/* * vim:ts=4:sw=4:expandtab * * i3 - an improved dynamic tiling window manager * © 2009 Michael Stapelberg and contributors (see also: LICENSE) * * ipc.c: UNIX domain socket IPC (initialization, client handling, protocol). * */ #include "all.h" #include "yajl_utils.h" #include #include #include #include #include #include #include #include #include #include char *current_socketpath = NULL; TAILQ_HEAD(ipc_client_head, ipc_client) all_clients = TAILQ_HEAD_INITIALIZER(all_clients); /* * Puts the given socket file descriptor into non-blocking mode or dies if * setting O_NONBLOCK failed. Non-blocking sockets are a good idea for our * IPC model because we should by no means block the window manager. * */ static void set_nonblock(int sockfd) { int flags = fcntl(sockfd, F_GETFL, 0); if (flags & O_NONBLOCK) { return; } flags |= O_NONBLOCK; if (fcntl(sockfd, F_SETFL, flags) < 0) err(-1, "Could not set O_NONBLOCK"); } static void ipc_client_timeout(EV_P_ ev_timer *w, int revents); static void ipc_socket_writeable_cb(EV_P_ struct ev_io *w, int revents); static ev_tstamp kill_timeout = 10.0; void ipc_set_kill_timeout(ev_tstamp new) { kill_timeout = new; } /* * Try to write the contents of the pending buffer to the client's subscription * socket. Will set, reset or clear the timeout and io write callbacks depending * on the result of the write operation. * */ static void ipc_push_pending(ipc_client *client) { const ssize_t result = writeall_nonblock(client->fd, client->buffer, client->buffer_size); if (result < 0) { return; } if ((size_t)result == client->buffer_size) { /* Everything was written successfully: clear the timer and stop the io * callback. */ FREE(client->buffer); client->buffer_size = 0; if (client->timeout) { ev_timer_stop(main_loop, client->timeout); FREE(client->timeout); } ev_io_stop(main_loop, client->write_callback); return; } /* Otherwise, make sure that the io callback is enabled and create a new * timer if needed. */ ev_io_start(main_loop, client->write_callback); if (!client->timeout) { struct ev_timer *timeout = scalloc(1, sizeof(struct ev_timer)); ev_timer_init(timeout, ipc_client_timeout, kill_timeout, 0.); timeout->data = client; client->timeout = timeout; ev_set_priority(timeout, EV_MINPRI); ev_timer_start(main_loop, client->timeout); } else if (result > 0) { /* Keep the old timeout when nothing is written. Otherwise, we would * keep a dead connection by continuously renewing its timeouts. */ ev_timer_stop(main_loop, client->timeout); ev_timer_set(client->timeout, kill_timeout, 0.0); ev_timer_start(main_loop, client->timeout); } if (result == 0) { return; } /* Shift the buffer to the left and reduce the allocated space. */ client->buffer_size -= (size_t)result; memmove(client->buffer, client->buffer + result, client->buffer_size); client->buffer = srealloc(client->buffer, client->buffer_size); } /* * Given a message and a message type, create the corresponding header, merge it * with the message and append it to the given client's output buffer. Also, * send the message if the client's buffer was empty. * */ static void ipc_send_client_message(ipc_client *client, size_t size, const uint32_t message_type, const uint8_t *payload) { const i3_ipc_header_t header = { .magic = {'i', '3', '-', 'i', 'p', 'c'}, .size = size, .type = message_type}; const size_t header_size = sizeof(i3_ipc_header_t); const size_t message_size = header_size + size; const bool push_now = (client->buffer_size == 0); client->buffer = srealloc(client->buffer, client->buffer_size + message_size); memcpy(client->buffer + client->buffer_size, ((void *)&header), header_size); memcpy(client->buffer + client->buffer_size + header_size, payload, size); client->buffer_size += message_size; if (push_now) { ipc_push_pending(client); } } static void free_ipc_client(ipc_client *client, int exempt_fd) { if (client->fd != exempt_fd) { DLOG("Disconnecting client on fd %d\n", client->fd); close(client->fd); } ev_io_stop(main_loop, client->read_callback); FREE(client->read_callback); ev_io_stop(main_loop, client->write_callback); FREE(client->write_callback); if (client->timeout) { ev_timer_stop(main_loop, client->timeout); FREE(client->timeout); } free(client->buffer); for (int i = 0; i < client->num_events; i++) { free(client->events[i]); } free(client->events); TAILQ_REMOVE(&all_clients, client, clients); free(client); } /* * Sends the specified event to all IPC clients which are currently connected * and subscribed to this kind of event. * */ void ipc_send_event(const char *event, uint32_t message_type, const char *payload) { ipc_client *current; TAILQ_FOREACH (current, &all_clients, clients) { for (int i = 0; i < current->num_events; i++) { if (strcasecmp(current->events[i], event) == 0) { ipc_send_client_message(current, strlen(payload), message_type, (uint8_t *)payload); break; } } } } /* * For shutdown events, we send the reason for the shutdown. */ static void ipc_send_shutdown_event(shutdown_reason_t reason) { yajl_gen gen = ygenalloc(); y(map_open); ystr("change"); if (reason == SHUTDOWN_REASON_RESTART) { ystr("restart"); } else if (reason == SHUTDOWN_REASON_EXIT) { ystr("exit"); } y(map_close); const unsigned char *payload; ylength length; y(get_buf, &payload, &length); ipc_send_event("shutdown", I3_IPC_EVENT_SHUTDOWN, (const char *)payload); y(free); } /* * Calls shutdown() on each socket and closes it. This function is to be called * when exiting or restarting only! * * exempt_fd is never closed. Set to -1 to close all fds. * */ void ipc_shutdown(shutdown_reason_t reason, int exempt_fd) { ipc_send_shutdown_event(reason); ipc_client *current; while (!TAILQ_EMPTY(&all_clients)) { current = TAILQ_FIRST(&all_clients); if (current->fd != exempt_fd) { shutdown(current->fd, SHUT_RDWR); } free_ipc_client(current, exempt_fd); } } /* * Executes the given command. * */ IPC_HANDLER(run_command) { /* To get a properly terminated buffer, we copy * message_size bytes out of the buffer */ char *command = sstrndup((const char *)message, message_size); LOG("IPC: received: *%.4000s*\n", command); yajl_gen gen = yajl_gen_alloc(NULL); CommandResult *result = parse_command(command, gen, client); free(command); if (result->needs_tree_render) tree_render(); command_result_free(result); const unsigned char *reply; ylength length; yajl_gen_get_buf(gen, &reply, &length); ipc_send_client_message(client, length, I3_IPC_REPLY_TYPE_COMMAND, (const uint8_t *)reply); yajl_gen_free(gen); } static void dump_rect(yajl_gen gen, const char *name, Rect r) { ystr(name); y(map_open); ystr("x"); y(integer, r.x); ystr("y"); y(integer, r.y); ystr("width"); y(integer, r.width); ystr("height"); y(integer, r.height); y(map_close); } static void dump_event_state_mask(yajl_gen gen, Binding *bind) { y(array_open); for (int i = 0; i < 20; i++) { if (bind->event_state_mask & (1 << i)) { switch (1 << i) { case XCB_KEY_BUT_MASK_SHIFT: ystr("shift"); break; case XCB_KEY_BUT_MASK_LOCK: ystr("lock"); break; case XCB_KEY_BUT_MASK_CONTROL: ystr("ctrl"); break; case XCB_KEY_BUT_MASK_MOD_1: ystr("Mod1"); break; case XCB_KEY_BUT_MASK_MOD_2: ystr("Mod2"); break; case XCB_KEY_BUT_MASK_MOD_3: ystr("Mod3"); break; case XCB_KEY_BUT_MASK_MOD_4: ystr("Mod4"); break; case XCB_KEY_BUT_MASK_MOD_5: ystr("Mod5"); break; case XCB_KEY_BUT_MASK_BUTTON_1: ystr("Button1"); break; case XCB_KEY_BUT_MASK_BUTTON_2: ystr("Button2"); break; case XCB_KEY_BUT_MASK_BUTTON_3: ystr("Button3"); break; case XCB_KEY_BUT_MASK_BUTTON_4: ystr("Button4"); break; case XCB_KEY_BUT_MASK_BUTTON_5: ystr("Button5"); break; case (I3_XKB_GROUP_MASK_1 << 16): ystr("Group1"); break; case (I3_XKB_GROUP_MASK_2 << 16): ystr("Group2"); break; case (I3_XKB_GROUP_MASK_3 << 16): ystr("Group3"); break; case (I3_XKB_GROUP_MASK_4 << 16): ystr("Group4"); break; } } } y(array_close); } static void dump_binding(yajl_gen gen, Binding *bind) { y(map_open); ystr("input_code"); y(integer, bind->keycode); ystr("input_type"); ystr((const char *)(bind->input_type == B_KEYBOARD ? "keyboard" : "mouse")); ystr("symbol"); if (bind->symbol == NULL) y(null); else ystr(bind->symbol); ystr("command"); ystr(bind->command); // This key is only provided for compatibility, new programs should use // event_state_mask instead. ystr("mods"); dump_event_state_mask(gen, bind); ystr("event_state_mask"); dump_event_state_mask(gen, bind); y(map_close); } void dump_node(yajl_gen gen, struct Con *con, bool inplace_restart) { y(map_open); ystr("id"); y(integer, (uintptr_t)con); ystr("type"); switch (con->type) { case CT_ROOT: ystr("root"); break; case CT_OUTPUT: ystr("output"); break; case CT_CON: ystr("con"); break; case CT_FLOATING_CON: ystr("floating_con"); break; case CT_WORKSPACE: ystr("workspace"); break; case CT_DOCKAREA: ystr("dockarea"); break; } /* provided for backwards compatibility only. */ ystr("orientation"); if (!con_is_split(con)) ystr("none"); else { if (con_orientation(con) == HORIZ) ystr("horizontal"); else ystr("vertical"); } ystr("scratchpad_state"); switch (con->scratchpad_state) { case SCRATCHPAD_NONE: ystr("none"); break; case SCRATCHPAD_FRESH: ystr("fresh"); break; case SCRATCHPAD_CHANGED: ystr("changed"); break; } ystr("percent"); if (con->percent == 0.0) y(null); else y(double, con->percent); ystr("urgent"); y(bool, con->urgent); ystr("marks"); y(array_open); mark_t *mark; TAILQ_FOREACH (mark, &(con->marks_head), marks) { ystr(mark->name); } y(array_close); ystr("focused"); y(bool, (con == focused)); if (con->type != CT_ROOT && con->type != CT_OUTPUT) { ystr("output"); ystr(con_get_output(con)->name); } ystr("layout"); switch (con->layout) { case L_DEFAULT: DLOG("About to dump layout=default, this is a bug in the code.\n"); assert(false); break; case L_SPLITV: ystr("splitv"); break; case L_SPLITH: ystr("splith"); break; case L_STACKED: ystr("stacked"); break; case L_TABBED: ystr("tabbed"); break; case L_DOCKAREA: ystr("dockarea"); break; case L_OUTPUT: ystr("output"); break; } ystr("workspace_layout"); switch (con->workspace_layout) { case L_DEFAULT: ystr("default"); break; case L_STACKED: ystr("stacked"); break; case L_TABBED: ystr("tabbed"); break; default: DLOG("About to dump workspace_layout=%d (none of default/stacked/tabbed), this is a bug.\n", con->workspace_layout); assert(false); break; } ystr("last_split_layout"); switch (con->layout) { case L_SPLITV: ystr("splitv"); break; default: ystr("splith"); break; } ystr("border"); switch (con->border_style) { case BS_NORMAL: ystr("normal"); break; case BS_NONE: ystr("none"); break; case BS_PIXEL: ystr("pixel"); break; } ystr("current_border_width"); y(integer, con->current_border_width); dump_rect(gen, "rect", con->rect); dump_rect(gen, "deco_rect", con->deco_rect); dump_rect(gen, "window_rect", con->window_rect); dump_rect(gen, "geometry", con->geometry); ystr("name"); if (con->window && con->window->name) ystr(i3string_as_utf8(con->window->name)); else if (con->name != NULL) ystr(con->name); else y(null); if (con->title_format != NULL) { ystr("title_format"); ystr(con->title_format); } if (con->type == CT_WORKSPACE) { ystr("num"); y(integer, con->num); } ystr("window"); if (con->window) y(integer, con->window->id); else y(null); ystr("window_type"); if (con->window) { if (con->window->window_type == A__NET_WM_WINDOW_TYPE_NORMAL) { ystr("normal"); } else if (con->window->window_type == A__NET_WM_WINDOW_TYPE_DOCK) { ystr("dock"); } else if (con->window->window_type == A__NET_WM_WINDOW_TYPE_DIALOG) { ystr("dialog"); } else if (con->window->window_type == A__NET_WM_WINDOW_TYPE_UTILITY) { ystr("utility"); } else if (con->window->window_type == A__NET_WM_WINDOW_TYPE_TOOLBAR) { ystr("toolbar"); } else if (con->window->window_type == A__NET_WM_WINDOW_TYPE_SPLASH) { ystr("splash"); } else if (con->window->window_type == A__NET_WM_WINDOW_TYPE_MENU) { ystr("menu"); } else if (con->window->window_type == A__NET_WM_WINDOW_TYPE_DROPDOWN_MENU) { ystr("dropdown_menu"); } else if (con->window->window_type == A__NET_WM_WINDOW_TYPE_POPUP_MENU) { ystr("popup_menu"); } else if (con->window->window_type == A__NET_WM_WINDOW_TYPE_TOOLTIP) { ystr("tooltip"); } else if (con->window->window_type == A__NET_WM_WINDOW_TYPE_NOTIFICATION) { ystr("notification"); } else { ystr("unknown"); } } else y(null); if (con->window && !inplace_restart) { /* Window properties are useless to preserve when restarting because * they will be queried again anyway. However, for i3-save-tree(1), * they are very useful and save i3-save-tree dealing with X11. */ ystr("window_properties"); y(map_open); #define DUMP_PROPERTY(key, prop_name) \ do { \ if (con->window->prop_name != NULL) { \ ystr(key); \ ystr(con->window->prop_name); \ } \ } while (0) DUMP_PROPERTY("class", class_class); DUMP_PROPERTY("instance", class_instance); DUMP_PROPERTY("window_role", role); if (con->window->name != NULL) { ystr("title"); ystr(i3string_as_utf8(con->window->name)); } ystr("transient_for"); if (con->window->transient_for == XCB_NONE) y(null); else y(integer, con->window->transient_for); y(map_close); } ystr("nodes"); y(array_open); Con *node; if (con->type != CT_DOCKAREA || !inplace_restart) { TAILQ_FOREACH (node, &(con->nodes_head), nodes) { dump_node(gen, node, inplace_restart); } } y(array_close); ystr("floating_nodes"); y(array_open); TAILQ_FOREACH (node, &(con->floating_head), floating_windows) { dump_node(gen, node, inplace_restart); } y(array_close); ystr("focus"); y(array_open); TAILQ_FOREACH (node, &(con->focus_head), focused) { y(integer, (uintptr_t)node); } y(array_close); ystr("fullscreen_mode"); y(integer, con->fullscreen_mode); ystr("sticky"); y(bool, con->sticky); ystr("floating"); switch (con->floating) { case FLOATING_AUTO_OFF: ystr("auto_off"); break; case FLOATING_AUTO_ON: ystr("auto_on"); break; case FLOATING_USER_OFF: ystr("user_off"); break; case FLOATING_USER_ON: ystr("user_on"); break; } ystr("swallows"); y(array_open); Match *match; TAILQ_FOREACH (match, &(con->swallow_head), matches) { /* We will generate a new restart_mode match specification after this * loop, so skip this one. */ if (match->restart_mode) continue; y(map_open); if (match->dock != M_DONTCHECK) { ystr("dock"); y(integer, match->dock); ystr("insert_where"); y(integer, match->insert_where); } #define DUMP_REGEX(re_name) \ do { \ if (match->re_name != NULL) { \ ystr(#re_name); \ ystr(match->re_name->pattern); \ } \ } while (0) DUMP_REGEX(class); DUMP_REGEX(instance); DUMP_REGEX(window_role); DUMP_REGEX(title); #undef DUMP_REGEX y(map_close); } if (inplace_restart) { if (con->window != NULL) { y(map_open); ystr("id"); y(integer, con->window->id); ystr("restart_mode"); y(bool, true); y(map_close); } } y(array_close); if (inplace_restart && con->window != NULL) { ystr("depth"); y(integer, con->depth); } if (inplace_restart && con->type == CT_ROOT && previous_workspace_name) { ystr("previous_workspace_name"); ystr(previous_workspace_name); } y(map_close); } static void dump_bar_bindings(yajl_gen gen, Barconfig *config) { if (TAILQ_EMPTY(&(config->bar_bindings))) return; ystr("bindings"); y(array_open); struct Barbinding *current; TAILQ_FOREACH (current, &(config->bar_bindings), bindings) { y(map_open); ystr("input_code"); y(integer, current->input_code); ystr("command"); ystr(current->command); ystr("release"); y(bool, current->release == B_UPON_KEYRELEASE); y(map_close); } y(array_close); } static char *canonicalize_output_name(char *name) { /* Do not canonicalize special output names. */ if (strcasecmp(name, "primary") == 0) { return name; } Output *output = get_output_by_name(name, false); return output ? output_primary_name(output) : name; } static void dump_bar_config(yajl_gen gen, Barconfig *config) { y(map_open); ystr("id"); ystr(config->id); if (config->num_outputs > 0) { ystr("outputs"); y(array_open); for (int c = 0; c < config->num_outputs; c++) { /* Convert monitor names (RandR ≥ 1.5) or output names * (RandR < 1.5) into monitor names. This way, existing * configs which use output names transparently keep * working. */ ystr(canonicalize_output_name(config->outputs[c])); } y(array_close); } if (!TAILQ_EMPTY(&(config->tray_outputs))) { ystr("tray_outputs"); y(array_open); struct tray_output_t *tray_output; TAILQ_FOREACH (tray_output, &(config->tray_outputs), tray_outputs) { ystr(canonicalize_output_name(tray_output->output)); } y(array_close); } #define YSTR_IF_SET(name) \ do { \ if (config->name) { \ ystr(#name); \ ystr(config->name); \ } \ } while (0) ystr("tray_padding"); y(integer, config->tray_padding); YSTR_IF_SET(socket_path); ystr("mode"); switch (config->mode) { case M_HIDE: ystr("hide"); break; case M_INVISIBLE: ystr("invisible"); break; case M_DOCK: default: ystr("dock"); break; } ystr("hidden_state"); switch (config->hidden_state) { case S_SHOW: ystr("show"); break; case S_HIDE: default: ystr("hide"); break; } ystr("modifier"); y(integer, config->modifier); dump_bar_bindings(gen, config); ystr("position"); if (config->position == P_BOTTOM) ystr("bottom"); else ystr("top"); YSTR_IF_SET(status_command); YSTR_IF_SET(font); if (config->separator_symbol) { ystr("separator_symbol"); ystr(config->separator_symbol); } ystr("workspace_buttons"); y(bool, !config->hide_workspace_buttons); ystr("workspace_min_width"); y(integer, config->workspace_min_width); ystr("strip_workspace_numbers"); y(bool, config->strip_workspace_numbers); ystr("strip_workspace_name"); y(bool, config->strip_workspace_name); ystr("binding_mode_indicator"); y(bool, !config->hide_binding_mode_indicator); ystr("verbose"); y(bool, config->verbose); #undef YSTR_IF_SET #define YSTR_IF_SET(name) \ do { \ if (config->colors.name) { \ ystr(#name); \ ystr(config->colors.name); \ } \ } while (0) ystr("colors"); y(map_open); YSTR_IF_SET(background); YSTR_IF_SET(statusline); YSTR_IF_SET(separator); YSTR_IF_SET(focused_background); YSTR_IF_SET(focused_statusline); YSTR_IF_SET(focused_separator); YSTR_IF_SET(focused_workspace_border); YSTR_IF_SET(focused_workspace_bg); YSTR_IF_SET(focused_workspace_text); YSTR_IF_SET(active_workspace_border); YSTR_IF_SET(active_workspace_bg); YSTR_IF_SET(active_workspace_text); YSTR_IF_SET(inactive_workspace_border); YSTR_IF_SET(inactive_workspace_bg); YSTR_IF_SET(inactive_workspace_text); YSTR_IF_SET(urgent_workspace_border); YSTR_IF_SET(urgent_workspace_bg); YSTR_IF_SET(urgent_workspace_text); YSTR_IF_SET(binding_mode_border); YSTR_IF_SET(binding_mode_bg); YSTR_IF_SET(binding_mode_text); y(map_close); y(map_close); #undef YSTR_IF_SET } IPC_HANDLER(tree) { setlocale(LC_NUMERIC, "C"); yajl_gen gen = ygenalloc(); dump_node(gen, croot, false); setlocale(LC_NUMERIC, ""); const unsigned char *payload; ylength length; y(get_buf, &payload, &length); ipc_send_client_message(client, length, I3_IPC_REPLY_TYPE_TREE, payload); y(free); } /* * Formats the reply message for a GET_WORKSPACES request and sends it to the * client * */ IPC_HANDLER(get_workspaces) { yajl_gen gen = ygenalloc(); y(array_open); Con *focused_ws = con_get_workspace(focused); Con *output; TAILQ_FOREACH (output, &(croot->nodes_head), nodes) { if (con_is_internal(output)) continue; Con *ws; TAILQ_FOREACH (ws, &(output_get_content(output)->nodes_head), nodes) { assert(ws->type == CT_WORKSPACE); y(map_open); ystr("id"); y(integer, (uintptr_t)ws); ystr("num"); y(integer, ws->num); ystr("name"); ystr(ws->name); ystr("visible"); y(bool, workspace_is_visible(ws)); ystr("focused"); y(bool, ws == focused_ws); ystr("rect"); y(map_open); ystr("x"); y(integer, ws->rect.x); ystr("y"); y(integer, ws->rect.y); ystr("width"); y(integer, ws->rect.width); ystr("height"); y(integer, ws->rect.height); y(map_close); ystr("output"); ystr(output->name); ystr("urgent"); y(bool, ws->urgent); y(map_close); } } y(array_close); const unsigned char *payload; ylength length; y(get_buf, &payload, &length); ipc_send_client_message(client, length, I3_IPC_REPLY_TYPE_WORKSPACES, payload); y(free); } /* * Formats the reply message for a GET_OUTPUTS request and sends it to the * client * */ IPC_HANDLER(get_outputs) { yajl_gen gen = ygenalloc(); y(array_open); Output *output; TAILQ_FOREACH (output, &outputs, outputs) { y(map_open); ystr("name"); ystr(output_primary_name(output)); ystr("active"); y(bool, output->active); ystr("primary"); y(bool, output->primary); ystr("rect"); y(map_open); ystr("x"); y(integer, output->rect.x); ystr("y"); y(integer, output->rect.y); ystr("width"); y(integer, output->rect.width); ystr("height"); y(integer, output->rect.height); y(map_close); ystr("current_workspace"); Con *ws = NULL; if (output->con && (ws = con_get_fullscreen_con(output->con, CF_OUTPUT))) ystr(ws->name); else y(null); y(map_close); } y(array_close); const unsigned char *payload; ylength length; y(get_buf, &payload, &length); ipc_send_client_message(client, length, I3_IPC_REPLY_TYPE_OUTPUTS, payload); y(free); } /* * Formats the reply message for a GET_MARKS request and sends it to the * client * */ IPC_HANDLER(get_marks) { yajl_gen gen = ygenalloc(); y(array_open); Con *con; TAILQ_FOREACH (con, &all_cons, all_cons) { mark_t *mark; TAILQ_FOREACH (mark, &(con->marks_head), marks) { ystr(mark->name); } } y(array_close); const unsigned char *payload; ylength length; y(get_buf, &payload, &length); ipc_send_client_message(client, length, I3_IPC_REPLY_TYPE_MARKS, payload); y(free); } /* * Returns the version of i3 * */ IPC_HANDLER(get_version) { yajl_gen gen = ygenalloc(); y(map_open); ystr("major"); y(integer, MAJOR_VERSION); ystr("minor"); y(integer, MINOR_VERSION); ystr("patch"); y(integer, PATCH_VERSION); ystr("human_readable"); ystr(i3_version); ystr("loaded_config_file_name"); ystr(current_configpath); y(map_close); const unsigned char *payload; ylength length; y(get_buf, &payload, &length); ipc_send_client_message(client, length, I3_IPC_REPLY_TYPE_VERSION, payload); y(free); } /* * Formats the reply message for a GET_BAR_CONFIG request and sends it to the * client. * */ IPC_HANDLER(get_bar_config) { yajl_gen gen = ygenalloc(); /* If no ID was passed, we return a JSON array with all IDs */ if (message_size == 0) { y(array_open); Barconfig *current; TAILQ_FOREACH (current, &barconfigs, configs) { ystr(current->id); } y(array_close); const unsigned char *payload; ylength length; y(get_buf, &payload, &length); ipc_send_client_message(client, length, I3_IPC_REPLY_TYPE_BAR_CONFIG, payload); y(free); return; } /* To get a properly terminated buffer, we copy * message_size bytes out of the buffer */ char *bar_id = NULL; sasprintf(&bar_id, "%.*s", message_size, message); LOG("IPC: looking for config for bar ID \"%s\"\n", bar_id); Barconfig *current, *config = NULL; TAILQ_FOREACH (current, &barconfigs, configs) { if (strcmp(current->id, bar_id) != 0) continue; config = current; break; } free(bar_id); if (!config) { /* If we did not find a config for the given ID, the reply will contain * a null 'id' field. */ y(map_open); ystr("id"); y(null); y(map_close); } else { dump_bar_config(gen, config); } const unsigned char *payload; ylength length; y(get_buf, &payload, &length); ipc_send_client_message(client, length, I3_IPC_REPLY_TYPE_BAR_CONFIG, payload); y(free); } /* * Returns a list of configured binding modes * */ IPC_HANDLER(get_binding_modes) { yajl_gen gen = ygenalloc(); y(array_open); struct Mode *mode; SLIST_FOREACH (mode, &modes, modes) { ystr(mode->name); } y(array_close); const unsigned char *payload; ylength length; y(get_buf, &payload, &length); ipc_send_client_message(client, length, I3_IPC_REPLY_TYPE_BINDING_MODES, payload); y(free); } /* * Callback for the YAJL parser (will be called when a string is parsed). * */ static int add_subscription(void *extra, const unsigned char *s, ylength len) { ipc_client *client = extra; DLOG("should add subscription to extra %p, sub %.*s\n", client, (int)len, s); int event = client->num_events; client->num_events++; client->events = srealloc(client->events, client->num_events * sizeof(char *)); /* We copy the string because it is not null-terminated and strndup() * is missing on some BSD systems */ client->events[event] = scalloc(len + 1, 1); memcpy(client->events[event], s, len); DLOG("client is now subscribed to:\n"); for (int i = 0; i < client->num_events; i++) { DLOG("event %s\n", client->events[i]); } DLOG("(done)\n"); return 1; } /* * Subscribes this connection to the event types which were given as a JSON * serialized array in the payload field of the message. * */ IPC_HANDLER(subscribe) { yajl_handle p; yajl_status stat; /* Setup the JSON parser */ static yajl_callbacks callbacks = { .yajl_string = add_subscription, }; p = yalloc(&callbacks, (void *)client); stat = yajl_parse(p, (const unsigned char *)message, message_size); if (stat != yajl_status_ok) { unsigned char *err; err = yajl_get_error(p, true, (const unsigned char *)message, message_size); ELOG("YAJL parse error: %s\n", err); yajl_free_error(p, err); const char *reply = "{\"success\":false}"; ipc_send_client_message(client, strlen(reply), I3_IPC_REPLY_TYPE_SUBSCRIBE, (const uint8_t *)reply); yajl_free(p); return; } yajl_free(p); const char *reply = "{\"success\":true}"; ipc_send_client_message(client, strlen(reply), I3_IPC_REPLY_TYPE_SUBSCRIBE, (const uint8_t *)reply); if (client->first_tick_sent) { return; } bool is_tick = false; for (int i = 0; i < client->num_events; i++) { if (strcmp(client->events[i], "tick") == 0) { is_tick = true; break; } } if (!is_tick) { return; } client->first_tick_sent = true; const char *payload = "{\"first\":true,\"payload\":\"\"}"; ipc_send_client_message(client, strlen(payload), I3_IPC_EVENT_TICK, (const uint8_t *)payload); } /* * Returns the raw last loaded i3 configuration file contents. */ IPC_HANDLER(get_config) { yajl_gen gen = ygenalloc(); y(map_open); ystr("config"); ystr(current_config); y(map_close); const unsigned char *payload; ylength length; y(get_buf, &payload, &length); ipc_send_client_message(client, length, I3_IPC_REPLY_TYPE_CONFIG, payload); y(free); } /* * Sends the tick event from the message payload to subscribers. Establishes a * synchronization point in event-related tests. */ IPC_HANDLER(send_tick) { yajl_gen gen = ygenalloc(); y(map_open); ystr("first"); y(bool, false); ystr("payload"); yajl_gen_string(gen, (unsigned char *)message, message_size); y(map_close); const unsigned char *payload; ylength length; y(get_buf, &payload, &length); ipc_send_event("tick", I3_IPC_EVENT_TICK, (const char *)payload); y(free); const char *reply = "{\"success\":true}"; ipc_send_client_message(client, strlen(reply), I3_IPC_REPLY_TYPE_TICK, (const uint8_t *)reply); DLOG("Sent tick event\n"); } struct sync_state { char *last_key; uint32_t rnd; xcb_window_t window; }; static int _sync_json_key(void *extra, const unsigned char *val, size_t len) { struct sync_state *state = extra; FREE(state->last_key); state->last_key = scalloc(len + 1, 1); memcpy(state->last_key, val, len); return 1; } static int _sync_json_int(void *extra, long long val) { struct sync_state *state = extra; if (strcasecmp(state->last_key, "rnd") == 0) { state->rnd = val; } else if (strcasecmp(state->last_key, "window") == 0) { state->window = (xcb_window_t)val; } return 1; } IPC_HANDLER(sync) { yajl_handle p; yajl_status stat; /* Setup the JSON parser */ static yajl_callbacks callbacks = { .yajl_map_key = _sync_json_key, .yajl_integer = _sync_json_int, }; struct sync_state state; memset(&state, '\0', sizeof(struct sync_state)); p = yalloc(&callbacks, (void *)&state); stat = yajl_parse(p, (const unsigned char *)message, message_size); FREE(state.last_key); if (stat != yajl_status_ok) { unsigned char *err; err = yajl_get_error(p, true, (const unsigned char *)message, message_size); ELOG("YAJL parse error: %s\n", err); yajl_free_error(p, err); const char *reply = "{\"success\":false}"; ipc_send_client_message(client, strlen(reply), I3_IPC_REPLY_TYPE_SYNC, (const uint8_t *)reply); yajl_free(p); return; } yajl_free(p); DLOG("received IPC sync request (rnd = %d, window = 0x%08x)\n", state.rnd, state.window); sync_respond(state.window, state.rnd); const char *reply = "{\"success\":true}"; ipc_send_client_message(client, strlen(reply), I3_IPC_REPLY_TYPE_SYNC, (const uint8_t *)reply); } /* The index of each callback function corresponds to the numeric * value of the message type (see include/i3/ipc.h) */ handler_t handlers[12] = { handle_run_command, handle_get_workspaces, handle_subscribe, handle_get_outputs, handle_tree, handle_get_marks, handle_get_bar_config, handle_get_version, handle_get_binding_modes, handle_get_config, handle_send_tick, handle_sync, }; /* * Handler for activity on a client connection, receives a message from a * client. * * For now, the maximum message size is 2048. I’m not sure for what the * IPC interface will be used in the future, thus I’m not implementing a * mechanism for arbitrarily long messages, as it seems like overkill * at the moment. * */ static void ipc_receive_message(EV_P_ struct ev_io *w, int revents) { uint32_t message_type; uint32_t message_length; uint8_t *message = NULL; ipc_client *client = (ipc_client *)w->data; assert(client->fd == w->fd); int ret = ipc_recv_message(w->fd, &message_type, &message_length, &message); /* EOF or other error */ if (ret < 0) { /* Was this a spurious read? See ev(3) */ if (ret == -1 && errno == EAGAIN) { FREE(message); return; } /* If not, there was some kind of error. We don’t bother and close the * connection. Delete the client from the list of clients. */ free_ipc_client(client, -1); FREE(message); return; } if (message_type >= (sizeof(handlers) / sizeof(handler_t))) DLOG("Unhandled message type: %d\n", message_type); else { handler_t h = handlers[message_type]; h(client, message, 0, message_length, message_type); } FREE(message); } static void ipc_client_timeout(EV_P_ ev_timer *w, int revents) { /* No need to be polite and check for writeability, the other callback would * have been called by now. */ ipc_client *client = (ipc_client *)w->data; char *cmdline = NULL; #if defined(__linux__) && defined(SO_PEERCRED) struct ucred peercred; socklen_t so_len = sizeof(peercred); if (getsockopt(client->fd, SOL_SOCKET, SO_PEERCRED, &peercred, &so_len) != 0) { goto end; } char *exepath; sasprintf(&exepath, "/proc/%d/cmdline", peercred.pid); int fd = open(exepath, O_RDONLY); free(exepath); if (fd == -1) { goto end; } char buf[512] = {'\0'}; /* cut off cmdline for the error message. */ const ssize_t n = read(fd, buf, sizeof(buf)); close(fd); if (n < 0) { goto end; } for (char *walk = buf; walk < buf + n - 1; walk++) { if (*walk == '\0') { *walk = ' '; } } cmdline = buf; if (cmdline) { ELOG("client %p with pid %d and cmdline '%s' on fd %d timed out, killing\n", client, peercred.pid, cmdline, client->fd); } end: #endif if (!cmdline) { ELOG("client %p on fd %d timed out, killing\n", client, client->fd); } free_ipc_client(client, -1); } static void ipc_socket_writeable_cb(EV_P_ ev_io *w, int revents) { DLOG("fd %d writeable\n", w->fd); ipc_client *client = (ipc_client *)w->data; /* If this callback is called then there should be a corresponding active * timer. */ assert(client->timeout != NULL); ipc_push_pending(client); } /* * Handler for activity on the listening socket, meaning that a new client * has just connected and we should accept() him. Sets up the event handler * for activity on the new connection and inserts the file descriptor into * the list of clients. * */ void ipc_new_client(EV_P_ struct ev_io *w, int revents) { struct sockaddr_un peer; socklen_t len = sizeof(struct sockaddr_un); int fd; if ((fd = accept(w->fd, (struct sockaddr *)&peer, &len)) < 0) { if (errno != EINTR) { perror("accept()"); } return; } /* Close this file descriptor on exec() */ (void)fcntl(fd, F_SETFD, FD_CLOEXEC); ipc_new_client_on_fd(EV_A_ fd); } /* * ipc_new_client_on_fd() only sets up the event handler * for activity on the new connection and inserts the file descriptor into * the list of clients. * * This variant is useful for the inherited IPC connection when restarting. * */ ipc_client *ipc_new_client_on_fd(EV_P_ int fd) { set_nonblock(fd); ipc_client *client = scalloc(1, sizeof(ipc_client)); client->fd = fd; client->read_callback = scalloc(1, sizeof(struct ev_io)); client->read_callback->data = client; ev_io_init(client->read_callback, ipc_receive_message, fd, EV_READ); ev_io_start(EV_A_ client->read_callback); client->write_callback = scalloc(1, sizeof(struct ev_io)); client->write_callback->data = client; ev_io_init(client->write_callback, ipc_socket_writeable_cb, fd, EV_WRITE); DLOG("IPC: new client connected on fd %d\n", fd); TAILQ_INSERT_TAIL(&all_clients, client, clients); return client; } /* * Creates the UNIX domain socket at the given path, sets it to non-blocking * mode, bind()s and listen()s on it. * */ int ipc_create_socket(const char *filename) { int sockfd; FREE(current_socketpath); char *resolved = resolve_tilde(filename); DLOG("Creating IPC-socket at %s\n", resolved); char *copy = sstrdup(resolved); const char *dir = dirname(copy); if (!path_exists(dir)) mkdirp(dir, DEFAULT_DIR_MODE); free(copy); /* Unlink the unix domain socket before */ unlink(resolved); if ((sockfd = socket(AF_LOCAL, SOCK_STREAM, 0)) < 0) { perror("socket()"); free(resolved); return -1; } (void)fcntl(sockfd, F_SETFD, FD_CLOEXEC); struct sockaddr_un addr; memset(&addr, 0, sizeof(struct sockaddr_un)); addr.sun_family = AF_LOCAL; strncpy(addr.sun_path, resolved, sizeof(addr.sun_path) - 1); if (bind(sockfd, (struct sockaddr *)&addr, sizeof(struct sockaddr_un)) < 0) { perror("bind()"); free(resolved); return -1; } set_nonblock(sockfd); if (listen(sockfd, 5) < 0) { perror("listen()"); free(resolved); return -1; } current_socketpath = resolved; return sockfd; } /* * Generates a json workspace event. Returns a dynamically allocated yajl * generator. Free with yajl_gen_free(). */ yajl_gen ipc_marshal_workspace_event(const char *change, Con *current, Con *old) { setlocale(LC_NUMERIC, "C"); yajl_gen gen = ygenalloc(); y(map_open); ystr("change"); ystr(change); ystr("current"); if (current == NULL) y(null); else dump_node(gen, current, false); ystr("old"); if (old == NULL) y(null); else dump_node(gen, old, false); y(map_close); setlocale(LC_NUMERIC, ""); return gen; } /* * For the workspace events we send, along with the usual "change" field, also * the workspace container in "current". For focus events, we send the * previously focused workspace in "old". */ void ipc_send_workspace_event(const char *change, Con *current, Con *old) { yajl_gen gen = ipc_marshal_workspace_event(change, current, old); const unsigned char *payload; ylength length; y(get_buf, &payload, &length); ipc_send_event("workspace", I3_IPC_EVENT_WORKSPACE, (const char *)payload); y(free); } /* * For the window events we send, along the usual "change" field, * also the window container, in "container". */ void ipc_send_window_event(const char *property, Con *con) { DLOG("Issue IPC window %s event (con = %p, window = 0x%08x)\n", property, con, (con->window ? con->window->id : XCB_WINDOW_NONE)); setlocale(LC_NUMERIC, "C"); yajl_gen gen = ygenalloc(); y(map_open); ystr("change"); ystr(property); ystr("container"); dump_node(gen, con, false); y(map_close); const unsigned char *payload; ylength length; y(get_buf, &payload, &length); ipc_send_event("window", I3_IPC_EVENT_WINDOW, (const char *)payload); y(free); setlocale(LC_NUMERIC, ""); } /* * For the barconfig update events, we send the serialized barconfig. */ void ipc_send_barconfig_update_event(Barconfig *barconfig) { DLOG("Issue barconfig_update event for id = %s\n", barconfig->id); setlocale(LC_NUMERIC, "C"); yajl_gen gen = ygenalloc(); dump_bar_config(gen, barconfig); const unsigned char *payload; ylength length; y(get_buf, &payload, &length); ipc_send_event("barconfig_update", I3_IPC_EVENT_BARCONFIG_UPDATE, (const char *)payload); y(free); setlocale(LC_NUMERIC, ""); } /* * For the binding events, we send the serialized binding struct. */ void ipc_send_binding_event(const char *event_type, Binding *bind) { DLOG("Issue IPC binding %s event (sym = %s, code = %d)\n", event_type, bind->symbol, bind->keycode); setlocale(LC_NUMERIC, "C"); yajl_gen gen = ygenalloc(); y(map_open); ystr("change"); ystr(event_type); ystr("binding"); dump_binding(gen, bind); y(map_close); const unsigned char *payload; ylength length; y(get_buf, &payload, &length); ipc_send_event("binding", I3_IPC_EVENT_BINDING, (const char *)payload); y(free); setlocale(LC_NUMERIC, ""); } /* * Sends a restart reply to the IPC client on the specified fd. */ void ipc_confirm_restart(ipc_client *client) { DLOG("ipc_confirm_restart(fd %d)\n", client->fd); static const char *reply = "[{\"success\":true}]"; ipc_send_client_message( client, strlen(reply), I3_IPC_REPLY_TYPE_COMMAND, (const uint8_t *)reply); ipc_push_pending(client); }