#include "server.h" #include #include #include #include #include #include #include "adb.h" #include "util/file.h" #include "util/log.h" #include "util/net_intr.h" #include "util/process_intr.h" #include "util/str.h" #define SC_SERVER_FILENAME "scrcpy-server" #define SC_SERVER_PATH_DEFAULT PREFIX "/share/scrcpy/" SC_SERVER_FILENAME #define SC_DEVICE_SERVER_PATH "/data/local/tmp/scrcpy-server.jar" static char * get_server_path(void) { #ifdef __WINDOWS__ const wchar_t *server_path_env = _wgetenv(L"SCRCPY_SERVER_PATH"); #else const char *server_path_env = getenv("SCRCPY_SERVER_PATH"); #endif if (server_path_env) { // if the envvar is set, use it #ifdef __WINDOWS__ char *server_path = sc_str_from_wchars(server_path_env); #else char *server_path = strdup(server_path_env); #endif if (!server_path) { LOG_OOM(); return NULL; } LOGD("Using SCRCPY_SERVER_PATH: %s", server_path); return server_path; } #ifndef PORTABLE LOGD("Using server: " SC_SERVER_PATH_DEFAULT); char *server_path = strdup(SC_SERVER_PATH_DEFAULT); if (!server_path) { LOG_OOM(); return NULL; } #else char *server_path = sc_file_get_local_path(SC_SERVER_FILENAME); if (!server_path) { LOGE("Could not get local file path, " "using " SC_SERVER_FILENAME " from current directory"); return strdup(SC_SERVER_FILENAME); } LOGD("Using server (portable): %s", server_path); #endif return server_path; } static void sc_server_params_destroy(struct sc_server_params *params) { // The server stores a copy of the params provided by the user free((char *) params->serial); free((char *) params->crop); free((char *) params->codec_options); free((char *) params->encoder_name); free((char *) params->tcpip_dst); } static bool sc_server_params_copy(struct sc_server_params *dst, const struct sc_server_params *src) { *dst = *src; // The params reference user-allocated memory, so we must copy them to // handle them from another thread #define COPY(FIELD) \ dst->FIELD = NULL; \ if (src->FIELD) { \ dst->FIELD = strdup(src->FIELD); \ if (!dst->FIELD) { \ goto error; \ } \ } COPY(serial); COPY(crop); COPY(codec_options); COPY(encoder_name); COPY(tcpip_dst); #undef COPY return true; error: sc_server_params_destroy(dst); return false; } static bool push_server(struct sc_intr *intr, const char *serial) { char *server_path = get_server_path(); if (!server_path) { return false; } if (!sc_file_is_regular(server_path)) { LOGE("'%s' does not exist or is not a regular file\n", server_path); free(server_path); return false; } bool ok = adb_push(intr, serial, server_path, SC_DEVICE_SERVER_PATH, 0); free(server_path); return ok; } static const char * log_level_to_server_string(enum sc_log_level level) { switch (level) { case SC_LOG_LEVEL_VERBOSE: return "verbose"; case SC_LOG_LEVEL_DEBUG: return "debug"; case SC_LOG_LEVEL_INFO: return "info"; case SC_LOG_LEVEL_WARN: return "warn"; case SC_LOG_LEVEL_ERROR: return "error"; default: assert(!"unexpected log level"); return "(unknown)"; } } static bool sc_server_sleep(struct sc_server *server, sc_tick deadline) { sc_mutex_lock(&server->mutex); bool timed_out = false; while (!server->stopped && !timed_out) { timed_out = !sc_cond_timedwait(&server->cond_stopped, &server->mutex, deadline); } bool stopped = server->stopped; sc_mutex_unlock(&server->mutex); return !stopped; } static sc_pid execute_server(struct sc_server *server, const struct sc_server_params *params) { sc_pid pid = SC_PROCESS_NONE; const char *cmd[128]; unsigned count = 0; cmd[count++] = "shell"; cmd[count++] = "CLASSPATH=" SC_DEVICE_SERVER_PATH; cmd[count++] = "app_process"; #ifdef SERVER_DEBUGGER # define SERVER_DEBUGGER_PORT "5005" cmd[count++] = # ifdef SERVER_DEBUGGER_METHOD_NEW /* Android 9 and above */ "-XjdwpProvider:internal -XjdwpOptions:transport=dt_socket,suspend=y," "server=y,address=" # else /* Android 8 and below */ "-agentlib:jdwp=transport=dt_socket,suspend=y,server=y,address=" # endif SERVER_DEBUGGER_PORT; #endif cmd[count++] = "/"; // unused cmd[count++] = "com.genymobile.scrcpy.Server"; cmd[count++] = SCRCPY_VERSION; unsigned dyn_idx = count; // from there, the strings are allocated #define ADD_PARAM(fmt, ...) { \ char *p = (char *) &cmd[count]; \ if (asprintf(&p, fmt, ## __VA_ARGS__) == -1) { \ goto end; \ } \ cmd[count++] = p; \ } #define STRBOOL(v) (v ? "true" : "false") ADD_PARAM("log_level=%s", log_level_to_server_string(params->log_level)); ADD_PARAM("bit_rate=%" PRIu32, params->bit_rate); if (params->max_size) { ADD_PARAM("max_size=%" PRIu16, params->max_size); } if (params->max_fps) { ADD_PARAM("max_fps=%" PRIu16, params->max_fps); } if (params->lock_video_orientation != SC_LOCK_VIDEO_ORIENTATION_UNLOCKED) { ADD_PARAM("lock_video_orientation=%" PRIi8, params->lock_video_orientation); } if (server->tunnel.forward) { ADD_PARAM("tunnel_forward=%s", STRBOOL(server->tunnel.forward)); } if (params->crop) { ADD_PARAM("crop=%s", params->crop); } if (!params->control) { // By default, control is true ADD_PARAM("control=%s", STRBOOL(params->control)); } if (params->display_id) { ADD_PARAM("display_id=%" PRIu32, params->display_id); } if (params->show_touches) { ADD_PARAM("show_touches=%s", STRBOOL(params->show_touches)); } if (params->stay_awake) { ADD_PARAM("stay_awake=%s", STRBOOL(params->stay_awake)); } if (params->codec_options) { ADD_PARAM("codec_options=%s", params->codec_options); } if (params->encoder_name) { ADD_PARAM("encoder_name=%s", params->encoder_name); } if (params->power_off_on_close) { ADD_PARAM("power_off_on_close=%s", STRBOOL(params->power_off_on_close)); } if (!params->clipboard_autosync) { // By defaut, clipboard_autosync is true ADD_PARAM("clipboard_autosync=%s", STRBOOL(params->clipboard_autosync)); } #undef ADD_PARAM #undef STRBOOL #ifdef SERVER_DEBUGGER LOGI("Server debugger waiting for a client on device port " SERVER_DEBUGGER_PORT "..."); // From the computer, run // adb forward tcp:5005 tcp:5005 // Then, from Android Studio: Run > Debug > Edit configurations... // On the left, click on '+', "Remote", with: // Host: localhost // Port: 5005 // Then click on "Debug" #endif // Inherit both stdout and stderr (all server logs are printed to stdout) pid = adb_execute(params->serial, cmd, count, 0); end: for (unsigned i = dyn_idx; i < count; ++i) { free((char *) cmd[i]); } return pid; } static bool connect_and_read_byte(struct sc_intr *intr, sc_socket socket, uint32_t tunnel_host, uint16_t tunnel_port) { bool ok = net_connect_intr(intr, socket, tunnel_host, tunnel_port); if (!ok) { return false; } char byte; // the connection may succeed even if the server behind the "adb tunnel" // is not listening, so read one byte to detect a working connection if (net_recv_intr(intr, socket, &byte, 1) != 1) { // the server is not listening yet behind the adb tunnel return false; } return true; } static sc_socket connect_to_server(struct sc_server *server, unsigned attempts, sc_tick delay, uint32_t host, uint16_t port) { do { LOGD("Remaining connection attempts: %u", attempts); sc_socket socket = net_socket(); if (socket != SC_SOCKET_NONE) { bool ok = connect_and_read_byte(&server->intr, socket, host, port); if (ok) { // it worked! return socket; } net_close(socket); } if (sc_intr_is_interrupted(&server->intr)) { // Stop immediately break; } if (attempts) { sc_tick deadline = sc_tick_now() + delay; bool ok = sc_server_sleep(server, deadline); if (!ok) { LOGI("Connection attempt stopped"); break; } } } while (--attempts); return SC_SOCKET_NONE; } bool sc_server_init(struct sc_server *server, const struct sc_server_params *params, const struct sc_server_callbacks *cbs, void *cbs_userdata) { bool ok = sc_server_params_copy(&server->params, params); if (!ok) { LOG_OOM(); return false; } ok = sc_mutex_init(&server->mutex); if (!ok) { sc_server_params_destroy(&server->params); return false; } ok = sc_cond_init(&server->cond_stopped); if (!ok) { sc_mutex_destroy(&server->mutex); sc_server_params_destroy(&server->params); return false; } ok = sc_intr_init(&server->intr); if (!ok) { sc_cond_destroy(&server->cond_stopped); sc_mutex_destroy(&server->mutex); sc_server_params_destroy(&server->params); return false; } server->stopped = false; server->video_socket = SC_SOCKET_NONE; server->control_socket = SC_SOCKET_NONE; sc_adb_tunnel_init(&server->tunnel); assert(cbs); assert(cbs->on_connection_failed); assert(cbs->on_connected); assert(cbs->on_disconnected); server->cbs = cbs; server->cbs_userdata = cbs_userdata; return true; } static bool device_read_info(struct sc_intr *intr, sc_socket device_socket, struct sc_server_info *info) { unsigned char buf[SC_DEVICE_NAME_FIELD_LENGTH + 4]; ssize_t r = net_recv_all_intr(intr, device_socket, buf, sizeof(buf)); if (r < SC_DEVICE_NAME_FIELD_LENGTH + 4) { LOGE("Could not retrieve device information"); return false; } // in case the client sends garbage buf[SC_DEVICE_NAME_FIELD_LENGTH - 1] = '\0'; memcpy(info->device_name, (char *) buf, sizeof(info->device_name)); info->frame_size.width = (buf[SC_DEVICE_NAME_FIELD_LENGTH] << 8) | buf[SC_DEVICE_NAME_FIELD_LENGTH + 1]; info->frame_size.height = (buf[SC_DEVICE_NAME_FIELD_LENGTH + 2] << 8) | buf[SC_DEVICE_NAME_FIELD_LENGTH + 3]; return true; } static bool sc_server_connect_to(struct sc_server *server, struct sc_server_info *info) { struct sc_adb_tunnel *tunnel = &server->tunnel; assert(tunnel->enabled); const char *serial = server->params.serial; bool control = server->params.control; sc_socket video_socket = SC_SOCKET_NONE; sc_socket control_socket = SC_SOCKET_NONE; if (!tunnel->forward) { video_socket = net_accept_intr(&server->intr, tunnel->server_socket); if (video_socket == SC_SOCKET_NONE) { goto fail; } if (control) { control_socket = net_accept_intr(&server->intr, tunnel->server_socket); if (control_socket == SC_SOCKET_NONE) { goto fail; } } } else { uint32_t tunnel_host = server->params.tunnel_host; if (!tunnel_host) { tunnel_host = IPV4_LOCALHOST; } uint16_t tunnel_port = server->params.tunnel_port; if (!tunnel_port) { tunnel_port = tunnel->local_port; } unsigned attempts = 100; sc_tick delay = SC_TICK_FROM_MS(100); video_socket = connect_to_server(server, attempts, delay, tunnel_host, tunnel_port); if (video_socket == SC_SOCKET_NONE) { goto fail; } if (control) { // we know that the device is listening, we don't need several // attempts control_socket = net_socket(); if (control_socket == SC_SOCKET_NONE) { goto fail; } bool ok = net_connect_intr(&server->intr, control_socket, tunnel_host, tunnel_port); if (!ok) { goto fail; } } } // we don't need the adb tunnel anymore sc_adb_tunnel_close(tunnel, &server->intr, serial); // The sockets will be closed on stop if device_read_info() fails bool ok = device_read_info(&server->intr, video_socket, info); if (!ok) { goto fail; } assert(video_socket != SC_SOCKET_NONE); assert(!control || control_socket != SC_SOCKET_NONE); server->video_socket = video_socket; server->control_socket = control_socket; return true; fail: if (video_socket != SC_SOCKET_NONE) { if (!net_close(video_socket)) { LOGW("Could not close video socket"); } } if (control_socket != SC_SOCKET_NONE) { if (!net_close(control_socket)) { LOGW("Could not close control socket"); } } // Always leave this function with tunnel disabled sc_adb_tunnel_close(tunnel, &server->intr, serial); return false; } static void sc_server_on_terminated(void *userdata) { struct sc_server *server = userdata; // If the server process dies before connecting to the server socket, // then the client will be stuck forever on accept(). To avoid the problem, // wake up the accept() call (or any other) when the server dies, like on // stop() (it is safe to call interrupt() twice). sc_intr_interrupt(&server->intr); server->cbs->on_disconnected(server, server->cbs_userdata); LOGD("Server terminated"); } static bool sc_server_fill_serial(struct sc_server *server) { // Retrieve the actual device immediately if not provided, so that all // future adb commands are executed for this specific device, even if other // devices are connected afterwards (without "more than one // device/emulator" error) if (!server->params.serial) { // The serial is owned by sc_server_params, and will be freed on destroy server->params.serial = adb_get_serialno(&server->intr, 0); if (!server->params.serial) { LOGE("Could not get device serial"); return false; } LOGD("Device serial: %s", server->params.serial); } return true; } static bool is_tcpip_mode_enabled(struct sc_server *server) { struct sc_intr *intr = &server->intr; const char *serial = server->params.serial; char *current_port = adb_getprop(intr, serial, "service.adb.tcp.port", SC_ADB_SILENT); if (!current_port) { return false; } // Is the device is listening on TCP on port 5555? bool enabled = !strcmp("5555", current_port); free(current_port); return enabled; } static bool wait_tcpip_mode_enabled(struct sc_server *server, unsigned attempts, sc_tick delay) { if (is_tcpip_mode_enabled(server)) { LOGI("TCP/IP mode enabled"); return true; } // Only print this log if TCP/IP is not enabled LOGI("Waiting for TCP/IP mode enabled..."); do { sc_tick deadline = sc_tick_now() + delay; if (!sc_server_sleep(server, deadline)) { LOGI("TCP/IP mode waiting interrupted"); return false; } if (is_tcpip_mode_enabled(server)) { LOGI("TCP/IP mode enabled"); return true; } } while (--attempts); return false; } char * append_port_5555(const char *ip) { size_t len = strlen(ip); // sizeof counts the final '\0' char *ip_port = malloc(len + sizeof(":5555")); if (!ip_port) { LOG_OOM(); return NULL; } memcpy(ip_port, ip, len); memcpy(ip_port + len, ":5555", sizeof(":5555")); return ip_port; } static bool sc_server_switch_to_tcpip(struct sc_server *server, char **out_ip_port) { const char *serial = server->params.serial; assert(serial); struct sc_intr *intr = &server->intr; char *ip = adb_get_device_ip(intr, serial, 0); if (!ip) { LOGE("Device IP not found"); return false; } char *ip_port = append_port_5555(ip); free(ip); if (!ip_port) { return false; } bool tcp_mode = is_tcpip_mode_enabled(server); if (!tcp_mode) { bool ok = adb_tcpip(intr, serial, 5555, SC_ADB_NO_STDOUT); if (!ok) { LOGE("Could not restart adbd in TCP/IP mode"); goto error; } unsigned attempts = 40; sc_tick delay = SC_TICK_FROM_MS(250); ok = wait_tcpip_mode_enabled(server, attempts, delay); if (!ok) { goto error; } } *out_ip_port = ip_port; return true; error: free(ip_port); return false; } static bool sc_server_connect_to_tcpip(struct sc_server *server, const char *ip_port) { struct sc_intr *intr = &server->intr; // Error expected if not connected, do not report any error adb_disconnect(intr, ip_port, SC_ADB_SILENT); bool ok = adb_connect(intr, ip_port, 0); if (!ok) { LOGE("Could not connect to %s", ip_port); return false; } // Override the serial, owned by the sc_server_params free((void *) server->params.serial); server->params.serial = strdup(ip_port); if (!server->params.serial) { LOG_OOM(); return false; } LOGI("Connected to %s", ip_port); return true; } static bool sc_server_configure_tcpip(struct sc_server *server) { char *ip_port; const struct sc_server_params *params = &server->params; // If tcpip parameter is given, then it must connect to this address. // Therefore, the device is unknown, so serial is meaningless at this point. assert(!params->serial || !params->tcpip_dst); if (params->tcpip_dst) { // Append ":5555" if no port is present bool contains_port = strchr(params->tcpip_dst, ':'); ip_port = contains_port ? strdup(params->tcpip_dst) : append_port_5555(params->tcpip_dst); if (!ip_port) { LOG_OOM(); return false; } } else { // The device IP address must be retrieved from the current // connected device if (!sc_server_fill_serial(server)) { return false; } // The serial is either the real serial when connected via USB, or // the IP:PORT when connected over TCP/IP. Only the latter contains // a colon. bool is_already_tcpip = strchr(params->serial, ':'); if (is_already_tcpip) { // Nothing to do LOGI("Device already connected via TCP/IP: %s", params->serial); return true; } bool ok = sc_server_switch_to_tcpip(server, &ip_port); if (!ok) { return false; } } // On success, this call changes params->serial bool ok = sc_server_connect_to_tcpip(server, ip_port); free(ip_port); return ok; } static int run_server(void *data) { struct sc_server *server = data; const struct sc_server_params *params = &server->params; if (params->serial) { LOGD("Device serial: %s", params->serial); } if (params->tcpip) { // params->serial may be changed after this call bool ok = sc_server_configure_tcpip(server); if (!ok) { goto error_connection_failed; } } // It is ok to call this function even if the device serial has been // changed by switching over TCP/IP if (!sc_server_fill_serial(server)) { goto error_connection_failed; } bool ok = push_server(&server->intr, params->serial); if (!ok) { goto error_connection_failed; } ok = sc_adb_tunnel_open(&server->tunnel, &server->intr, params->serial, params->port_range, params->force_adb_forward); if (!ok) { goto error_connection_failed; } // server will connect to our server socket sc_pid pid = execute_server(server, params); if (pid == SC_PROCESS_NONE) { sc_adb_tunnel_close(&server->tunnel, &server->intr, params->serial); goto error_connection_failed; } static const struct sc_process_listener listener = { .on_terminated = sc_server_on_terminated, }; struct sc_process_observer observer; ok = sc_process_observer_init(&observer, pid, &listener, server); if (!ok) { sc_process_terminate(pid); sc_process_wait(pid, true); // ignore exit code sc_adb_tunnel_close(&server->tunnel, &server->intr, params->serial); goto error_connection_failed; } ok = sc_server_connect_to(server, &server->info); // The tunnel is always closed by server_connect_to() if (!ok) { sc_process_terminate(pid); sc_process_wait(pid, true); // ignore exit code sc_process_observer_join(&observer); sc_process_observer_destroy(&observer); goto error_connection_failed; } // Now connected server->cbs->on_connected(server, server->cbs_userdata); // Wait for server_stop() sc_mutex_lock(&server->mutex); while (!server->stopped) { sc_cond_wait(&server->cond_stopped, &server->mutex); } sc_mutex_unlock(&server->mutex); // Interrupt sockets to wake up socket blocking calls on the server assert(server->video_socket != SC_SOCKET_NONE); net_interrupt(server->video_socket); net_close(server->video_socket); if (server->control_socket != SC_SOCKET_NONE) { // There is no control_socket if --no-control is set net_interrupt(server->control_socket); net_close(server->control_socket); } // Give some delay for the server to terminate properly #define WATCHDOG_DELAY SC_TICK_FROM_SEC(1) sc_tick deadline = sc_tick_now() + WATCHDOG_DELAY; bool terminated = sc_process_observer_timedwait(&observer, deadline); // After this delay, kill the server if it's not dead already. // On some devices, closing the sockets is not sufficient to wake up the // blocking calls while the device is asleep. if (!terminated) { // The process may have terminated since the check, but it is not // reaped (closed) yet, so its PID is still valid, and it is ok to call // sc_process_terminate() even in that case. LOGW("Killing the server..."); sc_process_terminate(pid); } sc_process_observer_join(&observer); sc_process_observer_destroy(&observer); sc_process_close(pid); return 0; error_connection_failed: server->cbs->on_connection_failed(server, server->cbs_userdata); return -1; } bool sc_server_start(struct sc_server *server) { bool ok = sc_thread_create(&server->thread, run_server, "scrcpy-server", server); if (!ok) { LOGE("Could not create server thread"); return false; } return true; } void sc_server_stop(struct sc_server *server) { sc_mutex_lock(&server->mutex); server->stopped = true; sc_cond_signal(&server->cond_stopped); sc_intr_interrupt(&server->intr); sc_mutex_unlock(&server->mutex); sc_thread_join(&server->thread, NULL); } void sc_server_destroy(struct sc_server *server) { sc_server_params_destroy(&server->params); sc_intr_destroy(&server->intr); sc_cond_destroy(&server->cond_stopped); sc_mutex_destroy(&server->mutex); }