/* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License (the "License"). * You may not use this file except in compliance with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or http://www.opensolaris.org/os/licensing. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright 2009 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include extern const nv_alloc_ops_t fmd_nv_alloc_ops; /* see fmd_nv.c */ const char _fmd_version[] = "1.2"; /* daemon version string */ static char _fmd_plat[MAXNAMELEN]; /* native platform string */ static char _fmd_isa[MAXNAMELEN]; /* native instruction set */ static struct utsname _fmd_uts; /* native uname(2) info */ static char _fmd_csn[MAXNAMELEN]; /* chassis serial number */ static char _fmd_prod[MAXNAMELEN]; /* product name string */ /* * Note: the configuration file path is ordered from most common to most host- * specific because new conf files are merged/override previous ones. The * module paths are in the opposite order, from most specific to most common, * because once a module is loaded fmd will not try to load over the same name. */ static const char _fmd_conf_path[] = "%r/usr/lib/fm/fmd:" "%r/usr/platform/%m/lib/fm/fmd:" "%r/usr/platform/%i/lib/fm/fmd:" "%r/etc/fm/fmd"; static const char _fmd_agent_path[] = "%r/usr/platform/%i/lib/fm/fmd/agents:" "%r/usr/platform/%m/lib/fm/fmd/agents:" "%r/usr/lib/fm/fmd/agents"; static const char _fmd_plugin_path[] = "%r/usr/platform/%i/lib/fm/fmd/plugins:" "%r/usr/platform/%m/lib/fm/fmd/plugins:" "%r/usr/lib/fm/fmd/plugins"; static const char _fmd_scheme_path[] = "usr/lib/fm/fmd/schemes"; static const fmd_conf_mode_t _fmd_cerror_modes[] = { { "unload", "unload offending client module", FMD_CERROR_UNLOAD }, { "stop", "stop daemon for debugger attach", FMD_CERROR_STOP }, { "abort", "abort daemon and force core dump", FMD_CERROR_ABORT }, { NULL, NULL, 0 } }; static const fmd_conf_mode_t _fmd_dbout_modes[] = { { "stderr", "send debug messages to stderr", FMD_DBOUT_STDERR }, { "syslog", "send debug messages to syslog", FMD_DBOUT_SYSLOG }, { NULL, NULL, 0 } }; static const fmd_conf_mode_t _fmd_debug_modes[] = { { "help", "display debugging modes and exit", FMD_DBG_HELP }, { "mod", "debug module load/unload/locking", FMD_DBG_MOD }, { "disp", "debug dispatch queue processing", FMD_DBG_DISP }, { "xprt", "debug transport-specific routines", FMD_DBG_XPRT }, { "evt", "debug event subsystem routines", FMD_DBG_EVT }, { "log", "debug log subsystem routines", FMD_DBG_LOG }, { "tmr", "debug timer subsystem routines", FMD_DBG_TMR }, { "fmri", "debug fmri subsystem routines", FMD_DBG_FMRI }, { "asru", "debug asru subsystem routines", FMD_DBG_ASRU }, { "case", "debug case subsystem routines", FMD_DBG_CASE }, { "ckpt", "debug checkpoint routines", FMD_DBG_CKPT }, { "rpc", "debug rpc service routines", FMD_DBG_RPC }, { "trace", "display matching trace calls", FMD_DBG_TRACE }, { "all", "enable all available debug modes", FMD_DBG_ALL }, { NULL, NULL, 0 } }; static int fmd_cerror_set(fmd_conf_param_t *pp, const char *value) { return (fmd_conf_mode_set(_fmd_cerror_modes, pp, value)); } static int fmd_dbout_set(fmd_conf_param_t *pp, const char *value) { return (fmd_conf_mode_set(_fmd_dbout_modes, pp, value)); } static int fmd_debug_set(fmd_conf_param_t *pp, const char *value) { int err = fmd_conf_mode_set(_fmd_debug_modes, pp, value); if (err == 0) fmd.d_fmd_debug = pp->cp_value.cpv_num; return (err); } static int fmd_trmode_set(fmd_conf_param_t *pp, const char *value) { fmd_tracebuf_f *func; if (strcasecmp(value, "none") == 0) func = fmd_trace_none; else if (strcasecmp(value, "lite") == 0) func = fmd_trace_lite; else if (strcasecmp(value, "full") == 0) func = fmd_trace_full; else return (fmd_set_errno(EFMD_CONF_INVAL)); fmd.d_thr_trace = (void (*)())func; pp->cp_value.cpv_ptr = (void *)func; return (0); } static void fmd_trmode_get(const fmd_conf_param_t *pp, void *ptr) { *((void **)ptr) = pp->cp_value.cpv_ptr; } static int fmd_clkmode_set(fmd_conf_param_t *pp, const char *value) { const fmd_timeops_t *ops; if (strcasecmp(value, "native") == 0) ops = &fmd_timeops_native; else if (strcasecmp(value, "simulated") == 0) ops = &fmd_timeops_simulated; else return (fmd_set_errno(EFMD_CONF_INVAL)); fmd.d_clockops = ops; pp->cp_value.cpv_ptr = (void *)ops; return (0); } static void fmd_clkmode_get(const fmd_conf_param_t *pp, void *ptr) { *((void **)ptr) = pp->cp_value.cpv_ptr; } static const fmd_conf_ops_t fmd_cerror_ops = { fmd_cerror_set, fmd_conf_mode_get, fmd_conf_notsup, fmd_conf_nop }; static const fmd_conf_ops_t fmd_dbout_ops = { fmd_dbout_set, fmd_conf_mode_get, fmd_conf_notsup, fmd_conf_nop }; static const fmd_conf_ops_t fmd_debug_ops = { fmd_debug_set, fmd_conf_mode_get, fmd_conf_notsup, fmd_conf_nop }; static const fmd_conf_ops_t fmd_trmode_ops = { fmd_trmode_set, fmd_trmode_get, fmd_conf_notsup, fmd_conf_nop }; static const fmd_conf_ops_t fmd_clkmode_ops = { fmd_clkmode_set, fmd_clkmode_get, fmd_conf_notsup, fmd_conf_nop }; static const fmd_conf_formal_t _fmd_conf[] = { { "agent.path", &fmd_conf_path, _fmd_agent_path }, /* path for agents */ { "alloc_msecs", &fmd_conf_uint32, "10" }, /* msecs before alloc retry */ { "alloc_tries", &fmd_conf_uint32, "3" }, /* max # of alloc retries */ { "chassis", &fmd_conf_string, _fmd_csn }, /* chassis serial number */ { "ckpt.dir", &fmd_conf_string, "var/fm/fmd/ckpt" }, /* ckpt directory path */ { "ckpt.dirmode", &fmd_conf_int32, "0700" }, /* ckpt directory perm mode */ { "ckpt.mode", &fmd_conf_int32, "0400" }, /* ckpt file perm mode */ { "ckpt.restore", &fmd_conf_bool, "true" }, /* restore checkpoints? */ { "ckpt.save", &fmd_conf_bool, "true" }, /* save checkpoints? */ { "ckpt.zero", &fmd_conf_bool, "false" }, /* zero checkpoints on start? */ { "client.buflim", &fmd_conf_size, "10m" }, /* client buffer space limit */ { "client.dbout", &fmd_dbout_ops, NULL }, /* client debug output sinks */ { "client.debug", &fmd_conf_bool, NULL }, /* client debug enable */ { "client.error", &fmd_cerror_ops, "unload" }, /* client error policy */ { "client.memlim", &fmd_conf_size, "10m" }, /* client allocation limit */ { "client.evqlim", &fmd_conf_uint32, "256" }, /* client event queue limit */ { "client.thrlim", &fmd_conf_uint32, "20" }, /* client aux thread limit */ { "client.thrsig", &fmd_conf_signal, "SIGUSR1" }, /* fmd_thr_signal() value */ { "client.tmrlim", &fmd_conf_uint32, "1024" }, /* client pending timer limit */ { "client.xprtlim", &fmd_conf_uint32, "256" }, /* client transport limit */ { "client.xprtlog", &fmd_conf_bool, NULL }, /* client transport logging? */ { "client.xprtqlim", &fmd_conf_uint32, "1024" }, /* client transport queue li */ { "clock", &fmd_clkmode_ops, "native" }, /* clock operation mode */ { "conf_path", &fmd_conf_path, _fmd_conf_path }, /* root config file path */ { "conf_file", &fmd_conf_string, "fmd.conf" }, /* root config file name */ { "core", &fmd_conf_bool, "false" }, /* force core dump on quit */ { "dbout", &fmd_dbout_ops, NULL }, /* daemon debug output sinks */ { "debug", &fmd_debug_ops, NULL }, /* daemon debugging flags */ { "dictdir", &fmd_conf_string, "usr/lib/fm/dict" }, /* default diagcode dir */ { "domain", &fmd_conf_string, NULL }, /* domain id for de auth */ { "fakenotpresent", &fmd_conf_uint32, "0" }, /* simulate rsrc not present */ { "fg", &fmd_conf_bool, "false" }, /* run daemon in foreground */ { "gc_interval", &fmd_conf_time, "1d" }, /* garbage collection intvl */ { "ids.avg", &fmd_conf_uint32, "4" }, /* desired idspace chain len */ { "ids.max", &fmd_conf_uint32, "1024" }, /* maximum idspace buckets */ { "isaname", &fmd_conf_string, _fmd_isa }, /* instruction set (uname -p) */ { "log.creator", &fmd_conf_string, "fmd" }, /* exacct log creator string */ { "log.error", &fmd_conf_string, "var/fm/fmd/errlog" }, /* error log path */ { "log.fault", &fmd_conf_string, "var/fm/fmd/fltlog" }, /* fault log path */ { "log.minfree", &fmd_conf_size, "2m" }, /* min log fsys free space */ { "log.rsrc", &fmd_conf_string, "var/fm/fmd/rsrc" }, /* asru log dir path */ { "log.tryrotate", &fmd_conf_uint32, "10" }, /* max log rotation attempts */ { "log.waitrotate", &fmd_conf_time, "200ms" }, /* log rotation retry delay */ { "log.xprt", &fmd_conf_string, "var/fm/fmd/xprt" }, /* transport log dir */ { "machine", &fmd_conf_string, _fmd_uts.machine }, /* machine name (uname -m) */ { "nodiagcode", &fmd_conf_string, "-" }, /* diagcode to use if error */ { "repaircode", &fmd_conf_string, "-" }, /* diagcode for list.repaired */ { "resolvecode", &fmd_conf_string, "-" }, /* diagcode for list.resolved */ { "updatecode", &fmd_conf_string, "-" }, /* diagcode for list.updated */ { "osrelease", &fmd_conf_string, _fmd_uts.release }, /* release (uname -r) */ { "osversion", &fmd_conf_string, _fmd_uts.version }, /* version (uname -v) */ { "platform", &fmd_conf_string, _fmd_plat }, /* platform string (uname -i) */ { "plugin.close", &fmd_conf_bool, "true" }, /* dlclose plugins on fini */ { "plugin.path", &fmd_conf_path, _fmd_plugin_path }, /* path for plugin mods */ { "product", &fmd_conf_string, _fmd_prod }, /* product name string */ { "rootdir", &fmd_conf_string, "" }, /* root directory for paths */ { "rpc.adm.path", &fmd_conf_string, NULL }, /* FMD_ADM rendezvous file */ { "rpc.adm.prog", &fmd_conf_uint32, "100169" }, /* FMD_ADM rpc program num */ { "rpc.api.path", &fmd_conf_string, NULL }, /* FMD_API rendezvous file */ { "rpc.api.prog", &fmd_conf_uint32, "100170" }, /* FMD_API rpc program num */ { "rpc.rcvsize", &fmd_conf_size, "128k" }, /* rpc receive buffer size */ { "rpc.sndsize", &fmd_conf_size, "128k" }, /* rpc send buffer size */ { "rsrc.age", &fmd_conf_time, "30d" }, /* max age of old rsrc log */ { "rsrc.zero", &fmd_conf_bool, "false" }, /* zero rsrc cache on start? */ { "schemedir", &fmd_conf_string, _fmd_scheme_path }, /* path for scheme mods */ { "self.name", &fmd_conf_string, "fmd-self-diagnosis" }, /* self-diag module */ { "self.dict", &fmd_conf_list, "FMD.dict" }, /* self-diag dictionary list */ { "server", &fmd_conf_string, _fmd_uts.nodename }, /* server id for de auth */ { "strbuckets", &fmd_conf_uint32, "211" }, /* size of string hashes */ #ifdef DEBUG { "trace.mode", &fmd_trmode_ops, "full" }, /* trace mode: none/lite/full */ #else { "trace.mode", &fmd_trmode_ops, "lite" }, /* trace mode: none/lite/full */ #endif { "trace.recs", &fmd_conf_uint32, "128" }, /* trace records per thread */ { "trace.frames", &fmd_conf_uint32, "16" }, /* max trace rec stack frames */ { "uuidlen", &fmd_conf_uint32, "36" }, /* UUID ASCII string length */ { "xprt.ttl", &fmd_conf_uint8, "1" }, /* default event time-to-live */ }; /* * Statistics maintained by fmd itself on behalf of various global subsystems. * NOTE: FMD_TYPE_STRING statistics should not be used here. If they are * required in the future, the FMD_ADM_MODGSTAT service routine must change. */ static fmd_statistics_t _fmd_stats = { { "errlog.replayed", FMD_TYPE_UINT64, "total events replayed from errlog" }, { "errlog.partials", FMD_TYPE_UINT64, "events partially committed in errlog" }, { "errlog.enospc", FMD_TYPE_UINT64, "events not appended to errlog (ENOSPC)" }, { "fltlog.enospc", FMD_TYPE_UINT64, "events not appended to fltlog (ENOSPC)" }, { "log.enospc", FMD_TYPE_UINT64, "events not appended to other logs (ENOSPC)" }, { "dr.gen", FMD_TYPE_UINT64, "dynamic reconfiguration generation" }, { "topo.gen", FMD_TYPE_UINT64, "topology snapshot generation" }, { "topo.drgen", FMD_TYPE_UINT64, "current topology DR generation number" }, }; /* * SMBIOS serial numbers can contain characters (particularly ':' and ' ') * that are invalid for the authority and can break FMRI parsing. We translate * any invalid characters to a safe '-', as well as trimming any leading or * trailing whitespace. Similarly, '/' can be found in some product names * so we translate that to '-'. */ void fmd_cleanup_auth_str(char *buf, const char *begin) { const char *end, *cp; char c; int i; end = begin + strlen(begin); while (begin < end && isspace(*begin)) begin++; while (begin < end && isspace(*(end - 1))) end--; if (begin >= end) return; cp = begin; for (i = 0; i < MAXNAMELEN - 1; i++) { if (cp >= end) break; c = *cp; if (c == ':' || c == '=' || c == '/' || isspace(c) || !isprint(c)) buf[i] = '-'; else buf[i] = c; cp++; } buf[i] = 0; } void fmd_create(fmd_t *dp, const char *arg0, const char *root, const char *conf) { fmd_conf_path_t *pap; char file[PATH_MAX]; const char *name; fmd_stat_t *sp; int i; smbios_hdl_t *shp; smbios_system_t s1; smbios_info_t s2; id_t id; di_prom_handle_t promh = DI_PROM_HANDLE_NIL; di_node_t rooth = DI_NODE_NIL; char *bufp; (void) sysinfo(SI_PLATFORM, _fmd_plat, sizeof (_fmd_plat)); (void) sysinfo(SI_ARCHITECTURE, _fmd_isa, sizeof (_fmd_isa)); (void) uname(&_fmd_uts); if ((shp = smbios_open(NULL, SMB_VERSION, 0, NULL)) != NULL) { if ((id = smbios_info_system(shp, &s1)) != SMB_ERR && smbios_info_common(shp, id, &s2) != SMB_ERR) { fmd_cleanup_auth_str(_fmd_prod, s2.smbi_product); fmd_cleanup_auth_str(_fmd_csn, s2.smbi_serial); } smbios_close(shp); } else if ((rooth = di_init("/", DINFOPROP)) != DI_NODE_NIL && (promh = di_prom_init()) != DI_PROM_HANDLE_NIL) { if (di_prom_prop_lookup_bytes(promh, rooth, "chassis-sn", (unsigned char **)&bufp) != -1) { fmd_cleanup_auth_str(_fmd_csn, bufp); } } if (promh != DI_PROM_HANDLE_NIL) di_prom_fini(promh); if (rooth != DI_NODE_NIL) di_fini(rooth); bzero(dp, sizeof (fmd_t)); dp->d_version = _fmd_version; dp->d_pname = fmd_strbasename(arg0); dp->d_pid = getpid(); if (pthread_key_create(&dp->d_key, NULL) != 0) fmd_error(EFMD_EXIT, "failed to create pthread key"); (void) pthread_mutex_init(&dp->d_xprt_lock, NULL); (void) pthread_mutex_init(&dp->d_err_lock, NULL); (void) pthread_mutex_init(&dp->d_thr_lock, NULL); (void) pthread_mutex_init(&dp->d_mod_lock, NULL); (void) pthread_mutex_init(&dp->d_stats_lock, NULL); (void) pthread_mutex_init(&dp->d_topo_lock, NULL); (void) pthread_rwlock_init(&dp->d_log_lock, NULL); (void) pthread_mutex_init(&dp->d_fmd_lock, NULL); (void) pthread_cond_init(&dp->d_fmd_cv, NULL); /* * A small number of properties must be set manually before we open * the root configuration file. These include any settings for our * memory allocator and path expansion token values, because these * values are needed by the routines in fmd_conf.c itself. After * the root configuration file is processed, we reset these properties * based upon the latest values from the configuration file. */ dp->d_alloc_msecs = 10; dp->d_alloc_tries = 3; dp->d_str_buckets = 211; dp->d_rootdir = root ? root : ""; dp->d_platform = _fmd_plat; dp->d_machine = _fmd_uts.machine; dp->d_isaname = _fmd_isa; dp->d_conf = fmd_conf_open(conf, sizeof (_fmd_conf) / sizeof (_fmd_conf[0]), _fmd_conf, FMD_CONF_DEFER); if (dp->d_conf == NULL) { fmd_error(EFMD_EXIT, "failed to load required configuration properties\n"); } (void) fmd_conf_getprop(dp->d_conf, "alloc.msecs", &dp->d_alloc_msecs); (void) fmd_conf_getprop(dp->d_conf, "alloc.tries", &dp->d_alloc_tries); (void) fmd_conf_getprop(dp->d_conf, "strbuckets", &dp->d_str_buckets); (void) fmd_conf_getprop(dp->d_conf, "platform", &dp->d_platform); (void) fmd_conf_getprop(dp->d_conf, "machine", &dp->d_machine); (void) fmd_conf_getprop(dp->d_conf, "isaname", &dp->d_isaname); /* * Manually specified rootdirs override config files, so only update * d_rootdir based on the config files we parsed if no 'root' was set. */ if (root == NULL) (void) fmd_conf_getprop(dp->d_conf, "rootdir", &dp->d_rootdir); else (void) fmd_conf_setprop(dp->d_conf, "rootdir", dp->d_rootdir); /* * Once the base conf file properties are loaded, lookup the values * of $conf_path and $conf_file and merge in any other conf files. */ (void) fmd_conf_getprop(dp->d_conf, "conf_path", &pap); (void) fmd_conf_getprop(dp->d_conf, "conf_file", &name); for (i = 0; i < pap->cpa_argc; i++) { (void) snprintf(file, sizeof (file), "%s/%s", pap->cpa_argv[i], name); if (access(file, F_OK) == 0) fmd_conf_merge(dp->d_conf, file); } /* * Update the value of fmd.d_fg based on "fg". We cache this property * because it must be accessed deep within fmd at fmd_verror() time. * Update any other properties that must be cached for performance. */ (void) fmd_conf_getprop(fmd.d_conf, "fg", &fmd.d_fg); (void) fmd_conf_getprop(fmd.d_conf, "xprt.ttl", &fmd.d_xprt_ttl); /* * Initialize our custom libnvpair allocator and create an nvlist for * authority elements corresponding to this instance of the daemon. */ (void) nv_alloc_init(&dp->d_nva, &fmd_nv_alloc_ops); dp->d_auth = fmd_protocol_authority(); /* * The fmd_module_t for the root module must be created manually. Most * of it remains unused and zero, except for the few things we fill in. */ dp->d_rmod = fmd_zalloc(sizeof (fmd_module_t), FMD_SLEEP); dp->d_rmod->mod_name = fmd_strdup(dp->d_pname, FMD_SLEEP); dp->d_rmod->mod_fmri = fmd_protocol_fmri_module(dp->d_rmod); fmd_list_append(&dp->d_mod_list, dp->d_rmod); fmd_module_hold(dp->d_rmod); (void) pthread_mutex_init(&dp->d_rmod->mod_lock, NULL); (void) pthread_cond_init(&dp->d_rmod->mod_cv, NULL); (void) pthread_mutex_init(&dp->d_rmod->mod_stats_lock, NULL); dp->d_rmod->mod_thread = fmd_thread_xcreate(dp->d_rmod, pthread_self()); dp->d_rmod->mod_stats = fmd_zalloc(sizeof (fmd_modstat_t), FMD_SLEEP); dp->d_rmod->mod_ustat = fmd_ustat_create(); if (pthread_setspecific(dp->d_key, dp->d_rmod->mod_thread) != 0) fmd_error(EFMD_EXIT, "failed to attach main thread key"); if ((dp->d_stats = (fmd_statistics_t *)fmd_ustat_insert( dp->d_rmod->mod_ustat, FMD_USTAT_NOALLOC, sizeof (_fmd_stats) / sizeof (fmd_stat_t), (fmd_stat_t *)&_fmd_stats, NULL)) == NULL) fmd_error(EFMD_EXIT, "failed to initialize statistics"); (void) pthread_mutex_lock(&dp->d_rmod->mod_lock); dp->d_rmod->mod_flags |= FMD_MOD_INIT; (void) pthread_mutex_unlock(&dp->d_rmod->mod_lock); /* * In addition to inserting the _fmd_stats collection of program-wide * statistics, we also insert a statistic named after each of our * errors and update these counts in fmd_verror() (see fmd_subr.c). */ dp->d_errstats = sp = fmd_zalloc(sizeof (fmd_stat_t) * (EFMD_END - EFMD_UNKNOWN), FMD_SLEEP); for (i = 0; i < EFMD_END - EFMD_UNKNOWN; i++, sp++) { (void) snprintf(sp->fmds_name, sizeof (sp->fmds_name), "err.%s", strrchr(fmd_errclass(EFMD_UNKNOWN + i), '.') + 1); sp->fmds_type = FMD_TYPE_UINT64; } (void) fmd_ustat_insert(dp->d_rmod->mod_ustat, FMD_USTAT_NOALLOC, EFMD_END - EFMD_UNKNOWN, dp->d_errstats, NULL); } void fmd_destroy(fmd_t *dp) { fmd_module_t *mp; fmd_case_t *cp; int core; (void) fmd_conf_getprop(fmd.d_conf, "core", &core); fmd_rpc_fini(); if (dp->d_xprt_ids != NULL) fmd_xprt_suspend_all(); /* * Unload the self-diagnosis module first. This ensures that it does * not get confused as we start unloading other modules, etc. We must * hold the dispq lock as a writer while doing so since it uses d_self. */ if (dp->d_self != NULL) { fmd_module_t *self; (void) pthread_rwlock_wrlock(&dp->d_disp->dq_lock); self = dp->d_self; dp->d_self = NULL; (void) pthread_rwlock_unlock(&dp->d_disp->dq_lock); fmd_module_unload(self); fmd_module_rele(self); } /* * Unload modules in reverse order *except* for the root module, which * is first in the list. This allows it to keep its thread and trace. */ for (mp = fmd_list_prev(&dp->d_mod_list); mp != dp->d_rmod; ) { fmd_module_unload(mp); mp = fmd_list_prev(mp); } if (dp->d_mod_hash != NULL) { fmd_modhash_destroy(dp->d_mod_hash); dp->d_mod_hash = NULL; } /* * Close both log files now that modules are no longer active. We must * set these pointers to NULL in case any subsequent errors occur. */ if (dp->d_errlog != NULL) { fmd_log_rele(dp->d_errlog); dp->d_errlog = NULL; } if (dp->d_fltlog != NULL) { fmd_log_rele(dp->d_fltlog); dp->d_fltlog = NULL; } /* * Now destroy the resource cache: each ASRU contains a case reference, * which may in turn contain a pointer to a referenced owning module. */ if (dp->d_asrus != NULL) { fmd_asru_hash_destroy(dp->d_asrus); dp->d_asrus = NULL; } /* * Now that all data structures that refer to modules are torn down, * no modules should be remaining on the module list except for d_rmod. * If we trip one of these assertions, we're missing a rele somewhere. */ ASSERT(fmd_list_prev(&dp->d_mod_list) == dp->d_rmod); ASSERT(fmd_list_next(&dp->d_mod_list) == dp->d_rmod); /* * Now destroy the root module. We clear its thread key first so any * calls to fmd_trace() inside of the module code will be ignored. */ (void) pthread_setspecific(dp->d_key, NULL); fmd_module_lock(dp->d_rmod); while ((cp = fmd_list_next(&dp->d_rmod->mod_cases)) != NULL) fmd_case_discard(cp, B_FALSE); fmd_module_unlock(dp->d_rmod); fmd_free(dp->d_rmod->mod_stats, sizeof (fmd_modstat_t)); dp->d_rmod->mod_stats = NULL; (void) pthread_mutex_lock(&dp->d_rmod->mod_lock); dp->d_rmod->mod_flags |= FMD_MOD_FINI; (void) pthread_mutex_unlock(&dp->d_rmod->mod_lock); fmd_module_rele(dp->d_rmod); ASSERT(fmd_list_next(&dp->d_mod_list) == NULL); /* * Now destroy the remaining global data structures. If 'core' was * set to true, force a core dump so we can check for memory leaks. */ if (dp->d_cases != NULL) fmd_case_hash_destroy(dp->d_cases); if (dp->d_disp != NULL) fmd_dispq_destroy(dp->d_disp); if (dp->d_timers != NULL) fmd_timerq_destroy(dp->d_timers); if (dp->d_schemes != NULL) fmd_scheme_hash_destroy(dp->d_schemes); if (dp->d_xprt_ids != NULL) fmd_idspace_destroy(dp->d_xprt_ids); if (dp->d_errstats != NULL) { fmd_free(dp->d_errstats, sizeof (fmd_stat_t) * (EFMD_END - EFMD_UNKNOWN)); } if (dp->d_conf != NULL) fmd_conf_close(dp->d_conf); fmd_topo_fini(); nvlist_free(dp->d_auth); (void) nv_alloc_fini(&dp->d_nva); dp->d_clockops->fto_fini(dp->d_clockptr); (void) pthread_key_delete(dp->d_key); bzero(dp, sizeof (fmd_t)); if (core) fmd_panic("forcing core dump at user request\n"); } /*ARGSUSED*/ static void fmd_gc(fmd_t *dp, id_t id, hrtime_t hrt) { hrtime_t delta; if (id != 0) { TRACE((FMD_DBG_MOD, "garbage collect start")); fmd_modhash_apply(dp->d_mod_hash, fmd_module_gc); TRACE((FMD_DBG_MOD, "garbage collect end")); (void) pthread_rwlock_rdlock(&dp->d_log_lock); fmd_log_update(dp->d_errlog); (void) pthread_rwlock_unlock(&dp->d_log_lock); } (void) fmd_conf_getprop(dp->d_conf, "gc_interval", &delta); (void) fmd_timerq_install(dp->d_timers, dp->d_rmod->mod_timerids, (fmd_timer_f *)fmd_gc, dp, NULL, delta); } /*ARGSUSED*/ static void fmd_clear_aged_rsrcs(fmd_t *dp, id_t id, hrtime_t hrt) { hrtime_t delta; fmd_asru_clear_aged_rsrcs(); (void) fmd_conf_getprop(dp->d_conf, "rsrc.age", &delta); (void) fmd_timerq_install(dp->d_timers, dp->d_rmod->mod_timerids, (fmd_timer_f *)fmd_clear_aged_rsrcs, dp, NULL, delta/10); } /* * Events are committed to the errlog after cases are checkpointed. If fmd * crashes before an event is ever associated with a module, this function will * be called to replay it to all subscribers. If fmd crashes in between the * subscriber checkpointing and committing the event in the error log, the * module will have seen the event and we don't want to replay it. So we look * for the event in all modules and transition it to the proper state. If * it is found, we commit it to the error log and do not replay it. The in- * memory case search used by fmd_module_contains() et al isn't particularly * efficient, but it is faster than doing read i/o's on every case event to * check their status or write i/o's on every event to replay to update states. * We can improve the efficiency of this lookup algorithm later if necessary. */ /*ARGSUSED*/ static void fmd_err_replay(fmd_log_t *lp, fmd_event_t *ep, fmd_t *dp) { fmd_module_t *mp; fmd_stat_t *sp; (void) pthread_mutex_lock(&dp->d_mod_lock); for (mp = fmd_list_next(&dp->d_mod_list); mp != NULL; mp = fmd_list_next(mp)) { if (fmd_module_contains(mp, ep)) { fmd_module_hold(mp); break; } } (void) pthread_mutex_unlock(&dp->d_mod_lock); if (mp != NULL) { fmd_event_commit(ep); fmd_module_rele(mp); sp = &dp->d_stats->ds_log_partials; } else { fmd_dispq_dispatch(dp->d_disp, ep, FMD_EVENT_DATA(ep)); sp = &dp->d_stats->ds_log_replayed; } (void) pthread_mutex_lock(&dp->d_stats_lock); sp->fmds_value.ui64++; (void) pthread_mutex_unlock(&dp->d_stats_lock); } void fmd_door_server(void *dip) { fmd_dprintf(FMD_DBG_XPRT, "door server starting for %p\n", dip); (void) pthread_setcancelstate(PTHREAD_CANCEL_DISABLE, NULL); (void) door_return(NULL, 0, NULL, 0); } /* * Custom door server create callback. Any fmd services that use doors will * require those threads to have their fmd-specific TSD initialized, etc. */ static void fmd_door(door_info_t *dip) { if (fmd_thread_create(fmd.d_rmod, fmd_door_server, dip) == NULL) fmd_panic("failed to create server for door %p", (void *)dip); } /* * This signal handler is installed for the client.thrsig signal to be used to * force an auxiliary thread to wake up from a system call and return EINTR in * response to a module's use of fmd_thr_signal(). We also trace the event. */ static void fmd_signal(int sig) { TRACE((FMD_DBG_MOD, "module thread received sig #%d", sig)); } void fmd_run(fmd_t *dp, int pfd) { char *nodc_key[] = { FMD_FLT_NODC, NULL }; char *repair_key[] = { FM_LIST_REPAIRED_CLASS, NULL }; char *resolve_key[] = { FM_LIST_RESOLVED_CLASS, NULL }; char *update_key[] = { FM_LIST_UPDATED_CLASS, NULL }; char code_str[128]; struct sigaction act; int status = FMD_EXIT_SUCCESS; const char *name; fmd_conf_path_t *pap; fmd_event_t *e; int dbout; /* * Cache all the current debug property settings in d_fmd_debug, * d_fmd_dbout, d_hdl_debug, and d_hdl_dbout. If a given debug mask * is non-zero and the corresponding dbout mask is zero, set dbout * to a sensible default value based on whether we have daemonized. */ (void) fmd_conf_getprop(dp->d_conf, "dbout", &dbout); if (dp->d_fmd_debug != 0 && dbout == 0) dp->d_fmd_dbout = dp->d_fg? FMD_DBOUT_STDERR : FMD_DBOUT_SYSLOG; else dp->d_fmd_dbout = dbout; (void) fmd_conf_getprop(dp->d_conf, "client.debug", &dp->d_hdl_debug); (void) fmd_conf_getprop(dp->d_conf, "client.dbout", &dbout); if (dp->d_hdl_debug != 0 && dbout == 0) dp->d_hdl_dbout = dp->d_fg? FMD_DBOUT_STDERR : FMD_DBOUT_SYSLOG; else dp->d_hdl_dbout = dbout; /* * Initialize remaining major program data structures such as the * clock, dispatch queues, log files, module hash collections, etc. * This work is done here rather than in fmd_create() to permit the -o * command-line option to modify properties after fmd_create() is done. */ name = dp->d_rootdir != NULL && *dp->d_rootdir != '\0' ? dp->d_rootdir : NULL; /* * The clock must be initialized before fmd_topo_init() because * fmd_topo_update() calls fmd_time_gethrtime(). */ dp->d_clockptr = dp->d_clockops->fto_init(); fmd_topo_init(); dp->d_xprt_ids = fmd_idspace_create("xprt_ids", 1, INT_MAX); fmd_xprt_suspend_all(); (void) door_server_create(fmd_door); dp->d_rmod->mod_timerids = fmd_idspace_create(dp->d_pname, 1, 16); dp->d_timers = fmd_timerq_create(); dp->d_disp = fmd_dispq_create(); dp->d_cases = fmd_case_hash_create(); /* * The root module's mod_queue is created with limit zero, making it * act like /dev/null; anything inserted here is simply ignored. */ dp->d_rmod->mod_queue = fmd_eventq_create(dp->d_rmod, &dp->d_rmod->mod_stats->ms_evqstat, &dp->d_rmod->mod_stats_lock, 0); /* * Once our subsystems that use signals have been set up, install the * signal handler for the fmd_thr_signal() API. Verify that the signal * being used for this purpose doesn't conflict with something else. */ (void) fmd_conf_getprop(dp->d_conf, "client.thrsig", &dp->d_thr_sig); if (sigaction(dp->d_thr_sig, NULL, &act) != 0) { fmd_error(EFMD_EXIT, "invalid signal selected for " "client.thrsig property: %d\n", dp->d_thr_sig); } if (act.sa_handler != SIG_IGN && act.sa_handler != SIG_DFL) { fmd_error(EFMD_EXIT, "signal selected for client.thrsig " "property is already in use: %d\n", dp->d_thr_sig); } act.sa_handler = fmd_signal; act.sa_flags = 0; (void) sigemptyset(&act.sa_mask); (void) sigaction(dp->d_thr_sig, &act, NULL); (void) fmd_conf_getprop(dp->d_conf, "schemedir", &name); dp->d_schemes = fmd_scheme_hash_create(dp->d_rootdir, name); (void) fmd_conf_getprop(dp->d_conf, "log.rsrc", &name); dp->d_asrus = fmd_asru_hash_create(dp->d_rootdir, name); (void) fmd_conf_getprop(dp->d_conf, "log.error", &name); dp->d_errlog = fmd_log_open(dp->d_rootdir, name, FMD_LOG_ERROR); (void) fmd_conf_getprop(dp->d_conf, "log.fault", &name); dp->d_fltlog = fmd_log_open(dp->d_rootdir, name, FMD_LOG_FAULT); if (dp->d_asrus == NULL || dp->d_errlog == NULL || dp->d_fltlog == NULL) fmd_error(EFMD_EXIT, "failed to initialize log files\n"); /* * Before loading modules, create an empty control event which will act * as a global barrier for module event processing. Each module we * load successfully will insert it at their head of their event queue, * and then pause inside of fmd_ctl_rele() after dequeuing the event. * This module barrier is required for two reasons: * * (a) During module loading, the restoration of case checkpoints may * result in a list.* event being recreated for which the intended * subscriber has not yet loaded depending on the load order. Such * events could then result in spurious "no subscriber" errors. * * (b) During errlog replay, a sequence of errors from a long time ago * may be replayed, and the module may attempt to install relative * timers associated with one or more of these events. If errlog * replay were "racing" with active module threads, an event E1 * that resulted in a relative timer T at time E1 + N nsec could * fire prior to an event E2 being enqueued, even if the relative * time ordering was E1 < E2 < E1 + N, causing mis-diagnosis. */ dp->d_mod_event = e = fmd_event_create(FMD_EVT_CTL, FMD_HRT_NOW, NULL, fmd_ctl_init(NULL)); fmd_event_hold(e); /* * Once all data structures are initialized, we load all of our modules * in order according to class in order to load up any subscriptions. * Once built-in modules are loaded, we detach from our waiting parent. */ dp->d_mod_hash = fmd_modhash_create(); if (fmd_builtin_loadall(dp->d_mod_hash) != 0 && !dp->d_fg) fmd_error(EFMD_EXIT, "failed to initialize fault manager\n"); (void) fmd_conf_getprop(dp->d_conf, "self.name", &name); dp->d_self = fmd_modhash_lookup(dp->d_mod_hash, name); if (dp->d_self != NULL) { if (fmd_module_dc_key2code(dp->d_self, nodc_key, code_str, sizeof (code_str)) == 0) (void) fmd_conf_setprop(dp->d_conf, "nodiagcode", code_str); if (fmd_module_dc_key2code(dp->d_self, repair_key, code_str, sizeof (code_str)) == 0) (void) fmd_conf_setprop(dp->d_conf, "repaircode", code_str); if (fmd_module_dc_key2code(dp->d_self, resolve_key, code_str, sizeof (code_str)) == 0) (void) fmd_conf_setprop(dp->d_conf, "resolvecode", code_str); if (fmd_module_dc_key2code(dp->d_self, update_key, code_str, sizeof (code_str)) == 0) (void) fmd_conf_setprop(dp->d_conf, "updatecode", code_str); } fmd_rpc_init(); dp->d_running = 1; /* we are now officially an active fmd */ /* * Now that we're running, if a pipe fd was specified, write an exit * status to it to indicate that our parent process can safely detach. * Then proceed to loading the remaining non-built-in modules. */ if (pfd >= 0) (void) write(pfd, &status, sizeof (status)); /* * Before loading all modules, repopulate the ASRU cache from its * persistent repository on disk. Then during module loading, the * restoration of checkpoint files will reparent any active cases. */ fmd_asru_hash_refresh(dp->d_asrus); (void) fmd_conf_getprop(dp->d_conf, "plugin.path", &pap); fmd_modhash_loadall(dp->d_mod_hash, pap, &fmd_rtld_ops, ".so"); (void) fmd_conf_getprop(dp->d_conf, "agent.path", &pap); fmd_modhash_loadall(dp->d_mod_hash, pap, &fmd_proc_ops, NULL); /* * With all modules loaded, replay fault events from the ASRU cache for * any ASRUs that must be retired, replay error events from the errlog * that did not finish processing the last time ran, and then release * the global module barrier by executing a final rele on d_mod_event. */ fmd_asru_hash_replay(dp->d_asrus); (void) pthread_rwlock_rdlock(&dp->d_log_lock); fmd_log_replay(dp->d_errlog, (fmd_log_f *)fmd_err_replay, dp); fmd_log_update(dp->d_errlog); (void) pthread_rwlock_unlock(&dp->d_log_lock); dp->d_mod_event = NULL; fmd_event_rele(e); /* * Now replay list.updated and list.repaired events */ fmd_case_repair_replay(); /* * Finally, awaken any threads associated with receiving events from * open transports and tell them to proceed with fmd_xprt_recv(). */ fmd_xprt_resume_all(); fmd_gc(dp, 0, 0); fmd_clear_aged_rsrcs(dp, 0, 0); (void) pthread_mutex_lock(&dp->d_fmd_lock); dp->d_booted = 1; (void) pthread_cond_broadcast(&dp->d_fmd_cv); (void) pthread_mutex_unlock(&dp->d_fmd_lock); } void fmd_help(fmd_t *dp) { const fmd_conf_mode_t *cmp; (void) printf("Usage: %s -o debug=mode[,mode]\n", dp->d_pname); for (cmp = _fmd_debug_modes; cmp->cm_name != NULL; cmp++) (void) printf("\t%s\t%s\n", cmp->cm_name, cmp->cm_desc); }