/** * mds — A micro-display server * Copyright © 2014 Mattias Andrée (maandree@member.fsf.org) * * 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 3 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, see . */ #include "mds-kkbd.h" #include #include #include #include #include #include #include #include #include #include #include #include #define reconnect_to_display() -1 /* TODO */ #ifdef __sparc__ # define GET_LED KIOCGLED # define SET_LED KIOCSLED #else # define GET_LED KDGETLED # define SET_LED KDSETLED #endif #ifdef __sparc__ # define LED_NUM_LOCK 1 # define LED_CAPS_LOCK 8 # define LED_SCRL_LOCK 4 # define LED_COMPOSE 2 #else # define LED_NUM_LOCK LED_NUM # define LED_CAPS_LOCK LED_CAP # define LED_SCRL_LOCK LED_SCR #endif #define MDS_KKBD_VARS_VERSION 0 /** * This variable should declared by the actual server implementation. * It must be configured before `main` is invoked. * * This tells the server-base how to behave */ server_characteristics_t server_characteristics = { .require_privileges = 0, .require_display = 1, .require_respawn_info = 0, .sanity_check_argc = 1, .fork_for_safety = 1 }; /** * Value of the ‘Message ID’ header for the next message */ static int32_t message_id = 1; /** * Buffer for received messages */ static mds_message_t received; /** * Whether the server is connected to the display */ static int connected = 1; /** * File descriptor for accessing the keyboard LED:s */ static int ledfd = 0; /** * Saved LED states */ static int saved_leds; /** * Saved TTY settings */ static struct termios saved_stty; /** * Save keyboard mode */ static int saved_kbd_mode; /** * Keycode remapping table */ static int* restrict mapping = NULL; /** * The size of `mapping` */ static size_t mapping_size = 0; /** * Scancode buffer */ static int scancode_buf[3] = { 0, 0, 0 }; /** * The number of elements stored in `scancode_buf` */ static int scancode_ptr = 0; /** * Message buffer for `send_key` */ static char* key_send_buffer = NULL; /** * The keyboard listener thread */ static pthread_t kbd_thread; /** * Whether `kbd_thread` has started */ static int kbd_thread_started = 0; /** * This function will be invoked before `initialise_server` (if not re-exec:ing) * or before `unmarshal_server` (if re-exec:ing) * * @return Non-zero on error */ int __attribute__((const)) preinitialise_server(void) { return 0; } /** * This function should initialise the server, * and it not invoked after a re-exec. * * @return Non-zero on error */ int initialise_server(void) { int stage = 0; const char* const message = "Command: intercept\n" "Message ID: 0\n" "Length: 18\n" "\n" "Command: keyboard\n"; if (full_send(message, strlen(message))) return 1; open_leds(); stage = 1; open_input(); stage = 2; fail_if (server_initialised()); stage = 0; fail_if (mds_message_initialise(&received)); fail_if (xmalloc(key_send_buffer, 111, char)); return 0; pfail: xperror(*argv); if (stage >= 2) close_input(); if (stage >= 1) close_leds(); mds_message_destroy(&received); return 1; } /** * This function will be invoked after `initialise_server` (if not re-exec:ing) * or after `unmarshal_server` (if re-exec:ing) * * @return Non-zero on error */ int postinitialise_server(void) { if (connected) return 0; if (reconnect_to_display()) { mds_message_destroy(&received); return 1; } connected = 1; return 0; } /** * This function is called by the parent server process when the * child server process exits, if the server has completed its * initialisation * * @param status The status the child died with */ void fork_cleanup(int status) { (void) status; close_input(); close_leds(); } /** * Calculate the number of bytes that will be stored by `marshal_server` * * On failure the program should `abort()` or exit by other means. * However it should not be possible for this function to fail. * * @return The number of bytes that will be stored by `marshal_server` */ size_t marshal_server_size(void) { size_t rc = 9 * sizeof(int) + sizeof(int32_t) + sizeof(struct termios); rc += sizeof(size_t) + mapping_size * sizeof(int); rc += mds_message_marshal_size(&received); return rc; } /** * Marshal server implementation specific data into a buffer * * @param state_buf The buffer for the marshalled data * @return Non-zero on error */ int marshal_server(char* state_buf) { buf_set_next(state_buf, int, MDS_KKBD_VARS_VERSION); buf_set_next(state_buf, int, connected); buf_set_next(state_buf, int32_t, message_id); buf_set_next(state_buf, int, ledfd); buf_set_next(state_buf, int, saved_leds); buf_set_next(state_buf, struct termios, saved_stty); buf_set_next(state_buf, int, saved_kbd_mode); buf_set_next(state_buf, int, scancode_ptr); buf_set_next(state_buf, int, scancode_buf[0]); buf_set_next(state_buf, int, scancode_buf[1]); buf_set_next(state_buf, int, scancode_buf[2]); buf_set_next(state_buf, size_t, mapping_size); if (mapping_size > 0) { memcpy(state_buf, mapping, mapping_size * sizeof(int)); state_buf += mapping_size * sizeof(int) / sizeof(char); } mds_message_marshal(&received, state_buf); mds_message_destroy(&received); free(mapping); return 0; } /** * Unmarshal server implementation specific data and update the servers state accordingly * * On critical failure the program should `abort()` or exit by other means. * That is, do not let `reexec_failure_recover` run successfully, if it unrecoverable * error has occurred or one severe enough that it is better to simply respawn. * * @param state_buf The marshalled data that as not been read already * @return Non-zero on error */ int unmarshal_server(char* state_buf) { /* buf_get_next(state_buf, int, MDS_KKBDOARD_VARS_VERSION); */ buf_next(state_buf, int, 1); buf_get_next(state_buf, int, connected); buf_get_next(state_buf, int32_t, message_id); buf_get_next(state_buf, int, ledfd); buf_get_next(state_buf, int, saved_leds); buf_get_next(state_buf, struct termios, saved_stty); buf_get_next(state_buf, int, saved_kbd_mode); buf_get_next(state_buf, int, scancode_ptr); buf_get_next(state_buf, int, scancode_buf[0]); buf_get_next(state_buf, int, scancode_buf[1]); buf_get_next(state_buf, int, scancode_buf[2]); buf_get_next(state_buf, size_t, mapping_size); if (mapping_size > 0) { fail_if (xmalloc(mapping, mapping_size, int)); memcpy(mapping, state_buf, mapping_size * sizeof(int)); state_buf += mapping_size * sizeof(int) / sizeof(char); } fail_if (mds_message_unmarshal(&received, state_buf)); return 0; pfail: xperror(*argv); mds_message_destroy(&received); free(mapping); abort(); /* We must abort on failure to not risk the keyboard getting stuck and freeze up the computer until someone ssh:es into it and kill the server. */ return -1; } /** * Attempt to recover from a re-exec failure that has been * detected after the server successfully updated it execution image * * @return Non-zero on error */ int __attribute__((const)) reexec_failure_recover(void) { return -1; } /** * Perform the server's mission * * @return Non-zero on error */ int master_loop(void) { int rc = 1, joined = 0; void* kbd_ret; fail_if ((errno = pthread_create(&kbd_thread, NULL, keyboard_loop, NULL))); while (!reexecing && !terminating) { int r = mds_message_read(&received, socket_fd); if (r == 0) { if (r = 0, r == 0) /* TODO handle_message() */ continue; } if (r == -2) { eprint("corrupt message received, aborting."); goto fail; } else if (errno == EINTR) continue; else if (errno != ECONNRESET) goto pfail; eprint("lost connection to server."); mds_message_destroy(&received); mds_message_initialise(&received); connected = 0; if (reconnect_to_display()) goto fail; connected = 1; } joined = 1; fail_if ((errno = pthread_join(kbd_thread, &kbd_ret))); rc = kbd_ret == NULL ? 0 : 1; goto fail; pfail: xperror(*argv); fail: if (!rc && reexecing) return 0; if ((!joined) && (errno = pthread_join(kbd_thread, NULL))) xperror(*argv); mds_message_destroy(&received); return rc; } /** * The keyboard listener thread's main function * * @param data Input data * @return Output data */ void* keyboard_loop(void* data) { (void) data; kbd_thread_started = 1; while (!reexecing && !terminating) if (fetch_keys() < 0) if (errno != EINTR) goto pfail; free(mapping); return NULL; pfail: xperror(*argv); free(mapping); raise(SIGTERM); return (void*)1024; } /** * Send a singal to all threads except the current thread * * @param signo The signal */ void signal_all(int signo) { pthread_t current_thread = pthread_self(); if (pthread_equal(current_thread, master_thread) == 0) pthread_kill(master_thread, signo); if (kbd_thread_started) if (pthread_equal(current_thread, kbd_thread) == 0) pthread_kill(kbd_thread, signo); } /** * Send a full message even if interrupted * * @param message The message to send * @param length The length of the message * @return Non-zero on success */ int full_send(const char* message, size_t length) { size_t sent; while (length > 0) { sent = send_message(socket_fd, message, length); if (sent > length) { eprint("Sent more of a message than exists in the message, aborting."); return -1; } else if ((sent < length) && (errno != EINTR)) { xperror(*argv); return -1; } message += sent; length -= sent; } return 0; } /** * Acquire access of the keyboard's LED:s * * @return Zero on success, -1 on error */ int open_leds(void) { #ifdef __sparc__ if ((ledfd = open(SPARC_KBD, O_RDONLY)) < 0) return -1; if (ioctl(ledfd, GET_LED, &saved_leds) < 0) { close(ledfd); return -1; } return 0; #else return ioctl(ledfd, GET_LED, &saved_leds); #endif } /** * Release access of the keyboard's LED:s */ void close_leds(void) { if (ioctl(ledfd, SET_LED, saved_leds) < 0) xperror(*argv); #ifdef __sparc__ close(ledfd); #endif } /** * Get active LED:s on the keyboard * * @return Active LED:s, -1 on error */ int get_leds(void) { int leds; if (ioctl(ledfd, GET_LED, &leds) < 0) return -1; #ifdef __sparc__ leds &= 15; #endif return leds; } /** * Set active LED:s on the keyboard * * @param leds Active LED:s * @return Zero on success, -1 on error */ int set_leds(int leds) { return ioctl(ledfd, SET_LED, leds); } /** * Acquire access of keyboard input * * @return Zero on success, -1 on error */ int open_input(void) { struct termios stty; if (tcgetattr(STDIN_FILENO, &saved_stty) < 0) return -1; stty = saved_stty; stty.c_lflag &= (tcflag_t)~(ECHO | ICANON | ISIG); stty.c_iflag = 0; if (tcsetattr(STDIN_FILENO, TCSAFLUSH, &stty) < 0) return -1; /* K_MEDIUMRAW: utilise keyboard drivers, but not layout */ if ((ioctl(STDIN_FILENO, KDGKBMODE, &saved_kbd_mode) < 0) || (ioctl(STDIN_FILENO, KDSKBMODE, K_MEDIUMRAW) < 0)) { xperror(*argv); return tcsetattr(STDIN_FILENO, TCSAFLUSH, &saved_stty); } return 0; } /** * Release access of keyboard input */ void close_input(void) { if (ioctl(STDIN_FILENO, KDSKBMODE, saved_kbd_mode) < 0) xperror(*argv); if (tcsetattr(STDIN_FILENO, TCSAFLUSH, &saved_stty) < 0) xperror(*argv); } /** * Broadcast a keyboard input event * * @param scancode The scancode * @param trio Whether the scancode has three integers rather than one * @return Zero on success, -1 on error */ int send_key(int* restrict scancode, int trio) { int keycode, released = (scancode[0] & 0x80) == 0x80; scancode[0] &= 0x7F; if (trio) { keycode = (scancode[1] &= 0x7F) << 7; keycode |= (scancode[2] &= 0x7F); } else keycode = scancode[0]; if ((size_t)keycode < mapping_size) keycode = mapping[keycode]; if (trio) sprintf(key_send_buffer, "Command: key-sent\n" "Scancode: %i %i %i\n" "Keycode: %i\n" "Released: %s\n" "Keyboard: kernel\n" "Message ID: " PRIi32 "\n" "\n", scancode[0], scancode[1], scancode[2], keycode, released ? "yes" : "no", message_id); else sprintf(key_send_buffer, "Command: key-sent\n" "Scancode: %i\n" "Keycode: %i\n" "Released: %s\n" "Keyboard: kernel\n" "Message ID: " PRIi32 "\n" "\n", scancode[0], keycode, released ? "yes" : "no", message_id); message_id = message_id == INT32_MAX ? 0 : (message_id + 1); return full_send(key_send_buffer, strlen(key_send_buffer)); } /** * Fetch and broadcast keys until interrupted * * @return Zero on success, -1 on error */ int fetch_keys(void) { #ifdef DEBUG int consecutive_escapes = 0; #endif int c; ssize_t r; for (;;) { r = read(STDIN_FILENO, &c, sizeof(int)); if (r <= 0) { if (r == 0) { raise(SIGTERM); errno = 0; } break; } #ifdef DEBUG if ((c & 0x7F) == 1) /* Exit with ESCAPE, ESCAPE, ESCAPE */ { if (++consecutive_escapes >= 2 * 3) { raise(SIGTERM); errno = 0; break; } } else consecutive_escapes = 0; #endif redo: scancode_buf[scancode_ptr] = c; if (scancode_ptr == 0) { if ((c & 0x7F) == 0) scancode_ptr++; else send_key(scancode_buf, 0); } else if (scancode_ptr == 1) { if ((c & 0x80) == 0) { scancode_ptr = 0; goto redo; } scancode_ptr++; } else { scancode_ptr = 0; if ((c & 0x80) == 0) { send_key(scancode_buf + 1, 0); goto redo; } send_key(scancode_buf, 1); } } return errno == 0 ? 0 : -1; }