/* GKrellM | Copyright (C) 1999-2010 Bill Wilson | | Author: Bill Wilson billw@gkrellm.net | Latest versions might be found at: http://gkrellm.net | | | GKrellM 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. | | GKrellM 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 http://www.gnu.org/licenses/ | | | Additional permission under GNU GPL version 3 section 7 | | If you modify this program, or any covered work, by linking or | combining it with the OpenSSL project's OpenSSL library (or a | modified version of that library), containing parts covered by | the terms of the OpenSSL or SSLeay licenses, you are granted | additional permission to convey the resulting work. | Corresponding Source for a non-source form of such a combination | shall include the source code for the parts of OpenSSL used as well | as that of the covered work. */ #include "gkrellmd.h" #include "gkrellmd-private.h" #include "log-private.h" #if !defined(WIN32) #include #endif // !WIN32 // win32 defines addrinfo but only supports getaddrinfo call on winxp or newer #if !defined(HAVE_GETADDRINFO) && !defined(WIN32) struct addrinfo { int ai_flags; /* AI_PASSIVE, AI_CANONNAME, AI_NUMERICHOST */ int ai_family; /* PF_xxx */ int ai_socktype; /* SOCK_xxx */ int ai_protocol; /* 0 or IPPROTO_xxx for IPv4 and IPv6 */ size_t ai_addrlen; /* length of ai_addr */ char *ai_canonname; /* canonical name for hostname */ struct sockaddr *ai_addr; /* binary address */ struct addrinfo *ai_next; /* next structure in linked list */ }; #endif // !HAVE_GETADDRINFO #if !defined(IPV6_V6ONLY) && defined(IPV6_BINDV6ONLY) #define IPV6_V6ONLY IPV6_BINDV6ONLY #endif struct GkrellmdConfig _GK; GkrellmdTicks GK; GList *gkrellmd_client_list, *gkrellmd_plugin_config_list; static GList *allow_host_list; #if !defined(WIN32) static gboolean detach_flag; struct { uid_t uid; uid_t gid; } drop_privs = { 0, 0 }; #endif /* !defined(WIN32) */ #if defined(WIN32) /* Flag that determines if gkrellmd was started as a console app (FALSE) or as a service (TRUE) */ static gboolean service_is_one = FALSE; // Flag that is TRUE while gkrellmd should stay in its main loop static gboolean service_running = FALSE; // Unique name for the installed windows service (do not translate!) static wchar_t* service_name = L"gkrellmd"; // User visible name for the installed windows service static wchar_t* service_display_name = L"GKrellM Daemon"; /* Current service status if running as a service, may be stopped or running (pausing is not supported) */ static SERVICE_STATUS service_status; /* Handle that allows changing the service status. Main use is to stop the running service. */ static SERVICE_STATUS_HANDLE service_status_handle = 0; /* Handle to our event log source. The Windows Event Log is used as a replacement for syslog-logging. */ static HANDLE h_event_log = NULL; #endif /* defined(WIN32) */ static gboolean gkrellmd_syslog_init() { #if defined(WIN32) h_event_log = RegisterEventSourceW(NULL, service_name); if (h_event_log == NULL) { g_warning("Cannot register event source for logging into Windows Event Log.\n"); return FALSE; } #else // Unix needs no logging initialization #endif return TRUE; } static gboolean gkrellmd_syslog_cleanup() { #if defined(WIN32) if (h_event_log) DeregisterEventSource(h_event_log); h_event_log = NULL; #else // Unix needs no further logging cleanup #endif return TRUE; } static void gkrellmd_syslog_log(GLogLevelFlags log_level, const gchar *message) { #if defined(WIN32) WORD event_type; const char *p_buf[1]; // Abort if event source is missing if (h_event_log == NULL) return; event_type = EVENTLOG_INFORMATION_TYPE; if (log_level & G_LOG_LEVEL_WARNING) event_type = EVENTLOG_WARNING_TYPE; if (log_level & G_LOG_LEVEL_CRITICAL || log_level & G_LOG_LEVEL_ERROR) event_type = EVENTLOG_ERROR_TYPE; p_buf[0] = message; ReportEventA( h_event_log, // Event source handle (HANDLE) event_type, // Event type (WORD) 0, // Event category (WORD) 0, // Event identifier (DWORD) NULL, // user security identifier (PSID) 1, // Number of substitution strings (WORD) 0, // Data Size (DWORD) p_buf, // Pointer to strings NULL // Pointer to Data ); #else int facility_priority; // default to info and override with other states if they are more important facility_priority = LOG_MAKEPRI(LOG_DAEMON, LOG_INFO); if (log_level & G_LOG_LEVEL_DEBUG) facility_priority = LOG_MAKEPRI(LOG_DAEMON, LOG_DEBUG); if (log_level & G_LOG_LEVEL_WARNING) facility_priority = LOG_MAKEPRI(LOG_DAEMON, LOG_WARNING); if (log_level & G_LOG_LEVEL_ERROR) facility_priority = LOG_MAKEPRI(LOG_DAEMON, LOG_ERR); if (log_level & G_LOG_LEVEL_CRITICAL) facility_priority = LOG_MAKEPRI(LOG_DAEMON, LOG_CRIT); syslog(facility_priority, "%s", message); #endif // defined(WIN32) } // gkrellmd_syslog_log() static void make_pidfile(void) { #if !defined(WIN32) FILE *f; if (!_GK.pidfile) return; f = fopen(_GK.pidfile, "w"); if (f) { fprintf(f, "%d\n", getpid()); fclose(f); } else g_warning("Can't create pidfile %s\n", _GK.pidfile); #endif } static void remove_pidfile(void) { #if !defined(WIN32) if (_GK.pidfile) unlink(_GK.pidfile); #endif } static void gkrellmd_cleanup() { gkrellm_sys_main_cleanup(); gkrellm_log_cleanup(); remove_pidfile(); } static void cb_sigterm(gint sig) { g_message("GKrellM Daemon %d.%d.%d%s: Exiting normally\n", GKRELLMD_VERSION_MAJOR, GKRELLMD_VERSION_MINOR, GKRELLMD_VERSION_REV, GKRELLMD_EXTRAVERSION); gkrellmd_cleanup(); exit(0); } gint gkrellmd_send_to_client(GkrellmdClient *client, gchar *buf) { gint n; if (!client->alive) return 0; #if defined(MSG_NOSIGNAL) n = send(client->fd, buf, strlen(buf), MSG_NOSIGNAL); #else n = send(client->fd, buf, strlen(buf), 0); #endif if (n < 0 && errno == EPIPE) { if (_GK.verbose) g_print("Write on closed pipe to host %s\n", client->hostname); client->alive = FALSE; } return n; } #if 0 static gint getline(gint fd, gchar *buf, gint len) { fd_set read_fds; struct timeval tv; gchar *s; gint result, n; FD_ZERO(&read_fds); FD_SET(fd, &read_fds); tv.tv_usec = 0; tv.tv_sec = 15; s = buf; *s = '\0'; for (n = 0; n < len - 1; ++n) { result = select(fd + 1, &read_fds, NULL, NULL, &tv); if (result <= 0 || read(fd, s, 1) != 1) break; if (*s == '\n') { *s = '\0'; break; } *++s = '\0'; } return n; } #endif #ifdef HAVE_GETADDRINFO static gboolean is_valid_reverse(char *addr, char *host, sa_family_t family) { struct addrinfo hints, *res, *r; int error, good; char addrbuf[NI_MAXHOST]; /* Reject numeric addresses */ memset(&hints, 0, sizeof(hints)); hints.ai_family = family; hints.ai_socktype = SOCK_STREAM; hints.ai_flags = AI_PASSIVE | AI_NUMERICHOST; if (getaddrinfo(host, NULL, &hints, &res) == 0) { freeaddrinfo(res); return 0; } /* Check for spoof */ memset(&hints, 0, sizeof(hints)); hints.ai_family = family; hints.ai_socktype = SOCK_STREAM; hints.ai_flags = AI_PASSIVE; if (getaddrinfo(host, NULL, &hints, &res) != 0) return 0; good = 0; for (r = res; good == 0 && r; r = r->ai_next) { error = getnameinfo(r->ai_addr, r->ai_addrlen, addrbuf, sizeof(addrbuf), NULL, 0, NI_NUMERICHOST | NI_WITHSCOPEID); if (error == 0 && strcmp(addr, addrbuf) == 0) { good = 1; break; } } freeaddrinfo(res); return good; } #endif /* Check for CIDR match. */ static gboolean cidr_match(struct sockaddr *sa, socklen_t salen, char *allowed) { #ifdef HAVE_GETADDRINFO struct addrinfo hints, *res; union { struct sockaddr_storage ss; struct sockaddr_in sin; struct sockaddr_in6 sin6; struct sockaddr sa; } ss; char *buf; char *p, *ep; guchar *addr, *pat; uint32_t mask; int plen; #if defined(INET6) int i; #endif gboolean result; buf = g_strdup(allowed); plen = -1; if ((p = strchr(buf, '/')) != NULL) { plen = strtoul(p + 1, &ep, 10); if (errno != 0 || ep == NULL || *ep != '\0' || plen < 0) { g_free(buf); return FALSE; } *p = '\0'; allowed = buf; } memset(&hints, 0, sizeof(hints)); hints.ai_family = AF_UNSPEC; hints.ai_socktype = SOCK_STREAM; hints.ai_flags = AI_PASSIVE | AI_NUMERICHOST; result = getaddrinfo(allowed, NULL, &hints, &res); g_free(buf); if (result != 0) return FALSE; memcpy(&ss, res->ai_addr, res->ai_addrlen); freeaddrinfo(res); if (sa->sa_family != ss.sa.sa_family) return FALSE; switch (sa->sa_family) { #if defined(INET6) case AF_INET6: if (plen < 0) plen = 128; if (plen > 128) return FALSE; if (ss.sin6.sin6_scope_id != 0 && ss.sin6.sin6_scope_id != ((struct sockaddr_in6 *)sa)->sin6_scope_id) return FALSE; addr = (guchar *)&((struct sockaddr_in6 *)sa)->sin6_addr; pat = (guchar *)&ss.sin6.sin6_addr; i = 0; while (plen > 0) { if (plen < 32) { mask = htonl(~(0xffffffff >> plen)); if ((*(uint32_t *)&addr[i] & mask) != (*(uint32_t *)&pat[i] & mask)) return FALSE; break; } if (*(uint32_t *)&addr[i] != *(uint32_t *)&pat[i]) return FALSE; i += 4; plen -= 32; } break; #endif case AF_INET: if (plen < 0) plen = 32; if (plen > 32) return FALSE; addr = (guchar *)&((struct sockaddr_in *)sa)->sin_addr; pat = (guchar *)&ss.sin.sin_addr; mask = htonl(~(0xffffffff >> plen)); if ((*(uint32_t *)addr & mask) != (*(uint32_t *)pat & mask)) return FALSE; break; default: return FALSE; } return TRUE; #else return FALSE; #endif } static gboolean allow_host(GkrellmdClient *client, struct sockaddr *sa, socklen_t salen) { GList *list; #ifdef HAVE_GETADDRINFO int error; char hostbuf[NI_MAXHOST], addrbuf[NI_MAXHOST]; #else struct hostent *hostent; #endif gchar buf[128]; gchar *hostname = NULL, *addr = NULL; gchar *s, *allowed; #ifdef HAVE_GETADDRINFO error = getnameinfo(sa, salen, addrbuf, sizeof(addrbuf), NULL, 0, NI_NUMERICHOST | NI_WITHSCOPEID); if (error == 0) { addr = addrbuf; error = getnameinfo(sa, salen, hostbuf, sizeof(hostbuf), NULL, 0, NI_NAMEREQD); if (error == 0 && is_valid_reverse(addrbuf, hostbuf, sa->sa_family)) hostname = hostbuf; } #else hostent = gethostbyaddr((gchar *)&((struct sockaddr_in *)sa)->sin_addr, sizeof(struct in_addr), AF_INET); if (hostent) hostname = hostent->h_name; addr = inet_ntoa(((struct sockaddr_in *)sa)->sin_addr); #endif client->hostname = g_strdup(hostname ? hostname : addr); if (!allow_host_list) return TRUE; for (list = allow_host_list; list; list = list->next) { allowed = (gchar *) list->data; if ( (hostname && !strcmp(hostname, allowed)) || (addr && !strcmp(addr, allowed)) || !strcmp("ALL", allowed) ) return TRUE; if (addr && cidr_match(sa, salen, allowed)) return TRUE; /* Check for simple IPv4 subnet match. Worry later about ranges and | other hosts_access type patterns. */ if ( addr && (s = strrchr(allowed, (int) '.')) != NULL && *(s + 1) == '*' && *(s + 2) == '\0' && !strncmp(addr, allowed, (gint) (s - allowed + 1)) ) return TRUE; } snprintf(buf, sizeof(buf), _("Connection not allowed from %s\n"), hostname ? hostname : addr); g_warning("%s", buf); gkrellmd_send_to_client(client, "\n"); gkrellmd_send_to_client(client, buf); return FALSE; } /* client sends line: gkrellm x.y.z */ static GkrellmdClient * accept_client(gint fd, struct sockaddr *sa, socklen_t salen) { GkrellmdClient *client; gchar buf[64], name[32]; gboolean client_limit; gint err; client = g_new0(GkrellmdClient, 1); client->fd = fd; client->alive = TRUE; client_limit = (g_list_length(gkrellmd_client_list) >= _GK.max_clients); if (!allow_host(client, sa, salen) || client_limit) { if (client_limit) { g_message(_("Too many clients, rejecting %s\n"), client->hostname); gkrellmd_send_to_client(client, "\nClient limit exceeded.\n"); } g_free(client->hostname); g_free(client); return NULL; } err = recv(fd, buf, sizeof(buf), 0); if (err > 0) buf[err] = '\0'; else buf[0] = '\0'; //getline(fd, buf, sizeof(buf)); if (_GK.verbose) g_print(_("connect string from client: %s\n"), buf); if ( sscanf(buf, "%31s %d.%d.%d", name, &client->major_version, &client->minor_version, &client->rev_version) == 4 && !strcmp(name, "gkrellm") ) { gkrellmd_client_list = g_list_append(gkrellmd_client_list, client); return client; } g_warning(_("Bad connect line from %s: %s\n"), client->hostname, buf); gkrellmd_send_to_client(client, "\nBad connect string!"); g_free(client->hostname); g_free(client); return NULL; } static void remove_client(gint fd) { GList *list; GkrellmdClient *client; for (list = gkrellmd_client_list; list; list = list->next) { client = (GkrellmdClient *) list->data; if (client->fd == fd) { g_message(_("Removing client %s\n"), client->hostname); #if defined(WIN32) closesocket(fd); #else close(fd); #endif g_free(client->hostname); g_free(client); gkrellmd_client_list = g_list_remove(gkrellmd_client_list, client); break; } } } static gint parse_config(gchar *config, gchar *arg) { if (!strcmp(config, "clear-hosts") || !strcmp(config, "c")) { gkrellm_free_glist_and_data(&allow_host_list); return 0; } if (!strcmp(config, "syslog")) { gkrellm_log_register(gkrellmd_syslog_log, gkrellmd_syslog_init, gkrellmd_syslog_cleanup); return 0; } #if !defined(WIN32) if (!strcmp(config, "detach") || !strcmp(config, "d")) { detach_flag = TRUE; return 0; } #endif // All following options take one argument that should be passed in arg if (!arg || !*arg) return -1; if (!strcmp(config, "update-hz") || !strcmp(config, "u")) _GK.update_HZ = atoi(arg); else if (!strcmp(config, "port") || !strcmp(config, "P")) _GK.server_port = atoi(arg); else if (!strcmp(config, "address") || !strcmp(config, "A")) _GK.server_address = g_strdup(arg); else if (!strcmp(config, "max-clients") || !strcmp(config, "m")) _GK.max_clients = atoi(arg); else if (!strcmp(config, "allow-host") || !strcmp(config, "a")) allow_host_list = g_list_append(allow_host_list, g_strdup(arg)); else if (!strcmp(config, "plugin-enable") || !strcmp(config, "pe")) gkrellmd_plugin_enable_list = g_list_append(gkrellmd_plugin_enable_list, g_strdup(arg)); else if (!strcmp(config, "plugin") || !strcmp(config, "p")) _GK.command_line_plugin = g_strdup(arg); else if (!strcmp(config, "io-timeout")) _GK.io_timeout = atoi(arg); else if (!strcmp(config, "reconnect-timeout")) _GK.reconnect_timeout = atoi(arg); else if (!strcmp(config, "fs-interval")) _GK.fs_interval = atoi(arg); else if (!strcmp(config, "nfs-interval")) _GK.nfs_interval = atoi(arg); else if (!strcmp(config, "inet-interval")) _GK.inet_interval = atoi(arg); else if (!strcmp(config, "mbmon-port")) _GK.mbmon_port = atoi(arg); else if (!strcmp(config, "net-timer")) _GK.net_timer = g_strdup(arg); else if (!strcmp(config, "debug-level") || !strcmp(config, "debug")) { _GK.debug_level = (gint) strtoul(arg, NULL, 0); if (_GK.debug_level > 0) g_print("Set debug-level to 0x%x\n", _GK.debug_level); } else if (!strcmp(config, "logfile")) gkrellm_log_set_filename(arg); #if !defined(WIN32) else if (!strcmp(config, "pidfile")) _GK.pidfile = g_strdup(arg); else if (!strcmp(config, "mailbox")) gkrellmd_add_mailbox(arg); else if (!strcmp(config, "user") || !strcmp(config, "U")) { struct passwd *tmp; if ((tmp = getpwnam(arg)) != (struct passwd*) 0) drop_privs.uid = tmp->pw_uid; else return -1; } else if (!strcmp(config, "group") || !strcmp(config, "G")) { struct group *tmp; if ((tmp = getgrnam(arg)) != (struct group*) 0) drop_privs.gid = tmp->gr_gid; else return -1; } #endif else return -1; return 1; } static void load_config(gchar *path) { FILE *f; PluginConfigRec *cfg; gchar buf[128+32+2], config[32], arg[128]; gchar *s, *plugin_config_block = NULL; //g_print("Trying to load config from file '%s'\n", path); f = g_fopen(path, "r"); if (!f) return; while (fgets(buf, sizeof(buf), f)) { if (!buf[0] || buf[0] == '#') continue; if (buf[0] == '[' || buf[0] == '<') { if (buf[1] == '/') { g_free(plugin_config_block); plugin_config_block = NULL; } else { if ( (s = strchr(buf, ']')) != NULL || (s = strchr(buf, '>')) != NULL ) *s = '\0'; plugin_config_block = g_strdup(&buf[1]); } continue; } if (plugin_config_block) { cfg = g_new0(PluginConfigRec, 1); cfg->name = g_strdup(plugin_config_block); if ((s = strchr(buf, '\n')) != NULL) *s = '\0'; cfg->line = g_strdup(buf); gkrellmd_plugin_config_list = g_list_append(gkrellmd_plugin_config_list, cfg); } else /* main gkrellmd config line */ { arg[0] = '\0'; sscanf(buf, "%31s %127s", config, arg); parse_config(config, arg); } } fclose(f); } const gchar * gkrellmd_config_getline(GkrellmdMonitor *mon) { GList *list; PluginConfigRec *cfg; if (!mon->privat) { mon->privat = g_new0(GkrellmdMonitorPrivate, 1); mon->privat->config_list = gkrellmd_plugin_config_list; } for (list = mon->privat->config_list; list; list = list->next) { cfg = (PluginConfigRec *) list->data; if (!strcmp(cfg->name, mon->name)) { mon->privat->config_list = list->next; return cfg->line; } } return NULL; } static void read_config(void) { gchar *path; #if defined(WIN32) gchar *install_path; #endif _GK.update_HZ = 3; _GK.debug_level = 0; _GK.max_clients = 2; _GK.server_port = GKRELLMD_SERVER_PORT; _GK.fs_interval = 2; _GK.nfs_interval = 16; _GK.inet_interval = 1; #if defined(GKRELLMD_SYS_ETC) path = g_build_filename(GKRELLMD_SYS_ETC, GKRELLMD_CONFIG, NULL); load_config(path); g_free(path); #endif #if defined(GKRELLMD_LOCAL_ETC) path = g_build_filename(GKRELLMD_LOCAL_ETC, GKRELLMD_CONFIG, NULL); load_config(path); g_free(path); #endif // on windows also load config from INSTALLDIR/etc/gkrellmd.conf #if defined(WIN32) install_path = g_win32_get_package_installation_directory_of_module(NULL); if (install_path != NULL) { path = g_build_filename(install_path, "etc", GKRELLMD_CONFIG, NULL); load_config(path); g_free(path); g_free(install_path); } #endif _GK.homedir = (gchar *) g_get_home_dir(); if (_GK.homedir == NULL) _GK.homedir = "."; // FIXME: doesn't look right to me path = g_build_filename(_GK.homedir, GKRELLMD_USER_CONFIG, NULL); load_config(path); g_free(path); } static void usage(void) { #if defined(WIN32) g_print(_("usage: gkrellmd command [options]\n")); g_print(_("commands:\n")); g_print(_(" --console run gkrellmd on console (not as a service)\n")); g_print(_(" --install install gkrellmd service and exit\n")); g_print(_(" --uninstall uninstall gkrellmd service and exit\n")); g_print(_(" -h, --help display this help and exit\n")); g_print(_(" -v, --version output version information and exit\n")); g_print(_("options (only for command '--console'):\n")); g_print(_(" -u, --update-hz F Monitor update frequency\n")); g_print(_(" -m, --max-clients N Number of simultaneous clients\n")); g_print(_(" -A, --address A Address of network interface to listen on\n")); g_print(_(" -P, --port P Server port to listen on\n")); g_print(_(" -a, --allow-host host Allow connections from specified hosts\n")); g_print(_(" -c, --clear-hosts Clears the current list of allowed hosts\n")); g_print(_(" --io-timeout N Close connection after N seconds of no I/O\n")); g_print(_(" --reconnect-timeout N Try to connect every N seconds after\n" " a disconnect\n")); g_print(_(" -p, --plugin name Enable a command line plugin\n")); g_print(_(" -pe, --plugin-enable name Enable an installed plugin\n")); g_print(_(" --plist List plugins and exit\n")); g_print(_(" --plog Print plugin install log\n")); g_print( " --logfile path Enable logging to a file\n"); g_print( " --syslog Enable logging to syslog\n"); g_print(_(" -V, --verbose increases the verbosity of gkrellmd\n")); g_print(_(" -debug, --debug-level n Turn debugging on for selective code sections.\n")); #else g_print(_("usage: gkrellmd [options]\n")); g_print(_("options:\n")); g_print(_(" -u, --update-hz F Monitor update frequency\n")); g_print(_(" -m, --max-clients N Number of simultaneous clients\n")); g_print(_(" -A, --address A Address of network interface to listen on\n")); g_print(_(" -P, --port P Server port to listen on\n")); g_print(_(" -a, --allow-host host Allow connections from specified hosts\n")); g_print(_(" -c, --clear-hosts Clears the current list of allowed hosts\n")); g_print(_(" --io-timeout N Close connection after N seconds of no I/O\n")); g_print(_(" --reconnect-timeout N Try to connect every N seconds after\n" " a disconnect\n")); g_print(_(" --mailbox path Send local mailbox counts to gkrellm clients.\n")); g_print(_(" -d, --detach Run in background and detach from terminal\n")); g_print(_(" -U, --user username Change to this username after startup\n")); g_print(_(" -G, --group groupname Change to this group after startup\n")); g_print(_(" -p, --plugin name Enable a command line plugin\n")); g_print(_(" -pe, --plugin-enable name Enable an installed plugin\n")); g_print(_(" --plist List plugins and exit\n")); g_print(_(" --plog Print plugin install log\n")); g_print( " --logfile path Enable logging to a file\n"); g_print( " --syslog Enable logging to the system syslog file\n"); g_print(_(" --pidfile path Create a PID file\n")); g_print(_(" -V, --verbose increases the verbosity of gkrellmd\n")); g_print(_(" -h, --help display this help and exit\n")); g_print(_(" -v, --version output version information and exit\n")); g_print(_(" -debug, --debug-level n Turn debugging on for selective code sections.\n")); #endif } static void get_args(gint argc, gchar **argv) { gchar *s; gint i, r; for (i = 1; i < argc; ++i) { s = argv[i]; if (*s == '-') { ++s; if (*s == '-') ++s; } if (!strcmp(s, "verbose") || !strcmp(s, "V")) _GK.verbose += 1; else if (!strcmp(s, "plist")) _GK.list_plugins = TRUE; else if (!strcmp(s, "plog")) _GK.log_plugins = TRUE; #if !defined(WIN32) else if (!strcmp(s, "without-libsensors")) _GK.without_libsensors = TRUE; #endif /* !WIN32 */ else if ( i < argc && ((r = parse_config(s, (i < argc - 1) ? argv[i+1] : NULL)) >= 0) ) { i += r; } else { g_print(_("Bad arg: %s\n"), argv[i]); usage(); exit(0); } } // for() } static int * socksetup(int af) { struct addrinfo hints, *res, *r; gint maxs, *s, *socks; #ifndef HAVE_GETADDRINFO struct sockaddr_in sin; #else gchar portnumber[6]; gint error; #endif memset(&hints, 0, sizeof(hints)); hints.ai_socktype = SOCK_STREAM; #ifdef HAVE_GETADDRINFO hints.ai_flags = AI_PASSIVE; hints.ai_family = af; snprintf(portnumber, sizeof(portnumber), "%d", _GK.server_port); if (!_GK.server_address || strlen(_GK.server_address) == 0) { error = getaddrinfo(NULL, portnumber, &hints, &res); } else { error = getaddrinfo(_GK.server_address, portnumber, &hints, &res); } if (error) { g_warning("gkrellmd %s\n", gai_strerror(error)); return NULL; } #else /* Set up the address structure for the listen socket and bind the | listen address to the socket. */ hints.ai_family = PF_INET; hints.ai_addrlen = sizeof(struct sockaddr_in); hints.ai_next = NULL; hints.ai_addr = (struct sockaddr *) &sin; sin.sin_family = PF_INET; if (!_GK.server_address || strlen(_GK.server_address) == 0) { sin.sin_addr.s_addr = INADDR_ANY; } else { sin.sin_addr.s_addr = inet_addr(_GK.server_address); } sin.sin_port = htons(_GK.server_port); res = &hints; #endif /* count max number of sockets we may open */ for (maxs = 0, r = res; r; r = r->ai_next, maxs++) ; socks = malloc((maxs + 1) * sizeof(int)); if (!socks) { g_warning("Could not allocate memory for sockets\n"); return NULL; } *socks = 0; /* num of sockets counter at start of array */ s = socks + 1; for (r = res; r; r = r->ai_next) { *s = socket(r->ai_family, r->ai_socktype, r->ai_protocol); if (*s < 0) continue; /* SO_REUSEADDR flag allows the server to restart immediately */ if (1) { #if defined(WIN32) const char on = 1; #else const int on = 1; #endif if (setsockopt(*s, SOL_SOCKET, SO_REUSEADDR, &on, sizeof(on)) < 0) { g_warning("gkrellmd: setsockopt (SO_REUSEADDR) failed\n"); #if defined(WIN32) closesocket(*s); #else close(*s); #endif continue; } } #ifdef IPV6_V6ONLY if (r->ai_family == AF_INET6) { const int on = 1; if (setsockopt(*s, IPPROTO_IPV6, IPV6_V6ONLY, &on, sizeof(on)) < 0) { g_warning("gkrellmd: setsockopt (IPV6_V6ONLY) failed\n"); #if defined(WIN32) closesocket(*s); #else close(*s); #endif continue; } } #endif if (bind(*s, r->ai_addr, r->ai_addrlen) < 0) { #if defined(WIN32) closesocket(*s); #else close(*s); #endif continue; } (*socks)++; s++; } #ifdef HAVE_GETADDRINFO if (res) freeaddrinfo(res); #endif if (*socks == 0) { g_warning("Could not bind to any socket\n"); free(socks); return NULL; } return socks; } #if !defined(WIN32) /* XXX: Recent glibc seems to have daemon(), too. */ #if defined(BSD4_4) #define HAVE_DAEMON #endif #if !defined(HAVE_DAEMON) && !defined(WIN32) && !defined(__solaris__) #include #endif #if !defined(_PATH_DEVNULL) #define _PATH_DEVNULL "/dev/null" #endif static gboolean detach_from_terminal(void) { #if !defined(HAVE_DAEMON) gint i, fd; #endif /* HAVE_DAEMON */ if (getppid() == 1) /* already a daemon */ return TRUE; #if defined(HAVE_DAEMON) if (daemon(0, 0)) { g_warning("Detach failed: %s\n", strerror(errno)); return FALSE; } #else i = fork(); if (i > 0) exit(0); if (i < 0 || setsid() == -1) /* new session process group */ { g_warning("Detach failed: %s\n", strerror(errno)); return FALSE; } if ((fd = open(_PATH_DEVNULL, O_RDWR, 0)) != -1) { dup2(fd, STDIN_FILENO); dup2(fd, STDOUT_FILENO); dup2(fd, STDERR_FILENO); if (fd > 2) close(fd); } if (chdir("/") != 0) { g_warning("Detach failed in chdir(\"/\"): %s\n", strerror(errno)); return FALSE; } #endif /* HAVE_DAEMON */ // signal(SIGCHLD, SIG_IGN); signal(SIGTSTP, SIG_IGN); signal(SIGTTOU, SIG_IGN); signal(SIGTTIN, SIG_IGN); signal(SIGHUP, SIG_IGN); #if !defined(MSG_NOSIGNAL) signal(SIGPIPE, SIG_IGN); #endif /* MSG_NOSIGNAL */ return TRUE; } #endif /* !defined(WIN32) */ static void drop_privileges(void) { #if !defined(WIN32) if (drop_privs.gid > (uid_t)0) { (void) setgroups((size_t)0, (gid_t*)0); (void) setgid(drop_privs.gid); } if (drop_privs.uid > (uid_t)0) (void) setuid(drop_privs.uid); #endif } static gint gkrellmd_run(gint argc, gchar **argv) { union { #ifdef HAVE_GETADDRINFO struct sockaddr_storage ss; #else struct sockaddr_in ss; #endif struct sockaddr_in sin; struct sockaddr sa; } client_addr; fd_set read_fds, test_fds; struct timeval tv; GkrellmdClient *client; size_t addr_len; gint fd, server_fd, client_fd, i; #if defined(WIN32) gulong nbytes; #else gint nbytes; #endif /* defined(WIN32) */ gint max_fd = -1; gint listen_fds = 0; gint interval, result; read_config(); get_args(argc, argv); // first message that might get logged g_message("Starting GKrellM Daemon %d.%d.%d%s\n", GKRELLMD_VERSION_MAJOR, GKRELLMD_VERSION_MINOR, GKRELLMD_VERSION_REV, GKRELLMD_EXTRAVERSION); if (_GK.verbose) g_print("update_HZ=%d\n", _GK.update_HZ); #if defined(WIN32) if (!service_is_one) { signal(SIGTERM, cb_sigterm); signal(SIGINT, cb_sigterm); } #else if ( detach_flag && !_GK.log_plugins && !_GK.list_plugins && _GK.debug_level == 0 ) { if (detach_from_terminal() == FALSE) return 1; } else { signal(SIGTERM, cb_sigterm); signal(SIGQUIT, cb_sigterm); signal(SIGTSTP, SIG_IGN); signal(SIGINT, cb_sigterm); } #endif /* defined(WIN32) */ make_pidfile(); gkrellm_sys_main_init(); drop_privileges(); _GK.start_time = time(0); if (_GK.update_HZ < 1 || _GK.update_HZ > 10) _GK.update_HZ = 3; if (_GK.fs_interval < 1 || _GK.fs_interval > 1000) _GK.fs_interval = 2; if (_GK.nfs_interval > 10000) _GK.nfs_interval = 16; if (_GK.inet_interval > 20) _GK.inet_interval = 20; gkrellmd_load_monitors(); _GK.server_fd = socksetup(PF_UNSPEC); if (_GK.server_fd == NULL) { g_warning("socket() failed: %s\n", strerror(errno)); gkrellmd_cleanup(); return 1; } /* Listen on the socket so a client gkrellm can connect. */ FD_ZERO(&read_fds); for (i = 1; i <= _GK.server_fd[0]; ++i) { if (listen(_GK.server_fd[i], 5) == -1) { #if defined(WIN32) closesocket(_GK.server_fd[i]); #else close(_GK.server_fd[i]); #endif continue; } ++listen_fds; FD_SET(_GK.server_fd[i], &read_fds); if (max_fd < _GK.server_fd[i]) max_fd = _GK.server_fd[i]; } if (listen_fds <= 0) { g_warning("listen() failed: %s\n", strerror(errno)); gkrellmd_cleanup(); return 1; } interval = 1000000 / _GK.update_HZ; gkrellm_debug(DEBUG_SERVER, "Entering main event loop\n"); // main event loop #if defined(WIN32) /* endless loop if: - we're a service and our service_running flag is TRUE - we're a console-app (--console argument passed at startup */ while(service_running == TRUE || service_is_one == FALSE) #else while(1) #endif { test_fds = read_fds; addr_len = sizeof(client_addr.ss); tv.tv_usec = interval; tv.tv_sec = 0; result = select(max_fd + 1, &test_fds, NULL, NULL, &tv); if (result == -1) { if (errno == EINTR) continue; g_warning("select() failed: %s\n", strerror(errno)); gkrellmd_cleanup(); return 1; } #if 0 /* BUG, result is 0 when test_fds has a set fd!! */ if (result == 0) { gkrellmd_update_monitors(); continue; } #endif for (fd = 0; fd <= max_fd; ++fd) { if (!FD_ISSET(fd, &test_fds)) continue; server_fd = -1; for (i = 1; i <= _GK.server_fd[0]; ++i) { if (fd == _GK.server_fd[i]) { server_fd = fd; break; } } if (server_fd >= 0) { gkrellm_debug(DEBUG_SERVER, "Calling accept() for new client connection\n"); client_fd = accept(server_fd, &client_addr.sa, (socklen_t *) (void *)&addr_len); if (client_fd == -1) { g_warning("accept() failed: %s\n", strerror(errno)); gkrellmd_cleanup(); return 1; } if (client_fd > max_fd) max_fd = client_fd; client = accept_client(client_fd, &client_addr.sa, addr_len); if (!client) { #if defined(WIN32) closesocket(client_fd); #else close(client_fd); #endif continue; } FD_SET(client_fd, &read_fds); gkrellmd_serve_setup(client); g_message(_("Accepted client %s:%u\n"), client->hostname, ntohs(client_addr.sin.sin_port)); } else { gkrellm_debug(DEBUG_SERVER, "Reading data from client connection\n"); #if defined(WIN32) ioctlsocket(fd, FIONREAD, &nbytes); #else ioctl(fd, FIONREAD, &nbytes); #endif if (nbytes == 0) { remove_client(fd); FD_CLR(fd, &read_fds); } else gkrellmd_client_read(fd, nbytes); } } gkrellmd_update_monitors(); } // while(1) return 0; } // gkrellmd_main() #if defined(WIN32) static void service_update_status(DWORD newState) { service_status.dwCurrentState = newState; SetServiceStatus(service_status_handle, &service_status); } void WINAPI service_control_handler(DWORD controlCode) { switch (controlCode) { case SERVICE_CONTROL_SHUTDOWN: case SERVICE_CONTROL_STOP: service_update_status(SERVICE_STOP_PENDING); service_running = FALSE; return; default: break; } } void WINAPI service_main(DWORD argc, WCHAR* argv[]) { gchar **argv_utf8; DWORD i; /* Init service status */ service_status.dwServiceType = SERVICE_WIN32; service_status.dwCurrentState = SERVICE_STOPPED; service_status.dwControlsAccepted = 0; service_status.dwWin32ExitCode = NO_ERROR; service_status.dwServiceSpecificExitCode = NO_ERROR; service_status.dwCheckPoint = 0; service_status.dwWaitHint = 0; service_status_handle = RegisterServiceCtrlHandlerW(service_name, service_control_handler); if (service_status_handle) { // convert all strings in argv pointer array from utf16 to utf8 argv_utf8 = g_malloc(argc * sizeof(gchar *)); for (i = 0; i < argc; i++) argv_utf8[i] = g_utf16_to_utf8(argv[i], -1, NULL, NULL, NULL); // service is starting service_update_status(SERVICE_START_PENDING); // service is running service_status.dwControlsAccepted |= (SERVICE_ACCEPT_STOP | SERVICE_ACCEPT_SHUTDOWN); service_update_status(SERVICE_RUNNING); service_running = TRUE; // gkrellmd_main returns on error or as soon as // service_running is FALSE (see service_control_handler()) gkrellmd_run(argc, argv_utf8); // service was stopped service_update_status(SERVICE_STOP_PENDING); // services are not stopped via process signals so we have to // clean up like in cb_sigterm() but without calling exit()! g_message("GKrellM Daemon %d.%d.%d%s: Exiting normally\n", GKRELLMD_VERSION_MAJOR, GKRELLMD_VERSION_MINOR, GKRELLMD_VERSION_REV, GKRELLMD_EXTRAVERSION); gkrellmd_cleanup(); // free all strings in pointer array and free the array itself for (i = 0; i < argc; i++) g_free(argv_utf8[i]); g_free(argv_utf8); // service is now stopped service_status.dwControlsAccepted &= ~(SERVICE_ACCEPT_STOP | SERVICE_ACCEPT_SHUTDOWN); service_update_status(SERVICE_STOPPED); // process is automatically terminated by windows now } } void service_run() { SERVICE_TABLE_ENTRYW service_table[] = { {service_name, service_main}, { 0, 0 } }; service_is_one = TRUE; // Blocking system call, will return if service is not needed anymore StartServiceCtrlDispatcherW(service_table); } static gboolean service_wait_for_stop(SC_HANDLE serviceHandle) { static const gulong waitTimeoutSec = 30; SERVICE_STATUS status; GTimer *waitTimer = NULL; gboolean ret = FALSE; if (!QueryServiceStatus(serviceHandle, &status)) { g_warning("Could not query status of %ls (%ld)\n", service_display_name, GetLastError()); return FALSE; } waitTimer = g_timer_new(); /* create and start */ while (status.dwCurrentState == SERVICE_STOP_PENDING) { g_usleep(status.dwWaitHint * 1000); if (!QueryServiceStatus(serviceHandle, &status)) { g_warning("Could not query status of %ls (%ld)\n", service_display_name, GetLastError()); ret = FALSE; break; } if (status.dwCurrentState == SERVICE_STOPPED) { ret = TRUE; break; } if (g_timer_elapsed(waitTimer, NULL) > waitTimeoutSec) { g_warning("Stopping %ls timed out\n", service_display_name); ret = FALSE; break; } } /*while*/ g_timer_destroy(waitTimer); return ret; } static gboolean service_stop(SC_HANDLE serviceHandle) { SERVICE_STATUS svcStatus; if (!QueryServiceStatus(serviceHandle, &svcStatus)) { g_warning("Could not query status of %ls (%ld)\n", service_display_name, GetLastError()); return FALSE; } /* service not running at all, just return that stopping worked out */ if (svcStatus.dwCurrentState == SERVICE_STOPPED) { g_print(_("%ls already stopped\n"), service_display_name); return TRUE; } /* service already stopping, just wait for its exit */ if (svcStatus.dwCurrentState == SERVICE_STOP_PENDING) { return service_wait_for_stop(serviceHandle); } /* Service is running, let's stop it */ if (!ControlService(serviceHandle, SERVICE_CONTROL_STOP, &svcStatus)) { g_warning(_("Could not stop %ls (%ld)\n"), service_display_name, GetLastError()); return FALSE; } // Wait for the service to stop. if (svcStatus.dwCurrentState == SERVICE_STOP_PENDING) { return service_wait_for_stop(serviceHandle); } return TRUE; } static gboolean service_install() { WCHAR path[_MAX_PATH + 1]; SC_HANDLE scmHandle; SC_HANDLE svcHandle; DWORD err; g_print(_("Installing %ls...\n"), service_display_name); if (GetModuleFileNameW(0, path, sizeof(path)/sizeof(path[0])) < 1) { g_warning("Could not determine path to gkrellmd service binary, error 0x%ld\n", GetLastError()); return FALSE; } scmHandle = OpenSCManagerW(NULL, NULL, SC_MANAGER_CREATE_SERVICE); if (!scmHandle) { err = GetLastError(); if (err == ERROR_ACCESS_DENIED) g_warning("Could not connect to service manager, access denied\n"); else g_warning("Could not connect to service manager, error 0x%lXd\n", err); return FALSE; } svcHandle = CreateServiceW(scmHandle, service_name, service_display_name, SERVICE_ALL_ACCESS, SERVICE_WIN32_OWN_PROCESS, SERVICE_AUTO_START, SERVICE_ERROR_NORMAL, path, 0, 0, 0, 0, 0); if (!svcHandle) { err = GetLastError(); if (err == ERROR_ACCESS_DENIED) g_warning("Could not install %ls, access denied\n", service_display_name); else if (err == ERROR_SERVICE_EXISTS || err == ERROR_DUPLICATE_SERVICE_NAME) g_warning("Could not install %ls, a service of the same name already exists\n", service_display_name); else g_warning("Could not install %ls, error 0x%lX\n", service_display_name, err); CloseServiceHandle(scmHandle); return FALSE; } else { g_print(_("%ls has been installed.\n"), service_display_name); } g_print(_("Starting %ls...\n"), service_display_name); if (!StartServiceW(svcHandle, 0, NULL)) { err = GetLastError(); if (err == ERROR_ACCESS_DENIED) g_warning("Could not start %ls, access denied\n", service_display_name); else g_warning("Could not start %ls, error 0x%lX\n", service_display_name, err); } else { g_print(_("%ls has been started.\n"), service_display_name); } CloseServiceHandle(svcHandle); CloseServiceHandle(scmHandle); return TRUE; } /* service_install() */ static gboolean service_uninstall() { SC_HANDLE scmHandle; SC_HANDLE svcHandle; BOOL delRet = FALSE; gchar *errmsg; g_print(_("Uninstalling %ls...\n"), service_display_name); scmHandle = OpenSCManagerW(NULL, NULL, SC_MANAGER_CONNECT); if (!scmHandle) { errmsg = g_win32_error_message(GetLastError()); g_warning("Could not connect to service manager: %s\n", errmsg); g_free(errmsg); return FALSE; } svcHandle = OpenServiceW(scmHandle, service_name, SERVICE_STOP | SERVICE_QUERY_STATUS | DELETE); if (!svcHandle) { errmsg = g_win32_error_message(GetLastError()); g_warning("Could not open %ls: %s\n", service_display_name, errmsg); g_free(errmsg); } else { // handle to gkrellm service acquired, now stop and uninstall it if (service_stop(svcHandle)) { delRet = DeleteService(svcHandle); if (!delRet) { errmsg = g_win32_error_message(GetLastError()); g_warning("Could not uninstall %ls: %s\n", service_display_name, errmsg); g_free(errmsg); } else { g_print(_("%ls has been uninstalled.\n"), service_display_name); } } CloseServiceHandle(svcHandle); } CloseServiceHandle(scmHandle); return delRet ? TRUE : FALSE; } /* service_uninstall() */ #endif /* defined(WIN32) */ GkrellmdTicks * gkrellmd_ticks(void) { return &GK; } gint gkrellmd_get_timer_ticks(void) { return GK.timer_ticks; } int main(int argc, char* argv[]) { int i; char *opt; #ifdef ENABLE_NLS #ifdef LOCALEDIR #if defined(WIN32) gchar *install_path; gchar *locale_dir; // Prepend app install path to locale dir install_path = g_win32_get_package_installation_directory_of_module(NULL); if (install_path != NULL) { locale_dir = g_build_filename(install_path, LOCALEDIR, NULL); bindtextdomain(PACKAGE_D, locale_dir); g_free(locale_dir); g_free(install_path); } #else bindtextdomain(PACKAGE_D, LOCALEDIR); #endif /* !WIN32 */ #endif /* LOCALEDIR */ textdomain(PACKAGE_D); bind_textdomain_codeset(PACKAGE_D, "UTF-8"); #endif /* ENABLE_NLS */ // Init logging-chain gkrellm_log_init(); /* Parse arguments for actions that exit gkrellmd immediately */ for (i = 1; i < argc; ++i) { opt = argv[i]; if (*opt == '-') { ++opt; if (*opt == '-') ++opt; } if (!strcmp(opt, "help") || !strcmp(opt, "h")) { usage(); return 0; } else if (!strcmp(opt, "version") || !strcmp(opt, "v")) { g_print("gkrellmd %d.%d.%d%s\n", GKRELLMD_VERSION_MAJOR, GKRELLMD_VERSION_MINOR, GKRELLMD_VERSION_REV, GKRELLMD_EXTRAVERSION); return 0; } #if defined(WIN32) else if (!strcmp(opt, "install")) { return (service_install() ? 1 : 0); } else if (!strcmp(opt, "uninstall")) { return (service_uninstall() ? 1 : 0); } else if (!strcmp(opt, "console")) { /* Special case for windows: run gkrellmd on console and not as a service. This is helpful for debugging purposes. */ int retVal; int newArgc = 0; char **newArgv = malloc((argc - 1) * sizeof(char *)); int j; for (j = 0; j < argc; ++j) { /* filter out option "--console" */ if (j == i) continue; newArgv[newArgc++] = argv[j]; } retVal = gkrellmd_run(newArgc, newArgv); free(newArgv); return retVal; } #endif /* defined(WIN32) */ } #if defined(WIN32) // win32: register service and wait for the service to be started/stopped service_run(); return 0; #else // Unix: just enter main loop return gkrellmd_run(argc, argv); #endif }