/* * 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 2007 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ #pragma ident "%Z%%M% %I% %E% SMI" #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 /* * Table of configuration file variable types ops-vector pointers. We use this * to convert from the property description array specified by the module to an * array of fmd_conf_formal_t's. The order of this array must match the order * of #define values specified in (i.e. FMD_TYPE_BOOL must be 0). * For now, the fmd_conf_list and fmd_conf_path types are not supported as we * do not believe modules need them and they would require more complexity. */ static const fmd_conf_ops_t *const _fmd_prop_ops[] = { &fmd_conf_bool, /* FMD_TYPE_BOOL */ &fmd_conf_int32, /* FMD_TYPE_INT32 */ &fmd_conf_uint32, /* FMD_TYPE_UINT32 */ &fmd_conf_int64, /* FMD_TYPE_INT64 */ &fmd_conf_uint64, /* FMD_TYPE_UINT64 */ &fmd_conf_string, /* FMD_TYPE_STRING */ &fmd_conf_time, /* FMD_TYPE_TIME */ &fmd_conf_size, /* FMD_TYPE_SIZE */ }; static void fmd_api_verror(fmd_module_t *, int, const char *, va_list) __NORETURN; static void fmd_api_error(fmd_module_t *, int, const char *, ...) __NORETURN; /* * fmd_api_vxerror() provides the engine underlying the fmd_hdl_[v]error() API * calls and the fmd_api_[v]error() utility routine defined below. The routine * formats the error, optionally associated with a particular errno code 'err', * and logs it as an ereport associated with the calling module. Depending on * other optional properties, we also emit a message to stderr and to syslog. */ static void fmd_api_vxerror(fmd_module_t *mp, int err, const char *format, va_list ap) { int raw_err = err; nvlist_t *nvl; fmd_event_t *e; char *class, *msg; size_t len1, len2; char c; /* * fmd_api_vxerror() counts as both an error of class EFMD_MODULE * as well as an instance of 'err' w.r.t. our internal bean counters. */ (void) pthread_mutex_lock(&fmd.d_err_lock); fmd.d_errstats[EFMD_MODULE - EFMD_UNKNOWN].fmds_value.ui64++; if (err > EFMD_UNKNOWN && err < EFMD_END) fmd.d_errstats[err - EFMD_UNKNOWN].fmds_value.ui64++; (void) pthread_mutex_unlock(&fmd.d_err_lock); /* * Format the message using vsnprintf(). As usual, if the format has a * newline in it, it is printed alone; otherwise strerror() is added. */ if (strchr(format, '\n') != NULL) err = 0; /* err is not relevant in the message */ len1 = vsnprintf(&c, 1, format, ap); len2 = err != 0 ? snprintf(&c, 1, ": %s\n", fmd_strerror(err)) : 0; msg = fmd_alloc(len1 + len2 + 1, FMD_SLEEP); (void) vsnprintf(msg, len1 + 1, format, ap); if (err != 0) { (void) snprintf(&msg[len1], len2 + 1, ": %s\n", fmd_strerror(err)); } /* * Create an error event corresponding to the error, insert it into the * error log, and dispatch it to the fmd-self-diagnosis engine. */ if (mp != fmd.d_self && (raw_err != EFMD_HDL_ABORT || fmd.d_running)) { if ((c = msg[len1 + len2 - 1]) == '\n') msg[len1 + len2 - 1] = '\0'; /* strip \n for event */ nvl = fmd_protocol_moderror(mp, err, msg); if (c == '\n') msg[len1 + len2 - 1] = c; (void) nvlist_lookup_string(nvl, FM_CLASS, &class); e = fmd_event_create(FMD_EVT_PROTOCOL, FMD_HRT_NOW, nvl, class); (void) pthread_rwlock_rdlock(&fmd.d_log_lock); fmd_log_append(fmd.d_errlog, e, NULL); (void) pthread_rwlock_unlock(&fmd.d_log_lock); fmd_event_transition(e, FMD_EVS_ACCEPTED); fmd_event_commit(e); fmd_dispq_dispatch(fmd.d_disp, e, class); } /* * Similar to fmd_vdebug(), if the debugging switches are enabled we * echo the module name and message to stderr and/or syslog. Unlike * fmd_vdebug(), we also print to stderr if foreground mode is enabled. * We also print the message if a built-in module is aborting before * fmd has detached from its parent (e.g. default transport failure). */ if (fmd.d_fg || (fmd.d_hdl_dbout & FMD_DBOUT_STDERR) || ( raw_err == EFMD_HDL_ABORT && !fmd.d_running)) { (void) pthread_mutex_lock(&fmd.d_err_lock); (void) fprintf(stderr, "%s: %s: %s", fmd.d_pname, mp->mod_name, msg); (void) pthread_mutex_unlock(&fmd.d_err_lock); } if (fmd.d_hdl_dbout & FMD_DBOUT_SYSLOG) { syslog(LOG_ERR | LOG_DAEMON, "%s ERROR: %s: %s", fmd.d_pname, mp->mod_name, msg); } fmd_free(msg, len1 + len2 + 1); } /*PRINTFLIKE3*/ static void fmd_api_xerror(fmd_module_t *mp, int err, const char *format, ...) { va_list ap; va_start(ap, format); fmd_api_vxerror(mp, err, format, ap); va_end(ap); } /* * fmd_api_verror() is a wrapper around fmd_api_vxerror() for API subroutines. * It calls fmd_module_unlock() on behalf of its caller, logs the error, and * then aborts the API call and the surrounding module entry point by doing an * fmd_module_abort(), which longjmps to the place where we entered the module. */ static void fmd_api_verror(fmd_module_t *mp, int err, const char *format, va_list ap) { if (fmd_module_locked(mp)) fmd_module_unlock(mp); fmd_api_vxerror(mp, err, format, ap); fmd_module_abort(mp, err); } /*PRINTFLIKE3*/ static void fmd_api_error(fmd_module_t *mp, int err, const char *format, ...) { va_list ap; va_start(ap, format); fmd_api_verror(mp, err, format, ap); va_end(ap); } /* * Common code for fmd_api_module_lock() and fmd_api_transport_impl(). This * code verifies that the handle is valid and associated with a proper thread. */ static fmd_module_t * fmd_api_module(fmd_hdl_t *hdl) { fmd_thread_t *tp; fmd_module_t *mp; /* * If our TSD is not present at all, this is either a serious bug or * someone has created a thread behind our back and is using fmd's API. * We can't call fmd_api_error() because we can't be sure that we can * unwind our state back to an enclosing fmd_module_dispatch(), so we * must panic instead. This is likely a module design or coding error. */ if ((tp = pthread_getspecific(fmd.d_key)) == NULL) { fmd_panic("fmd module api call made using " "client handle %p from unknown thread\n", (void *)hdl); } /* * If our TSD refers to the root module and is a door server thread, * then it was created asynchronously at the request of a module but * is using now the module API as an auxiliary module thread. We reset * tp->thr_mod to the module handle so it can act as a module thread. */ if (tp->thr_mod == fmd.d_rmod && tp->thr_func == &fmd_door_server) tp->thr_mod = (fmd_module_t *)hdl; if ((mp = tp->thr_mod) != (fmd_module_t *)hdl) { fmd_api_error(mp, EFMD_HDL_INVAL, "client handle %p is not valid\n", (void *)hdl); } if (mp->mod_flags & FMD_MOD_FAIL) { fmd_api_error(mp, EFMD_MOD_FAIL, "module has experienced an unrecoverable error\n"); } return (mp); } /* * fmd_api_module_lock() is used as a wrapper around fmd_module_lock() and a * common prologue to each fmd_api.c routine. It verifies that the handle is * valid and owned by the current server thread, locks the handle, and then * verifies that the caller is performing an operation on a registered handle. * If any tests fail, the entire API call is aborted by fmd_api_error(). */ static fmd_module_t * fmd_api_module_lock(fmd_hdl_t *hdl) { fmd_module_t *mp = fmd_api_module(hdl); fmd_module_lock(mp); if (mp->mod_info == NULL) { fmd_api_error(mp, EFMD_HDL_NOTREG, "client handle %p has not been registered\n", (void *)hdl); } return (mp); } /* * Utility function for API entry points that accept fmd_case_t's. We cast cp * to fmd_case_impl_t and check to make sure the case is owned by the caller. */ static fmd_case_impl_t * fmd_api_case_impl(fmd_module_t *mp, fmd_case_t *cp) { fmd_case_impl_t *cip = (fmd_case_impl_t *)cp; if (cip == NULL || cip->ci_mod != mp) { fmd_api_error(mp, EFMD_CASE_OWNER, "case %p is invalid or not owned by caller\n", (void *)cip); } return (cip); } /* * Utility function for API entry points that accept fmd_xprt_t's. We cast xp * to fmd_transport_t and check to make sure the case is owned by the caller. * Note that we could make this check safer by actually walking mp's transport * list, but that requires holding the module lock and this routine needs to be * MT-hot w.r.t. auxiliary module threads. Ultimately any loadable module can * cause us to crash anyway, so we optimize for scalability over safety here. */ static fmd_xprt_impl_t * fmd_api_transport_impl(fmd_hdl_t *hdl, fmd_xprt_t *xp) { fmd_module_t *mp = fmd_api_module(hdl); fmd_xprt_impl_t *xip = (fmd_xprt_impl_t *)xp; if (xip == NULL || xip->xi_queue->eq_mod != mp) { fmd_api_error(mp, EFMD_XPRT_OWNER, "xprt %p is invalid or not owned by caller\n", (void *)xp); } return (xip); } /* * fmd_hdl_register() is the one function which cannot use fmd_api_error() to * report errors, because that routine causes the module to abort. Failure to * register is instead handled by having fmd_hdl_register() return an error to * the _fmd_init() function and then detecting no registration when it returns. * So we use this routine for fmd_hdl_register() error paths instead. */ static int fmd_hdl_register_error(fmd_module_t *mp, int err) { if (fmd_module_locked(mp)) fmd_module_unlock(mp); fmd_api_xerror(mp, err, "failed to register"); return (fmd_set_errno(err)); } static void fmd_hdl_nop(void) { /* empty function for use with unspecified module entry points */ } int fmd_hdl_register(fmd_hdl_t *hdl, int version, const fmd_hdl_info_t *mip) { fmd_thread_t *tp = pthread_getspecific(fmd.d_key); fmd_module_t *mp = tp->thr_mod; const fmd_prop_t *prop; const fmd_conf_path_t *pap; fmd_conf_formal_t *cfp; fmd_hdl_ops_t ops; const char *conf = NULL; char buf[PATH_MAX]; int i; if (mp != (fmd_module_t *)hdl) return (fmd_hdl_register_error(mp, EFMD_HDL_INVAL)); fmd_module_lock(mp); /* * First perform some sanity checks on our input. The API version must * be supported by FMD and the handle can only be registered once by * the module thread to which we assigned this client handle. The info * provided for the handle must be valid and have the minimal settings. */ if (version > FMD_API_VERSION_4) return (fmd_hdl_register_error(mp, EFMD_VER_NEW)); if (version < FMD_API_VERSION_1) return (fmd_hdl_register_error(mp, EFMD_VER_OLD)); if (mp->mod_conf != NULL) return (fmd_hdl_register_error(mp, EFMD_HDL_REG)); if (pthread_self() != mp->mod_thread->thr_tid) return (fmd_hdl_register_error(mp, EFMD_HDL_TID)); if (mip == NULL || mip->fmdi_desc == NULL || mip->fmdi_vers == NULL || mip->fmdi_ops == NULL) return (fmd_hdl_register_error(mp, EFMD_HDL_INFO)); /* * Copy the module's ops vector into a local variable to account for * changes in the module ABI. Then if any of the optional entry points * are NULL, set them to nop so we don't have to check before calling. */ bzero(&ops, sizeof (ops)); if (version < FMD_API_VERSION_3) bcopy(mip->fmdi_ops, &ops, offsetof(fmd_hdl_ops_t, fmdo_send)); else if (version < FMD_API_VERSION_4) bcopy(mip->fmdi_ops, &ops, offsetof(fmd_hdl_ops_t, fmdo_topo)); else bcopy(mip->fmdi_ops, &ops, sizeof (ops)); if (ops.fmdo_recv == NULL) ops.fmdo_recv = (void (*)())fmd_hdl_nop; if (ops.fmdo_timeout == NULL) ops.fmdo_timeout = (void (*)())fmd_hdl_nop; if (ops.fmdo_close == NULL) ops.fmdo_close = (void (*)())fmd_hdl_nop; if (ops.fmdo_stats == NULL) ops.fmdo_stats = (void (*)())fmd_hdl_nop; if (ops.fmdo_gc == NULL) ops.fmdo_gc = (void (*)())fmd_hdl_nop; if (ops.fmdo_send == NULL) ops.fmdo_send = (int (*)())fmd_hdl_nop; if (ops.fmdo_topo == NULL) ops.fmdo_topo = (void (*)())fmd_hdl_nop; /* * Make two passes through the property array to initialize the formals * to use for processing the module's .conf file. In the first pass, * we validate the types and count the number of properties. In the * second pass we copy the strings and fill in the appropriate ops. */ for (prop = mip->fmdi_props, i = 0; prop != NULL && prop->fmdp_name != NULL; prop++, i++) { if (prop->fmdp_type >= sizeof (_fmd_prop_ops) / sizeof (_fmd_prop_ops[0])) { fmd_api_xerror(mp, EFMD_HDL_PROP, "property %s uses invalid type %u\n", prop->fmdp_name, prop->fmdp_type); return (fmd_hdl_register_error(mp, EFMD_HDL_PROP)); } } mp->mod_argc = i; mp->mod_argv = fmd_zalloc(sizeof (fmd_conf_formal_t) * i, FMD_SLEEP); prop = mip->fmdi_props; cfp = mp->mod_argv; for (i = 0; i < mp->mod_argc; i++, prop++, cfp++) { cfp->cf_name = fmd_strdup(prop->fmdp_name, FMD_SLEEP); cfp->cf_ops = _fmd_prop_ops[prop->fmdp_type]; cfp->cf_default = fmd_strdup(prop->fmdp_defv, FMD_SLEEP); } /* * If this module came from an on-disk file, compute the name of the * corresponding .conf file and parse properties from it if it exists. */ if (mp->mod_path != NULL) { (void) strlcpy(buf, mp->mod_path, sizeof (buf)); (void) fmd_strdirname(buf); (void) strlcat(buf, "/", sizeof (buf)); (void) strlcat(buf, mp->mod_name, sizeof (buf)); (void) strlcat(buf, ".conf", sizeof (buf)); if (access(buf, F_OK) == 0) conf = buf; } if ((mp->mod_conf = fmd_conf_open(conf, mp->mod_argc, mp->mod_argv, 0)) == NULL) return (fmd_hdl_register_error(mp, EFMD_MOD_CONF)); fmd_conf_propagate(fmd.d_conf, mp->mod_conf, mp->mod_name); /* * Look up the list of the libdiagcode dictionaries associated with the * module. If none were specified, use the value from daemon's config. * We only fail if the module specified an explicit dictionary. */ (void) fmd_conf_getprop(mp->mod_conf, FMD_PROP_DICTIONARIES, &pap); if (pap->cpa_argc == 0 && mp->mod_ops == &fmd_bltin_ops) (void) fmd_conf_getprop(fmd.d_conf, "self.dict", &pap); for (i = 0; i < pap->cpa_argc; i++) { if (fmd_module_dc_opendict(mp, pap->cpa_argv[i]) != 0) { fmd_api_xerror(mp, errno, "failed to open dictionary %s", pap->cpa_argv[i]); return (fmd_hdl_register_error(mp, EFMD_MOD_CONF)); } } /* * Make a copy of the handle information and store it in mod_info. We * do not need to bother copying fmdi_props since they're already read. */ mp->mod_info = fmd_alloc(sizeof (fmd_hdl_info_t), FMD_SLEEP); mp->mod_info->fmdi_desc = fmd_strdup(mip->fmdi_desc, FMD_SLEEP); mp->mod_info->fmdi_vers = fmd_strdup(mip->fmdi_vers, FMD_SLEEP); mp->mod_info->fmdi_ops = fmd_alloc(sizeof (fmd_hdl_ops_t), FMD_SLEEP); bcopy(&ops, (void *)mp->mod_info->fmdi_ops, sizeof (fmd_hdl_ops_t)); mp->mod_info->fmdi_props = NULL; /* * Allocate an FMRI representing this module. We'll use this later * if the module decides to publish any events (e.g. list.suspects). */ mp->mod_fmri = fmd_protocol_fmri_module(mp); /* * Any subscriptions specified in the conf file are now stored in the * corresponding property. Add all of these to the dispatch queue. */ (void) fmd_conf_getprop(mp->mod_conf, FMD_PROP_SUBSCRIPTIONS, &pap); for (i = 0; i < pap->cpa_argc; i++) { fmd_dispq_insert(fmd.d_disp, mp->mod_queue, pap->cpa_argv[i]); fmd_xprt_subscribe_all(pap->cpa_argv[i]); } /* * Unlock the module and restore any pre-existing module checkpoint. * If the checkpoint is missing or corrupt, we just keep going. */ fmd_module_unlock(mp); fmd_ckpt_restore(mp); return (0); } /* * If an auxiliary thread exists for the specified module at unregistration * time, send it an asynchronous cancellation to force it to exit and then * join with it (we expect this to either succeed quickly or return ESRCH). * Once this is complete we can destroy the associated fmd_thread_t data. */ static void fmd_module_thrcancel(fmd_idspace_t *ids, id_t id, fmd_module_t *mp) { fmd_thread_t *tp = fmd_idspace_getspecific(ids, id); fmd_dprintf(FMD_DBG_MOD, "cancelling %s auxiliary thread %u\n", mp->mod_name, tp->thr_tid); ASSERT(tp->thr_tid == id); (void) pthread_cancel(tp->thr_tid); (void) pthread_join(tp->thr_tid, NULL); fmd_thread_destroy(tp, FMD_THREAD_NOJOIN); } void fmd_module_unregister(fmd_module_t *mp) { fmd_conf_formal_t *cfp = mp->mod_argv; const fmd_conf_path_t *pap; fmd_case_t *cp; fmd_xprt_t *xp; int i; TRACE((FMD_DBG_MOD, "unregister %p (%s)", (void *)mp, mp->mod_name)); ASSERT(fmd_module_locked(mp)); /* * If any transports are still open, they have send threads that are * using the module handle: shut them down and join with these threads. */ while ((xp = fmd_list_next(&mp->mod_transports)) != NULL) fmd_xprt_destroy(xp); /* * If any auxiliary threads exist, they may be using our module handle, * and therefore could cause a fault as soon as we start destroying it. * Module writers should clean up any threads before unregistering: we * forcibly cancel any remaining auxiliary threads before proceeding. */ fmd_idspace_apply(mp->mod_threads, (void (*)())fmd_module_thrcancel, mp); if (mp->mod_error == 0) fmd_ckpt_save(mp); /* take one more checkpoint if needed */ /* * Delete any cases associated with the module (UNSOLVED, SOLVED, or * CLOSE_WAIT) as if fmdo_close() has finished processing them. */ while ((cp = fmd_list_next(&mp->mod_cases)) != NULL) fmd_case_delete(cp); fmd_ustat_delete_references(mp->mod_ustat); (void) fmd_conf_getprop(mp->mod_conf, FMD_PROP_SUBSCRIPTIONS, &pap); for (i = 0; i < pap->cpa_argc; i++) { fmd_xprt_unsubscribe_all(pap->cpa_argv[i]); fmd_dispq_delete(fmd.d_disp, mp->mod_queue, pap->cpa_argv[i]); } fmd_conf_close(mp->mod_conf); mp->mod_conf = NULL; for (i = 0; i < mp->mod_argc; i++, cfp++) { fmd_strfree((char *)cfp->cf_name); fmd_strfree((char *)cfp->cf_default); } fmd_free(mp->mod_argv, sizeof (fmd_conf_formal_t) * mp->mod_argc); mp->mod_argv = NULL; mp->mod_argc = 0; nvlist_free(mp->mod_fmri); mp->mod_fmri = NULL; fmd_strfree((char *)mp->mod_info->fmdi_desc); fmd_strfree((char *)mp->mod_info->fmdi_vers); fmd_free((void *)mp->mod_info->fmdi_ops, sizeof (fmd_hdl_ops_t)); fmd_free(mp->mod_info, sizeof (fmd_hdl_info_t)); mp->mod_info = NULL; fmd_eventq_abort(mp->mod_queue); } void fmd_hdl_unregister(fmd_hdl_t *hdl) { fmd_module_t *mp = fmd_api_module_lock(hdl); fmd_module_unregister(mp); fmd_module_unlock(mp); } void fmd_hdl_subscribe(fmd_hdl_t *hdl, const char *class) { fmd_module_t *mp = fmd_api_module_lock(hdl); if (fmd_conf_setprop(mp->mod_conf, FMD_PROP_SUBSCRIPTIONS, class) == 0) { fmd_dispq_insert(fmd.d_disp, mp->mod_queue, class); fmd_xprt_subscribe_all(class); } fmd_module_unlock(mp); } void fmd_hdl_unsubscribe(fmd_hdl_t *hdl, const char *class) { fmd_module_t *mp = fmd_api_module_lock(hdl); if (fmd_conf_delprop(mp->mod_conf, FMD_PROP_SUBSCRIPTIONS, class) == 0) { fmd_xprt_unsubscribe_all(class); fmd_dispq_delete(fmd.d_disp, mp->mod_queue, class); } fmd_module_unlock(mp); fmd_eventq_cancel(mp->mod_queue, FMD_EVT_PROTOCOL, (void *)class); } void fmd_hdl_setspecific(fmd_hdl_t *hdl, void *spec) { fmd_module_t *mp = fmd_api_module_lock(hdl); mp->mod_spec = spec; fmd_module_unlock(mp); } void * fmd_hdl_getspecific(fmd_hdl_t *hdl) { fmd_module_t *mp = fmd_api_module_lock(hdl); void *spec = mp->mod_spec; fmd_module_unlock(mp); return (spec); } void fmd_hdl_opendict(fmd_hdl_t *hdl, const char *dict) { fmd_module_t *mp = fmd_api_module_lock(hdl); const fmd_conf_path_t *pap; int i; /* * Update the dictionary property in order to preserve the list of * pathnames and expand any % tokens in the path. Then retrieve the * new dictionary names from cpa_argv[] and open them one at a time. */ (void) fmd_conf_setprop(mp->mod_conf, FMD_PROP_DICTIONARIES, dict); (void) fmd_conf_getprop(mp->mod_conf, FMD_PROP_DICTIONARIES, &pap); ASSERT(pap->cpa_argc > mp->mod_dictc); for (i = mp->mod_dictc; i < pap->cpa_argc; i++) { if (fmd_module_dc_opendict(mp, pap->cpa_argv[i]) != 0) { fmd_api_error(mp, EFMD_MOD_DICT, "failed to open dictionary %s for module %s", pap->cpa_argv[i], mp->mod_name); } } fmd_module_unlock(mp); } topo_hdl_t * fmd_hdl_topo_hold(fmd_hdl_t *hdl, int v) { fmd_module_t *mp = fmd_api_module_lock(hdl); topo_hdl_t *thp; if (v != TOPO_VERSION) { fmd_api_error(mp, EFMD_MOD_TOPO, "libtopo version mismatch: " "fmd version %d != client version %d\n", TOPO_VERSION, v); } thp = fmd_module_topo_hold(mp); ASSERT(thp != NULL); fmd_module_unlock(mp); return (thp); } void fmd_hdl_topo_rele(fmd_hdl_t *hdl, topo_hdl_t *thp) { fmd_module_t *mp = fmd_api_module_lock(hdl); if (fmd_module_topo_rele(mp, thp) != 0) fmd_api_error(mp, EFMD_MOD_TOPO, "failed to release invalid " "topo handle: %p\n", (void *)thp); fmd_module_unlock(mp); } void * fmd_hdl_alloc(fmd_hdl_t *hdl, size_t size, int flags) { fmd_module_t *mp = fmd_api_module_lock(hdl); void *data; if (mp->mod_stats->ms_memlimit.fmds_value.ui64 - mp->mod_stats->ms_memtotal.fmds_value.ui64 < size) { fmd_api_error(mp, EFMD_HDL_NOMEM, "%s's allocation of %lu " "bytes exceeds module memory limit (%llu)\n", mp->mod_name, (ulong_t)size, (u_longlong_t) mp->mod_stats->ms_memtotal.fmds_value.ui64); } if ((data = fmd_alloc(size, flags)) != NULL) mp->mod_stats->ms_memtotal.fmds_value.ui64 += size; fmd_module_unlock(mp); return (data); } void * fmd_hdl_zalloc(fmd_hdl_t *hdl, size_t size, int flags) { void *data = fmd_hdl_alloc(hdl, size, flags); if (data != NULL) bzero(data, size); return (data); } void fmd_hdl_free(fmd_hdl_t *hdl, void *data, size_t size) { fmd_module_t *mp = fmd_api_module_lock(hdl); fmd_free(data, size); mp->mod_stats->ms_memtotal.fmds_value.ui64 -= size; fmd_module_unlock(mp); } char * fmd_hdl_strdup(fmd_hdl_t *hdl, const char *s, int flags) { char *p; if (s != NULL) p = fmd_hdl_alloc(hdl, strlen(s) + 1, flags); else p = NULL; if (p != NULL) (void) strcpy(p, s); return (p); } void fmd_hdl_strfree(fmd_hdl_t *hdl, char *s) { if (s != NULL) fmd_hdl_free(hdl, s, strlen(s) + 1); } void fmd_hdl_vabort(fmd_hdl_t *hdl, const char *format, va_list ap) { fmd_api_verror(fmd_api_module_lock(hdl), EFMD_HDL_ABORT, format, ap); } /*PRINTFLIKE2*/ void fmd_hdl_abort(fmd_hdl_t *hdl, const char *format, ...) { fmd_module_t *mp = fmd_api_module_lock(hdl); va_list ap; va_start(ap, format); fmd_api_verror(mp, EFMD_HDL_ABORT, format, ap); va_end(ap); } void fmd_hdl_verror(fmd_hdl_t *hdl, const char *format, va_list ap) { fmd_module_t *mp = fmd_api_module_lock(hdl); fmd_api_vxerror(mp, errno, format, ap); fmd_module_unlock(mp); } /*PRINTFLIKE2*/ void fmd_hdl_error(fmd_hdl_t *hdl, const char *format, ...) { va_list ap; va_start(ap, format); fmd_hdl_verror(hdl, format, ap); va_end(ap); } void fmd_hdl_vdebug(fmd_hdl_t *hdl, const char *format, va_list ap) { fmd_module_t *mp = fmd_api_module_lock(hdl); char *msg; size_t len; char c; if (!(fmd.d_hdl_debug)) { mp->mod_stats->ms_debugdrop.fmds_value.ui64++; fmd_module_unlock(mp); return; } len = vsnprintf(&c, 1, format, ap); if ((msg = fmd_alloc(len + 2, FMD_NOSLEEP)) == NULL) { mp->mod_stats->ms_debugdrop.fmds_value.ui64++; fmd_module_unlock(mp); return; } (void) vsnprintf(msg, len + 1, format, ap); if (msg[len - 1] != '\n') (void) strcpy(&msg[len], "\n"); if (fmd.d_hdl_dbout & FMD_DBOUT_STDERR) { (void) pthread_mutex_lock(&fmd.d_err_lock); (void) fprintf(stderr, "%s DEBUG: %s: %s", fmd.d_pname, mp->mod_name, msg); (void) pthread_mutex_unlock(&fmd.d_err_lock); } if (fmd.d_hdl_dbout & FMD_DBOUT_SYSLOG) { syslog(LOG_DEBUG | LOG_DAEMON, "%s DEBUG: %s: %s", fmd.d_pname, mp->mod_name, msg); } fmd_free(msg, len + 2); fmd_module_unlock(mp); } /*PRINTFLIKE2*/ void fmd_hdl_debug(fmd_hdl_t *hdl, const char *format, ...) { va_list ap; va_start(ap, format); fmd_hdl_vdebug(hdl, format, ap); va_end(ap); } int32_t fmd_prop_get_int32(fmd_hdl_t *hdl, const char *name) { fmd_module_t *mp = fmd_api_module_lock(hdl); const fmd_conf_ops_t *ops = fmd_conf_gettype(mp->mod_conf, name); int32_t value = 0; if (ops == &fmd_conf_bool || ops == &fmd_conf_int32 || ops == &fmd_conf_uint32) (void) fmd_conf_getprop(mp->mod_conf, name, &value); else if (ops != NULL) { fmd_api_error(mp, EFMD_PROP_TYPE, "property %s is not of int32 type\n", name); } else { fmd_api_error(mp, EFMD_PROP_DEFN, "property %s is not defined\n", name); } fmd_module_unlock(mp); return (value); } int64_t fmd_prop_get_int64(fmd_hdl_t *hdl, const char *name) { fmd_module_t *mp = fmd_api_module_lock(hdl); const fmd_conf_ops_t *ops = fmd_conf_gettype(mp->mod_conf, name); int64_t value = 0; if (ops == &fmd_conf_int64 || ops == &fmd_conf_uint64 || ops == &fmd_conf_time || ops == &fmd_conf_size) (void) fmd_conf_getprop(mp->mod_conf, name, &value); else if (ops != NULL) { fmd_api_error(mp, EFMD_PROP_TYPE, "property %s is not of int64 type\n", name); } else { fmd_api_error(mp, EFMD_PROP_DEFN, "property %s is not defined\n", name); } fmd_module_unlock(mp); return (value); } char * fmd_prop_get_string(fmd_hdl_t *hdl, const char *name) { fmd_module_t *mp = fmd_api_module_lock(hdl); const fmd_conf_ops_t *ops = fmd_conf_gettype(mp->mod_conf, name); char *value = NULL; const char *s; if (ops == &fmd_conf_string) { (void) fmd_conf_getprop(mp->mod_conf, name, &s); value = fmd_strdup(s, FMD_SLEEP); } else if (ops != NULL) { fmd_api_error(mp, EFMD_PROP_TYPE, "property %s is not of string type\n", name); } else { fmd_api_error(mp, EFMD_PROP_DEFN, "property %s is not defined\n", name); } fmd_module_unlock(mp); return (value); } void fmd_prop_free_string(fmd_hdl_t *hdl, char *s) { fmd_module_t *mp = fmd_api_module_lock(hdl); fmd_strfree(s); fmd_module_unlock(mp); } fmd_stat_t * fmd_stat_create(fmd_hdl_t *hdl, uint_t flags, uint_t argc, fmd_stat_t *argv) { fmd_module_t *mp = fmd_api_module_lock(hdl); fmd_stat_t *ep, *sp; if (flags & ~FMD_STAT_ALLOC) { fmd_api_error(mp, EFMD_STAT_FLAGS, "invalid flags 0x%x passed to fmd_stat_create\n", flags); } if ((sp = fmd_ustat_insert(mp->mod_ustat, flags | FMD_USTAT_VALIDATE, argc, argv, &ep)) == NULL) { fmd_api_error(mp, errno, "failed to publish stat '%s'", ep->fmds_name); } fmd_module_unlock(mp); return (sp); } void fmd_stat_destroy(fmd_hdl_t *hdl, uint_t argc, fmd_stat_t *argv) { fmd_module_t *mp = fmd_api_module_lock(hdl); fmd_ustat_delete(mp->mod_ustat, argc, argv); fmd_module_unlock(mp); } void fmd_stat_setstr(fmd_hdl_t *hdl, fmd_stat_t *sp, const char *s) { char *str = fmd_strdup(s, FMD_SLEEP); fmd_module_t *mp = fmd_api_module_lock(hdl); if (sp->fmds_type != FMD_TYPE_STRING) { fmd_strfree(str); fmd_api_error(mp, EFMD_STAT_TYPE, "stat '%s' is not a string\n", sp->fmds_name); } fmd_strfree(sp->fmds_value.str); sp->fmds_value.str = str; fmd_module_unlock(mp); } fmd_case_t * fmd_case_open(fmd_hdl_t *hdl, void *data) { fmd_module_t *mp = fmd_api_module_lock(hdl); fmd_case_t *cp = fmd_case_create(mp, data); fmd_module_unlock(mp); return (cp); } void fmd_case_reset(fmd_hdl_t *hdl, fmd_case_t *cp) { fmd_module_t *mp = fmd_api_module_lock(hdl); fmd_case_impl_t *cip = fmd_api_case_impl(mp, cp); if (cip->ci_state >= FMD_CASE_SOLVED) { fmd_api_error(mp, EFMD_CASE_STATE, "cannot solve %s: " "case is already solved or closed\n", cip->ci_uuid); } fmd_case_reset_suspects(cp); fmd_module_unlock(mp); } void fmd_case_solve(fmd_hdl_t *hdl, fmd_case_t *cp) { fmd_module_t *mp = fmd_api_module_lock(hdl); fmd_case_impl_t *cip = fmd_api_case_impl(mp, cp); if (cip->ci_state >= FMD_CASE_SOLVED) { fmd_api_error(mp, EFMD_CASE_STATE, "cannot solve %s: " "case is already solved or closed\n", cip->ci_uuid); } fmd_case_transition(cp, FMD_CASE_SOLVED, FMD_CF_SOLVED); fmd_module_unlock(mp); } void fmd_case_close(fmd_hdl_t *hdl, fmd_case_t *cp) { fmd_module_t *mp = fmd_api_module_lock(hdl); (void) fmd_api_case_impl(mp, cp); /* validate 'cp' */ fmd_case_transition(cp, FMD_CASE_CLOSE_WAIT, FMD_CF_ISOLATED); fmd_module_unlock(mp); } const char * fmd_case_uuid(fmd_hdl_t *hdl, fmd_case_t *cp) { fmd_module_t *mp = fmd_api_module_lock(hdl); fmd_case_impl_t *cip = fmd_api_case_impl(mp, cp); const char *uuid = cip->ci_uuid; fmd_module_unlock(mp); return (uuid); } fmd_case_t * fmd_case_uulookup(fmd_hdl_t *hdl, const char *uuid) { fmd_module_t *cmp, *mp = fmd_api_module_lock(hdl); fmd_case_t *cp = fmd_case_hash_lookup(fmd.d_cases, uuid); if (cp != NULL) { cmp = ((fmd_case_impl_t *)cp)->ci_mod; fmd_case_rele(cp); } else cmp = NULL; fmd_module_unlock(mp); return (cmp == mp ? cp : NULL); } void fmd_case_uuclose(fmd_hdl_t *hdl, const char *uuid) { fmd_module_t *mp = fmd_api_module_lock(hdl); fmd_case_t *cp = fmd_case_hash_lookup(fmd.d_cases, uuid); if (cp != NULL) { fmd_case_transition(cp, FMD_CASE_CLOSE_WAIT, FMD_CF_ISOLATED); fmd_case_rele(cp); } fmd_module_unlock(mp); } int fmd_case_uuclosed(fmd_hdl_t *hdl, const char *uuid) { fmd_module_t *mp = fmd_api_module_lock(hdl); fmd_case_t *cp = fmd_case_hash_lookup(fmd.d_cases, uuid); fmd_case_impl_t *cip = (fmd_case_impl_t *)cp; int rv = FMD_B_TRUE; if (cip != NULL) { rv = cip->ci_state >= FMD_CASE_CLOSE_WAIT; fmd_case_rele(cp); } fmd_module_unlock(mp); return (rv); } static int fmd_case_instate(fmd_hdl_t *hdl, fmd_case_t *cp, uint_t state) { fmd_module_t *mp = fmd_api_module_lock(hdl); fmd_case_impl_t *cip = fmd_api_case_impl(mp, cp); int rv = cip->ci_state >= state; fmd_module_unlock(mp); return (rv); } int fmd_case_solved(fmd_hdl_t *hdl, fmd_case_t *cp) { return (fmd_case_instate(hdl, cp, FMD_CASE_SOLVED)); } int fmd_case_closed(fmd_hdl_t *hdl, fmd_case_t *cp) { return (fmd_case_instate(hdl, cp, FMD_CASE_CLOSE_WAIT)); } void fmd_case_add_ereport(fmd_hdl_t *hdl, fmd_case_t *cp, fmd_event_t *ep) { fmd_module_t *mp = fmd_api_module_lock(hdl); (void) fmd_api_case_impl(mp, cp); /* validate 'cp' */ if (fmd_case_insert_event(cp, ep)) mp->mod_stats->ms_accepted.fmds_value.ui64++; fmd_module_unlock(mp); } void fmd_case_add_serd(fmd_hdl_t *hdl, fmd_case_t *cp, const char *name) { fmd_module_t *mp = fmd_api_module_lock(hdl); fmd_serd_elem_t *sep; fmd_serd_eng_t *sgp; if ((sgp = fmd_serd_eng_lookup(&mp->mod_serds, name)) == NULL) { fmd_api_error(mp, EFMD_SERD_NAME, "failed to add events from serd engine '%s'", name); } (void) fmd_api_case_impl(mp, cp); /* validate 'cp' */ for (sep = fmd_list_next(&sgp->sg_list); sep != NULL; sep = fmd_list_next(sep)) { if (fmd_case_insert_event(cp, sep->se_event)) mp->mod_stats->ms_accepted.fmds_value.ui64++; } fmd_module_unlock(mp); } void fmd_case_add_suspect(fmd_hdl_t *hdl, fmd_case_t *cp, nvlist_t *nvl) { fmd_module_t *mp = fmd_api_module_lock(hdl); fmd_case_impl_t *cip = fmd_api_case_impl(mp, cp); char *class; if (cip->ci_state >= FMD_CASE_SOLVED) { fmd_api_error(mp, EFMD_CASE_STATE, "cannot add suspect to " "%s: case is already solved or closed\n", cip->ci_uuid); } if (nvlist_lookup_string(nvl, FM_CLASS, &class) != 0 || class == NULL || *class == '\0') { fmd_api_error(mp, EFMD_CASE_EVENT, "cannot add suspect to " "%s: suspect event is missing a class\n", cip->ci_uuid); } fmd_case_insert_suspect(cp, nvl); fmd_module_unlock(mp); } void fmd_case_setspecific(fmd_hdl_t *hdl, fmd_case_t *cp, void *data) { fmd_module_t *mp = fmd_api_module_lock(hdl); fmd_case_impl_t *cip = fmd_api_case_impl(mp, cp); (void) pthread_mutex_lock(&cip->ci_lock); cip->ci_data = data; (void) pthread_mutex_unlock(&cip->ci_lock); fmd_module_unlock(mp); } void * fmd_case_getspecific(fmd_hdl_t *hdl, fmd_case_t *cp) { fmd_module_t *mp = fmd_api_module_lock(hdl); fmd_case_impl_t *cip = fmd_api_case_impl(mp, cp); void *data; (void) pthread_mutex_lock(&cip->ci_lock); data = cip->ci_data; (void) pthread_mutex_unlock(&cip->ci_lock); fmd_module_unlock(mp); return (data); } void fmd_case_setprincipal(fmd_hdl_t *hdl, fmd_case_t *cp, fmd_event_t *ep) { fmd_module_t *mp = fmd_api_module_lock(hdl); (void) fmd_api_case_impl(mp, cp); /* validate 'cp' */ if (fmd_case_insert_principal(cp, ep)) mp->mod_stats->ms_accepted.fmds_value.ui64++; fmd_module_unlock(mp); } fmd_event_t * fmd_case_getprincipal(fmd_hdl_t *hdl, fmd_case_t *cp) { fmd_module_t *mp = fmd_api_module_lock(hdl); fmd_case_impl_t *cip = fmd_api_case_impl(mp, cp); fmd_event_t *ep; (void) pthread_mutex_lock(&cip->ci_lock); ep = cip->ci_principal; (void) pthread_mutex_unlock(&cip->ci_lock); fmd_module_unlock(mp); return (ep); } fmd_case_t * fmd_case_next(fmd_hdl_t *hdl, fmd_case_t *cp) { fmd_module_t *mp = fmd_api_module_lock(hdl); if (cp != NULL) cp = fmd_list_next(fmd_api_case_impl(mp, cp)); else cp = fmd_list_next(&mp->mod_cases); fmd_module_unlock(mp); return (cp); } fmd_case_t * fmd_case_prev(fmd_hdl_t *hdl, fmd_case_t *cp) { fmd_module_t *mp = fmd_api_module_lock(hdl); if (cp != NULL) cp = fmd_list_prev(fmd_api_case_impl(mp, cp)); else cp = fmd_list_prev(&mp->mod_cases); fmd_module_unlock(mp); return (cp); } /* * Utility function for fmd_buf_* routines. If a case is specified, use the * case's ci_bufs hash; otherwise use the module's global mod_bufs hash. */ static fmd_buf_hash_t * fmd_buf_gethash(fmd_module_t *mp, fmd_case_t *cp) { return (cp ? &fmd_api_case_impl(mp, cp)->ci_bufs : &mp->mod_bufs); } void fmd_buf_create(fmd_hdl_t *hdl, fmd_case_t *cp, const char *name, size_t size) { fmd_module_t *mp = fmd_api_module_lock(hdl); fmd_buf_hash_t *bhp = fmd_buf_gethash(mp, cp); fmd_buf_t *bp = fmd_buf_lookup(bhp, name); if (bp == NULL) { if (fmd_strbadid(name, FMD_B_TRUE) != NULL || size == 0) { fmd_api_error(mp, EFMD_BUF_INVAL, "cannot create '%s' " "(size %lu): %s\n", name, (ulong_t)size, fmd_strerror(EFMD_BUF_INVAL)); } if (mp->mod_stats->ms_buflimit.fmds_value.ui64 - mp->mod_stats->ms_buftotal.fmds_value.ui64 < size) { fmd_api_error(mp, EFMD_BUF_LIMIT, "cannot create '%s': " "buf limit exceeded (%llu)\n", name, (u_longlong_t) mp->mod_stats->ms_buflimit.fmds_value.ui64); } mp->mod_stats->ms_buftotal.fmds_value.ui64 += size; bp = fmd_buf_insert(bhp, name, size); } else { fmd_api_error(mp, EFMD_BUF_EXISTS, "cannot create '%s': buffer already exists\n", name); } if (cp != NULL) fmd_case_setdirty(cp); else fmd_module_setdirty(mp); fmd_module_unlock(mp); } void fmd_buf_destroy(fmd_hdl_t *hdl, fmd_case_t *cp, const char *name) { fmd_module_t *mp = fmd_api_module_lock(hdl); fmd_buf_hash_t *bhp = fmd_buf_gethash(mp, cp); fmd_buf_t *bp = fmd_buf_lookup(bhp, name); if (bp != NULL) { mp->mod_stats->ms_buftotal.fmds_value.ui64 -= bp->buf_size; fmd_buf_delete(bhp, name); if (cp != NULL) fmd_case_setdirty(cp); else fmd_module_setdirty(mp); } fmd_module_unlock(mp); } void fmd_buf_read(fmd_hdl_t *hdl, fmd_case_t *cp, const char *name, void *buf, size_t size) { fmd_module_t *mp = fmd_api_module_lock(hdl); fmd_buf_t *bp = fmd_buf_lookup(fmd_buf_gethash(mp, cp), name); if (bp == NULL) { fmd_api_error(mp, EFMD_BUF_NOENT, "no buf named '%s' is " "associated with %s\n", name, cp ? "case" : "module"); } bcopy(bp->buf_data, buf, MIN(bp->buf_size, size)); if (size > bp->buf_size) bzero((char *)buf + bp->buf_size, size - bp->buf_size); fmd_module_unlock(mp); } void fmd_buf_write(fmd_hdl_t *hdl, fmd_case_t *cp, const char *name, const void *buf, size_t size) { fmd_module_t *mp = fmd_api_module_lock(hdl); fmd_buf_hash_t *bhp = fmd_buf_gethash(mp, cp); fmd_buf_t *bp = fmd_buf_lookup(bhp, name); if (bp == NULL) { if (fmd_strbadid(name, FMD_B_TRUE) != NULL || size == 0) { fmd_api_error(mp, EFMD_BUF_INVAL, "cannot write '%s' " "(size %lu): %s\n", name, (ulong_t)size, fmd_strerror(EFMD_BUF_INVAL)); } if (mp->mod_stats->ms_buflimit.fmds_value.ui64 - mp->mod_stats->ms_buftotal.fmds_value.ui64 < size) { fmd_api_error(mp, EFMD_BUF_LIMIT, "cannot write '%s': " "buf limit exceeded (%llu)\n", name, (u_longlong_t) mp->mod_stats->ms_buflimit.fmds_value.ui64); } mp->mod_stats->ms_buftotal.fmds_value.ui64 += size; bp = fmd_buf_insert(bhp, name, size); } else if (size > bp->buf_size) { fmd_api_error(mp, EFMD_BUF_OFLOW, "write to buf '%s' overflows buf size (%lu > %lu)\n", name, (ulong_t)size, (ulong_t)bp->buf_size); } bcopy(buf, bp->buf_data, MIN(bp->buf_size, size)); bp->buf_flags |= FMD_BUF_DIRTY; if (cp != NULL) fmd_case_setdirty(cp); else fmd_module_setdirty(mp); fmd_module_unlock(mp); } size_t fmd_buf_size(fmd_hdl_t *hdl, fmd_case_t *cp, const char *name) { fmd_module_t *mp = fmd_api_module_lock(hdl); fmd_buf_hash_t *bhp = fmd_buf_gethash(mp, cp); fmd_buf_t *bp; size_t size; if ((bp = fmd_buf_lookup(bhp, name)) != NULL) size = bp->buf_size; else size = 0; fmd_module_unlock(mp); return (size); } void fmd_serd_create(fmd_hdl_t *hdl, const char *name, uint_t n, hrtime_t t) { fmd_module_t *mp = fmd_api_module_lock(hdl); if (fmd_serd_eng_lookup(&mp->mod_serds, name) != NULL) { fmd_api_error(mp, EFMD_SERD_EXISTS, "failed to create serd engine '%s': %s\n", name, fmd_strerror(EFMD_SERD_EXISTS)); } (void) fmd_serd_eng_insert(&mp->mod_serds, name, n, t); fmd_module_setdirty(mp); fmd_module_unlock(mp); } void fmd_serd_destroy(fmd_hdl_t *hdl, const char *name) { fmd_module_t *mp = fmd_api_module_lock(hdl); fmd_serd_eng_delete(&mp->mod_serds, name); fmd_module_setdirty(mp); fmd_module_unlock(mp); } int fmd_serd_exists(fmd_hdl_t *hdl, const char *name) { fmd_module_t *mp = fmd_api_module_lock(hdl); int rv = (fmd_serd_eng_lookup(&mp->mod_serds, name) != NULL); fmd_module_unlock(mp); return (rv); } void fmd_serd_reset(fmd_hdl_t *hdl, const char *name) { fmd_module_t *mp = fmd_api_module_lock(hdl); fmd_serd_eng_t *sgp; if ((sgp = fmd_serd_eng_lookup(&mp->mod_serds, name)) == NULL) { fmd_api_error(mp, EFMD_SERD_NAME, "serd engine '%s' does not exist\n", name); } fmd_serd_eng_reset(sgp); fmd_module_setdirty(mp); fmd_module_unlock(mp); } int fmd_serd_record(fmd_hdl_t *hdl, const char *name, fmd_event_t *ep) { fmd_module_t *mp = fmd_api_module_lock(hdl); fmd_serd_eng_t *sgp; int err; if ((sgp = fmd_serd_eng_lookup(&mp->mod_serds, name)) == NULL) { fmd_api_error(mp, EFMD_SERD_NAME, "failed to add record to serd engine '%s'", name); } err = fmd_serd_eng_record(sgp, ep); if (sgp->sg_flags & FMD_SERD_DIRTY) fmd_module_setdirty(mp); fmd_module_unlock(mp); return (err); } int fmd_serd_fired(fmd_hdl_t *hdl, const char *name) { fmd_module_t *mp = fmd_api_module_lock(hdl); fmd_serd_eng_t *sgp; int err; if ((sgp = fmd_serd_eng_lookup(&mp->mod_serds, name)) == NULL) { fmd_api_error(mp, EFMD_SERD_NAME, "serd engine '%s' does not exist\n", name); } err = fmd_serd_eng_fired(sgp); fmd_module_unlock(mp); return (err); } int fmd_serd_empty(fmd_hdl_t *hdl, const char *name) { fmd_module_t *mp = fmd_api_module_lock(hdl); fmd_serd_eng_t *sgp; int empty; if ((sgp = fmd_serd_eng_lookup(&mp->mod_serds, name)) == NULL) { fmd_api_error(mp, EFMD_SERD_NAME, "serd engine '%s' does not exist\n", name); } empty = fmd_serd_eng_empty(sgp); fmd_module_unlock(mp); return (empty); } pthread_t fmd_thr_create(fmd_hdl_t *hdl, void (*func)(void *), void *arg) { fmd_module_t *mp = fmd_api_module_lock(hdl); fmd_thread_t *tp; pthread_t tid; if (mp->mod_stats->ms_thrtotal.fmds_value.ui32 >= mp->mod_stats->ms_thrlimit.fmds_value.ui32) { fmd_api_error(mp, EFMD_THR_LIMIT, "%s request to create an " "auxiliary thread exceeds module thread limit (%u)\n", mp->mod_name, mp->mod_stats->ms_thrlimit.fmds_value.ui32); } if ((tp = fmd_thread_create(mp, func, arg)) == NULL) { fmd_api_error(mp, EFMD_THR_CREATE, "failed to create auxiliary thread"); } tid = tp->thr_tid; mp->mod_stats->ms_thrtotal.fmds_value.ui32++; (void) fmd_idspace_xalloc(mp->mod_threads, tid, tp); fmd_module_unlock(mp); return (tid); } void fmd_thr_destroy(fmd_hdl_t *hdl, pthread_t tid) { fmd_module_t *mp = fmd_api_module_lock(hdl); fmd_thread_t *tp; int err; if (pthread_self() == tid) { fmd_api_error(mp, EFMD_THR_INVAL, "auxiliary thread tried to " "destroy itself (tid %u)\n", tid); } if ((tp = fmd_idspace_getspecific(mp->mod_threads, tid)) == NULL) { fmd_api_error(mp, EFMD_THR_INVAL, "auxiliary thread tried to " "destroy an invalid thread (tid %u)\n", tid); } /* * Wait for the specified thread to exit and then join with it. Since * the thread may need to make API calls in order to complete its work * we must sleep with the module lock unheld, and then reacquire it. */ fmd_module_unlock(mp); err = pthread_join(tid, NULL); mp = fmd_api_module_lock(hdl); /* * Since pthread_join() was called without the module lock held, if * multiple callers attempted to destroy the same auxiliary thread * simultaneously, one will succeed and the others will get ESRCH. * Therefore we silently ignore ESRCH but only allow the caller who * succeessfully joined with the auxiliary thread to destroy it. */ if (err != 0 && err != ESRCH) { fmd_api_error(mp, EFMD_THR_JOIN, "failed to join with auxiliary thread %u\n", tid); } if (err == 0) { fmd_thread_destroy(tp, FMD_THREAD_NOJOIN); mp->mod_stats->ms_thrtotal.fmds_value.ui32--; (void) fmd_idspace_free(mp->mod_threads, tid); } fmd_module_unlock(mp); } void fmd_thr_signal(fmd_hdl_t *hdl, pthread_t tid) { fmd_module_t *mp = fmd_api_module_lock(hdl); if (tid != mp->mod_thread->thr_tid && fmd_idspace_getspecific(mp->mod_threads, tid) == NULL) { fmd_api_error(mp, EFMD_THR_INVAL, "tid %u is not a valid " "thread id for module %s\n", tid, mp->mod_name); } (void) pthread_kill(tid, fmd.d_thr_sig); fmd_module_unlock(mp); } id_t fmd_timer_install(fmd_hdl_t *hdl, void *arg, fmd_event_t *ep, hrtime_t delta) { fmd_module_t *mp = fmd_api_module_lock(hdl); fmd_modtimer_t *t; id_t id; if (delta < 0) { fmd_api_error(mp, EFMD_TIMER_INVAL, "timer delta %lld is not a valid interval\n", delta); } t = fmd_alloc(sizeof (fmd_modtimer_t), FMD_SLEEP); t->mt_mod = mp; t->mt_arg = arg; t->mt_id = -1; if ((id = fmd_timerq_install(fmd.d_timers, mp->mod_timerids, (fmd_timer_f *)fmd_module_timeout, t, ep, delta)) == -1) { fmd_free(t, sizeof (fmd_modtimer_t)); fmd_api_error(mp, EFMD_TIMER_LIMIT, "failed to install timer +%lld", delta); } fmd_module_unlock(mp); return (id); } void fmd_timer_remove(fmd_hdl_t *hdl, id_t id) { fmd_module_t *mp = fmd_api_module_lock(hdl); fmd_modtimer_t *t; if (!fmd_idspace_valid(mp->mod_timerids, id)) { fmd_api_error(mp, EFMD_TIMER_INVAL, "id %ld is not a valid timer id\n", id); } /* * If the timer has not fired (t != NULL), remove it from the timer * queue. If the timer has fired (t == NULL), we could be in one of * two situations: a) we are processing the timer callback or b) * the timer event is on the module queue awaiting dispatch. For a), * fmd_timerq_remove() will wait for the timer callback function * to complete and queue an event for dispatch. For a) and b), * we cancel the outstanding timer event from the module's dispatch * queue. */ if ((t = fmd_timerq_remove(fmd.d_timers, mp->mod_timerids, id)) != NULL) fmd_free(t, sizeof (fmd_modtimer_t)); fmd_module_unlock(mp); fmd_eventq_cancel(mp->mod_queue, FMD_EVT_TIMEOUT, (void *)id); } nvlist_t * fmd_nvl_create_fault(fmd_hdl_t *hdl, const char *class, uint8_t certainty, nvlist_t *asru, nvlist_t *fru, nvlist_t *rsrc) { fmd_module_t *mp; topo_hdl_t *thp; nvlist_t *nvl; char *loc = NULL; int err; mp = fmd_api_module_lock(hdl); if (class == NULL || class[0] == '\0') fmd_api_error(mp, EFMD_NVL_INVAL, "invalid fault class\n"); thp = fmd_module_topo_hold(mp); /* * Try to find the location label for this resource */ (void) topo_fmri_label(thp, rsrc, &loc, &err); if (loc == NULL) (void) topo_fmri_label(thp, fru, &loc, &err); nvl = fmd_protocol_fault(class, certainty, asru, fru, rsrc, loc); if (loc != NULL) topo_hdl_strfree(thp, loc); err = fmd_module_topo_rele(mp, thp); ASSERT(err == 0); fmd_module_unlock(mp); return (nvl); } int fmd_nvl_class_match(fmd_hdl_t *hdl, nvlist_t *nvl, const char *pattern) { fmd_module_t *mp = fmd_api_module_lock(hdl); char *class; int rv; rv = (nvl != NULL && nvlist_lookup_string(nvl, FM_CLASS, &class) == 0 && fmd_strmatch(class, pattern)); fmd_module_unlock(mp); return (rv); } int fmd_nvl_fmri_expand(fmd_hdl_t *hdl, nvlist_t *nvl) { fmd_module_t *mp = fmd_api_module_lock(hdl); int rv; if (nvl == NULL) { fmd_api_error(mp, EFMD_NVL_INVAL, "invalid nvlist %p\n", (void *)nvl); } rv = fmd_fmri_expand(nvl); fmd_module_unlock(mp); return (rv); } int fmd_nvl_fmri_present(fmd_hdl_t *hdl, nvlist_t *nvl) { fmd_module_t *mp = fmd_api_module_lock(hdl); int rv; if (nvl == NULL) { fmd_api_error(mp, EFMD_NVL_INVAL, "invalid nvlist %p\n", (void *)nvl); } rv = fmd_fmri_present(nvl); fmd_module_unlock(mp); if (rv < 0) { fmd_api_error(mp, EFMD_FMRI_OP, "invalid fmri for " "fmd_nvl_fmri_present\n"); } return (rv); } int fmd_nvl_fmri_unusable(fmd_hdl_t *hdl, nvlist_t *nvl) { fmd_module_t *mp = fmd_api_module_lock(hdl); int rv; if (nvl == NULL) { fmd_api_error(mp, EFMD_NVL_INVAL, "invalid nvlist %p\n", (void *)nvl); } rv = fmd_fmri_unusable(nvl); fmd_module_unlock(mp); if (rv < 0) { fmd_api_error(mp, EFMD_FMRI_OP, "invalid fmri for " "fmd_nvl_fmri_unusable\n"); } return (rv); } int fmd_nvl_fmri_faulty(fmd_hdl_t *hdl, nvlist_t *nvl) { fmd_module_t *mp = fmd_api_module_lock(hdl); fmd_asru_hash_t *ahp = fmd.d_asrus; fmd_asru_t *ap; int rv = 0; if (nvl == NULL) { fmd_api_error(mp, EFMD_NVL_INVAL, "invalid nvlist %p\n", (void *)nvl); } if ((ap = fmd_asru_hash_lookup_nvl(ahp, nvl, FMD_B_FALSE)) != NULL) { rv = (ap->asru_flags & FMD_ASRU_FAULTY) != 0; fmd_asru_hash_release(ahp, ap); } fmd_module_unlock(mp); return (rv); } int fmd_nvl_fmri_contains(fmd_hdl_t *hdl, nvlist_t *n1, nvlist_t *n2) { fmd_module_t *mp = fmd_api_module_lock(hdl); int rv; if (n1 == NULL || n2 == NULL) { fmd_api_error(mp, EFMD_NVL_INVAL, "invalid nvlist(s): %p, %p\n", (void *)n1, (void *)n2); } rv = fmd_fmri_contains(n1, n2); fmd_module_unlock(mp); if (rv < 0) { fmd_api_error(mp, EFMD_FMRI_OP, "invalid fmri for " "fmd_nvl_fmri_contains\n"); } return (rv); } nvlist_t * fmd_nvl_fmri_translate(fmd_hdl_t *hdl, nvlist_t *fmri, nvlist_t *auth) { fmd_module_t *mp = fmd_api_module_lock(hdl); nvlist_t *xfmri; if (fmri == NULL || auth == NULL) { fmd_api_error(mp, EFMD_NVL_INVAL, "invalid nvlist(s): %p, %p\n", (void *)fmri, (void *)auth); } xfmri = fmd_fmri_translate(fmri, auth); fmd_module_unlock(mp); return (xfmri); } int fmd_event_local(fmd_hdl_t *hdl, fmd_event_t *ep) { if (hdl == NULL || ep == NULL) { fmd_api_error(fmd_api_module_lock(hdl), EFMD_EVENT_INVAL, "NULL parameter specified to fmd_event_local\n"); } return (((fmd_event_impl_t *)ep)->ev_flags & FMD_EVF_LOCAL); } /*ARGSUSED*/ uint64_t fmd_event_ena_create(fmd_hdl_t *hdl) { return (fmd_ena()); } fmd_xprt_t * fmd_xprt_open(fmd_hdl_t *hdl, uint_t flags, nvlist_t *auth, void *data) { fmd_module_t *mp = fmd_api_module_lock(hdl); fmd_xprt_t *xp; if (flags & ~FMD_XPRT_CMASK) { fmd_api_error(mp, EFMD_XPRT_INVAL, "invalid transport flags 0x%x\n", flags); } if ((flags & FMD_XPRT_RDWR) != FMD_XPRT_RDWR && (flags & FMD_XPRT_RDWR) != FMD_XPRT_RDONLY) { fmd_api_error(mp, EFMD_XPRT_INVAL, "cannot open write-only transport\n"); } if (mp->mod_stats->ms_xprtopen.fmds_value.ui32 >= mp->mod_stats->ms_xprtlimit.fmds_value.ui32) { fmd_api_error(mp, EFMD_XPRT_LIMIT, "%s request to create a " "transport exceeds module transport limit (%u)\n", mp->mod_name, mp->mod_stats->ms_xprtlimit.fmds_value.ui32); } if ((xp = fmd_xprt_create(mp, flags, auth, data)) == NULL) fmd_api_error(mp, errno, "cannot create transport"); fmd_module_unlock(mp); return (xp); } void fmd_xprt_close(fmd_hdl_t *hdl, fmd_xprt_t *xp) { fmd_module_t *mp = fmd_api_module_lock(hdl); fmd_xprt_impl_t *xip = fmd_api_transport_impl(hdl, xp); /* * Although this could be supported, it doesn't seem necessary or worth * the trouble. For now, just detect this and trigger a module abort. * If it is needed, transports should grow reference counts and a new * event type will need to be enqueued for the main thread to reap it. */ if (xip->xi_thread != NULL && xip->xi_thread->thr_tid == pthread_self()) { fmd_api_error(mp, EFMD_XPRT_INVAL, "fmd_xprt_close() cannot be called from fmdo_send()\n"); } fmd_xprt_destroy(xp); fmd_module_unlock(mp); } void fmd_xprt_post(fmd_hdl_t *hdl, fmd_xprt_t *xp, nvlist_t *nvl, hrtime_t hrt) { fmd_xprt_impl_t *xip = fmd_api_transport_impl(hdl, xp); /* * fmd_xprt_recv() must block during startup waiting for fmd to globally * clear FMD_XPRT_DSUSPENDED. As such, we can't allow it to be called * from a module's _fmd_init() routine, because that would block * fmd from completing initial module loading, resulting in a deadlock. */ if ((xip->xi_flags & FMD_XPRT_ISUSPENDED) && (pthread_self() == xip->xi_queue->eq_mod->mod_thread->thr_tid)) { fmd_api_error(fmd_api_module_lock(hdl), EFMD_XPRT_INVAL, "fmd_xprt_post() cannot be called from _fmd_init()\n"); } fmd_xprt_recv(xp, nvl, hrt); } void fmd_xprt_suspend(fmd_hdl_t *hdl, fmd_xprt_t *xp) { (void) fmd_api_transport_impl(hdl, xp); /* validate 'xp' */ fmd_xprt_xsuspend(xp, FMD_XPRT_SUSPENDED); } void fmd_xprt_resume(fmd_hdl_t *hdl, fmd_xprt_t *xp) { (void) fmd_api_transport_impl(hdl, xp); /* validate 'xp' */ fmd_xprt_xresume(xp, FMD_XPRT_SUSPENDED); } int fmd_xprt_error(fmd_hdl_t *hdl, fmd_xprt_t *xp) { fmd_xprt_impl_t *xip = fmd_api_transport_impl(hdl, xp); return (xip->xi_state == _fmd_xprt_state_err); } /* * Translate all FMRIs in the specified name-value pair list for the specified * FMRI authority, and return a new name-value pair list for the translation. * This function is the recursive engine used by fmd_xprt_translate(), below. */ static nvlist_t * fmd_xprt_xtranslate(nvlist_t *nvl, nvlist_t *auth) { uint_t i, j, n; nvpair_t *nvp, **nvps; uint_t nvpslen = 0; char *name; size_t namelen = 0; nvlist_t **a, **b; nvlist_t *l, *r; data_type_t type; char *s; int err; (void) nvlist_xdup(nvl, &nvl, &fmd.d_nva); /* * Count up the number of name-value pairs in 'nvl' and compute the * maximum length of a name used in this list for use below. */ for (nvp = nvlist_next_nvpair(nvl, NULL); nvp != NULL; nvp = nvlist_next_nvpair(nvl, nvp), nvpslen++) { size_t len = strlen(nvpair_name(nvp)); namelen = MAX(namelen, len); } nvps = alloca(sizeof (nvpair_t *) * nvpslen); name = alloca(namelen + 1); /* * Store a snapshot of the name-value pairs in 'nvl' into nvps[] so * that we can iterate over the original pairs in the loop below while * performing arbitrary insert and delete operations on 'nvl' itself. */ for (i = 0, nvp = nvlist_next_nvpair(nvl, NULL); nvp != NULL; nvp = nvlist_next_nvpair(nvl, nvp)) nvps[i++] = nvp; /* * Now iterate over the snapshot of the name-value pairs. If we find a * value that is of type NVLIST or NVLIST_ARRAY, we translate that * object by either calling ourself recursively on it, or calling into * fmd_fmri_translate() if the object is an FMRI. We then rip out the * original name-value pair and replace it with the translated one. */ for (i = 0; i < nvpslen; i++) { nvp = nvps[i]; type = nvpair_type(nvp); switch (type) { case DATA_TYPE_NVLIST_ARRAY: if (nvpair_value_nvlist_array(nvp, &a, &n) != 0 || a == NULL || n == 0) continue; /* array is zero-sized; skip it */ b = fmd_alloc(sizeof (nvlist_t *) * n, FMD_SLEEP); /* * If the first array nvlist element looks like an FMRI * then assume the other elements are FMRIs as well. * If any b[j]'s can't be translated, then EINVAL will * be returned from nvlist_add_nvlist_array() below. */ if (nvlist_lookup_string(*a, FM_FMRI_SCHEME, &s) == 0) { for (j = 0; j < n; j++) b[j] = fmd_fmri_translate(a[j], auth); } else { for (j = 0; j < n; j++) b[j] = fmd_xprt_xtranslate(a[j], auth); } (void) strcpy(name, nvpair_name(nvp)); (void) nvlist_remove(nvl, name, type); err = nvlist_add_nvlist_array(nvl, name, b, n); for (j = 0; j < n; j++) nvlist_free(b[j]); fmd_free(b, sizeof (nvlist_t *) * n); if (err != 0) { nvlist_free(nvl); errno = err; return (NULL); } break; case DATA_TYPE_NVLIST: if (nvpair_value_nvlist(nvp, &l) == 0 && nvlist_lookup_string(l, FM_FMRI_SCHEME, &s) == 0) r = fmd_fmri_translate(l, auth); else r = fmd_xprt_xtranslate(l, auth); if (r == NULL) { nvlist_free(nvl); return (NULL); } (void) strcpy(name, nvpair_name(nvp)); (void) nvlist_remove(nvl, name, type); (void) nvlist_add_nvlist(nvl, name, r); nvlist_free(r); break; } } return (nvl); } nvlist_t * fmd_xprt_translate(fmd_hdl_t *hdl, fmd_xprt_t *xp, fmd_event_t *ep) { fmd_xprt_impl_t *xip = fmd_api_transport_impl(hdl, xp); if (xip->xi_auth == NULL) { fmd_api_error(fmd_api_module_lock(hdl), EFMD_XPRT_INVAL, "no authority defined for transport %p\n", (void *)xp); } return (fmd_xprt_xtranslate(FMD_EVENT_NVL(ep), xip->xi_auth)); } void fmd_xprt_setspecific(fmd_hdl_t *hdl, fmd_xprt_t *xp, void *data) { fmd_api_transport_impl(hdl, xp)->xi_data = data; } void * fmd_xprt_getspecific(fmd_hdl_t *hdl, fmd_xprt_t *xp) { return (fmd_api_transport_impl(hdl, xp)->xi_data); }