/* * The Qubes OS Project, http://www.qubes-os.org * * Copyright (C) 2010 Rafal Wojtczuk * * This program is free software; you can redistribute it and/or * modify it under the terms of the GNU General Public License * as published by the Free Software Foundation; either version 2 * of the License, or (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA. * */ #include #include #include #include #include #include #include #include #include #include #include #include #include "qrexec.h" #include "libqrexec-utils.h" enum fdtype { FDTYPE_INVALID, FDTYPE_STDOUT, FDTYPE_STDERR }; struct _process_fd { int client_id; int type; int is_blocked; }; struct _client_info { int stdin_fd; int stdout_fd; int stderr_fd; int exit_status; int is_exited; int pid; int is_blocked; int is_close_after_flush_needed; struct buffer buffer; }; int max_process_fd = -1; /* indexed by file descriptor */ struct _process_fd process_fd[MAX_FDS]; /* indexed by client id, which is descriptor number of a client in daemon */ struct _client_info client_info[MAX_FDS]; int trigger_fd; int passfd_socket; int meminfo_write_started = 0; void do_exec(const char *cmd); void init() { peer_server_init(REXEC_PORT); umask(0); mkfifo(QREXEC_AGENT_TRIGGER_PATH, 0666); passfd_socket = get_server_socket(QREXEC_AGENT_FDPASS_PATH); umask(077); trigger_fd = open(QREXEC_AGENT_TRIGGER_PATH, O_RDONLY | O_NONBLOCK); register_exec_func(do_exec); } void wake_meminfo_writer() { FILE *f; int pid; if (meminfo_write_started) /* wake meminfo-writer only once */ return; f = fopen(MEMINFO_WRITER_PIDFILE, "r"); if (f == NULL) { /* no meminfo-writer found, ignoring */ return; } if (fscanf(f, "%d", &pid) < 1) { fclose(f); /* no meminfo-writer found, ignoring */ return; } fclose(f); if (pid <= 1 || pid > 0xffff) { /* check within acceptable range */ return; } if (kill(pid, SIGUSR1) < 0) { /* Can't send signal */ return; } meminfo_write_started = 1; } void no_colon_in_cmd() { fprintf(stderr, "cmdline is supposed to be in user:command form\n"); exit(1); } void do_exec(const char *cmd) { char buf[strlen(QUBES_RPC_MULTIPLEXER_PATH) + strlen(cmd) - strlen(QUBES_RPC_MAGIC_CMD) + 1]; char *realcmd = index(cmd, ':'), *user; if (!realcmd) no_colon_in_cmd(); /* mark end of username and move to command */ user=strndup(cmd,realcmd-cmd); realcmd++; /* ignore "nogui:" prefix in linux agent */ if (strncmp(realcmd, "nogui:", 6) == 0) realcmd+=6; /* replace magic RPC cmd with RPC multiplexer path */ if (strncmp(realcmd, QUBES_RPC_MAGIC_CMD " ", strlen(QUBES_RPC_MAGIC_CMD)+1)==0) { strcpy(buf, QUBES_RPC_MULTIPLEXER_PATH); strcpy(buf + strlen(QUBES_RPC_MULTIPLEXER_PATH), realcmd + strlen(QUBES_RPC_MAGIC_CMD)); realcmd = buf; } signal(SIGCHLD, SIG_DFL); signal(SIGPIPE, SIG_DFL); execl("/bin/su", "su", "-", user, "-c", realcmd, NULL); perror("execl"); exit(1); } void handle_just_exec(int client_id, int len) { char buf[len]; int fdn, pid; read_all_vchan_ext(buf, len); switch (pid = fork()) { case -1: perror("fork"); exit(1); case 0: fdn = open("/dev/null", O_RDWR); fix_fds(fdn, fdn, fdn); do_exec(buf); perror("execl"); exit(1); default:; } fprintf(stderr, "executed (nowait) %s pid %d\n", buf, pid); } void create_info_about_client(int client_id, int pid, int stdin_fd, int stdout_fd, int stderr_fd) { process_fd[stdout_fd].client_id = client_id; process_fd[stdout_fd].type = FDTYPE_STDOUT; process_fd[stdout_fd].is_blocked = 0; process_fd[stderr_fd].client_id = client_id; process_fd[stderr_fd].type = FDTYPE_STDERR; process_fd[stderr_fd].is_blocked = 0; if (stderr_fd > max_process_fd) max_process_fd = stderr_fd; if (stdout_fd > max_process_fd) max_process_fd = stdout_fd; set_nonblock(stdin_fd); client_info[client_id].stdin_fd = stdin_fd; client_info[client_id].stdout_fd = stdout_fd; client_info[client_id].stderr_fd = stderr_fd; client_info[client_id].exit_status = 0; client_info[client_id].is_exited = 0; client_info[client_id].pid = pid; client_info[client_id].is_blocked = 0; client_info[client_id].is_close_after_flush_needed = 0; buffer_init(&client_info[client_id].buffer); } void handle_exec(int client_id, int len) { char buf[len]; int pid, stdin_fd, stdout_fd, stderr_fd; read_all_vchan_ext(buf, len); do_fork_exec(buf, &pid, &stdin_fd, &stdout_fd, &stderr_fd); create_info_about_client(client_id, pid, stdin_fd, stdout_fd, stderr_fd); fprintf(stderr, "executed %s pid %d\n", buf, pid); } void handle_connect_existing(int client_id, int len) { int stdin_fd, stdout_fd, stderr_fd; char buf[len]; read_all_vchan_ext(buf, len); sscanf(buf, "%d %d %d", &stdin_fd, &stdout_fd, &stderr_fd); create_info_about_client(client_id, -1, stdin_fd, stdout_fd, stderr_fd); client_info[client_id].is_exited = 1; //do not wait for SIGCHLD } void update_max_process_fd() { int i; for (i = max_process_fd; i >= 0 && process_fd[i].type == FDTYPE_INVALID; i--); max_process_fd = i; } void send_exit_code(int client_id, int status) { struct server_header s_hdr; s_hdr.type = MSG_AGENT_TO_SERVER_EXIT_CODE; s_hdr.client_id = client_id; s_hdr.len = sizeof status; write_all_vchan_ext(&s_hdr, sizeof s_hdr); write_all_vchan_ext(&status, sizeof(status)); fprintf(stderr, "send exit code %d for client_id %d pid %d\n", status, client_id, client_info[client_id].pid); } // erase process data structures, possibly forced by remote void remove_process(int client_id, int status) { int i; if (!client_info[client_id].pid) return; if (client_info[client_id].stdin_fd >= 0) fork_and_flush_stdin(client_info[client_id].stdin_fd, &client_info[client_id].buffer); #if 0 // let's let it die by itself, possibly after it has received buffered stdin kill(client_info[client_id].pid, SIGKILL); #endif if (status != -1) send_exit_code(client_id, status); close(client_info[client_id].stdin_fd); client_info[client_id].pid = 0; client_info[client_id].stdin_fd = -1; client_info[client_id].is_blocked = 0; buffer_free(&client_info[client_id].buffer); for (i = 0; i <= max_process_fd; i++) if (process_fd[i].type != FDTYPE_INVALID && process_fd[i].client_id == client_id) { process_fd[i].type = FDTYPE_INVALID; process_fd[i].client_id = -1; process_fd[i].is_blocked = 0; close(i); } update_max_process_fd(); } // remove process not immediately after it has exited, but after its stdout and stderr has been drained // previous method implemented in flush_out_err was broken - it cannot work when peer signalled it is blocked void possibly_remove_process(int client_id) { if (client_info[client_id].stdout_fd == -1 && client_info[client_id].stderr_fd == -1 && client_info[client_id].is_exited) remove_process(client_id, client_info[client_id].exit_status); } void handle_input(int client_id, int len) { char buf[len]; read_all_vchan_ext(buf, len); if (!client_info[client_id].pid || client_info[client_id].stdin_fd == -1) return; if (len == 0) { if (client_info[client_id].is_blocked) client_info[client_id].is_close_after_flush_needed = 1; else { close(client_info[client_id].stdin_fd); client_info[client_id].stdin_fd = -1; } return; } switch (write_stdin (client_info[client_id].stdin_fd, client_id, buf, len, &client_info[client_id].buffer)) { case WRITE_STDIN_OK: break; case WRITE_STDIN_BUFFERED: client_info[client_id].is_blocked = 1; break; case WRITE_STDIN_ERROR: // do not remove process, as it still can write data to stdout close(client_info[client_id].stdin_fd); client_info[client_id].stdin_fd = -1; client_info[client_id].is_blocked = 0; break; default: fprintf(stderr, "unknown write_stdin?\n"); exit(1); } } void set_blocked_outerr(int client_id, int val) { process_fd[client_info[client_id].stdout_fd].is_blocked = val; process_fd[client_info[client_id].stderr_fd].is_blocked = val; } void handle_server_data() { struct server_header s_hdr; read_all_vchan_ext(&s_hdr, sizeof s_hdr); // fprintf(stderr, "got %x %x %x\n", s_hdr.type, s_hdr.client_id, // s_hdr.len); switch (s_hdr.type) { case MSG_XON: set_blocked_outerr(s_hdr.client_id, 0); break; case MSG_XOFF: set_blocked_outerr(s_hdr.client_id, 1); break; case MSG_SERVER_TO_AGENT_CONNECT_EXISTING: handle_connect_existing(s_hdr.client_id, s_hdr.len); break; case MSG_SERVER_TO_AGENT_EXEC_CMDLINE: wake_meminfo_writer(); handle_exec(s_hdr.client_id, s_hdr.len); break; case MSG_SERVER_TO_AGENT_JUST_EXEC: wake_meminfo_writer(); handle_just_exec(s_hdr.client_id, s_hdr.len); break; case MSG_SERVER_TO_AGENT_INPUT: handle_input(s_hdr.client_id, s_hdr.len); break; case MSG_SERVER_TO_AGENT_CLIENT_END: remove_process(s_hdr.client_id, -1); break; default: fprintf(stderr, "msg type from daemon is %d ?\n", s_hdr.type); exit(1); } } void handle_process_data(int fd) { struct server_header s_hdr; char buf[MAX_DATA_CHUNK]; int ret; int len; len = buffer_space_vchan_ext(); if (len <= sizeof s_hdr) return; ret = read(fd, buf, len - sizeof s_hdr); s_hdr.client_id = process_fd[fd].client_id; if (process_fd[fd].type == FDTYPE_STDOUT) s_hdr.type = MSG_AGENT_TO_SERVER_STDOUT; else if (process_fd[fd].type == FDTYPE_STDERR) s_hdr.type = MSG_AGENT_TO_SERVER_STDERR; else { fprintf(stderr, "fd=%d, client_id=%d, type=%d ?\n", fd, process_fd[fd].client_id, process_fd[fd].type); exit(1); } s_hdr.len = ret; if (ret >= 0) { write_all_vchan_ext(&s_hdr, sizeof s_hdr); write_all_vchan_ext(buf, ret); } if (ret == 0) { int client_id = process_fd[fd].client_id; if (process_fd[fd].type == FDTYPE_STDOUT) client_info[client_id].stdout_fd = -1; else client_info[client_id].stderr_fd = -1; process_fd[fd].type = FDTYPE_INVALID; process_fd[fd].client_id = -1; process_fd[fd].is_blocked = 0; close(fd); update_max_process_fd(); possibly_remove_process(client_id); } if (ret < 0) remove_process(process_fd[fd].client_id, 127); } volatile int child_exited; void sigchld_handler(int x) { child_exited = 1; signal(SIGCHLD, sigchld_handler); } int find_info(int pid) { int i; for (i = 0; i < MAX_FDS; i++) if (client_info[i].pid == pid) return i; return -1; } void handle_process_data_all(fd_set * select_fds) { int i; for (i = 0; i <= max_process_fd; i++) if (process_fd[i].type != FDTYPE_INVALID && FD_ISSET(i, select_fds)) handle_process_data(i); } void reap_children() { int status; int pid; int client_id; while ((pid = waitpid(-1, &status, WNOHANG)) > 0) { client_id = find_info(pid); if (client_id < 0) continue; client_info[client_id].is_exited = 1; client_info[client_id].exit_status = status; possibly_remove_process(client_id); } child_exited = 0; } int fill_fds_for_select(fd_set * rdset, fd_set * wrset) { int max = -1; int fd, i; FD_ZERO(rdset); FD_ZERO(wrset); for (i = 0; i <= max_process_fd; i++) if (process_fd[i].type != FDTYPE_INVALID && !process_fd[i].is_blocked) { FD_SET(i, rdset); max = i; } FD_SET(trigger_fd, rdset); if (trigger_fd > max) max = trigger_fd; FD_SET(passfd_socket, rdset); if (passfd_socket > max) max = passfd_socket; for (i = 0; i < MAX_FDS; i++) if (client_info[i].pid && client_info[i].is_blocked) { fd = client_info[i].stdin_fd; FD_SET(fd, wrset); if (fd > max) max = fd; } return max; } void flush_client_data_agent(int client_id) { struct _client_info *info = &client_info[client_id]; switch (flush_client_data (info->stdin_fd, client_id, &info->buffer)) { case WRITE_STDIN_OK: info->is_blocked = 0; if (info->is_close_after_flush_needed) { close(info->stdin_fd); info->stdin_fd = -1; info->is_close_after_flush_needed = 0; } break; case WRITE_STDIN_ERROR: // do not remove process, as it still can write data to stdout info->is_blocked = 0; close(info->stdin_fd); info->stdin_fd = -1; info->is_close_after_flush_needed = 0; break; case WRITE_STDIN_BUFFERED: break; default: fprintf(stderr, "unknown flush_client_data?\n"); exit(1); } } void handle_new_passfd() { int fd = do_accept(passfd_socket); if (fd >= MAX_FDS) { fprintf(stderr, "too many clients ?\n"); exit(1); } // let client know what fd has been allocated write(fd, &fd, sizeof(fd)); } void handle_trigger_io() { struct server_header s_hdr; struct trigger_connect_params params; int ret; s_hdr.client_id = 0; s_hdr.len = 0; ret = read(trigger_fd, ¶ms, sizeof(params)); if (ret == sizeof(params)) { s_hdr.type = MSG_AGENT_TO_SERVER_TRIGGER_CONNECT_EXISTING; write_all_vchan_ext(&s_hdr, sizeof s_hdr); write_all_vchan_ext(¶ms, sizeof params); } // trigger_fd is nonblock - so no need to reopen // not really, need to reopen at EOF if (ret <= 0) { close(trigger_fd); trigger_fd = open(QREXEC_AGENT_TRIGGER_PATH, O_RDONLY | O_NONBLOCK); } } int main() { fd_set rdset, wrset; int max; int i; sigset_t chld_set; init(); signal(SIGCHLD, sigchld_handler); signal(SIGPIPE, SIG_IGN); sigemptyset(&chld_set); sigaddset(&chld_set, SIGCHLD); for (;;) { sigprocmask(SIG_BLOCK, &chld_set, NULL); if (child_exited) reap_children(); max = fill_fds_for_select(&rdset, &wrset); if (buffer_space_vchan_ext() <= sizeof(struct server_header)) FD_ZERO(&rdset); wait_for_vchan_or_argfd(max, &rdset, &wrset); sigprocmask(SIG_UNBLOCK, &chld_set, NULL); if (FD_ISSET(passfd_socket, &rdset)) handle_new_passfd(); while (read_ready_vchan_ext()) handle_server_data(); if (FD_ISSET(trigger_fd, &rdset)) handle_trigger_io(); handle_process_data_all(&rdset); for (i = 0; i <= MAX_FDS; i++) if (client_info[i].pid && client_info[i].is_blocked && FD_ISSET(client_info[i].stdin_fd, &wrset)) flush_client_data_agent(i); } }