/* * 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 "sunFM_impl.h" #include "resource.h" static uu_avl_pool_t *rsrc_fmri_avl_pool; static uu_avl_pool_t *rsrc_index_avl_pool; static uu_avl_t *rsrc_fmri_avl; static uu_avl_t *rsrc_index_avl; #define VALID_AVL_STATE (rsrc_fmri_avl_pool != NULL && \ rsrc_index_avl_pool != NULL && rsrc_fmri_avl != NULL && \ rsrc_index_avl != NULL) #define UPDATE_WAIT_MILLIS 10 /* poll interval in milliseconds */ /* * Update types: single-index and all are mutually exclusive; a count * update is optional. */ #define UCT_INDEX 0x1 #define UCT_ALL 0x2 #define UCT_COUNT 0x4 #define UCT_FLAGS 0x7 #define RESOURCE_DATA_VALID(d) ((d)->d_valid == valid_stamp) /* * Locking strategy is described in module.c. */ static ulong_t max_index; static int valid_stamp; static uint32_t rsrc_count; static pthread_mutex_t update_lock; static pthread_cond_t update_cv; static volatile enum { US_QUIET, US_NEEDED, US_INPROGRESS } update_status; static Netsnmp_Node_Handler sunFmResourceTable_handler; static Netsnmp_Node_Handler sunFmResourceCount_handler; static sunFmResource_data_t * key_build(const char *fmri, const ulong_t index) { static sunFmResource_data_t key; key.d_index = index; if (fmri) (void) strlcpy(key.d_ari_fmri, fmri, sizeof (key.d_ari_fmri)); else key.d_ari_fmri[0] = '\0'; return (&key); } /* * If fmri is the fmri of a resource we have previously seen and indexed, return * data for it. Otherwise, return NULL. Note that the resource may not be * valid; that is, it may have been removed from the fault manager since its * information was last updated. */ static sunFmResource_data_t * resource_lookup_fmri(const char *fmri) { sunFmResource_data_t *key; key = key_build(fmri, 0); return (uu_avl_find(rsrc_fmri_avl, key, NULL, NULL)); } /* * If index corresponds to a resource we have previously seen and indexed, * return data for it. Otherwise, return NULL. Note that the resource may * not be valid; that is, it may have been expired from the fault manager * since its information was last updated. */ static sunFmResource_data_t * resource_lookup_index_exact(const ulong_t index) { sunFmResource_data_t *key; key = key_build(NULL, index); return (uu_avl_find(rsrc_index_avl, key, NULL, NULL)); } /* * If index corresponds to a valid (that is, extant as of latest information * from the fault manager) resource, return the data for that resource. * Otherwise, return the data for the valid resource whose index is as close as * possible to index but not lower. This preserves the lexicographical * ordering required for GETNEXT processing. */ static sunFmResource_data_t * resource_lookup_index_nextvalid(const ulong_t index) { sunFmResource_data_t *key, *data; uu_avl_index_t idx; key = key_build(NULL, index); if ((data = uu_avl_find(rsrc_index_avl, key, NULL, &idx)) != NULL && RESOURCE_DATA_VALID(data)) return (data); data = uu_avl_nearest_next(rsrc_index_avl, idx); while (data != NULL && !RESOURCE_DATA_VALID(data)) data = uu_avl_next(rsrc_index_avl, data); return (data); } /* * Possible update the contents of a single resource within the cache. This * is our callback from fmd_rsrc_iter. */ static int rsrcinfo_update_one(const fmd_adm_rsrcinfo_t *rsrcinfo, void *arg) { const sunFmResource_update_ctx_t *update_ctx = (sunFmResource_update_ctx_t *)arg; sunFmResource_data_t *data = resource_lookup_fmri(rsrcinfo->ari_fmri); ++rsrc_count; /* * A resource we haven't seen before. We're obligated to index * it and link it into our cache so that we can find it, but we're * not obligated to fill it in completely unless we're doing a * full update or this is the resource we were asked for. This * avoids unnecessary iteration and memory manipulation for data * we're not going to return for this request. */ if (data == NULL) { uu_avl_index_t idx; DEBUGMSGTL((MODNAME_STR, "found new resource %s\n", rsrcinfo->ari_fmri)); if ((data = SNMP_MALLOC_TYPEDEF(sunFmResource_data_t)) == NULL) { (void) snmp_log(LOG_ERR, MODNAME_STR ": Out of memory " "for new resource data at %s:%d\n", __FILE__, __LINE__); return (1); } /* * We allocate indices sequentially and never reuse them. * This ensures we can always return valid GETNEXT responses * without having to reindex, and it provides the user a * more consistent view of the fault manager. */ data->d_index = ++max_index; DEBUGMSGTL((MODNAME_STR, "index %lu is %s@%p\n", data->d_index, rsrcinfo->ari_fmri, data)); (void) strlcpy(data->d_ari_fmri, rsrcinfo->ari_fmri, sizeof (data->d_ari_fmri)); uu_avl_node_init(data, &data->d_fmri_avl, rsrc_fmri_avl_pool); (void) uu_avl_find(rsrc_fmri_avl, data, NULL, &idx); uu_avl_insert(rsrc_fmri_avl, data, idx); uu_avl_node_init(data, &data->d_index_avl, rsrc_index_avl_pool); (void) uu_avl_find(rsrc_index_avl, data, NULL, &idx); uu_avl_insert(rsrc_index_avl, data, idx); DEBUGMSGTL((MODNAME_STR, "completed new resource %lu/%s@%p\n", data->d_index, data->d_ari_fmri, data)); } data->d_valid = valid_stamp; DEBUGMSGTL((MODNAME_STR, "timestamp updated for %lu/%s@%p: %lu\n", data->d_index, data->d_ari_fmri, data, data->d_valid)); if ((update_ctx->uc_type & UCT_ALL) || update_ctx->uc_index == data->d_index) { (void) strlcpy(data->d_ari_case, rsrcinfo->ari_case, sizeof (data->d_ari_case)); data->d_ari_flags = rsrcinfo->ari_flags; } return (!(update_ctx->uc_type & UCT_ALL) && update_ctx->uc_index == data->d_index); } /* * Update some or all resource data from fmd. If type includes UCT_ALL, all * resources will be indexed and their data cached. If type includes * UCT_INDEX, updates will stop once the resource matching index has been * updated. If UCT_COUNT is set, the number of faulted resources will be * set. * * Returns appropriate SNMP error codes. */ static int rsrcinfo_update(sunFmResource_update_ctx_t *update_ctx) { fmd_adm_t *adm; int err; ASSERT(update_ctx != NULL); ASSERT((update_ctx->uc_type & (UCT_ALL|UCT_INDEX)) != (UCT_ALL|UCT_INDEX)); ASSERT((update_ctx->uc_type & ~UCT_FLAGS) == 0); ASSERT(VALID_AVL_STATE); if ((adm = fmd_adm_open(update_ctx->uc_host, update_ctx->uc_prog, update_ctx->uc_version)) == NULL) { (void) snmp_log(LOG_ERR, MODNAME_STR ": Communication with fmd " "failed: %s\n", strerror(errno)); return (SNMP_ERR_RESOURCEUNAVAILABLE); } if (update_ctx->uc_type == UCT_COUNT) { err = fmd_adm_rsrc_count(adm, update_ctx->uc_all, &rsrc_count); } else { ++valid_stamp; rsrc_count = 0; err = fmd_adm_rsrc_iter(adm, update_ctx->uc_all, rsrcinfo_update_one, update_ctx); DEBUGMSGTL((MODNAME_STR, "resource iteration completed\n")); } fmd_adm_close(adm); if (err != 0) { (void) snmp_log(LOG_ERR, MODNAME_STR ": fmd resource " "information update failed: %s\n", fmd_adm_errmsg(adm)); return (SNMP_ERR_RESOURCEUNAVAILABLE); } return (SNMP_ERR_NOERROR); } /*ARGSUSED*/ static void update_thread(void *arg) { /* * The current rsrcinfo_update implementation offers minimal savings * for the use of index-only updates; therefore we always do a full * update. If it becomes advantageous to limit updates to a single * index, the contexts can be queued by the handler instead. */ sunFmResource_update_ctx_t uc; uc.uc_host = NULL; uc.uc_prog = FMD_ADM_PROGRAM; uc.uc_version = FMD_ADM_VERSION; uc.uc_all = 0; uc.uc_index = 0; uc.uc_type = UCT_ALL; for (;;) { (void) pthread_mutex_lock(&update_lock); update_status = US_QUIET; while (update_status == US_QUIET) (void) pthread_cond_wait(&update_cv, &update_lock); update_status = US_INPROGRESS; (void) pthread_mutex_unlock(&update_lock); (void) rsrcinfo_update(&uc); } } static void request_update(void) { (void) pthread_mutex_lock(&update_lock); if (update_status != US_QUIET) { (void) pthread_mutex_unlock(&update_lock); return; } update_status = US_NEEDED; (void) pthread_cond_signal(&update_cv); (void) pthread_mutex_unlock(&update_lock); } /*ARGSUSED*/ static int resource_compare_fmri(const void *l, const void *r, void *private) { sunFmResource_data_t *l_data = (sunFmResource_data_t *)l; sunFmResource_data_t *r_data = (sunFmResource_data_t *)r; ASSERT(l_data != NULL && r_data != NULL); return (strcmp(l_data->d_ari_fmri, r_data->d_ari_fmri)); } /*ARGSUSED*/ static int resource_compare_index(const void *l, const void *r, void *private) { sunFmResource_data_t *l_data = (sunFmResource_data_t *)l; sunFmResource_data_t *r_data = (sunFmResource_data_t *)r; ASSERT(l_data != NULL && r_data != NULL); return (l_data->d_index < r_data->d_index ? -1 : l_data->d_index > r_data->d_index ? 1 : 0); } int sunFmResourceTable_init(void) { static oid sunFmResourceTable_oid[] = { SUNFMRESOURCETABLE_OID }; static oid sunFmResourceCount_oid[] = { SUNFMRESOURCECOUNT_OID, 0 }; netsnmp_table_registration_info *table_info; netsnmp_handler_registration *handler; int err; if ((err = pthread_mutex_init(&update_lock, NULL)) != 0) { (void) snmp_log(LOG_ERR, MODNAME_STR ": mutex_init failure: " "%s\n", strerror(err)); return (MIB_REGISTRATION_FAILED); } if ((err = pthread_cond_init(&update_cv, NULL)) != 0) { (void) snmp_log(LOG_ERR, MODNAME_STR ": cond_init failure: " "%s\n", strerror(err)); return (MIB_REGISTRATION_FAILED); } if ((err = pthread_create(NULL, NULL, (void *(*)(void *))update_thread, NULL)) != 0) { (void) snmp_log(LOG_ERR, MODNAME_STR ": error creating update " "thread: %s\n", strerror(err)); return (MIB_REGISTRATION_FAILED); } if ((table_info = SNMP_MALLOC_TYPEDEF(netsnmp_table_registration_info)) == NULL) return (MIB_REGISTRATION_FAILED); if ((handler = netsnmp_create_handler_registration("sunFmResourceTable", sunFmResourceTable_handler, sunFmResourceTable_oid, OID_LENGTH(sunFmResourceTable_oid), HANDLER_CAN_RONLY)) == NULL) { SNMP_FREE(table_info); return (MIB_REGISTRATION_FAILED); } /* * The Net-SNMP template uses add_indexes here, but that * function is unsafe because it does not check for failure. */ if (netsnmp_table_helper_add_index(table_info, ASN_UNSIGNED) == NULL) { SNMP_FREE(table_info); SNMP_FREE(handler); return (MIB_REGISTRATION_FAILED); } table_info->min_column = SUNFMRESOURCE_COLMIN; table_info->max_column = SUNFMRESOURCE_COLMAX; if ((rsrc_fmri_avl_pool = uu_avl_pool_create("rsrc_fmri", sizeof (sunFmResource_data_t), offsetof(sunFmResource_data_t, d_fmri_avl), resource_compare_fmri, UU_AVL_DEBUG)) == NULL) { (void) snmp_log(LOG_ERR, MODNAME_STR ": rsrc_fmri avl pool " "creation failed: %s\n", uu_strerror(uu_error())); snmp_free_varbind(table_info->indexes); SNMP_FREE(table_info); SNMP_FREE(handler); } if ((rsrc_fmri_avl = uu_avl_create(rsrc_fmri_avl_pool, NULL, UU_AVL_DEBUG)) == NULL) { (void) snmp_log(LOG_ERR, MODNAME_STR ": rsrc_fmri avl creation " "failed: %s\n", uu_strerror(uu_error())); snmp_free_varbind(table_info->indexes); SNMP_FREE(table_info); SNMP_FREE(handler); uu_avl_pool_destroy(rsrc_fmri_avl_pool); return (MIB_REGISTRATION_FAILED); } if ((rsrc_index_avl_pool = uu_avl_pool_create("rsrc_index", sizeof (sunFmResource_data_t), offsetof(sunFmResource_data_t, d_index_avl), resource_compare_index, UU_AVL_DEBUG)) == NULL) { (void) snmp_log(LOG_ERR, MODNAME_STR ": rsrc_index avl pool " "creation failed: %s\n", uu_strerror(uu_error())); snmp_free_varbind(table_info->indexes); SNMP_FREE(table_info); SNMP_FREE(handler); uu_avl_destroy(rsrc_fmri_avl); uu_avl_pool_destroy(rsrc_fmri_avl_pool); } if ((rsrc_index_avl = uu_avl_create(rsrc_index_avl_pool, NULL, UU_AVL_DEBUG)) == NULL) { (void) snmp_log(LOG_ERR, MODNAME_STR ": rsrc_index avl " "creation failed: %s\n", uu_strerror(uu_error())); snmp_free_varbind(table_info->indexes); SNMP_FREE(table_info); SNMP_FREE(handler); uu_avl_destroy(rsrc_fmri_avl); uu_avl_pool_destroy(rsrc_fmri_avl_pool); uu_avl_pool_destroy(rsrc_index_avl_pool); return (MIB_REGISTRATION_FAILED); } if ((err = netsnmp_register_table(handler, table_info)) != MIB_REGISTERED_OK) { snmp_free_varbind(table_info->indexes); SNMP_FREE(table_info); SNMP_FREE(handler); uu_avl_destroy(rsrc_fmri_avl); uu_avl_pool_destroy(rsrc_fmri_avl_pool); uu_avl_destroy(rsrc_index_avl); uu_avl_pool_destroy(rsrc_index_avl_pool); return (err); } if ((err = netsnmp_register_read_only_instance( netsnmp_create_handler_registration("sunFmResourceCount", sunFmResourceCount_handler, sunFmResourceCount_oid, OID_LENGTH(sunFmResourceCount_oid), HANDLER_CAN_RONLY))) != MIB_REGISTERED_OK) { /* * There's no way to unregister the table handler, so we * can't free any of the data, either. */ return (err); } return (MIB_REGISTERED_OK); } /* * These two functions form the core of GET/GETNEXT/GETBULK handling (the * only kind we do). They perform two functions: * * - First, frob the request to set all the index variables to correspond * to the value that's going to be returned. For GET, this is a nop; * for GETNEXT/GETBULK it always requires some work. * - Second, find and return the fmd resource information corresponding to * the (possibly updated) indices. * * These should be as fast as possible; they run in the agent thread. */ static sunFmResource_data_t * sunFmResourceTable_nextrsrc(netsnmp_handler_registration *reginfo, netsnmp_table_request_info *table_info) { sunFmResource_data_t *data; netsnmp_variable_list *var; ulong_t index; /* * If we have no index, we must make one. */ if (table_info->number_indexes < 1) { oid tmpoid[MAX_OID_LEN]; index = 1; DEBUGMSGTL((MODNAME_STR, "nextrsrc: no indexes given\n")); var = SNMP_MALLOC_TYPEDEF(netsnmp_variable_list); (void) snmp_set_var_typed_value(var, ASN_UNSIGNED, (uchar_t *)&index, sizeof (index)); (void) memcpy(tmpoid, reginfo->rootoid, reginfo->rootoid_len * sizeof (oid)); tmpoid[reginfo->rootoid_len] = 1; tmpoid[reginfo->rootoid_len + 1] = table_info->colnum; if (build_oid(&var->name, &var->name_length, tmpoid, reginfo->rootoid_len + 2, var) != SNMPERR_SUCCESS) { snmp_free_varbind(var); return (NULL); } DEBUGMSGTL((MODNAME_STR, "nextrsrc: built fake index:\n")); DEBUGMSGVAR((MODNAME_STR, var)); DEBUGMSG((MODNAME_STR, "\n")); } else { var = snmp_clone_varbind(table_info->indexes); index = *var->val.integer; DEBUGMSGTL((MODNAME_STR, "nextrsrc: received index:\n")); DEBUGMSGVAR((MODNAME_STR, var)); DEBUGMSG((MODNAME_STR, "\n")); index++; } snmp_free_varbind(table_info->indexes); table_info->indexes = NULL; table_info->number_indexes = 0; if ((data = resource_lookup_index_nextvalid(index)) == NULL) { DEBUGMSGTL((MODNAME_STR, "nextrsrc: exact match not found for " "index %lu; trying next column\n", index)); if (table_info->colnum >= netsnmp_find_table_registration_info(reginfo)->max_column) { snmp_free_varbind(var); DEBUGMSGTL((MODNAME_STR, "nextrsrc: out of columns\n")); return (NULL); } table_info->colnum++; index = 1; data = resource_lookup_index_nextvalid(index); } if (data == NULL) { DEBUGMSGTL((MODNAME_STR, "nextrsrc: exact match not found for " "index %lu; stopping\n", index)); snmp_free_varbind(var); return (NULL); } *var->val.integer = data->d_index; table_info->indexes = var; table_info->number_indexes = 1; DEBUGMSGTL((MODNAME_STR, "matching data is %lu/%s@%p\n", data->d_index, data->d_ari_fmri, data)); return (data); } /*ARGSUSED*/ static sunFmResource_data_t * sunFmResourceTable_rsrc(netsnmp_handler_registration *reginfo, netsnmp_table_request_info *table_info) { ASSERT(table_info->number_indexes == 1); return (resource_lookup_index_exact(table_info->index_oid[0])); } /*ARGSUSED*/ static void sunFmResourceTable_return(unsigned int reg, void *arg) { netsnmp_delegated_cache *cache = (netsnmp_delegated_cache *)arg; netsnmp_request_info *request; netsnmp_agent_request_info *reqinfo; netsnmp_handler_registration *reginfo; netsnmp_table_request_info *table_info; sunFmResource_data_t *data; ulong_t rsrcstate; ASSERT(netsnmp_handler_check_cache(cache) != NULL); (void) pthread_mutex_lock(&update_lock); if (update_status != US_QUIET) { struct timeval tv; tv.tv_sec = UPDATE_WAIT_MILLIS / 1000; tv.tv_usec = (UPDATE_WAIT_MILLIS % 1000) * 1000; (void) snmp_alarm_register_hr(tv, 0, sunFmResourceTable_return, cache); (void) pthread_mutex_unlock(&update_lock); return; } request = cache->requests; reqinfo = cache->reqinfo; reginfo = cache->reginfo; table_info = netsnmp_extract_table_info(request); request->delegated = 0; ASSERT(table_info->colnum >= SUNFMRESOURCE_COLMIN); ASSERT(table_info->colnum <= SUNFMRESOURCE_COLMAX); /* * table_info->colnum contains the column number requested. * table_info->indexes contains a linked list of snmp variable * bindings for the indexes of the table. Values in the list * have been set corresponding to the indexes of the * request. We have other guarantees as well: * * - The column number is always within range. * - If we have no index data, table_info->index_oid_len is 0. * - We will never receive requests outside our table nor * those with the first subid anything other than 1 (Entry) * nor those without a column number. This is true even * for GETNEXT requests. */ switch (reqinfo->mode) { case MODE_GET: if ((data = sunFmResourceTable_rsrc(reginfo, table_info)) == NULL) { netsnmp_free_delegated_cache(cache); (void) pthread_mutex_unlock(&update_lock); return; } break; case MODE_GETNEXT: case MODE_GETBULK: if ((data = sunFmResourceTable_nextrsrc(reginfo, table_info)) == NULL) { netsnmp_free_delegated_cache(cache); (void) pthread_mutex_unlock(&update_lock); return; } break; default: (void) snmp_log(LOG_ERR, MODNAME_STR ": Unsupported request " "mode %d\n", reqinfo->mode); netsnmp_free_delegated_cache(cache); (void) pthread_mutex_unlock(&update_lock); return; } switch (table_info->colnum) { case SUNFMRESOURCE_COL_FMRI: (void) netsnmp_table_build_result(reginfo, request, table_info, ASN_OCTET_STR, (uchar_t *)data->d_ari_fmri, strlen(data->d_ari_fmri)); break; case SUNFMRESOURCE_COL_STATUS: switch (data->d_ari_flags & (FMD_ADM_RSRC_FAULTY|FMD_ADM_RSRC_UNUSABLE)) { default: rsrcstate = SUNFMRESOURCE_STATE_OK; break; case FMD_ADM_RSRC_FAULTY: rsrcstate = SUNFMRESOURCE_STATE_DEGRADED; break; case FMD_ADM_RSRC_UNUSABLE: rsrcstate = SUNFMRESOURCE_STATE_UNKNOWN; break; case FMD_ADM_RSRC_FAULTY | FMD_ADM_RSRC_UNUSABLE: rsrcstate = SUNFMRESOURCE_STATE_FAULTED; break; } (void) netsnmp_table_build_result(reginfo, request, table_info, ASN_INTEGER, (uchar_t *)&rsrcstate, sizeof (rsrcstate)); break; case SUNFMRESOURCE_COL_DIAGNOSISUUID: (void) netsnmp_table_build_result(reginfo, request, table_info, ASN_OCTET_STR, (uchar_t *)data->d_ari_case, strlen(data->d_ari_case)); break; default: break; } netsnmp_free_delegated_cache(cache); (void) pthread_mutex_unlock(&update_lock); } static int sunFmResourceTable_handler(netsnmp_mib_handler *handler, netsnmp_handler_registration *reginfo, netsnmp_agent_request_info *reqinfo, netsnmp_request_info *requests) { netsnmp_request_info *request; struct timeval tv; tv.tv_sec = UPDATE_WAIT_MILLIS / 1000; tv.tv_usec = (UPDATE_WAIT_MILLIS % 1000) * 1000; request_update(); for (request = requests; request; request = request->next) { if (request->processed != 0) continue; if (netsnmp_extract_table_info(request) == NULL) continue; request->delegated = 1; (void) snmp_alarm_register_hr(tv, 0, sunFmResourceTable_return, (void *) netsnmp_create_delegated_cache(handler, reginfo, reqinfo, request, NULL)); } return (SNMP_ERR_NOERROR); } /*ARGSUSED*/ static void sunFmResourceCount_return(unsigned int reg, void *arg) { netsnmp_delegated_cache *cache = (netsnmp_delegated_cache *)arg; netsnmp_request_info *request; netsnmp_agent_request_info *reqinfo; ulong_t rsrc_count_long; ASSERT(netsnmp_handler_check_cache(cache) != NULL); (void) pthread_mutex_lock(&update_lock); if (update_status != US_QUIET) { struct timeval tv; tv.tv_sec = UPDATE_WAIT_MILLIS / 1000; tv.tv_usec = (UPDATE_WAIT_MILLIS % 1000) * 1000; (void) snmp_alarm_register_hr(tv, 0, sunFmResourceCount_return, cache); (void) pthread_mutex_unlock(&update_lock); return; } request = cache->requests; reqinfo = cache->reqinfo; request->delegated = 0; switch (reqinfo->mode) { /* * According to the documentation, it's not possible for us ever to * be called with MODE_GETNEXT. However, Net-SNMP does the following: * - set reqinfo->mode to MODE_GET * - invoke the handler * - set reqinfo->mode to MODE_GETNEXT (even if the request was not * actually processed; i.e. it's been delegated) * Since we're called back later with the same reqinfo, we see * GETNEXT. Therefore this case is needed to work around the * Net-SNMP bug. */ case MODE_GET: case MODE_GETNEXT: DEBUGMSGTL((MODNAME_STR, "resource count is %u\n", rsrc_count)); rsrc_count_long = (ulong_t)rsrc_count; (void) snmp_set_var_typed_value(request->requestvb, ASN_GAUGE, (uchar_t *)&rsrc_count_long, sizeof (rsrc_count_long)); break; default: (void) snmp_log(LOG_ERR, MODNAME_STR ": Unsupported request " "mode %d\n", reqinfo->mode); } netsnmp_free_delegated_cache(cache); (void) pthread_mutex_unlock(&update_lock); } static int sunFmResourceCount_handler(netsnmp_mib_handler *handler, netsnmp_handler_registration *reginfo, netsnmp_agent_request_info *reqinfo, netsnmp_request_info *requests) { struct timeval tv; tv.tv_sec = UPDATE_WAIT_MILLIS / 1000; tv.tv_usec = (UPDATE_WAIT_MILLIS % 1000) * 1000; request_update(); /* * We are never called for a GETNEXT when registered as an * instance; it's handled for us and converted to a GET. * Also, an instance handler is given only one request at a time, so * we don't need to loop over a list of requests. */ if (requests->processed != 0) return (SNMP_ERR_NOERROR); requests->delegated = 1; (void) snmp_alarm_register_hr(tv, 0, sunFmResourceCount_return, (void *) netsnmp_create_delegated_cache(handler, reginfo, reqinfo, requests, NULL)); return (SNMP_ERR_NOERROR); }