/* * vim:ts=4:sw=4:expandtab * * i3 - an improved dynamic tiling window manager * * © 2009-2011 Michael Stapelberg and contributors * * See file LICENSE for license information. * * ipc.c: Everything about the UNIX domain sockets for IPC * */ #include #include #include #include #include #include #include #include #include "all.h" char *current_socketpath = NULL; /* Shorter names for all those yajl_gen_* functions */ #define y(x, ...) yajl_gen_ ## x (gen, ##__VA_ARGS__) #define ystr(str) yajl_gen_string(gen, (unsigned char*)str, strlen(str)) 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); flags |= O_NONBLOCK; if (fcntl(sockfd, F_SETFL, flags) < 0) err(-1, "Could not set O_NONBLOCK"); } /* * Emulates mkdir -p (creates any missing folders) * */ static bool mkdirp(const char *path) { if (mkdir(path, S_IRWXU | S_IRGRP | S_IXGRP | S_IROTH | S_IXOTH) == 0) return true; if (errno != ENOENT) { ELOG("mkdir(%s) failed: %s\n", path, strerror(errno)); return false; } char *copy = strdup(path); /* strip trailing slashes, if any */ while (copy[strlen(copy)-1] == '/') copy[strlen(copy)-1] = '\0'; char *sep = strrchr(copy, '/'); if (sep == NULL) return false; *sep = '\0'; bool result = false; if (mkdirp(copy)) result = mkdirp(path); free(copy); return result; } static void ipc_send_message(int fd, const unsigned char *payload, int message_type, int message_size) { int buffer_size = strlen("i3-ipc") + sizeof(uint32_t) + sizeof(uint32_t) + message_size; char msg[buffer_size]; char *walk = msg; strncpy(walk, "i3-ipc", buffer_size - 1); walk += strlen("i3-ipc"); memcpy(walk, &message_size, sizeof(uint32_t)); walk += sizeof(uint32_t); memcpy(walk, &message_type, sizeof(uint32_t)); walk += sizeof(uint32_t); memcpy(walk, payload, message_size); int sent_bytes = 0; int bytes_to_go = buffer_size; while (sent_bytes < bytes_to_go) { int n = write(fd, msg + sent_bytes, bytes_to_go); if (n == -1) { DLOG("write() failed: %s\n", strerror(errno)); return; } sent_bytes += n; bytes_to_go -= n; } } /* * 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) { /* see if this client is interested in this event */ bool interested = false; for (int i = 0; i < current->num_events; i++) { if (strcasecmp(current->events[i], event) != 0) continue; interested = true; break; } if (!interested) continue; ipc_send_message(current->fd, (const unsigned char*)payload, message_type, strlen(payload)); } } /* * Calls shutdown() on each socket and closes it. This function to be called * when exiting or restarting only! * */ void ipc_shutdown() { ipc_client *current; TAILQ_FOREACH(current, &all_clients, clients) { shutdown(current->fd, SHUT_RDWR); close(current->fd); } } /* * Executes the command and returns whether it could be successfully parsed * or not (at the moment, always returns true). * */ IPC_HANDLER(command) { /* To get a properly terminated buffer, we copy * message_size bytes out of the buffer */ char *command = scalloc(message_size + 1); strncpy(command, (const char*)message, message_size); LOG("IPC: received: *%s*\n", command); const char *reply = parse_cmd((const char*)command); free(command); /* If no reply was provided, we just use the default success message */ if (reply == NULL) reply = "{\"success\":true}"; ipc_send_message(fd, (const unsigned char*)reply, I3_IPC_REPLY_TYPE_COMMAND, strlen(reply)); } 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); } void dump_node(yajl_gen gen, struct Con *con, bool inplace_restart) { y(map_open); ystr("id"); y(integer, (long int)con); ystr("type"); y(integer, con->type); ystr("orientation"); switch (con->orientation) { case NO_ORIENTATION: ystr("none"); break; case HORIZ: ystr("horizontal"); break; case VERT: ystr("vertical"); break; } ystr("percent"); if (con->percent == 0.0) y(null); else y(double, con->percent); ystr("urgent"); y(bool, con->urgent); ystr("focused"); y(bool, (con == focused)); ystr("layout"); switch (con->layout) { case L_DEFAULT: ystr("default"); 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("border"); switch (con->border_style) { case BS_NORMAL: ystr("normal"); break; case BS_NONE: ystr("none"); break; case BS_1PIXEL: ystr("1pixel"); break; } dump_rect(gen, "rect", con->rect); dump_rect(gen, "window_rect", con->window_rect); dump_rect(gen, "geometry", con->geometry); ystr("name"); ystr(con->name); 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("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), nodes) { y(integer, (long int)node); } y(array_close); ystr("fullscreen_mode"); y(integer, con->fullscreen_mode); ystr("swallows"); y(array_open); Match *match; TAILQ_FOREACH(match, &(con->swallow_head), matches) { if (match->dock != -1) { y(map_open); ystr("dock"); y(integer, match->dock); ystr("insert_where"); y(integer, match->insert_where); y(map_close); } /* TODO: the other swallow keys */ } if (inplace_restart) { if (con->window != NULL) { y(map_open); ystr("id"); y(integer, con->window->id); y(map_close); } } y(array_close); y(map_close); } IPC_HANDLER(tree) { setlocale(LC_NUMERIC, "C"); #if YAJL_MAJOR >= 2 yajl_gen gen = yajl_gen_alloc(NULL); #else yajl_gen gen = yajl_gen_alloc(NULL, NULL); #endif dump_node(gen, croot, false); setlocale(LC_NUMERIC, ""); const unsigned char *payload; #if YAJL_MAJOR >= 2 size_t length; #else unsigned int length; #endif y(get_buf, &payload, &length); ipc_send_message(fd, payload, I3_IPC_REPLY_TYPE_TREE, length); y(free); } /* * Formats the reply message for a GET_WORKSPACES request and sends it to the * client * */ IPC_HANDLER(get_workspaces) { #if YAJL_MAJOR >= 2 yajl_gen gen = yajl_gen_alloc(NULL); #else yajl_gen gen = yajl_gen_alloc(NULL, NULL); #endif y(array_open); Con *focused_ws = con_get_workspace(focused); Con *output; TAILQ_FOREACH(output, &(croot->nodes_head), nodes) { Con *ws; TAILQ_FOREACH(ws, &(output_get_content(output)->nodes_head), nodes) { assert(ws->type == CT_WORKSPACE); y(map_open); ystr("num"); if (ws->num == -1) y(null); else 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; #if YAJL_MAJOR >= 2 size_t length; #else unsigned int length; #endif y(get_buf, &payload, &length); ipc_send_message(fd, payload, I3_IPC_REPLY_TYPE_WORKSPACES, length); y(free); } /* * Formats the reply message for a GET_OUTPUTS request and sends it to the * client * */ IPC_HANDLER(get_outputs) { #if YAJL_MAJOR >= 2 yajl_gen gen = yajl_gen_alloc(NULL); #else yajl_gen gen = yajl_gen_alloc(NULL, NULL); #endif y(array_open); Output *output; TAILQ_FOREACH(output, &outputs, outputs) { y(map_open); ystr("name"); ystr(output->name); ystr("active"); y(bool, output->active); 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; #if YAJL_MAJOR >= 2 size_t length; #else unsigned int length; #endif y(get_buf, &payload, &length); ipc_send_message(fd, payload, I3_IPC_REPLY_TYPE_OUTPUTS, length); y(free); } /* * Callback for the YAJL parser (will be called when a string is parsed). * */ #if YAJL_MAJOR < 2 static int add_subscription(void *extra, const unsigned char *s, unsigned int len) { #else static int add_subscription(void *extra, const unsigned char *s, size_t len) { #endif ipc_client *client = extra; DLOG("should add subscription to extra %p, sub %.*s\n", client, len, s); int event = client->num_events; client->num_events++; client->events = realloc(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); 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_callbacks callbacks; yajl_status stat; ipc_client *current, *client = NULL; /* Search the ipc_client structure for this connection */ TAILQ_FOREACH(current, &all_clients, clients) { if (current->fd != fd) continue; client = current; break; } if (client == NULL) { ELOG("Could not find ipc_client data structure for fd %d\n", fd); return; } /* Setup the JSON parser */ memset(&callbacks, 0, sizeof(yajl_callbacks)); callbacks.yajl_string = add_subscription; #if YAJL_MAJOR >= 2 p = yajl_alloc(&callbacks, NULL, (void*)client); #else p = yajl_alloc(&callbacks, NULL, NULL, (void*)client); #endif 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_message(fd, (const unsigned char*)reply, I3_IPC_REPLY_TYPE_SUBSCRIBE, strlen(reply)); yajl_free(p); return; } yajl_free(p); const char *reply = "{\"success\":true}"; ipc_send_message(fd, (const unsigned char*)reply, I3_IPC_REPLY_TYPE_SUBSCRIBE, strlen(reply)); } /* The index of each callback function corresponds to the numeric * value of the message type (see include/i3/ipc.h) */ handler_t handlers[5] = { handle_command, handle_get_workspaces, handle_subscribe, handle_get_outputs, handle_tree }; /* * 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) { char buf[2048]; int n = read(w->fd, buf, sizeof(buf)); /* On error or an empty message, we close the connection */ if (n <= 0) { #if 0 /* FIXME: I get these when closing a client socket, * therefore we just treat them as an error. Is this * correct? */ if (errno == EAGAIN || errno == EWOULDBLOCK) return; #endif /* If not, there was some kind of error. We don’t bother * and close the connection */ close(w->fd); /* Delete the client from the list of clients */ ipc_client *current; TAILQ_FOREACH(current, &all_clients, clients) { if (current->fd != w->fd) continue; for (int i = 0; i < current->num_events; i++) free(current->events[i]); /* We can call TAILQ_REMOVE because we break out of the * TAILQ_FOREACH afterwards */ TAILQ_REMOVE(&all_clients, current, clients); break; } ev_io_stop(EV_A_ w); DLOG("IPC: client disconnected\n"); return; } /* Terminate the message correctly */ buf[n] = '\0'; /* Check if the message starts with the i3 IPC magic code */ if (n < strlen(I3_IPC_MAGIC)) { DLOG("IPC: message too short, ignoring\n"); return; } if (strncmp(buf, I3_IPC_MAGIC, strlen(I3_IPC_MAGIC)) != 0) { DLOG("IPC: message does not start with the IPC magic\n"); return; } uint8_t *message = (uint8_t*)buf; while (n > 0) { DLOG("IPC: n = %d\n", n); message += strlen(I3_IPC_MAGIC); n -= strlen(I3_IPC_MAGIC); /* The next 32 bit after the magic are the message size */ uint32_t message_size; memcpy(&message_size, (uint32_t*)message, sizeof(uint32_t)); message += sizeof(uint32_t); n -= sizeof(uint32_t); if (message_size > n) { DLOG("IPC: Either the message size was wrong or the message was not read completely, dropping\n"); return; } /* The last 32 bits of the header are the message type */ uint32_t message_type; memcpy(&message_type, (uint32_t*)message, sizeof(uint32_t)); message += sizeof(uint32_t); n -= sizeof(uint32_t); if (message_type >= (sizeof(handlers) / sizeof(handler_t))) DLOG("Unhandled message type: %d\n", message_type); else { handler_t h = handlers[message_type]; h(w->fd, message, n, message_size, message_type); } n -= message_size; message += message_size; } } /* * 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 client; if ((client = accept(w->fd, (struct sockaddr*)&peer, &len)) < 0) { if (errno == EINTR) return; else perror("accept()"); return; } set_nonblock(client); struct ev_io *package = scalloc(sizeof(struct ev_io)); ev_io_init(package, ipc_receive_message, client, EV_READ); ev_io_start(EV_A_ package); DLOG("IPC: new client connected\n"); ipc_client *new = scalloc(sizeof(ipc_client)); new->fd = client; TAILQ_INSERT_TAIL(&all_clients, new, clients); } /* * 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); 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; }