/* su_daemon.c - The entrypoint for su, connect to daemon and send correct info */ #define _GNU_SOURCE #include #include #include #include #include #include #include #include #include #include #include #include "magisk.h" #include "daemon.h" #include "utils.h" #include "su.h" #include "pts.h" #include "list.h" // Constants for the atty bitfield #define ATTY_IN 1 #define ATTY_OUT 2 #define ATTY_ERR 4 #define TIMEOUT 3 #define LOCK_LIST() pthread_mutex_lock(&list_lock) #define LOCK_UID() pthread_mutex_lock(&info->lock) #define UNLOCK_LIST() pthread_mutex_unlock(&list_lock) #define UNLOCK_UID() pthread_mutex_unlock(&info->lock) static struct list_head active_list, waiting_list; static pthread_t su_collector = 0; static pthread_mutex_t list_lock = PTHREAD_MUTEX_INITIALIZER; int pipefd[2]; static void sighandler(int sig) { restore_stdin(); // Assume we'll only be called before death // See note before sigaction() in set_stdin_raw() // // Now, close all standard I/O to cause the pumps // to exit so we can continue and retrieve the exit // code close(STDIN_FILENO); close(STDOUT_FILENO); close(STDERR_FILENO); // Put back all the default handlers struct sigaction act; memset(&act, 0, sizeof(act)); act.sa_handler = SIG_DFL; for (int i = 0; quit_signals[i]; ++i) { sigaction(quit_signals[i], &act, NULL); } } // Maintain the lists periodically static void *collector(void *args) { LOGD("su: collector started\n"); struct su_info *node; while(1) { sleep(1); LOCK_LIST(); list_for_each(node, &active_list, struct su_info, pos) { if (--node->clock == 0) { // Timeout, move to waiting list __ = list_pop(&node->pos); list_insert_end(&waiting_list, &node->pos); } } list_for_each(node, &waiting_list, struct su_info, pos) { if (node->ref == 0) { // Nothing is using the info, remove it __ = list_pop(&node->pos); pthread_mutex_destroy(&node->lock); free(node); } } UNLOCK_LIST(); } } void su_daemon_receiver(int client, struct ucred *credential) { LOGD("su: request from client: %d\n", client); struct su_info *info = NULL, *node; int new_request = 0; LOCK_LIST(); if (!su_collector) { init_list_head(&active_list); init_list_head(&waiting_list); xpthread_create(&su_collector, NULL, collector, NULL); } // Search for existing in the active list list_for_each(node, &active_list, struct su_info, pos) { if (node->uid == credential->uid) { info = node; break; } } // If no exist, create a new request if (info == NULL) { new_request = 1; info = malloc(sizeof(*info)); info->uid = credential->uid; info->policy = QUERY; info->ref = 0; info->count = 0; pthread_mutex_init(&info->lock, NULL); list_insert_end(&active_list, &info->pos); } info->clock = TIMEOUT; /* Reset timer */ ++info->ref; /* Increment reference count */ UNLOCK_LIST(); LOGD("su: request from uid=[%d] (#%d)\n", info->uid, ++info->count); // Default values struct su_context ctx = { .info = info, .to = { .uid = UID_ROOT, .login = 0, .keepenv = 0, .shell = DEFAULT_SHELL, .command = NULL, }, .pid = credential->pid, .notify = new_request, }; // Lock before the policy is determined LOCK_UID(); // Not cached, do the checks if (info->policy == QUERY) { // Get data from database database_check(&ctx); // Check requester if (info->policy == QUERY) { if (info->st.st_gid != info->st.st_uid) { LOGE("Bad uid/gid %d/%d for Superuser Requestor", info->st.st_gid, info->st.st_uid); info->policy = DENY; ctx.notify = 0; } else if ((info->uid % 100000) == (info->st.st_uid % 100000)) { info->policy = ALLOW; info->root_access = ROOT_ACCESS_APPS_AND_ADB; ctx.notify = 0; } } // always allow if it's root if (info->uid == UID_ROOT) { info->policy = ALLOW; info->root_access = ROOT_ACCESS_APPS_AND_ADB; ctx.notify = 0; } // If still not determined, open a pipe and wait for results if (info->policy == QUERY) xpipe2(ctx.pipefd, O_CLOEXEC); } // Fork a new process, the child process will need to setsid, // open a pseudo-terminal if needed, and will eventually run exec // The parent process will wait for the result and // send the return code back to our client int child = fork(); if (child < 0) PLOGE("fork"); if (child) { // Wait for results if (info->policy == QUERY) { xxread(ctx.pipefd[0], &info->policy, sizeof(info->policy)); close(ctx.pipefd[0]); close(ctx.pipefd[1]); } // The policy is determined, unlock UNLOCK_UID(); // Wait result LOGD("su: waiting child: [%d]\n", child); int status, code; if (waitpid(child, &status, 0) > 0) code = WEXITSTATUS(status); else code = -1; /* Passing the return code back to the client: * The client might be closed unexpectedly (e.g. swipe a root app out of recents) * In that case, writing to the client (which doesn't exist) will result in SIGPIPE * Here we simply just ignore the situation. */ struct sigaction act; memset(&act, 0, sizeof(act)); act.sa_handler = SIG_IGN; sigaction(SIGPIPE, &act, NULL); LOGD("su: return code: [%d]\n", code); write(client, &code, sizeof(code)); close(client); // Restore default handler for SIGPIPE act.sa_handler = SIG_DFL; sigaction(SIGPIPE, &act, NULL); // Decrement reference count LOCK_LIST(); --info->ref; UNLOCK_LIST(); return; } LOGD("su: child process started\n"); UNLOCK_UID(); // ack write_int(client, 1); // Become session leader xsetsid(); // Migrate environment from client char path[32], buf[4096]; snprintf(path, sizeof(path), "/proc/%d/cwd", ctx.pid); xreadlink(path, ctx.cwd, sizeof(ctx.cwd)); snprintf(path, sizeof(path), "/proc/%d/environ", ctx.pid); memset(buf, 0, sizeof(buf)); int fd = open(path, O_RDONLY); read(fd, buf, sizeof(buf)); clearenv(); for (size_t pos = 0; buf[pos];) { putenv(buf + pos); pos += strlen(buf + pos) + 1; } // Let's read some info from the socket int argc = read_int(client); if (argc < 0 || argc > 512) { LOGE("unable to allocate args: %d", argc); exit2(1); } LOGD("su: argc=[%d]\n", argc); char **argv = (char**) xmalloc(sizeof(char*) * (argc + 1)); argv[argc] = NULL; for (int i = 0; i < argc; i++) { argv[i] = read_string(client); LOGD("su: argv[%d]=[%s]\n", i, argv[i]); // Replace -cn with -z, -mm with -M for supporting getopt_long if (strcmp(argv[i], "-cn") == 0) strcpy(argv[i], "-z"); else if (strcmp(argv[i], "-mm") == 0) strcpy(argv[i], "-M"); } // Get pts_slave char *pts_slave = read_string(client); LOGD("su: pts_slave=[%s]\n", pts_slave); // The the FDs for each of the streams int infd = recv_fd(client); int outfd = recv_fd(client); int errfd = recv_fd(client); int ptsfd = -1; // We no longer need the access to socket in the child, close it close(client); if (pts_slave[0]) { //Check pts_slave file is owned by daemon_from_uid struct stat stbuf; xstat(pts_slave, &stbuf); //If caller is not root, ensure the owner of pts_slave is the caller if(stbuf.st_uid != info->uid && info->uid != 0) { LOGE("su: Wrong permission of pts_slave"); exit2(1); } // Opening the TTY has to occur after the // fork() and setsid() so that it becomes // our controlling TTY and not the daemon's ptsfd = xopen(pts_slave, O_RDWR); if (infd < 0) { LOGD("su: stdin using PTY"); infd = ptsfd; } if (outfd < 0) { LOGD("su: stdout using PTY"); outfd = ptsfd; } if (errfd < 0) { LOGD("su: stderr using PTY"); errfd = ptsfd; } } free(pts_slave); // Swap out stdin, stdout, stderr xdup2(infd, STDIN_FILENO); xdup2(outfd, STDOUT_FILENO); xdup2(errfd, STDERR_FILENO); close(ptsfd); // Give main the reference su_ctx = &ctx; su_daemon_main(argc, argv); } /* * Connect daemon, send argc, argv, cwd, pts slave */ int su_client_main(int argc, char *argv[]) { char buffer[PATH_MAX]; int ptmx, socketfd; // Connect to client socketfd = connect_daemon(); // Tell the daemon we are su write_int(socketfd, SUPERUSER); // Number of command line arguments write_int(socketfd, argc); // Command line arguments for (int i = 0; i < argc; i++) { write_string(socketfd, argv[i]); } // Determine which one of our streams are attached to a TTY int atty = 0; if (isatty(STDIN_FILENO)) atty |= ATTY_IN; if (isatty(STDOUT_FILENO)) atty |= ATTY_OUT; if (isatty(STDERR_FILENO)) atty |= ATTY_ERR; if (atty) { // We need a PTY. Get one. ptmx = pts_open(buffer, sizeof(buffer)); } else { buffer[0] = '\0'; } // Send the pts_slave path to the daemon write_string(socketfd, buffer); // Send stdin if (atty & ATTY_IN) { // Using PTY send_fd(socketfd, -1); } else { send_fd(socketfd, STDIN_FILENO); } // Send stdout if (atty & ATTY_OUT) { // Forward SIGWINCH watch_sigwinch_async(STDOUT_FILENO, ptmx); // Using PTY send_fd(socketfd, -1); } else { send_fd(socketfd, STDOUT_FILENO); } // Send stderr if (atty & ATTY_ERR) { // Using PTY send_fd(socketfd, -1); } else { send_fd(socketfd, STDERR_FILENO); } // Wait for acknowledgement from daemon read_int(socketfd); if (atty & ATTY_IN) { setup_sighandlers(sighandler); pump_stdin_async(ptmx); } if (atty & ATTY_OUT) { pump_stdout_blocking(ptmx); } // Get the exit code int code = read_int(socketfd); close(socketfd); return code; }