/* SPDX-License-Identifier: GPL-3.0-or-later * Copyright © 2016-2018 The TokTok team. * Copyright © 2014-2016 Tox project. */ /* * Tox DHT bootstrap daemon. * Main file. */ #ifndef _XOPEN_SOURCE #define _XOPEN_SOURCE 600 #endif // system provided #include #include #include // system header, rather than C, because we need it for POSIX sigaction(2) #include // C #include #include #include #include #include // toxcore #include "../../../toxcore/tox.h" #include "../../../toxcore/LAN_discovery.h" #include "../../../toxcore/TCP_server.h" #include "../../../toxcore/logger.h" #include "../../../toxcore/mono_time.h" #include "../../../toxcore/onion_announce.h" #include "../../../toxcore/util.h" // misc #include "../../bootstrap_node_packets.h" #include "command_line_arguments.h" #include "config.h" #include "global.h" #include "log.h" #define SLEEP_MILLISECONDS(MS) usleep(1000*MS) // Uses the already existing key or creates one if it didn't exist // // returns 1 on success // 0 on failure - no keys were read or stored static int manage_keys(DHT *dht, char *keys_file_path) { enum { KEYS_SIZE = CRYPTO_PUBLIC_KEY_SIZE + CRYPTO_SECRET_KEY_SIZE }; uint8_t keys[KEYS_SIZE]; FILE *keys_file; // Check if file exits, proceed to open and load keys keys_file = fopen(keys_file_path, "r"); if (keys_file != nullptr) { const size_t read_size = fread(keys, sizeof(uint8_t), KEYS_SIZE, keys_file); if (read_size != KEYS_SIZE) { fclose(keys_file); return 0; } dht_set_self_public_key(dht, keys); dht_set_self_secret_key(dht, keys + CRYPTO_PUBLIC_KEY_SIZE); } else { // Otherwise save new keys memcpy(keys, dht_get_self_public_key(dht), CRYPTO_PUBLIC_KEY_SIZE); memcpy(keys + CRYPTO_PUBLIC_KEY_SIZE, dht_get_self_secret_key(dht), CRYPTO_SECRET_KEY_SIZE); keys_file = fopen(keys_file_path, "w"); if (!keys_file) { return 0; } const size_t write_size = fwrite(keys, sizeof(uint8_t), KEYS_SIZE, keys_file); if (write_size != KEYS_SIZE) { fclose(keys_file); return 0; } } fclose(keys_file); return 1; } // Prints public key static void print_public_key(const uint8_t *public_key) { char buffer[2 * CRYPTO_PUBLIC_KEY_SIZE + 1]; int index = 0; size_t i; for (i = 0; i < CRYPTO_PUBLIC_KEY_SIZE; i++) { index += sprintf(buffer + index, "%02X", public_key[i]); } log_write(LOG_LEVEL_INFO, "Public Key: %s\n", buffer); } // Demonizes the process, appending PID to the PID file and closing file descriptors based on log backend // Terminates the application if the daemonization fails. static void daemonize(LOG_BACKEND log_backend, char *pid_file_path) { // Check if the PID file exists FILE *pid_file; if ((pid_file = fopen(pid_file_path, "r"))) { log_write(LOG_LEVEL_WARNING, "Another instance of the daemon is already running, PID file %s exists.\n", pid_file_path); fclose(pid_file); } // Open the PID file for writing pid_file = fopen(pid_file_path, "a+"); if (pid_file == nullptr) { log_write(LOG_LEVEL_ERROR, "Couldn't open the PID file for writing: %s. Exiting.\n", pid_file_path); exit(1); } // Fork off from the parent process const pid_t pid = fork(); if (pid > 0) { fprintf(pid_file, "%d", pid); fclose(pid_file); log_write(LOG_LEVEL_INFO, "Forked successfully: PID: %d.\n", pid); exit(0); } else { fclose(pid_file); } if (pid < 0) { log_write(LOG_LEVEL_ERROR, "Forking failed. Exiting.\n"); exit(1); } // Create a new SID for the child process if (setsid() < 0) { log_write(LOG_LEVEL_ERROR, "SID creation failure. Exiting.\n"); exit(1); } // Change the current working directory if ((chdir("/")) < 0) { log_write(LOG_LEVEL_ERROR, "Couldn't change working directory to '/'. Exiting.\n"); exit(1); } // Go quiet if (log_backend != LOG_BACKEND_STDOUT) { close(STDOUT_FILENO); close(STDIN_FILENO); close(STDERR_FILENO); } } // Logs toxcore logger message using our logger facility static void toxcore_logger_callback(void *context, Logger_Level level, const char *file, int line, const char *func, const char *message, void *userdata) { LOG_LEVEL log_level; switch (level) { case LOGGER_LEVEL_TRACE: log_level = LOG_LEVEL_INFO; break; case LOGGER_LEVEL_DEBUG: log_level = LOG_LEVEL_INFO; break; case LOGGER_LEVEL_INFO: log_level = LOG_LEVEL_INFO; break; case LOGGER_LEVEL_WARNING: log_level = LOG_LEVEL_WARNING; break; case LOGGER_LEVEL_ERROR: log_level = LOG_LEVEL_ERROR; break; default: log_level = LOG_LEVEL_INFO; break; } log_write(log_level, "%s:%d(%s) %s\n", file, line, func, message); } static volatile sig_atomic_t caught_signal = 0; static void handle_signal(int signum) { caught_signal = signum; } int main(int argc, char *argv[]) { umask(077); char *cfg_file_path; LOG_BACKEND log_backend; bool run_in_foreground; // choose backend for printing command line argument parsing output based on whether the daemon is being run from a terminal log_backend = isatty(STDOUT_FILENO) ? LOG_BACKEND_STDOUT : LOG_BACKEND_SYSLOG; log_open(log_backend); handle_command_line_arguments(argc, argv, &cfg_file_path, &log_backend, &run_in_foreground); log_close(); log_open(log_backend); log_write(LOG_LEVEL_INFO, "Running \"%s\" version %lu.\n", DAEMON_NAME, DAEMON_VERSION_NUMBER); char *pid_file_path = nullptr; char *keys_file_path = nullptr; int port; int enable_ipv6; int enable_ipv4_fallback; int enable_lan_discovery; int enable_tcp_relay; uint16_t *tcp_relay_ports = nullptr; int tcp_relay_port_count; int enable_motd; char *motd = nullptr; if (get_general_config(cfg_file_path, &pid_file_path, &keys_file_path, &port, &enable_ipv6, &enable_ipv4_fallback, &enable_lan_discovery, &enable_tcp_relay, &tcp_relay_ports, &tcp_relay_port_count, &enable_motd, &motd)) { log_write(LOG_LEVEL_INFO, "General config read successfully\n"); } else { log_write(LOG_LEVEL_ERROR, "Couldn't read config file: %s. Exiting.\n", cfg_file_path); return 1; } if (port < MIN_ALLOWED_PORT || port > MAX_ALLOWED_PORT) { log_write(LOG_LEVEL_ERROR, "Invalid port: %d, should be in [%d, %d]. Exiting.\n", port, MIN_ALLOWED_PORT, MAX_ALLOWED_PORT); free(motd); free(tcp_relay_ports); free(keys_file_path); free(pid_file_path); return 1; } if (!run_in_foreground) { daemonize(log_backend, pid_file_path); } free(pid_file_path); IP ip; ip_init(&ip, enable_ipv6); Logger *logger = logger_new(); if (MIN_LOGGER_LEVEL == LOGGER_LEVEL_TRACE || MIN_LOGGER_LEVEL == LOGGER_LEVEL_DEBUG) { logger_callback_log(logger, toxcore_logger_callback, nullptr, nullptr); } Networking_Core *net = new_networking(logger, ip, port); if (net == nullptr) { if (enable_ipv6 && enable_ipv4_fallback) { log_write(LOG_LEVEL_WARNING, "Couldn't initialize IPv6 networking. Falling back to using IPv4.\n"); enable_ipv6 = 0; ip_init(&ip, enable_ipv6); net = new_networking(logger, ip, port); if (net == nullptr) { log_write(LOG_LEVEL_ERROR, "Couldn't fallback to IPv4. Exiting.\n"); logger_kill(logger); free(motd); free(tcp_relay_ports); free(keys_file_path); return 1; } } else { log_write(LOG_LEVEL_ERROR, "Couldn't initialize networking. Exiting.\n"); logger_kill(logger); free(motd); free(tcp_relay_ports); free(keys_file_path); return 1; } } Mono_Time *const mono_time = mono_time_new(); if (mono_time == nullptr) { log_write(LOG_LEVEL_ERROR, "Couldn't initialize monotonic timer. Exiting.\n"); kill_networking(net); logger_kill(logger); free(motd); free(tcp_relay_ports); free(keys_file_path); return 1; } mono_time_update(mono_time); DHT *const dht = new_dht(logger, mono_time, net, true); if (dht == nullptr) { log_write(LOG_LEVEL_ERROR, "Couldn't initialize Tox DHT instance. Exiting.\n"); mono_time_free(mono_time); kill_networking(net); logger_kill(logger); free(motd); free(tcp_relay_ports); free(keys_file_path); return 1; } Onion *onion = new_onion(mono_time, dht); if (!onion) { log_write(LOG_LEVEL_ERROR, "Couldn't initialize Tox Onion. Exiting.\n"); kill_dht(dht); mono_time_free(mono_time); kill_networking(net); logger_kill(logger); free(motd); free(tcp_relay_ports); free(keys_file_path); return 1; } Onion_Announce *onion_a = new_onion_announce(mono_time, dht); if (!onion_a) { log_write(LOG_LEVEL_ERROR, "Couldn't initialize Tox Onion Announce. Exiting.\n"); kill_onion(onion); kill_dht(dht); mono_time_free(mono_time); kill_networking(net); logger_kill(logger); free(motd); free(tcp_relay_ports); free(keys_file_path); return 1; } if (enable_motd) { if (bootstrap_set_callbacks(dht_get_net(dht), DAEMON_VERSION_NUMBER, (uint8_t *)motd, strlen(motd) + 1) == 0) { log_write(LOG_LEVEL_INFO, "Set MOTD successfully.\n"); free(motd); } else { log_write(LOG_LEVEL_ERROR, "Couldn't set MOTD: %s. Exiting.\n", motd); kill_onion_announce(onion_a); kill_onion(onion); kill_dht(dht); mono_time_free(mono_time); kill_networking(net); logger_kill(logger); free(motd); free(tcp_relay_ports); free(keys_file_path); return 1; } } if (manage_keys(dht, keys_file_path)) { log_write(LOG_LEVEL_INFO, "Keys are managed successfully.\n"); free(keys_file_path); } else { log_write(LOG_LEVEL_ERROR, "Couldn't read/write: %s. Exiting.\n", keys_file_path); kill_onion_announce(onion_a); kill_onion(onion); kill_dht(dht); mono_time_free(mono_time); kill_networking(net); logger_kill(logger); free(tcp_relay_ports); free(keys_file_path); return 1; } TCP_Server *tcp_server = nullptr; if (enable_tcp_relay) { if (tcp_relay_port_count == 0) { log_write(LOG_LEVEL_ERROR, "No TCP relay ports read. Exiting.\n"); kill_onion_announce(onion_a); kill_onion(onion); kill_dht(dht); mono_time_free(mono_time); kill_networking(net); logger_kill(logger); free(tcp_relay_ports); return 1; } tcp_server = new_TCP_server(enable_ipv6, tcp_relay_port_count, tcp_relay_ports, dht_get_self_secret_key(dht), onion); free(tcp_relay_ports); if (tcp_server != nullptr) { log_write(LOG_LEVEL_INFO, "Initialized Tox TCP server successfully.\n"); struct rlimit limit; const rlim_t rlim_suggested = 32768; const rlim_t rlim_min = 4096; assert(rlim_suggested >= rlim_min); if (!getrlimit(RLIMIT_NOFILE, &limit)) { if (limit.rlim_cur < limit.rlim_max) { // Some systems have a hard limit of over 1000000 open file descriptors, so let's cap it at something reasonable // so that we don't set it to an unreasonably high number. limit.rlim_cur = limit.rlim_max > rlim_suggested ? rlim_suggested : limit.rlim_max; setrlimit(RLIMIT_NOFILE, &limit); } } if (!getrlimit(RLIMIT_NOFILE, &limit) && limit.rlim_cur < rlim_min) { log_write(LOG_LEVEL_WARNING, "Current limit on the number of files this process can open (%ju) is rather low for the proper functioning of the TCP server. " "Consider raising the limit to at least %ju or the recommended %ju. " "Continuing using the current limit (%ju).\n", (uintmax_t)limit.rlim_cur, (uintmax_t)rlim_min, (uintmax_t)rlim_suggested, (uintmax_t)limit.rlim_cur); } } else { log_write(LOG_LEVEL_ERROR, "Couldn't initialize Tox TCP server. Exiting.\n"); kill_onion_announce(onion_a); kill_onion(onion); kill_dht(dht); mono_time_free(mono_time); kill_networking(net); logger_kill(logger); return 1; } } if (bootstrap_from_config(cfg_file_path, dht, enable_ipv6)) { log_write(LOG_LEVEL_INFO, "List of bootstrap nodes read successfully.\n"); } else { log_write(LOG_LEVEL_ERROR, "Couldn't read list of bootstrap nodes in %s. Exiting.\n", cfg_file_path); kill_TCP_server(tcp_server); kill_onion_announce(onion_a); kill_onion(onion); kill_dht(dht); mono_time_free(mono_time); kill_networking(net); logger_kill(logger); return 1; } print_public_key(dht_get_self_public_key(dht)); uint64_t last_LANdiscovery = 0; const uint16_t net_htons_port = net_htons(port); int waiting_for_dht_connection = 1; if (enable_lan_discovery) { lan_discovery_init(dht); log_write(LOG_LEVEL_INFO, "Initialized LAN discovery successfully.\n"); } struct sigaction sa; sa.sa_handler = handle_signal; // Try to restart interrupted system calls if they are restartable sa.sa_flags = SA_RESTART; // Prevent the signal handler from being called again before it returns sigfillset(&sa.sa_mask); if (sigaction(SIGINT, &sa, nullptr)) { log_write(LOG_LEVEL_WARNING, "Couldn't set signal handler for SIGINT. Continuing without the signal handler set.\n"); } if (sigaction(SIGTERM, &sa, nullptr)) { log_write(LOG_LEVEL_WARNING, "Couldn't set signal handler for SIGTERM. Continuing without the signal handler set.\n"); } while (!caught_signal) { mono_time_update(mono_time); do_dht(dht); if (enable_lan_discovery && mono_time_is_timeout(mono_time, last_LANdiscovery, LAN_DISCOVERY_INTERVAL)) { lan_discovery_send(net_htons_port, dht); last_LANdiscovery = mono_time_get(mono_time); } if (enable_tcp_relay) { do_TCP_server(tcp_server, mono_time); } networking_poll(dht_get_net(dht), nullptr); if (waiting_for_dht_connection && dht_isconnected(dht)) { log_write(LOG_LEVEL_INFO, "Connected to another bootstrap node successfully.\n"); waiting_for_dht_connection = 0; } SLEEP_MILLISECONDS(30); } switch (caught_signal) { case SIGINT: log_write(LOG_LEVEL_INFO, "Received SIGINT (%d) signal. Exiting.\n", SIGINT); break; case SIGTERM: log_write(LOG_LEVEL_INFO, "Received SIGTERM (%d) signal. Exiting.\n", SIGTERM); break; default: log_write(LOG_LEVEL_INFO, "Received (%d) signal. Exiting.\n", caught_signal); } if (enable_lan_discovery) { lan_discovery_kill(dht); } kill_TCP_server(tcp_server); kill_onion_announce(onion_a); kill_onion(onion); kill_dht(dht); mono_time_free(mono_time); kill_networking(net); logger_kill(logger); return 0; }