REQ_ERROR(req, GetLastError()); } POST_COMPLETION_FOR_REQ(loop, req); return 0; } static void CALLBACK post_completion_read_wait(void* context, BOOLEAN timed_out) { uv_read_t* req; uv_tcp_t* handle; req = (uv_read_t*) context; assert(req != NULL); handle = (uv_tcp_t*)req->data; assert(handle != NULL); assert(!timed_out); if (!PostQueuedCompletionStatus(handle->loop->iocp, req->u.io.overlapped.InternalHigh, 0, &req->u.io.overlapped)) { uv_fatal_error(GetLastError(), "PostQueuedCompletionStatus"); } } static void CALLBACK post_completion_write_wait(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->u.io.overlapped.InternalHigh, 0, &req->u.io.overlapped)) { uv_fatal_error(GetLastError(), "PostQueuedCompletionStatus"); } } static void uv__pipe_queue_read(uv_loop_t* loop, uv_pipe_t* handle) { uv_read_t* req; int result; assert(handle->flags & UV_HANDLE_READING); assert(!(handle->flags & UV_HANDLE_READ_PENDING)); assert(handle->handle != INVALID_HANDLE_VALUE); req = &handle->read_req; if (handle->flags & UV_HANDLE_NON_OVERLAPPED_PIPE) { handle->pipe.conn.readfile_thread_handle = NULL; /* Reset cancellation. */ if (!QueueUserWorkItem(&uv_pipe_zero_readfile_thread_proc, req, WT_EXECUTELONGFUNCTION)) { /* Make this req pending reporting an error. */ SET_REQ_ERROR(req, GetLastError()); goto error; } } else { memset(&req->u.io.overlapped, 0, sizeof(req->u.io.overlapped)); if (handle->flags & UV_HANDLE_EMULATE_IOCP) { assert(req->event_handle != NULL); req->u.io.overlapped.hEvent = (HANDLE) ((uintptr_t) req->event_handle | 1); } /* Do 0-read */ result = ReadFile(handle->handle, &uv_zero_, 0, NULL, &req->u.io.overlapped); if (!result && GetLastError() != ERROR_IO_PENDING) { /* Make this req pending reporting an error. */ SET_REQ_ERROR(req, GetLastError()); goto error; } if (handle->flags & UV_HANDLE_EMULATE_IOCP) { if (req->wait_handle == INVALID_HANDLE_VALUE) { if (!RegisterWaitForSingleObject(&req->wait_handle, req->event_handle, post_completion_read_wait, (void*) req, INFINITE, WT_EXECUTEINWAITTHREAD)) { SET_REQ_ERROR(req, GetLastError()); goto error; } } } } /* Start the eof timer if there is one */ eof_timer_start(handle); handle->flags |= UV_HANDLE_READ_PENDING; handle->reqs_pending++; return; error: uv__insert_pending_req(loop, (uv_req_t*)req); handle->flags |= UV_HANDLE_READ_PENDING; handle->reqs_pending++; } int uv__pipe_read_start(uv_pipe_t* handle, uv_alloc_cb alloc_cb, uv_read_cb read_cb) { uv_loop_t* loop = handle->loop; handle->flags |= UV_HANDLE_READING; INCREASE_ACTIVE_COUNT(loop, handle); handle->read_cb = read_cb; handle->alloc_cb = alloc_cb; /* 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 == NULL) { handle->read_req.event_handle = CreateEvent(NULL, 0, 0, NULL); if (handle->read_req.event_handle == NULL) { uv_fatal_error(GetLastError(), "CreateEvent"); } } uv__pipe_queue_read(loop, handle); } return 0; } static void uv__insert_non_overlapped_write_req(uv_pipe_t* handle, uv_write_t* req) { req->next_req = NULL; if (handle->pipe.conn.non_overlapped_writes_tail) { req->next_req = handle->pipe.conn.non_overlapped_writes_tail->next_req; handle->pipe.conn.non_overlapped_writes_tail->next_req = (uv_req_t*)req; handle->pipe.conn.non_overlapped_writes_tail = req; } else { req->next_req = (uv_req_t*)req; handle->pipe.conn.non_overlapped_writes_tail = req; } } static uv_write_t* uv_remove_non_overlapped_write_req(uv_pipe_t* handle) { uv_write_t* req; if (handle->pipe.conn.non_overlapped_writes_tail) { req = (uv_write_t*)handle->pipe.conn.non_overlapped_writes_tail->next_req; if (req == handle->pipe.conn.non_overlapped_writes_tail) { handle->pipe.conn.non_overlapped_writes_tail = NULL; } else { handle->pipe.conn.non_overlapped_writes_tail->next_req = req->next_req; } return req; } else { /* queue empty */ return NULL; } } static void uv__queue_non_overlapped_write(uv_pipe_t* handle) { uv_write_t* req = uv_remove_non_overlapped_write_req(handle); if (req) { if (!QueueUserWorkItem(&uv_pipe_writefile_thread_proc, req, WT_EXECUTELONGFUNCTION)) { uv_fatal_error(GetLastError(), "QueueUserWorkItem"); } } } static int uv__build_coalesced_write_req(uv_write_t* user_req, const uv_buf_t bufs[], size_t nbufs, uv_write_t** req_out, uv_buf_t* write_buf_out) { /* Pack into a single heap-allocated buffer: * (a) a uv_write_t structure where libuv stores the actual state. * (b) a pointer to the original uv_write_t. * (c) data from all `bufs` entries. */ char* heap_buffer; size_t heap_buffer_length, heap_buffer_offset; uv__coalesced_write_t* coalesced_write_req; /* (a) + (b) */ char* data_start; /* (c) */ size_t data_length; unsigned int i; /* Compute combined size of all combined buffers from `bufs`. */ data_length = 0; for (i = 0; i < nbufs; i++) data_length += bufs[i].len; /* The total combined size of data buffers should not exceed UINT32_MAX, * because WriteFile() won't accept buffers larger than that. */ if (data_length > UINT32_MAX) return WSAENOBUFS; /* Maps to UV_ENOBUFS. */ /* Compute heap buffer size. */ heap_buffer_length = sizeof *coalesced_write_req + /* (a) + (b) */ data_length; /* (c) */ /* Allocate buffer. */ heap_buffer = uv__malloc(heap_buffer_length); if (heap_buffer == NULL) return ERROR_NOT_ENOUGH_MEMORY; /* Maps to UV_ENOMEM. */ /* Copy uv_write_t information to the buffer. */ coalesced_write_req = (uv__coalesced_write_t*) heap_buffer; coalesced_write_req->req = *user_req; /* copy (a) */ coalesced_write_req->req.coalesced = 1; coalesced_write_req->user_req = user_req; /* copy (b) */ heap_buffer_offset = sizeof *coalesced_write_req; /* offset (a) + (b) */ /* Copy data buffers to the heap buffer. */ data_start = &heap_buffer[heap_buffer_offset]; for (i = 0; i < nbufs; i++) { memcpy(&heap_buffer[heap_buffer_offset], bufs[i].base, bufs[i].len); /* copy (c) */ heap_buffer_offset += bufs[i].len; /* offset (c) */ } assert(heap_buffer_offset == heap_buffer_length); /* Set out arguments and return. */ *req_out = &coalesced_write_req->req; *write_buf_out = uv_buf_init(data_start, (unsigned int) data_length); return 0; } static int uv__pipe_write_data(uv_loop_t* loop, uv_write_t* req, uv_pipe_t* handle, const uv_buf_t bufs[], size_t nbufs, uv_write_cb cb, int copy_always) { int err; int result; uv_buf_t write_buf; assert(handle->handle != INVALID_HANDLE_VALUE); UV_REQ_INIT(req, UV_WRITE); req->handle = (uv_stream_t*) handle; req->send_handle = NULL; req->cb = cb; /* Private fields. */ req->coalesced = 0; req->event_handle = NULL; req->wait_handle = INVALID_HANDLE_VALUE; /* Prepare the overlapped structure. */ memset(&req->u.io.overlapped, 0, sizeof(req->u.io.overlapped)); if (handle->flags & (UV_HANDLE_EMULATE_IOCP | UV_HANDLE_BLOCKING_WRITES)) { req->event_handle = CreateEvent(NULL, 0, 0, NULL); if (req->event_handle == NULL) { uv_fatal_error(GetLastError(), "CreateEvent"); } req->u.io.overlapped.hEvent = (HANDLE) ((uintptr_t) req->event_handle | 1); } req->write_buffer = uv_null_buf_; if (nbufs == 0) { /* Write empty buffer. */ write_buf = uv_null_buf_; } else if (nbufs == 1 && !copy_always) { /* Write directly from bufs[0]. */ write_buf = bufs[0]; } else { /* Coalesce all `bufs` into one big buffer. This also creates a new * write-request structure that replaces the old one. */ err = uv__build_coalesced_write_req(req, bufs, nbufs, &req, &write_buf); if (err != 0) return err; } if ((handle->flags & (UV_HANDLE_BLOCKING_WRITES | UV_HANDLE_NON_OVERLAPPED_PIPE)) == (UV_HANDLE_BLOCKING_WRITES | UV_HANDLE_NON_OVERLAPPED_PIPE)) { DWORD bytes; result = WriteFile(handle->handle, write_buf.base, write_buf.len, &bytes, NULL); if (!result) { err = GetLastError(); return err; } else { /* Request completed immediately. */ req->u.io.queued_bytes = 0; } REGISTER_HANDLE_REQ(loop, handle, req); handle->reqs_pending++; handle->stream.conn.write_reqs_pending++; POST_COMPLETION_FOR_REQ(loop, req); return 0; } else if (handle->flags & UV_HANDLE_NON_OVERLAPPED_PIPE) { req->write_buffer = write_buf; uv__insert_non_overlapped_write_req(handle, req); if (handle->stream.conn.write_reqs_pending == 0) { uv__queue_non_overlapped_write(handle); } /* Request queued by the kernel. */ req->u.io.queued_bytes = write_buf.len; handle->write_queue_size += req->u.io.queued_bytes; } else if (handle->flags & UV_HANDLE_BLOCKING_WRITES) { /* Using overlapped IO, but wait for completion before returning */ result = WriteFile(handle->handle, write_buf.base, write_buf.len, NULL, &req->u.io.overlapped); if (!result && GetLastError() != ERROR_IO_PENDING) { err = GetLastError(); CloseHandle(req->event_handle); req->event_handle = NULL; return err; } if (result) { /* Request completed immediately. */ req->u.io.queued_bytes = 0; } else { /* Request queued by the kernel. */ req->u.io.queued_bytes = write_buf.len; handle->write_queue_size += req->u.io.queued_bytes; if (WaitForSingleObject(req->event_handle, INFINITE) != WAIT_OBJECT_0) { err = GetLastError(); CloseHandle(req->event_handle); req->event_handle = NULL; return err; } } CloseHandle(req->event_handle); req->event_handle = NULL; REGISTER_HANDLE_REQ(loop, handle, req); handle->reqs_pending++; handle->stream.conn.write_reqs_pending++; return 0; } else { result = WriteFile(handle->handle, write_buf.base, write_buf.len, NULL, &req->u.io.overlapped); if (!result && GetLastError() != ERROR_IO_PENDING) { return GetLastError(); } if (result) { /* Request completed immediately. */ req->u.io.queued_bytes = 0; } else { /* Request queued by the kernel. */ req->u.io.queued_bytes = write_buf.len; handle->write_queue_size += req->u.io.queued_bytes; } if (handle->flags & UV_HANDLE_EMULATE_IOCP) { if (!RegisterWaitForSingleObject(&req->wait_handle, req->event_handle, post_completion_write_wait, (void*) req, INFINITE, WT_EXECUTEINWAITTHREAD)) { return GetLastError(); } } } REGISTER_HANDLE_REQ(loop, handle, req); handle->reqs_pending++; handle->stream.conn.write_reqs_pending++; return 0; } static DWORD uv__pipe_get_ipc_remote_pid(uv_pipe_t* handle) { DWORD* pid = &handle->pipe.conn.ipc_remote_pid; /* If the both ends of the IPC pipe are owned by the same process, * the remote end pid may not yet be set. If so, do it here. * TODO: this is weird; it'd probably better to use a handshake. */ if (*pid == 0) { GetNamedPipeClientProcessId(handle->handle, pid); if (*pid == GetCurrentProcessId()) { GetNamedPipeServerProcessId(handle->handle, pid); } } return *pid; } int uv__pipe_write_ipc(uv_loop_t* loop, uv_write_t* req, uv_pipe_t* handle, const uv_buf_t data_bufs[], size_t data_buf_count, uv_stream_t* send_handle, uv_write_cb cb) { uv_buf_t stack_bufs[6]; uv_buf_t* bufs; size_t buf_count, buf_index; uv__ipc_frame_header_t frame_header; uv__ipc_socket_xfer_type_t xfer_type = UV__IPC_SOCKET_XFER_NONE; uv__ipc_socket_xfer_info_t xfer_info; uint64_t data_length; size_t i; int err; /* Compute the combined size of data buffers. */ data_length = 0; for (i = 0; i < data_buf_count; i++) data_length += data_bufs[i].len; if (data_length > UINT32_MAX) return WSAENOBUFS; /* Maps to UV_ENOBUFS. */ /* Prepare the frame's socket xfer payload. */ if (send_handle != NULL) { uv_tcp_t* send_tcp_handle = (uv_tcp_t*) send_handle; /* Verify that `send_handle` it is indeed a tcp handle. */ if (send_tcp_handle->type != UV_TCP) return ERROR_NOT_SUPPORTED; /* Export the tcp handle. */ err = uv__tcp_xfer_export(send_tcp_handle, uv__pipe_get_ipc_remote_pid(handle), &xfer_type, &xfer_info); if (err != 0) return err; } /* Compute the number of uv_buf_t's required. */ buf_count = 1 + data_buf_count; /* Frame header and data buffers. */ if (send_handle != NULL) buf_count += 1; /* One extra for the socket xfer information. */ /* Use the on-stack buffer array if it is big enough; otherwise allocate * space for it on the heap. */ if (buf_count < ARRAY_SIZE(stack_bufs)) { /* Use on-stack buffer array. */ bufs = stack_bufs; } else { /* Use heap-allocated buffer array. */ bufs = uv__calloc(buf_count, sizeof(uv_buf_t)); if (bufs == NULL) return ERROR_NOT_ENOUGH_MEMORY; /* Maps to UV_ENOMEM. */ } buf_index = 0; /* Initialize frame header and add it to the buffers list. */ memset(&frame_header, 0, sizeof frame_header); bufs[buf_index++] = uv_buf_init((char*) &frame_header, sizeof frame_header); if (send_handle != NULL) { /* Add frame header flags. */ switch (xfer_type) { case UV__IPC_SOCKET_XFER_TCP_CONNECTION: frame_header.flags |= UV__IPC_FRAME_HAS_SOCKET_XFER | UV__IPC_FRAME_XFER_IS_TCP_CONNECTION; break; case UV__IPC_SOCKET_XFER_TCP_SERVER: frame_header.flags |= UV__IPC_FRAME_HAS_SOCKET_XFER; break; default: assert(0); /* Unreachable. */ } /* Add xfer info buffer. */ bufs[buf_index++] = uv_buf_init((char*) &xfer_info, sizeof xfer_info); } if (data_length > 0) { /* Update frame header. */ frame_header.flags |= UV__IPC_FRAME_HAS_DATA; frame_header.data_length = (uint32_t) data_length; /* Add data buffers to buffers list. */ for (i = 0; i < data_buf_count; i++) bufs[buf_index++] = data_bufs[i]; } /* Write buffers. We set the `always_copy` flag, so it is not a problem that * some of the written data lives on the stack. */ err = uv__pipe_write_data(loop, req, handle, bufs, buf_count, cb, 1); /* If we had to heap-allocate the bufs array, free it now. */ if (bufs != stack_bufs) { uv__free(bufs); } return err; } int uv__pipe_write(uv_loop_t* loop, uv_write_t* req, uv_pipe_t* handle, const uv_buf_t bufs[], size_t nbufs, uv_stream_t* send_handle, uv_write_cb cb) { if (handle->ipc) { /* IPC pipe write: use framing protocol. */ return uv__pipe_write_ipc(loop, req, handle, bufs, nbufs, send_handle, cb); } else { /* Non-IPC pipe write: put data on the wire directly. */ assert(send_handle == NULL); return uv__pipe_write_data(loop, req, handle, bufs, nbufs, cb, 0); } } static void uv__pipe_read_eof(uv_loop_t* loop, uv_pipe_t* handle, uv_buf_t buf) { /* If there is an eof timer running, we don't need it any more, so discard * it. */ eof_timer_destroy(handle); uv_read_stop((uv_stream_t*) handle); handle->read_cb((uv_stream_t*) handle, UV_EOF, &buf); } static void uv__pipe_read_error(uv_loop_t* loop, uv_pipe_t* handle, int error, uv_buf_t buf) { /* If there is an eof timer running, we don't need it any more, so discard * it. */ eof_timer_destroy(handle); uv_read_stop((uv_stream_t*) handle); handle->read_cb((uv_stream_t*)handle, uv_translate_sys_error(error), &buf); } static void uv__pipe_read_error_or_eof(uv_loop_t* loop, uv_pipe_t* handle, int error, uv_buf_t buf) { if (error == ERROR_BROKEN_PIPE) { uv__pipe_read_eof(loop, handle, buf); } else { uv__pipe_read_error(loop, handle, error, buf); } } static void uv__pipe_queue_ipc_xfer_info( uv_pipe_t* handle, uv__ipc_socket_xfer_type_t xfer_type, uv__ipc_socket_xfer_info_t* xfer_info) { uv__ipc_xfer_queue_item_t* item; item = (uv__ipc_xfer_queue_item_t*) uv__malloc(sizeof(*item)); if (item == NULL) uv_fatal_error(ERROR_OUTOFMEMORY, "uv__malloc"); item->xfer_type = xfer_type; item->xfer_info = *xfer_info; uv__queue_insert_tail(&handle->pipe.conn.ipc_xfer_queue, &item->member); handle->pipe.conn.ipc_xfer_queue_length++; } /* Read an exact number of bytes from a pipe. If an error or end-of-file is * encountered before the requested number of bytes are read, an error is * returned. */ static int uv__pipe_read_exactly(HANDLE h, void* buffer, DWORD count) { DWORD bytes_read, bytes_read_now; bytes_read = 0; while (bytes_read < count) { if (!ReadFile(h, (char*) buffer + bytes_read, count - bytes_read, &bytes_read_now, NULL)) { return GetLastError(); } bytes_read += bytes_read_now; } assert(bytes_read == count); return 0; } static DWORD uv__pipe_read_data(uv_loop_t* loop, uv_pipe_t* handle, DWORD suggested_bytes, DWORD max_bytes) { DWORD bytes_read; uv_buf_t buf; /* Ask the user for a buffer to read data into. */ buf = uv_buf_init(NULL, 0); handle->alloc_cb((uv_handle_t*) handle, suggested_bytes, &buf); if (buf.base == NULL || buf.len == 0) { handle->read_cb((uv_stream_t*) handle, UV_ENOBUFS, &buf); return 0; /* Break out of read loop. */ } /* Ensure we read at most the smaller of: * (a) the length of the user-allocated buffer. * (b) the maximum data length as specified by the `max_bytes` argument. */ if (max_bytes > buf.len) max_bytes = buf.len; /* Read into the user buffer. */ if (!ReadFile(handle->handle, buf.base, max_bytes, &bytes_read, NULL)) { uv__pipe_read_error_or_eof(loop, handle, GetLastError(), buf); return 0; /* Break out of read loop. */ } /* Call the read callback. */ handle->read_cb((uv_stream_t*) handle, bytes_read, &buf); return bytes_read; } static DWORD uv__pipe_read_ipc(uv_loop_t* loop, uv_pipe_t* handle) { uint32_t* data_remaining = &handle->pipe.conn.ipc_data_frame.payload_remaining; int err; if (*data_remaining > 0) { /* Read frame data payload. */ DWORD bytes_read = uv__pipe_read_data(loop, handle, *data_remaining, *data_remaining); *data_remaining -= bytes_read; return bytes_read; } else { /* Start of a new IPC frame. */ uv__ipc_frame_header_t frame_header; uint32_t xfer_flags; uv__ipc_socket_xfer_type_t xfer_type; uv__ipc_socket_xfer_info_t xfer_info; /* Read the IPC frame header. */ err = uv__pipe_read_exactly( handle->handle, &frame_header, sizeof frame_header); if (err) goto error; /* Validate that flags are valid. */ if ((frame_header.flags & ~UV__IPC_FRAME_VALID_FLAGS) != 0) goto invalid; /* Validate that reserved2 is zero. */ if (frame_header.reserved2 != 0) goto invalid; /* Parse xfer flags. */ xfer_flags = frame_header.flags & UV__IPC_FRAME_XFER_FLAGS; if (xfer_flags & UV__IPC_FRAME_HAS_SOCKET_XFER) { /* Socket coming -- determine the type. */ xfer_type = xfer_flags & UV__IPC_FRAME_XFER_IS_TCP_CONNECTION ? UV__IPC_SOCKET_XFER_TCP_CONNECTION : UV__IPC_SOCKET_XFER_TCP_SERVER; } else if (xfer_flags == 0) { /* No socket. */ xfer_type = UV__IPC_SOCKET_XFER_NONE; } else { /* Invalid flags. */ goto invalid; } /* Parse data frame information. */ if (frame_header.flags & UV__IPC_FRAME_HAS_DATA) { *data_remaining = frame_header.data_length; } else if (frame_header.data_length != 0) { /* Data length greater than zero but data flag not set -- invalid. */ goto invalid; } /* If no socket xfer info follows, return here. Data will be read in a * subsequent invocation of uv__pipe_read_ipc(). */ if (xfer_type == UV__IPC_SOCKET_XFER_NONE) return sizeof frame_header; /* Number of bytes read. */ /* Read transferred socket information. */ err = uv__pipe_read_exactly(handle->handle, &xfer_info, sizeof xfer_info); if (err) goto error; /* Store the pending socket info. */ uv__pipe_queue_ipc_xfer_info(handle, xfer_type, &xfer_info); /* Return number of bytes read. */ return sizeof frame_header + sizeof xfer_info; } invalid: /* Invalid frame. */ err = WSAECONNABORTED; /* Maps to UV_ECONNABORTED. */ error: uv__pipe_read_error_or_eof(loop, handle, err, uv_null_buf_); return 0; /* Break out of read loop. */ } void uv__process_pipe_read_req(uv_loop_t* loop, uv_pipe_t* handle, uv_req_t* req) { assert(handle->type == UV_NAMED_PIPE); handle->flags &= ~(UV_HANDLE_READ_PENDING | UV_HANDLE_CANCELLATION_PENDING); DECREASE_PENDING_REQ_COUNT(handle); eof_timer_stop(handle); /* At this point, we're done with bookkeeping. If the user has stopped * reading the pipe in the meantime, there is nothing left to do, since there * is no callback that we can call. */ if (!(handle->flags & UV_HANDLE_READING)) return; if (!REQ_SUCCESS(req)) { /* An error occurred doing the zero-read. */ DWORD err = GET_REQ_ERROR(req); /* If the read was cancelled by uv__pipe_interrupt_read(), the request may * indicate an ERROR_OPERATION_ABORTED error. This error isn't relevant to * the user; we'll start a new zero-read at the end of this function. */ if (err != ERROR_OPERATION_ABORTED) uv__pipe_read_error_or_eof(loop, handle, err, uv_null_buf_); } else { /* The zero-read completed without error, indicating there is data * available in the kernel buffer. */ DWORD avail; /* Get the number of bytes available. */ avail = 0; if (!PeekNamedPipe(handle->handle, NULL, 0, NULL, &avail, NULL)) uv__pipe_read_error_or_eof(loop, handle, GetLastError(), uv_null_buf_); /* Read until we've either read all the bytes available, or the 'reading' * flag is cleared. */ while (avail > 0 && handle->flags & UV_HANDLE_READING) { /* Depending on the type of pipe, read either IPC frames or raw data. */ DWORD bytes_read = handle->ipc ? uv__pipe_read_ipc(loop, handle) : uv__pipe_read_data(loop, handle, avail, (DWORD) -1); /* If no bytes were read, treat this as an indication that an error * occurred, and break out of the read loop. */ if (bytes_read == 0) break; /* It is possible that more bytes were read than we thought were * available. To prevent `avail` from underflowing, break out of the loop * if this is the case. */ if (bytes_read > avail) break; /* Recompute the number of bytes available. */ avail -= bytes_read; } } /* Start another zero-read request if necessary. */ if ((handle->flags & UV_HANDLE_READING) && !(handle->flags & UV_HANDLE_READ_PENDING)) { uv__pipe_queue_read(loop, handle); } } void uv__process_pipe_write_req(uv_loop_t* loop, uv_pipe_t* handle, uv_write_t* req) { int err; assert(handle->type == UV_NAMED_PIPE); assert(handle->write_queue_size >= req->u.io.queued_bytes); handle->write_queue_size -= req->u.io.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); req->wait_handle = INVALID_HANDLE_VALUE; } if (req->event_handle) { CloseHandle(req->event_handle); req->event_handle = NULL; } } err = GET_REQ_ERROR(req); /* If this was a coalesced write, extract pointer to the user_provided * uv_write_t structure so we can pass the expected pointer to the callback, * then free the heap-allocated write req. */ if (req->coalesced) { uv__coalesced_write_t* coalesced_write = container_of(req, uv__coalesced_write_t, req); req = coalesced_write->user_req; uv__free(coalesced_write); } if (req->cb) { req->cb(req, uv_translate_sys_error(err)); } handle->stream.conn.write_reqs_pending--; if (handle->flags & UV_HANDLE_NON_OVERLAPPED_PIPE && handle->pipe.conn.non_overlapped_writes_tail) { assert(handle->stream.conn.write_reqs_pending > 0); uv__queue_non_overlapped_write(handle); } if (handle->stream.conn.write_reqs_pending == 0 && uv__is_stream_shutting(handle)) uv__pipe_shutdown(loop, handle, handle->stream.conn.shutdown_req); DECREASE_PENDING_REQ_COUNT(handle); } void uv__process_pipe_accept_req(uv_loop_t* loop, uv_pipe_t* handle, uv_req_t* raw_req) { uv_pipe_accept_t* req = (uv_pipe_accept_t*) raw_req; assert(handle->type == UV_NAMED_PIPE); if (handle->flags & UV_HANDLE_CLOSING) { /* The req->pipeHandle should be freed already in uv__pipe_close(). */ assert(req->pipeHandle == INVALID_HANDLE_VALUE); DECREASE_PENDING_REQ_COUNT(handle); return; } if (REQ_SUCCESS(req)) { assert(req->pipeHandle != INVALID_HANDLE_VALUE); req->next_pending = handle->pipe.serv.pending_accepts; handle->pipe.serv.pending_accepts = req; if (handle->stream.serv.connection_cb) { handle->stream.serv.connection_cb((uv_stream_t*)handle, 0); } } else { if (req->pipeHandle != INVALID_HANDLE_VALUE) { CloseHandle(req->pipeHandle); req->pipeHandle = INVALID_HANDLE_VALUE; } if (!(handle->flags & UV_HANDLE_CLOSING)) { uv__pipe_queue_accept(loop, handle, req, FALSE); } } DECREASE_PENDING_REQ_COUNT(handle); } void uv__process_pipe_connect_req(uv_loop_t* loop, uv_pipe_t* handle, uv_connect_t* req) { HANDLE pipeHandle; DWORD duplex_flags; int err; assert(handle->type == UV_NAMED_PIPE); UNREGISTER_HANDLE_REQ(loop, handle, req); err = 0; if (REQ_SUCCESS(req)) { pipeHandle = req->u.connect.pipeHandle; duplex_flags = req->u.connect.duplex_flags; if (handle->flags & UV_HANDLE_CLOSING) err = UV_ECANCELED; else err = uv__set_pipe_handle(loop, handle, pipeHandle, -1, duplex_flags); if (err) CloseHandle(pipeHandle); } else { err = uv_translate_sys_error(GET_REQ_ERROR(req)); } if (req->cb) req->cb(req, err); DECREASE_PENDING_REQ_COUNT(handle); } void uv__process_pipe_shutdown_req(uv_loop_t* loop, uv_pipe_t* handle, uv_shutdown_t* req) { int err; assert(handle->type == UV_NAMED_PIPE); /* Clear the shutdown_req field so we don't go here again. */ handle->stream.conn.shutdown_req = NULL; UNREGISTER_HANDLE_REQ(loop, handle, req); if (handle->flags & UV_HANDLE_CLOSING) { /* Already closing. Cancel the shutdown. */ err = UV_ECANCELED; } else if (!REQ_SUCCESS(req)) { /* An error occurred in trying to shutdown gracefully. */ err = uv_translate_sys_error(GET_REQ_ERROR(req)); } else { if (handle->flags & UV_HANDLE_READABLE) { /* Initialize and optionally start the eof timer. Only do this if the pipe * is readable and we haven't seen EOF come in ourselves. */ eof_timer_init(handle); /* If reading start the timer right now. Otherwise uv__pipe_queue_read will * start it. */ if (handle->flags & UV_HANDLE_READ_PENDING) { eof_timer_start(handle); } } else { /* This pipe is not readable. We can just close it to let the other end * know that we're done writing. */ close_pipe(handle); } err = 0; } if (req->cb) req->cb(req, err); DECREASE_PENDING_REQ_COUNT(handle); } static void eof_timer_init(uv_pipe_t* pipe) { int r; assert(pipe->pipe.conn.eof_timer == NULL); assert(pipe->flags & UV_HANDLE_CONNECTION); pipe->pipe.conn.eof_timer = (uv_timer_t*) uv__malloc(sizeof *pipe->pipe.conn.eof_timer); r = uv_timer_init(pipe->loop, pipe->pipe.conn.eof_timer); assert(r == 0); /* timers can't fail */ (void) r; pipe->pipe.conn.eof_timer->data = pipe; uv_unref((uv_handle_t*) pipe->pipe.conn.eof_timer); } static void eof_timer_start(uv_pipe_t* pipe) { assert(pipe->flags & UV_HANDLE_CONNECTION); if (pipe->pipe.conn.eof_timer != NULL) { uv_timer_start(pipe->pipe.conn.eof_timer, eof_timer_cb, eof_timeout, 0); } } static void eof_timer_stop(uv_pipe_t* pipe) { assert(pipe->flags & UV_HANDLE_CONNECTION); if (pipe->pipe.conn.eof_timer != NULL) { uv_timer_stop(pipe->pipe.conn.eof_timer); } } static void eof_timer_cb(uv_timer_t* timer) { uv_pipe_t* pipe = (uv_pipe_t*) timer->data; uv_loop_t* loop = timer->loop; assert(pipe->type == UV_NAMED_PIPE); /* This should always be true, since we start the timer only in * uv__pipe_queue_read after successfully calling ReadFile, or in * uv__process_pipe_shutdown_req if a read is pending, and we always * immediately stop the timer in uv__process_pipe_read_req. */ assert(pipe->flags & UV_HANDLE_READ_PENDING); /* If there are many packets coming off the iocp then the timer callback may * be called before the read request is coming off the queue. Therefore we * check here if the read request has completed but will be processed later. */ if ((pipe->flags & UV_HANDLE_READ_PENDING) && HasOverlappedIoCompleted(&pipe->read_req.u.io.overlapped)) { return; } /* Force both ends off the pipe. */ close_pipe(pipe); /* Stop reading, so the pending read that is going to fail will not be * reported to the user. */ uv_read_stop((uv_stream_t*) pipe); /* Report the eof and update flags. This will get reported even if the user * stopped reading in the meantime. TODO: is that okay? */ uv__pipe_read_eof(loop, pipe, uv_null_buf_); } static void eof_timer_destroy(uv_pipe_t* pipe) { assert(pipe->flags & UV_HANDLE_CONNECTION); if (pipe->pipe.conn.eof_timer) { uv_close((uv_handle_t*) pipe->pipe.conn.eof_timer, eof_timer_close_cb); pipe->pipe.conn.eof_timer = NULL; } } static void eof_timer_close_cb(uv_handle_t* handle) { assert(handle->type == UV_TIMER); uv__free(handle); } int uv_pipe_open(uv_pipe_t* pipe, uv_file file) { HANDLE os_handle = uv__get_osfhandle(file); NTSTATUS nt_status; IO_STATUS_BLOCK io_status; FILE_ACCESS_INFORMATION access; DWORD duplex_flags = 0; int err; if (os_handle == INVALID_HANDLE_VALUE) return UV_EBADF; if (pipe->flags & UV_HANDLE_PIPESERVER) return UV_EINVAL; if (pipe->flags & UV_HANDLE_CONNECTION) return UV_EBUSY; uv__pipe_connection_init(pipe); uv__once_init(); /* In order to avoid closing a stdio file descriptor 0-2, duplicate the * underlying OS handle and forget about the original fd. * We could also opt to use the original OS handle and just never close it, * but then there would be no reliable way to cancel pending read operations * upon close. */ if (file <= 2) { if (!DuplicateHandle(INVALID_HANDLE_VALUE, os_handle, INVALID_HANDLE_VALUE, &os_handle, 0, FALSE, DUPLICATE_SAME_ACCESS)) return uv_translate_sys_error(GetLastError()); assert(os_handle != INVALID_HANDLE_VALUE); file = -1; } /* Determine what kind of permissions we have on this handle. * Cygwin opens the pipe in message mode, but we can support it, * just query the access flags and set the stream flags accordingly. */ nt_status = pNtQueryInformationFile(os_handle, &io_status, &access, sizeof(access), FileAccessInformation); if (nt_status != STATUS_SUCCESS) return UV_EINVAL; if (pipe->ipc) { if (!(access.AccessFlags & FILE_WRITE_DATA) || !(access.AccessFlags & FILE_READ_DATA)) { return UV_EINVAL; } } if (access.AccessFlags & FILE_WRITE_DATA) duplex_flags |= UV_HANDLE_WRITABLE; if (access.AccessFlags & FILE_READ_DATA) duplex_flags |= UV_HANDLE_READABLE; err = uv__set_pipe_handle(pipe->loop, pipe, os_handle, file, duplex_flags); if (err) { if (file == -1) CloseHandle(os_handle); return err; } if (pipe->ipc) { assert(!(pipe->flags & UV_HANDLE_NON_OVERLAPPED_PIPE)); GetNamedPipeClientProcessId(os_handle, &pipe->pipe.conn.ipc_remote_pid); if (pipe->pipe.conn.ipc_remote_pid == GetCurrentProcessId()) { GetNamedPipeServerProcessId(os_handle, &pipe->pipe.conn.ipc_remote_pid); } assert(pipe->pipe.conn.ipc_remote_pid != (DWORD)(uv_pid_t) -1); } return 0; } static int uv__pipe_getname(const uv_pipe_t* handle, char* buffer, size_t* size) { NTSTATUS nt_status; IO_STATUS_BLOCK io_status; FILE_NAME_INFORMATION tmp_name_info; FILE_NAME_INFORMATION* name_info; WCHAR* name_buf; unsigned int addrlen; unsigned int name_size; unsigned int name_len; int err; uv__once_init(); name_info = NULL; if (handle->name != NULL) { /* The user might try to query the name before we are connected, * and this is just easier to return the cached value if we have it. */ name_buf = handle->name; name_len = wcslen(name_buf); /* check how much space we need */ addrlen = WideCharToMultiByte(CP_UTF8, 0, name_buf, name_len, NULL, 0, NULL, NULL); if (!addrlen) { *size = 0; err = uv_translate_sys_error(GetLastError()); return err; } else if (addrlen >= *size) { *size = addrlen + 1; err = UV_ENOBUFS; goto error; } addrlen = WideCharToMultiByte(CP_UTF8, 0, name_buf, name_len, buffer, addrlen, NULL, NULL); if (!addrlen) { *size = 0; err = uv_translate_sys_error(GetLastError()); return err; } *size = addrlen; buffer[addrlen] = '\0'; return 0; } if (handle->handle == INVALID_HANDLE_VALUE) { *size = 0; return UV_EINVAL; } /* NtQueryInformationFile will block if another thread is performing a * blocking operation on the queried handle. If the pipe handle is * synchronous, there may be a worker thread currently calling ReadFile() on * the pipe handle, which could cause a deadlock. To avoid this, interrupt * the read. */ if (handle->flags & UV_HANDLE_CONNECTION && handle->flags & UV_HANDLE_NON_OVERLAPPED_PIPE) { uv__pipe_interrupt_read((uv_pipe_t*) handle); /* cast away const warning */ } nt_status = pNtQueryInformationFile(handle->handle, &io_status, &tmp_name_info, sizeof tmp_name_info, FileNameInformation); if (nt_status == STATUS_BUFFER_OVERFLOW) { name_size = sizeof(*name_info) + tmp_name_info.FileNameLength; name_info = uv__malloc(name_size); if (!name_info) { *size = 0; err = UV_ENOMEM; goto cleanup; } nt_status = pNtQueryInformationFile(handle->handle, &io_status, name_info, name_size, FileNameInformation); } if (nt_status != STATUS_SUCCESS) { *size = 0; err = uv_translate_sys_error(pRtlNtStatusToDosError(nt_status)); goto error; } if (!name_info) { /* the struct on stack was used */ name_buf = tmp_name_info.FileName; name_len = tmp_name_info.FileNameLength; } else { name_buf = name_info->FileName; name_len = name_info->FileNameLength; } if (name_len == 0) { *size = 0; err = 0; goto error; } name_len /= sizeof(WCHAR); /* check how much space we need */ addrlen = WideCharToMultiByte(CP_UTF8, 0, name_buf, name_len, NULL, 0, NULL, NULL); if (!addrlen) { *size = 0; err = uv_translate_sys_error(GetLastError()); goto error; } else if (pipe_prefix_len + addrlen >= *size) { /* "\\\\.\\pipe" + name */ *size = pipe_prefix_len + addrlen + 1; err = UV_ENOBUFS; goto error; } memcpy(buffer, pipe_prefix, pipe_prefix_len); addrlen = WideCharToMultiByte(CP_UTF8, 0, name_buf, name_len, buffer+pipe_prefix_len, *size-pipe_prefix_len, NULL, NULL); if (!addrlen) { *size = 0; err = uv_translate_sys_error(GetLastError()); goto error; } addrlen += pipe_prefix_len; *size = addrlen; buffer[addrlen] = '\0'; err = 0; error: uv__free(name_info); cleanup: return err; } int uv_pipe_pending_count(uv_pipe_t* handle) { if (!handle->ipc) return 0; return handle->pipe.conn.ipc_xfer_queue_length; } int uv_pipe_getsockname(const uv_pipe_t* handle, char* buffer, size_t* size) { if (handle->flags & UV_HANDLE_BOUND) return uv__pipe_getname(handle, buffer, size); if (handle->flags & UV_HANDLE_CONNECTION || handle->handle != INVALID_HANDLE_VALUE) { *size = 0; return 0; } return UV_EBADF; } int uv_pipe_getpeername(const uv_pipe_t* handle, char* buffer, size_t* size) { /* emulate unix behaviour */ if (handle->flags & UV_HANDLE_BOUND) return UV_ENOTCONN; if (handle->handle != INVALID_HANDLE_VALUE) return uv__pipe_getname(handle, buffer, size); if (handle->flags & UV_HANDLE_CONNECTION) { if (handle->name != NULL) return uv__pipe_getname(handle, buffer, size); } return UV_EBADF; } uv_handle_type uv_pipe_pending_type(uv_pipe_t* handle) { if (!handle->ipc) return UV_UNKNOWN_HANDLE; if (handle->pipe.conn.ipc_xfer_queue_length == 0) return UV_UNKNOWN_HANDLE; else return UV_TCP; } int uv_pipe_chmod(uv_pipe_t* handle, int mode) { SID_IDENTIFIER_AUTHORITY sid_world = { SECURITY_WORLD_SID_AUTHORITY }; PACL old_dacl, new_dacl; PSECURITY_DESCRIPTOR sd; EXPLICIT_ACCESS ea; PSID everyone; int error; if (handle == NULL || handle->handle == INVALID_HANDLE_VALUE) return UV_EBADF; if (mode != UV_READABLE && mode != UV_WRITABLE && mode != (UV_WRITABLE | UV_READABLE)) return UV_EINVAL; if (!AllocateAndInitializeSid(&sid_world, 1, SECURITY_WORLD_RID, 0, 0, 0, 0, 0, 0, 0, &everyone)) { error = GetLastError(); goto done; } if (GetSecurityInfo(handle->handle, SE_KERNEL_OBJECT, DACL_SECURITY_INFORMATION, NULL, NULL, &old_dacl, NULL, &sd)) { error = GetLastError(); goto clean_sid; } memset(&ea, 0, sizeof(EXPLICIT_ACCESS)); if (mode & UV_READABLE) ea.grfAccessPermissions |= GENERIC_READ | FILE_WRITE_ATTRIBUTES; if (mode & UV_WRITABLE) ea.grfAccessPermissions |= GENERIC_WRITE | FILE_READ_ATTRIBUTES; ea.grfAccessPermissions |= SYNCHRONIZE; ea.grfAccessMode = SET_ACCESS; ea.grfInheritance = NO_INHERITANCE; ea.Trustee.TrusteeForm = TRUSTEE_IS_SID; ea.Trustee.TrusteeType = TRUSTEE_IS_WELL_KNOWN_GROUP; ea.Trustee.ptstrName = (LPTSTR)everyone; if (SetEntriesInAcl(1, &ea, old_dacl, &new_dacl)) { error = GetLastError(); goto clean_sd; } if (SetSecurityInfo(handle->handle, SE_KERNEL_OBJECT, DACL_SECURITY_INFORMATION, NULL, NULL, new_dacl, NULL)) { error = GetLastError(); goto clean_dacl; } error = 0; clean_dacl: LocalFree((HLOCAL) new_dacl); clean_sd: LocalFree((HLOCAL) sd); clean_sid: FreeSid(everyone); done: return uv_translate_sys_error(error); }