// Copyright © Tavian Barnes // SPDX-License-Identifier: 0BSD #include "xspawn.h" #include "alloc.h" #include "bfstd.h" #include "config.h" #include "list.h" #include #include #include #include #include #include #include #if BFS_USE_PATHS_H # include #endif #if _POSIX_SPAWN > 0 # include #endif /** * Types of spawn actions. */ enum bfs_spawn_op { BFS_SPAWN_OPEN, BFS_SPAWN_CLOSE, BFS_SPAWN_DUP2, BFS_SPAWN_FCHDIR, BFS_SPAWN_SETRLIMIT, }; /** * A spawn action. */ struct bfs_spawn_action { /** The next action in the list. */ struct bfs_spawn_action *next; /** This action's operation. */ enum bfs_spawn_op op; /** The input fd (or -1). */ int in_fd; /** The output fd (or -1). */ int out_fd; /** Operation-specific args. */ union { /** BFS_SPAWN_OPEN args. */ struct { const char *path; int flags; mode_t mode; }; /** BFS_SPAWN_SETRLIMIT args. */ struct { int resource; struct rlimit rlimit; }; }; }; int bfs_spawn_init(struct bfs_spawn *ctx) { ctx->flags = 0; SLIST_INIT(ctx); #if _POSIX_SPAWN > 0 ctx->flags |= BFS_SPAWN_USE_POSIX; errno = posix_spawn_file_actions_init(&ctx->actions); if (errno != 0) { return -1; } errno = posix_spawnattr_init(&ctx->attr); if (errno != 0) { posix_spawn_file_actions_destroy(&ctx->actions); return -1; } #endif return 0; } int bfs_spawn_destroy(struct bfs_spawn *ctx) { #if _POSIX_SPAWN > 0 posix_spawnattr_destroy(&ctx->attr); posix_spawn_file_actions_destroy(&ctx->actions); #endif for_slist (struct bfs_spawn_action, action, ctx) { free(action); } return 0; } #if _POSIX_SPAWN > 0 /** Set some posix_spawnattr flags. */ attr(maybe_unused) static int bfs_spawn_addflags(struct bfs_spawn *ctx, short flags) { short prev; errno = posix_spawnattr_getflags(&ctx->attr, &prev); if (errno != 0) { return -1; } short next = prev | flags; if (next != prev) { errno = posix_spawnattr_setflags(&ctx->attr, next); if (errno != 0) { return -1; } } return 0; } #endif // _POSIX_SPAWN > 0 /** Allocate a spawn action. */ static struct bfs_spawn_action *bfs_spawn_action(enum bfs_spawn_op op) { struct bfs_spawn_action *action = ALLOC(struct bfs_spawn_action); if (!action) { return NULL; } SLIST_ITEM_INIT(action); action->op = op; action->in_fd = -1; action->out_fd = -1; return action; } int bfs_spawn_addopen(struct bfs_spawn *ctx, int fd, const char *path, int flags, mode_t mode) { struct bfs_spawn_action *action = bfs_spawn_action(BFS_SPAWN_OPEN); if (!action) { return -1; } #if _POSIX_SPAWN > 0 if (ctx->flags & BFS_SPAWN_USE_POSIX) { errno = posix_spawn_file_actions_addopen(&ctx->actions, fd, path, flags, mode); if (errno != 0) { free(action); return -1; } } #endif action->out_fd = fd; action->path = path; action->flags = flags; action->mode = mode; SLIST_APPEND(ctx, action); return 0; } int bfs_spawn_addclose(struct bfs_spawn *ctx, int fd) { struct bfs_spawn_action *action = bfs_spawn_action(BFS_SPAWN_CLOSE); if (!action) { return -1; } #if _POSIX_SPAWN > 0 if (ctx->flags & BFS_SPAWN_USE_POSIX) { errno = posix_spawn_file_actions_addclose(&ctx->actions, fd); if (errno != 0) { free(action); return -1; } } #endif action->out_fd = fd; SLIST_APPEND(ctx, action); return 0; } int bfs_spawn_adddup2(struct bfs_spawn *ctx, int oldfd, int newfd) { struct bfs_spawn_action *action = bfs_spawn_action(BFS_SPAWN_DUP2); if (!action) { return -1; } #if _POSIX_SPAWN > 0 if (ctx->flags & BFS_SPAWN_USE_POSIX) { errno = posix_spawn_file_actions_adddup2(&ctx->actions, oldfd, newfd); if (errno != 0) { free(action); return -1; } } #endif action->in_fd = oldfd; action->out_fd = newfd; SLIST_APPEND(ctx, action); return 0; } /** * https://www.austingroupbugs.net/view.php?id=1208#c4830 says: * * ... a search of the directories passed as the environment variable * PATH ..., using the working directory of the child process after all * file_actions have been performed. * * but macOS and NetBSD resolve the PATH *before* file_actions (because there * posix_spawn() is its own syscall). */ #define BFS_POSIX_SPAWNP_AFTER_FCHDIR !(__APPLE__ || __NetBSD_Prereq__(10, 0, 0)) int bfs_spawn_addfchdir(struct bfs_spawn *ctx, int fd) { struct bfs_spawn_action *action = bfs_spawn_action(BFS_SPAWN_FCHDIR); if (!action) { return -1; } #ifndef BFS_HAS_POSIX_SPAWN_FCHDIR # define BFS_HAS_POSIX_SPAWN_FCHDIR __NetBSD_Prereq__(10, 0, 0) #endif #ifndef BFS_HAS_POSIX_SPAWN_FCHDIR_NP # if __GLIBC__ # define BFS_HAS_POSIX_SPAWN_FCHDIR_NP __GLIBC_PREREQ(2, 29) # elif __ANDROID__ # define BFS_HAS_POSIX_SPAWN_FCHDIR_NP (__ANDROID_API__ >= 34) # else # define BFS_HAS_POSIX_SPAWN_FCHDIR_NP (__linux__ || __FreeBSD__ || __APPLE__) # endif #endif #if BFS_HAS_POSIX_SPAWN_FCHDIR # define BFS_POSIX_SPAWN_FCHDIR posix_spawn_file_actions_addfchdir #elif BFS_HAS_POSIX_SPAWN_FCHDIR_NP # define BFS_POSIX_SPAWN_FCHDIR posix_spawn_file_actions_addfchdir_np #endif #if _POSIX_SPAWN > 0 && defined(BFS_POSIX_SPAWN_FCHDIR) if (ctx->flags & BFS_SPAWN_USE_POSIX) { errno = BFS_POSIX_SPAWN_FCHDIR(&ctx->actions, fd); if (errno != 0) { free(action); return -1; } } #else ctx->flags &= ~BFS_SPAWN_USE_POSIX; #endif action->in_fd = fd; SLIST_APPEND(ctx, action); return 0; } int bfs_spawn_setrlimit(struct bfs_spawn *ctx, int resource, const struct rlimit *rl) { struct bfs_spawn_action *action = bfs_spawn_action(BFS_SPAWN_SETRLIMIT); if (!action) { goto fail; } #ifdef POSIX_SPAWN_SETRLIMIT if (bfs_spawn_addflags(ctx, POSIX_SPAWN_SETRLIMIT) != 0) { goto fail; } errno = posix_spawnattr_setrlimit(&ctx->attr, resource, rl); if (errno != 0) { goto fail; } #else ctx->flags &= ~BFS_SPAWN_USE_POSIX; #endif action->resource = resource; action->rlimit = *rl; SLIST_APPEND(ctx, action); return 0; fail: free(action); return -1; } /** * Context for resolving executables in the $PATH. */ struct bfs_resolver { /** The executable to spawn. */ const char *exe; /** The $PATH to resolve in. */ char *path; /** A buffer to hold the resolved path. */ char *buf; /** The size of the buffer. */ size_t len; /** Whether the executable is already resolved. */ bool done; /** Whether to free(path). */ bool free; }; /** Free a $PATH resolution context. */ static void bfs_resolve_free(struct bfs_resolver *res) { if (res->free) { free(res->path); } free(res->buf); } /** Get the next component in the $PATH. */ static bool bfs_resolve_next(const char **path, const char **next, size_t *len) { *path = *next; if (!*path) { return false; } *next = strchr(*path, ':'); if (*next) { *len = *next - *path; ++*next; } else { *len = strlen(*path); } if (*len == 0) { // POSIX 8.3: "A zero-length prefix is a legacy feature that // indicates the current working directory." *path = "."; *len = 1; } return true; } /** Finish resolving an executable, potentially from the child process. */ static int bfs_resolve_late(struct bfs_resolver *res) { if (res->done) { return 0; } char *buf = res->buf; char *end = buf + res->len; const char *path; const char *next = res->path; size_t len; while (bfs_resolve_next(&path, &next, &len)) { char *cur = xstpencpy(buf, end, path, len); cur = xstpecpy(cur, end, "/"); cur = xstpecpy(cur, end, res->exe); if (cur == end) { bfs_bug("PATH resolution buffer too small"); errno = ENOMEM; return -1; } if (xfaccessat(AT_FDCWD, buf, X_OK) == 0) { res->exe = buf; res->done = true; return 0; } } errno = ENOENT; return -1; } /** Check if we can skip path resolution entirely. */ static bool bfs_can_skip_resolve(const struct bfs_resolver *res, const struct bfs_spawn *ctx) { if (ctx && !(ctx->flags & BFS_SPAWN_USE_PATH)) { return true; } if (strchr(res->exe, '/')) { return true; } return false; } /** Check if any $PATH components are relative. */ static bool bfs_resolve_relative(const struct bfs_resolver *res) { const char *path; const char *next = res->path; size_t len; while (bfs_resolve_next(&path, &next, &len)) { if (path[0] != '/') { return true; } } return false; } /** Check if we can resolve the executable before file actions. */ static bool bfs_can_resolve_early(const struct bfs_resolver *res, const struct bfs_spawn *ctx) { if (!bfs_resolve_relative(res)) { return true; } if (ctx) { for_slist (const struct bfs_spawn_action, action, ctx) { if (action->op == BFS_SPAWN_FCHDIR) { return false; } } } return true; } /** Get the required path resolution buffer size. */ static size_t bfs_resolve_capacity(const struct bfs_resolver *res) { size_t max = 0; const char *path; const char *next = res->path; size_t len; while (bfs_resolve_next(&path, &next, &len)) { if (len > max) { max = len; } } // path + "/" + exe + '\0' return max + 1 + strlen(res->exe) + 1; } /** Begin resolving an executable, from the parent process. */ static int bfs_resolve_early(struct bfs_resolver *res, const char *exe, const struct bfs_spawn *ctx) { *res = (struct bfs_resolver) { .exe = exe, }; if (bfs_can_skip_resolve(res, ctx)) { res->done = true; return 0; } res->path = getenv("PATH"); if (!res->path) { #if defined(_CS_PATH) res->path = xconfstr(_CS_PATH); res->free = true; #elif defined(_PATH_DEFPATH) res->path = _PATH_DEFPATH; #else errno = ENOENT; #endif } if (!res->path) { goto fail; } bool can_finish = bfs_can_resolve_early(res, ctx); #if BFS_POSIX_SPAWNP_AFTER_FCHDIR bool use_posix = ctx && (ctx->flags & BFS_SPAWN_USE_POSIX); if (!can_finish && use_posix) { // posix_spawnp() will do the resolution, so don't bother // allocating a buffer return 0; } #endif res->len = bfs_resolve_capacity(res); res->buf = malloc(res->len); if (!res->buf) { goto fail; } if (can_finish && bfs_resolve_late(res) != 0) { goto fail; } return 0; fail: bfs_resolve_free(res); return -1; } #if _POSIX_SPAWN > 0 /** bfs_spawn() implementation using posix_spawn(). */ static pid_t bfs_posix_spawn(struct bfs_resolver *res, const struct bfs_spawn *ctx, char **argv, char **envp) { pid_t ret; if (res->done) { errno = posix_spawn(&ret, res->exe, &ctx->actions, &ctx->attr, argv, envp); } else { errno = posix_spawnp(&ret, res->exe, &ctx->actions, &ctx->attr, argv, envp); } if (errno != 0) { return -1; } return ret; } /** Check if we can use posix_spawn(). */ static bool bfs_use_posix_spawn(const struct bfs_resolver *res, const struct bfs_spawn *ctx) { if (!(ctx->flags & BFS_SPAWN_USE_POSIX)) { return false; } #if !BFS_POSIX_SPAWNP_AFTER_FCHDIR if (!res->done) { return false; } #endif return true; } #endif // _POSIX_SPAWN > 0 /** Actually exec() the new process. */ static noreturn void bfs_spawn_exec(struct bfs_resolver *res, const struct bfs_spawn *ctx, char **argv, char **envp, int pipefd[2]) { xclose(pipefd[0]); for_slist (const struct bfs_spawn_action, action, ctx) { int fd; // Move the error-reporting pipe out of the way if necessary... if (action->out_fd == pipefd[1]) { fd = dup_cloexec(pipefd[1]); if (fd < 0) { goto fail; } xclose(pipefd[1]); pipefd[1] = fd; } // ... and pretend the pipe doesn't exist if (action->in_fd == pipefd[1]) { errno = EBADF; goto fail; } switch (action->op) { case BFS_SPAWN_OPEN: fd = open(action->path, action->flags, action->mode); if (fd < 0) { goto fail; } if (fd != action->out_fd) { if (dup2(fd, action->out_fd) < 0) { goto fail; } } break; case BFS_SPAWN_CLOSE: if (close(action->out_fd) != 0) { goto fail; } break; case BFS_SPAWN_DUP2: if (dup2(action->in_fd, action->out_fd) < 0) { goto fail; } break; case BFS_SPAWN_FCHDIR: if (fchdir(action->in_fd) != 0) { goto fail; } break; case BFS_SPAWN_SETRLIMIT: if (setrlimit(action->resource, &action->rlimit) != 0) { goto fail; } break; } } if (bfs_resolve_late(res) != 0) { goto fail; } execve(res->exe, argv, envp); fail:; int error = errno; // In case of a write error, the parent will still see that we exited // unsuccessfully, but won't know why (void)xwrite(pipefd[1], &error, sizeof(error)); xclose(pipefd[1]); _Exit(127); } /** bfs_spawn() implementation using fork()/exec(). */ static pid_t bfs_fork_spawn(struct bfs_resolver *res, const struct bfs_spawn *ctx, char **argv, char **envp) { // Use a pipe to report errors from the child int pipefd[2]; if (pipe_cloexec(pipefd) != 0) { return -1; } pid_t pid = fork(); if (pid < 0) { close_quietly(pipefd[1]); close_quietly(pipefd[0]); return -1; } else if (pid == 0) { // Child bfs_spawn_exec(res, ctx, argv, envp, pipefd); } // Parent xclose(pipefd[1]); int error; ssize_t nbytes = xread(pipefd[0], &error, sizeof(error)); xclose(pipefd[0]); if (nbytes == sizeof(error)) { int wstatus; xwaitpid(pid, &wstatus, 0); errno = error; return -1; } return pid; } /** Call the right bfs_spawn() implementation. */ static pid_t bfs_spawn_impl(struct bfs_resolver *res, const struct bfs_spawn *ctx, char **argv, char **envp) { #if _POSIX_SPAWN > 0 if (bfs_use_posix_spawn(res, ctx)) { return bfs_posix_spawn(res, ctx, argv, envp); } #endif return bfs_fork_spawn(res, ctx, argv, envp); } pid_t bfs_spawn(const char *exe, const struct bfs_spawn *ctx, char **argv, char **envp) { // execvp()/posix_spawnp() are typically implemented with repeated // execv() calls for each $PATH component until one succeeds. It's // faster to resolve the full path ahead of time. struct bfs_resolver res; if (bfs_resolve_early(&res, exe, ctx) != 0) { return -1; } extern char **environ; if (!envp) { envp = environ; } pid_t ret = bfs_spawn_impl(&res, ctx, argv, envp); bfs_resolve_free(&res); return ret; } char *bfs_spawn_resolve(const char *exe) { struct bfs_resolver res; if (bfs_resolve_early(&res, exe, NULL) != 0) { return NULL; } if (bfs_resolve_late(&res) != 0) { bfs_resolve_free(&res); return NULL; } char *ret; if (res.exe == res.buf) { ret = res.buf; res.buf = NULL; } else { ret = strdup(res.exe); } bfs_resolve_free(&res); return ret; }