/* 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 "uv.h" #include "internal.h" #include #include #include #include #include #include #include #include #include #if defined(__APPLE__) && !TARGET_OS_IPHONE # include # define environ (*_NSGetEnviron()) #else extern char **environ; #endif #ifdef __linux__ # include #endif static void uv__chld(uv_signal_t* handle, int signum) { uv_process_t* process; uv_loop_t* loop; int exit_status; int term_signal; int status; pid_t pid; QUEUE pending; QUEUE* q; QUEUE* h; assert(signum == SIGCHLD); QUEUE_INIT(&pending); loop = handle->loop; h = &loop->process_handles; q = QUEUE_HEAD(h); while (q != h) { process = QUEUE_DATA(q, uv_process_t, queue); q = QUEUE_NEXT(q); do pid = waitpid(process->pid, &status, WNOHANG); while (pid == -1 && errno == EINTR); if (pid == 0) continue; if (pid == -1) { if (errno != ECHILD) abort(); continue; } process->status = status; QUEUE_REMOVE(&process->queue); QUEUE_INSERT_TAIL(&pending, &process->queue); } h = &pending; q = QUEUE_HEAD(h); while (q != h) { process = QUEUE_DATA(q, uv_process_t, queue); q = QUEUE_NEXT(q); QUEUE_REMOVE(&process->queue); QUEUE_INIT(&process->queue); uv__handle_stop(process); if (process->exit_cb == NULL) continue; exit_status = 0; if (WIFEXITED(process->status)) exit_status = WEXITSTATUS(process->status); term_signal = 0; if (WIFSIGNALED(process->status)) term_signal = WTERMSIG(process->status); process->exit_cb(process, exit_status, term_signal); } assert(QUEUE_EMPTY(&pending)); } int uv__make_socketpair(int fds[2], int flags) { #if defined(__linux__) static int no_cloexec; if (no_cloexec) goto skip; if (socketpair(AF_UNIX, SOCK_STREAM | UV__SOCK_CLOEXEC | flags, 0, fds) == 0) return 0; /* Retry on EINVAL, it means SOCK_CLOEXEC is not supported. * Anything else is a genuine error. */ if (errno != EINVAL) return -errno; no_cloexec = 1; skip: #endif if (socketpair(AF_UNIX, SOCK_STREAM, 0, fds)) return -errno; uv__cloexec(fds[0], 1); uv__cloexec(fds[1], 1); if (flags & UV__F_NONBLOCK) { uv__nonblock(fds[0], 1); uv__nonblock(fds[1], 1); } return 0; } int uv__make_pipe(int fds[2], int flags) { #if defined(__linux__) static int no_pipe2; if (no_pipe2) goto skip; if (uv__pipe2(fds, flags | UV__O_CLOEXEC) == 0) return 0; if (errno != ENOSYS) return -errno; no_pipe2 = 1; skip: #endif if (pipe(fds)) return -errno; uv__cloexec(fds[0], 1); uv__cloexec(fds[1], 1); if (flags & UV__F_NONBLOCK) { uv__nonblock(fds[0], 1); uv__nonblock(fds[1], 1); } return 0; } /* * Used for initializing stdio streams like options.stdin_stream. Returns * zero on success. See also the cleanup section in uv_spawn(). */ static int uv__process_init_stdio(uv_stdio_container_t* container, int fds[2]) { int mask; int fd; mask = UV_IGNORE | UV_CREATE_PIPE | UV_INHERIT_FD | UV_INHERIT_STREAM; switch (container->flags & mask) { case UV_IGNORE: return 0; case UV_CREATE_PIPE: assert(container->data.stream != NULL); if (container->data.stream->type != UV_NAMED_PIPE) return -EINVAL; else return uv__make_socketpair(fds, 0); case UV_INHERIT_FD: case UV_INHERIT_STREAM: if (container->flags & UV_INHERIT_FD) fd = container->data.fd; else fd = uv__stream_fd(container->data.stream); if (fd == -1) return -EINVAL; fds[1] = fd; return 0; default: assert(0 && "Unexpected flags"); return -EINVAL; } } static int uv__process_open_stream(uv_stdio_container_t* container, int pipefds[2], int writable) { int flags; if (!(container->flags & UV_CREATE_PIPE) || pipefds[0] < 0) return 0; if (uv__close(pipefds[1])) if (errno != EINTR && errno != EINPROGRESS) abort(); pipefds[1] = -1; uv__nonblock(pipefds[0], 1); if (container->data.stream->type == UV_NAMED_PIPE && ((uv_pipe_t*)container->data.stream)->ipc) flags = UV_STREAM_READABLE | UV_STREAM_WRITABLE; else if (writable) flags = UV_STREAM_WRITABLE; else flags = UV_STREAM_READABLE; return uv__stream_open(container->data.stream, pipefds[0], flags); } static void uv__process_close_stream(uv_stdio_container_t* container) { if (!(container->flags & UV_CREATE_PIPE)) return; uv__stream_close((uv_stream_t*)container->data.stream); } static void uv__write_int(int fd, int val) { ssize_t n; do n = write(fd, &val, sizeof(val)); while (n == -1 && errno == EINTR); if (n == -1 && errno == EPIPE) return; /* parent process has quit */ assert(n == sizeof(val)); } static void uv__process_child_init(const uv_process_options_t* options, int stdio_count, int (*pipes)[2], int error_fd) { int close_fd; int use_fd; int fd; if (options->flags & UV_PROCESS_DETACHED) setsid(); /* First duplicate low numbered fds, since it's not safe to duplicate them, * they could get replaced. Example: swapping stdout and stderr; without * this fd 2 (stderr) would be duplicated into fd 1, thus making both * stdout and stderr go to the same fd, which was not the intention. */ for (fd = 0; fd < stdio_count; fd++) { use_fd = pipes[fd][1]; if (use_fd < 0 || use_fd >= fd) continue; pipes[fd][1] = fcntl(use_fd, F_DUPFD, stdio_count); if (pipes[fd][1] == -1) { uv__write_int(error_fd, -errno); _exit(127); } } for (fd = 0; fd < stdio_count; fd++) { close_fd = pipes[fd][0]; use_fd = pipes[fd][1]; if (use_fd < 0) { if (fd >= 3) continue; else { /* redirect stdin, stdout and stderr to /dev/null even if UV_IGNORE is * set */ use_fd = open("/dev/null", fd == 0 ? O_RDONLY : O_RDWR); close_fd = use_fd; if (use_fd == -1) { uv__write_int(error_fd, -errno); _exit(127); } } } if (fd == use_fd) uv__cloexec(use_fd, 0); else fd = dup2(use_fd, fd); if (fd == -1) { uv__write_int(error_fd, -errno); _exit(127); } if (fd <= 2) uv__nonblock(fd, 0); if (close_fd >= stdio_count) uv__close(close_fd); } for (fd = 0; fd < stdio_count; fd++) { use_fd = pipes[fd][1]; if (use_fd >= stdio_count) uv__close(use_fd); } if (options->cwd != NULL && chdir(options->cwd)) { uv__write_int(error_fd, -errno); _exit(127); } if (options->flags & (UV_PROCESS_SETUID | UV_PROCESS_SETGID)) { /* When dropping privileges from root, the `setgroups` call will * remove any extraneous groups. If we don't call this, then * even though our uid has dropped, we may still have groups * that enable us to do super-user things. This will fail if we * aren't root, so don't bother checking the return value, this * is just done as an optimistic privilege dropping function. */ SAVE_ERRNO(setgroups(0, NULL)); } if ((options->flags & UV_PROCESS_SETGID) && setgid(options->gid)) { uv__write_int(error_fd, -errno); _exit(127); } if ((options->flags & UV_PROCESS_SETUID) && setuid(options->uid)) { uv__write_int(error_fd, -errno); _exit(127); } if (options->env != NULL) { environ = options->env; } execvp(options->file, options->args); uv__write_int(error_fd, -errno); _exit(127); } int uv_spawn(uv_loop_t* loop, uv_process_t* process, const uv_process_options_t* options) { int signal_pipe[2] = { -1, -1 }; int (*pipes)[2]; int stdio_count; ssize_t r; pid_t pid; int err; int exec_errorno; int i; int status; assert(options->file != NULL); assert(!(options->flags & ~(UV_PROCESS_DETACHED | UV_PROCESS_SETGID | UV_PROCESS_SETUID | UV_PROCESS_WINDOWS_HIDE | UV_PROCESS_WINDOWS_VERBATIM_ARGUMENTS))); uv__handle_init(loop, (uv_handle_t*)process, UV_PROCESS); QUEUE_INIT(&process->queue); stdio_count = options->stdio_count; if (stdio_count < 3) stdio_count = 3; err = -ENOMEM; pipes = uv__malloc(stdio_count * sizeof(*pipes)); if (pipes == NULL) goto error; for (i = 0; i < stdio_count; i++) { pipes[i][0] = -1; pipes[i][1] = -1; } for (i = 0; i < options->stdio_count; i++) { err = uv__process_init_stdio(options->stdio + i, pipes[i]); if (err) goto error; } /* This pipe is used by the parent to wait until * the child has called `execve()`. We need this * to avoid the following race condition: * * if ((pid = fork()) > 0) { * kill(pid, SIGTERM); * } * else if (pid == 0) { * execve("/bin/cat", argp, envp); * } * * The parent sends a signal immediately after forking. * Since the child may not have called `execve()` yet, * there is no telling what process receives the signal, * our fork or /bin/cat. * * To avoid ambiguity, we create a pipe with both ends * marked close-on-exec. Then, after the call to `fork()`, * the parent polls the read end until it EOFs or errors with EPIPE. */ err = uv__make_pipe(signal_pipe, 0); if (err) goto error; uv_signal_start(&loop->child_watcher, uv__chld, SIGCHLD); /* Acquire write lock to prevent opening new fds in worker threads */ uv_rwlock_wrlock(&loop->cloexec_lock); pid = fork(); if (pid == -1) { err = -errno; uv_rwlock_wrunlock(&loop->cloexec_lock); uv__close(signal_pipe[0]); uv__close(signal_pipe[1]); goto error; } if (pid == 0) { uv__process_child_init(options, stdio_count, pipes, signal_pipe[1]); abort(); } /* Release lock in parent process */ uv_rwlock_wrunlock(&loop->cloexec_lock); uv__close(signal_pipe[1]); process->status = 0; exec_errorno = 0; do r = read(signal_pipe[0], &exec_errorno, sizeof(exec_errorno)); while (r == -1 && errno == EINTR); if (r == 0) ; /* okay, EOF */ else if (r == sizeof(exec_errorno)) { do err = waitpid(pid, &status, 0); /* okay, read errorno */ while (err == -1 && errno == EINTR); assert(err == pid); } else if (r == -1 && errno == EPIPE) { do err = waitpid(pid, &status, 0); /* okay, got EPIPE */ while (err == -1 && errno == EINTR); assert(err == pid); } else abort(); uv__close(signal_pipe[0]); for (i = 0; i < options->stdio_count; i++) { err = uv__process_open_stream(options->stdio + i, pipes[i], i == 0); if (err == 0) continue; while (i--) uv__process_close_stream(options->stdio + i); goto error; } /* Only activate this handle if exec() happened successfully */ if (exec_errorno == 0) { QUEUE_INSERT_TAIL(&loop->process_handles, &process->queue); uv__handle_start(process); } process->pid = pid; process->exit_cb = options->exit_cb; uv__free(pipes); return exec_errorno; error: if (pipes != NULL) { for (i = 0; i < stdio_count; i++) { if (i < options->stdio_count) if (options->stdio[i].flags & (UV_INHERIT_FD | UV_INHERIT_STREAM)) continue; if (pipes[i][0] != -1) close(pipes[i][0]); if (pipes[i][1] != -1) close(pipes[i][1]); } uv__free(pipes); } return err; } int uv_process_kill(uv_process_t* process, int signum) { return uv_kill(process->pid, signum); } int uv_kill(int pid, int signum) { if (kill(pid, signum)) return -errno; else return 0; } void uv__process_close(uv_process_t* handle) { QUEUE_REMOVE(&handle->queue); uv__handle_stop(handle); if (QUEUE_EMPTY(&handle->loop->process_handles)) uv_signal_stop(&handle->loop->child_watcher); }