/* * 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. */ /* * The SNMP picl plugin connects to the agent on the SP and creates * and populates the /physical-platform subtree in picl tree for use * by picl consumers. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "picloids.h" #include "libpiclsnmp.h" #include "snmpplugin.h" #pragma init(snmpplugin_register) /* place in .init section */ picld_plugin_reg_t snmpplugin_reg = { PICLD_PLUGIN_VERSION_1, PICLD_PLUGIN_NON_CRITICAL, "snmp_plugin", snmpplugin_init, snmpplugin_fini }; static picl_snmphdl_t hdl; /* * The stale_tree_rwlp protects the stale_xxx vars. The 'stale_tree' flag * and the 'rebuild_tree' flag below are both initialized to B_TRUE to * let the tree_builder() thread build the initial tree without blocking. */ static rwlock_t stale_tree_rwlp; static boolean_t stale_tree = B_TRUE; /* * vol_props, volprop_ndx and n_vol_props are protected by the stale_tree * flag. They are read only when the stale_tree flag is B_FALSE and written * to only when the flag is B_TRUE. * * The change_time (last changed time) is read by only one thread at a * time when stale_tree is B_FALSE (protected by stale_tree_rwlp). It is * written by only one thread (the tree builder) when stale_tree is B_TRUE. * * Note that strictly speaking, change_time should be uint_t (timeticks32). * But keeping it as int is fine, since we don't do any arithmetic on it * except equality check. */ static vol_prophdl_t *vol_props = NULL; static int volprop_ndx = 0, n_vol_props = 0; static int change_time = 0; static time_t change_time_check; /* * The rebuild_tree_lock and cv are used by the tree builder thread. * rebuild_tree has to be initialized to B_TRUE to let the tree_builder * do the first build without blocking. */ static mutex_t rebuild_tree_lock; static cond_t rebuild_tree_cv; static boolean_t rebuild_tree = B_TRUE; static boolean_t tree_builder_thr_exit = B_FALSE; static thread_t tree_builder_thr_id; /* * The cache_refresh thread periodically queries the snmp cache refresh work * queue and processes jobs from it to keep cache entries from expiring. It * attempts to run in cycles of CACHE_REFRESH_CYCLE seconds each, first * processing cache refresh jobs and then sleeping for the remainder of the * cycle once the next refresh job expiration is at least * CACHE_REFRESH_MIN_WINDOW seconds in the future. * * NOTE: By using a thread to keep the SNMP cache refreshed in the background, * we are both adding load to the system and reducing the system's ability to * operate in power-saving mode when there is minimal load. While these * tradeoffs are acceptable at this time in light of customer concerns about * performance, it may be desirable in the future to move this work into the * firmware. Also, while the current cycle times performed well on the largest * sun4v config currently available (Batoka), they may need to be revisited for * future systems if the number of sensors increases significantly. */ #define CACHE_REFRESH_CYCLE 60 #define CACHE_REFRESH_MIN_WINDOW 75 static mutex_t cache_refresh_lock; static cond_t cache_refresh_cv; static boolean_t cache_refresh_thr_exit = B_FALSE; static thread_t cache_refresh_thr_id; /* * These two should really not be global */ static picl_nodehdl_t *physplat_nodes = NULL; static int n_physplat_nodes = 0; static char *group1[] = { OID_entPhysicalDescr, OID_entPhysicalContainedIn, OID_entPhysicalClass, OID_entPhysicalName, OID_entPhysicalHardwareRev, OID_entPhysicalFirmwareRev, OID_entPhysicalSerialNum, OID_entPhysicalMfgName, OID_entPhysicalModelName, OID_entPhysicalIsFRU, 0 }; static char *group2[] = { OID_sunPlatEquipmentHolderAcceptableTypes, OID_sunPlatCircuitPackReplaceable, OID_sunPlatCircuitPackHotSwappable, OID_sunPlatPhysicalClass, OID_sunPlatSensorClass, OID_sunPlatSensorType, OID_sunPlatAlarmType, OID_sunPlatPowerSupplyClass, 0 }; static char *group3[] = { OID_sunPlatNumericSensorEnabledThresholds, OID_sunPlatNumericSensorBaseUnits, OID_sunPlatNumericSensorRateUnits, 0 }; static char *group4[] = { OID_sunPlatBinarySensorInterpretTrue, OID_sunPlatBinarySensorInterpretFalse, 0 }; static char *volgroup1[] = { OID_sunPlatBinarySensorCurrent, OID_sunPlatBinarySensorExpected, 0 }; static char *volgroup2[] = { OID_sunPlatNumericSensorExponent, OID_sunPlatNumericSensorCurrent, OID_sunPlatNumericSensorLowerThresholdFatal, OID_sunPlatNumericSensorLowerThresholdCritical, OID_sunPlatNumericSensorLowerThresholdNonCritical, OID_sunPlatNumericSensorUpperThresholdNonCritical, OID_sunPlatNumericSensorUpperThresholdCritical, OID_sunPlatNumericSensorUpperThresholdFatal, 0 }; static char *volgroup3[] = { OID_sunPlatEquipmentOperationalState, 0 }; static char *volgroup4[] = { OID_sunPlatAlarmState, 0 }; static char *volgroup5[] = { OID_sunPlatBatteryStatus, 0 }; /* * The following two items must match the Sun Platform MIB specification * in their indices and values. */ static char *sensor_baseunits[] = { "", "other", "unknown", "degC", "degF", "degK", "volts", "amps", "watts", "joules", "coulombs", "va", "nits", "lumens", "lux", "candelas", "kPa", "psi", "newtons", "cfm", "rpm", "hertz", "seconds", "minutes", "hours", "days", "weeks", "mils", "inches", "feet", "cubicInches", "cubicFeet", "meters", "cubicCentimeters", "cubicMeters", "liters", "fluidOunces", "radians", "steradians", "revolutions", "cycles", "gravities", "ounces", "pounds", "footPounds", "ounceInches", "gauss", "gilberts", "henries", "farads", "ohms", "siemens", "moles", "becquerels", "ppm", "decibels", "dBA", "dbC", "grays", "sieverts", "colorTemperatureDegK", "bits", "bytes", "words", "doubleWords", "quadWords", "percentage" }; static const int n_baseunits = sizeof (sensor_baseunits) / sizeof (char *); static char *sensor_rateunits[] = { "", "none", "perMicroSecond", "perMilliSecond", "perSecond", "perMinute", "perHour", "perDay", "perWeek", "perMonth", "perYear" }; static const int n_rateunits = sizeof (sensor_rateunits) / sizeof (char *); /* * Local declarations */ static void snmpplugin_register(void); static void register_group(char **g, int is_volatile); static void *tree_builder(void *arg); static int build_physplat(picl_nodehdl_t *subtree_rootp); static void free_resources(picl_nodehdl_t subtree_root); static picl_nodehdl_t make_node(picl_nodehdl_t subtree_root, int row, int *snmp_syserr_p); static void save_nodeh(picl_nodehdl_t nodeh, int row); static picl_nodehdl_t lookup_nodeh(int row); static void save_volprop(picl_prophdl_t prop, char *oidstr, int row, int proptype); static void check_for_stale_data(boolean_t nocache); static int read_volprop(ptree_rarg_t *parg, void *buf); static void threshold(picl_nodehdl_t node, char *oidstr, int row, char *propname, int *snmp_syserr_p); static void add_thresholds(picl_nodehdl_t node, int row, int *snmp_syserr_p); static char *get_slot_type(int row, int *snmp_syserr_p); static int add_volatile_prop(picl_nodehdl_t nodeh, char *name, int type, int access, int size, int (*rdfunc)(ptree_rarg_t *, void *), int (*wrfunc)(ptree_warg_t *, const void *), picl_prophdl_t *propp); static int add_string_prop(picl_nodehdl_t node, char *propname, char *propval); static int add_void_prop(picl_nodehdl_t node, char *propname); static void add_prop(picl_nodehdl_t nodeh, picl_prophdl_t *php, char *label, int row, sp_propid_t pp, int *snmp_syserr_p); static void *cache_refresher(void *arg); static void cache_refresher_fini(void); static void log_msg(int pri, const char *fmt, ...); #ifdef SNMPPLUGIN_DEBUG static mutex_t snmpplugin_dbuf_lock; static char *snmpplugin_dbuf = NULL; static char *snmpplugin_dbuf_curp = NULL; static int snmpplugin_dbuf_sz = 0; static int snmpplugin_dbuf_overflow = 0; static char snmpplugin_lbuf[SNMPPLUGIN_DMAX_LINE]; static void snmpplugin_log_init(void); static void snmpplugin_log(const char *fmt, ...); static void snmpplugin_log_append(void); static void snmpplugin_dbuf_realloc(void); #endif static void snmpplugin_register(void) { (void) picld_plugin_register(&snmpplugin_reg); } static void register_group(char **g, int is_volatile) { int i, len = 0; int n_oids; char *p, *oidstrs; for (i = 0; g[i]; i++) len += strlen(g[i]) + 1; n_oids = i; if ((oidstrs = (char *)calloc(1, len)) == NULL) return; for (p = oidstrs, i = 0; g[i]; i++) { (void) strcpy(p, g[i]); p += strlen(g[i]) + 1; } snmp_register_group(hdl, oidstrs, n_oids, is_volatile); free(oidstrs); } void snmpplugin_init(void) { int ret; (void) mutex_init(&rebuild_tree_lock, USYNC_THREAD, NULL); (void) cond_init(&rebuild_tree_cv, USYNC_THREAD, NULL); (void) rwlock_init(&stale_tree_rwlp, USYNC_THREAD, NULL); tree_builder_thr_exit = B_FALSE; LOGINIT(); /* * Create the tree-builder thread and let it take over */ LOGPRINTF("Tree-builder thread being created.\n"); if ((ret = thr_create(NULL, NULL, tree_builder, NULL, THR_BOUND, &tree_builder_thr_id)) < 0) { log_msg(LOG_ERR, SNMPP_CANT_CREATE_TREE_BUILDER, ret); snmp_fini(hdl); hdl = NULL; (void) rwlock_destroy(&stale_tree_rwlp); (void) cond_destroy(&rebuild_tree_cv); (void) mutex_destroy(&rebuild_tree_lock); tree_builder_thr_exit = B_TRUE; return; } /* * While the cache refresher thread does improve performance, it is not * integral to the proper function of the plugin. If we fail to create * the thread for some reason, we will simply continue without * refreshing. */ (void) mutex_init(&cache_refresh_lock, USYNC_THREAD, NULL); (void) cond_init(&cache_refresh_cv, USYNC_THREAD, NULL); cache_refresh_thr_exit = B_FALSE; LOGPRINTF("Cache refresher thread being created.\n"); if (thr_create(NULL, NULL, cache_refresher, NULL, THR_BOUND, &cache_refresh_thr_id) < 0) { (void) cond_destroy(&cache_refresh_cv); (void) mutex_destroy(&cache_refresh_lock); cache_refresh_thr_exit = B_TRUE; } } void snmpplugin_fini(void) { if (tree_builder_thr_exit == B_TRUE) return; /* * Make reads of volatile properties return PICL_PROPUNAVAILABLE * since we're about to recycle the plug-in. No need to worry * about removing /physical-platform since tree_builder() will * take care of recycling it for us. */ (void) rw_wrlock(&stale_tree_rwlp); stale_tree = B_TRUE; if (vol_props) { free(vol_props); } vol_props = NULL; volprop_ndx = 0; n_vol_props = 0; (void) rw_unlock(&stale_tree_rwlp); /* clean up the cache_refresher thread and structures */ cache_refresher_fini(); /* wake up the tree_builder thread, tell it to exit */ (void) mutex_lock(&rebuild_tree_lock); rebuild_tree = B_TRUE; tree_builder_thr_exit = B_TRUE; (void) cond_signal(&rebuild_tree_cv); (void) mutex_unlock(&rebuild_tree_lock); /* reap the thread */ (void) thr_join(tree_builder_thr_id, NULL, NULL); /* close the channel */ if (hdl != NULL) { snmp_fini(hdl); hdl = NULL; } /* finish cleanup... */ (void) rwlock_destroy(&stale_tree_rwlp); (void) cond_destroy(&rebuild_tree_cv); (void) mutex_destroy(&rebuild_tree_lock); } /*ARGSUSED*/ static void * tree_builder(void *arg) { int ret, rv; picl_nodehdl_t root_node; picl_nodehdl_t physplat_root; picl_nodehdl_t old_physplat_root; /* * Initialize SNMP service */ LOGPRINTF("Initializing SNMP service.\n"); if ((hdl = snmp_init()) == NULL) { log_msg(LOG_ERR, SNMPP_CANT_INIT); return ((void *)-1); } /* * Register OID groupings for BULKGET optimizations */ LOGPRINTF("Registering OID groups.\n"); register_group(group1, 0); register_group(group2, 0); register_group(group3, 0); register_group(group4, 0); register_group(volgroup1, 1); register_group(volgroup2, 1); register_group(volgroup3, 1); register_group(volgroup4, 1); register_group(volgroup5, 1); (void) mutex_lock(&rebuild_tree_lock); for (;;) { LOGPRINTF("tree_builder: check whether to rebuild subtree\n"); while (rebuild_tree == B_FALSE) (void) cond_wait(&rebuild_tree_cv, &rebuild_tree_lock); LOGPRINTF("tree_builder: woke up\n"); if (tree_builder_thr_exit == B_TRUE) { (void) mutex_unlock(&rebuild_tree_lock); LOGPRINTF("tree_builder: time to exit\n"); return (NULL); } old_physplat_root = NULL; physplat_root = NULL; LOGPRINTF("tree_builder: getting root node\n"); if ((ret = ptree_get_root(&root_node)) != PICL_SUCCESS) { (void) mutex_unlock(&rebuild_tree_lock); log_msg(LOG_ERR, SNMPP_NO_ROOT, ret); return ((void *)-2); } LOGPRINTF("tree_builder: getting existing physplat node\n"); rv = ptree_find_node(root_node, PICL_PROP_NAME, PICL_PTYPE_CHARSTRING, PICL_NODE_PHYSPLAT, sizeof (PICL_NODE_PHYSPLAT), &old_physplat_root); LOGPRINTF("tree_builder: building physical-platform\n"); if ((ret = build_physplat(&physplat_root)) < 0) { (void) mutex_unlock(&rebuild_tree_lock); log_msg(LOG_ERR, SNMPP_CANT_CREATE_PHYSPLAT, ret); cache_refresher_fini(); snmp_fini(hdl); hdl = NULL; return ((void *)-3); } if (rv == PICL_SUCCESS && old_physplat_root != NULL) { LOGPRINTF("tree_builder: destroying existing nodes\n"); ptree_delete_node(old_physplat_root); ptree_destroy_node(old_physplat_root); } LOGPRINTF("tree_builder: attaching new subtree\n"); if ((ret = ptree_add_node(root_node, physplat_root)) < 0) { (void) mutex_unlock(&rebuild_tree_lock); free_resources(physplat_root); log_msg(LOG_ERR, SNMPP_CANT_CREATE_PHYSPLAT, ret); cache_refresher_fini(); snmp_fini(hdl); hdl = NULL; return ((void *)-4); } LOGPRINTF("tree_builder: setting stale_tree to FALSE\n"); (void) rw_wrlock(&stale_tree_rwlp); stale_tree = B_FALSE; (void) rw_unlock(&stale_tree_rwlp); LOGPRINTF("tree_builder: setting rebuild_tree to FALSE\n"); rebuild_tree = B_FALSE; } /*NOTREACHED*/ return (NULL); } static int build_physplat(picl_nodehdl_t *subtree_rootp) { int change_time1; int row, nxtrow; int clr_linkreset = 0; int ret = 0; int snmp_syserr = 0; retry: (void) snmp_reinit(hdl, clr_linkreset); clr_linkreset = 0; /* * Record LastChangeTime before we start building the tree */ ret = snmp_get_int(hdl, OID_entLastChangeTime, 0, &change_time1, &snmp_syserr); if (ret < 0) { if (snmp_syserr == ECANCELED) { LOGPRINTF(SNMPP_LINK_RESET); clr_linkreset = 1; goto retry; } log_msg(LOG_WARNING, SNMPP_CANT_FETCH_OBJECT_VAL, snmp_syserr ? snmp_syserr : ret, OID_entLastChangeTime, 0); } /* * Create the physical-platform node */ ret = ptree_create_node(PICL_NODE_PHYSPLAT, PICL_CLASS_PICL, subtree_rootp); if (ret != PICL_SUCCESS) return (-1); /* * Scan entPhysicalTable and build the "physical-platform" subtree */ ret = 0; for (row = -1; ret == 0; row = nxtrow) { ret = snmp_get_nextrow(hdl, OID_entPhysicalDescr, row, &nxtrow, &snmp_syserr); if (ret == 0) (void) make_node(*subtree_rootp, nxtrow, &snmp_syserr); switch (snmp_syserr) { case ECANCELED: /* * If we get this error, a link reset must've * happened and we need to throw away everything * we have now and rebuild the tree again. */ log_msg(LOG_WARNING, SNMPP_LINK_RESET); free_resources(*subtree_rootp); clr_linkreset = 1; goto retry; /*NOTREACHED*/ break; case ENOSPC: /* end of MIB */ LOGPRINTF("build_physplat: end of MIB\n"); break; case ENOENT: /* end of table */ LOGPRINTF("build_physplat: end of table\n"); break; default: /* * make_node() will print messages so don't * repeat that exercise here. */ if (ret == -1) { log_msg(LOG_WARNING, SNMPP_CANT_FETCH_OBJECT_VAL, snmp_syserr ? snmp_syserr : ret, OID_entPhysicalDescr, row); } } } /* * Record LastChangeTime after we're done building the tree */ ret = snmp_get_int(hdl, OID_entLastChangeTime, 0, &change_time, &snmp_syserr); if (ret < 0) { if (snmp_syserr == ECANCELED) { log_msg(LOG_WARNING, SNMPP_LINK_RESET); free_resources(*subtree_rootp); clr_linkreset = 1; goto retry; } else log_msg(LOG_WARNING, SNMPP_CANT_FETCH_OBJECT_VAL, snmp_syserr ? snmp_syserr : ret, OID_entLastChangeTime, row); } /* * If they don't match, some hotplugging must've happened, * free resources we've created and still holding, then go * back and retry */ if (change_time != change_time1) { LOGPRINTF("build_physplat: entLastChangeTime has changed!\n"); free_resources(*subtree_rootp); change_time1 = change_time; goto retry; } /* * The physplat_nodes table is no longer needed, free it */ if (physplat_nodes) { free(physplat_nodes); physplat_nodes = NULL; n_physplat_nodes = 0; } return (0); } /* * Destroy all resources that were created during the building * of the subtree */ static void free_resources(picl_nodehdl_t subtree_root) { if (physplat_nodes) { free(physplat_nodes); physplat_nodes = NULL; n_physplat_nodes = 0; } if (subtree_root) { (void) ptree_delete_node(subtree_root); (void) ptree_destroy_node(subtree_root); } if (vol_props) { free(vol_props); n_vol_props = 0; volprop_ndx = 0; } } static picl_nodehdl_t make_node(picl_nodehdl_t subtree_root, int row, int *snmp_syserr_p) { picl_nodehdl_t nodeh, parenth; picl_prophdl_t proph; char *phys_name, *node_name; int parent_row; int ent_physclass, sunplat_physclass; int sensor_class, sensor_type; int alarm_type; int ps_class; int ret; /* * If we've already created this picl node, just return it */ if ((nodeh = lookup_nodeh(row)) != NULL) return (nodeh); /* * If we are creating it only now, make sure we have the parent * created first; if there's no parent, then parent it to the * subtree's root node */ ret = snmp_get_int(hdl, OID_entPhysicalContainedIn, row, &parent_row, snmp_syserr_p); CHECK_LINKRESET(snmp_syserr_p, NULL) if (ret < 0 || parent_row <= 0) parenth = subtree_root; else { parenth = make_node(subtree_root, parent_row, snmp_syserr_p); CHECK_LINKRESET(snmp_syserr_p, NULL) if (parenth == NULL) parenth = subtree_root; } /* * Figure out the physical-platform node name from entPhysicalName; * all rows in the MIB that have a valid entPhysicalIndex should * have a physical name. */ ret = snmp_get_str(hdl, OID_entPhysicalName, row, &phys_name, snmp_syserr_p); CHECK_LINKRESET(snmp_syserr_p, NULL) if (ret < 0 || phys_name == NULL) { log_msg(LOG_WARNING, SNMPP_NO_ENTPHYSNAME, row); return (NULL); } node_name = basename(phys_name); ret = snmp_get_int(hdl, OID_entPhysicalClass, row, &ent_physclass, snmp_syserr_p); CHECK_LINKRESET(snmp_syserr_p, NULL) if (ret < 0) { log_msg(LOG_WARNING, SNMPP_CANT_FETCH_OBJECT_VAL, *snmp_syserr_p ? *snmp_syserr_p : ret, OID_entPhysicalClass, row); free(phys_name); return (NULL); } switch (ent_physclass) { case SPC_OTHER: ret = snmp_get_int(hdl, OID_sunPlatPhysicalClass, row, &sunplat_physclass, snmp_syserr_p); CHECK_LINKRESET(snmp_syserr_p, NULL) if (ret < 0) { log_msg(LOG_WARNING, SNMPP_CANT_FETCH_OBJECT_VAL, *snmp_syserr_p ? *snmp_syserr_p : ret, OID_sunPlatPhysicalClass, row); free(phys_name); return (NULL); } if (sunplat_physclass == SSPC_ALARM) { ret = snmp_get_int(hdl, OID_sunPlatAlarmType, row, &alarm_type, snmp_syserr_p); CHECK_LINKRESET(snmp_syserr_p, NULL) if (ret < 0) { log_msg(LOG_WARNING, SNMPP_CANT_FETCH_OBJECT_VAL, *snmp_syserr_p ? *snmp_syserr_p : ret, OID_sunPlatAlarmType, row); free(phys_name); return (NULL); } if (alarm_type == SSAT_VISIBLE) { ADD_NODE(PICL_CLASS_LED) } else { ADD_NODE(PICL_CLASS_ALARM) } add_prop(nodeh, &proph, node_name, row, PP_STATE, snmp_syserr_p); CHECK_LINKRESET(snmp_syserr_p, NULL) } else { ADD_NODE(PICL_CLASS_OTHER) } add_prop(nodeh, &proph, node_name, row, PP_OPSTATUS, snmp_syserr_p); CHECK_LINKRESET(snmp_syserr_p, NULL) break; case SPC_UNKNOWN: ADD_NODE(PICL_CLASS_UNKNOWN) break; case SPC_CHASSIS: ADD_NODE(PICL_CLASS_CHASSIS) add_prop(nodeh, &proph, node_name, row, PP_OPSTATUS, snmp_syserr_p); CHECK_LINKRESET(snmp_syserr_p, NULL) break; case SPC_BACKPLANE: ADD_NODE(PICL_CLASS_BACKPLANE) add_prop(nodeh, &proph, node_name, row, PP_OPSTATUS, snmp_syserr_p); CHECK_LINKRESET(snmp_syserr_p, NULL) break; case SPC_CONTAINER: ADD_NODE(PICL_CLASS_CONTAINER) add_prop(nodeh, &proph, node_name, row, PP_OPSTATUS, snmp_syserr_p); CHECK_LINKRESET(snmp_syserr_p, NULL) add_prop(nodeh, &proph, node_name, row, PP_SLOT_TYPE, snmp_syserr_p); CHECK_LINKRESET(snmp_syserr_p, NULL) break; case SPC_POWERSUPPLY: ret = snmp_get_int(hdl, OID_sunPlatPowerSupplyClass, row, &ps_class, snmp_syserr_p); CHECK_LINKRESET(snmp_syserr_p, NULL) if (ret < 0) { log_msg(LOG_WARNING, SNMPP_CANT_FETCH_OBJECT_VAL, *snmp_syserr_p ? *snmp_syserr_p : ret, OID_sunPlatPowerSupplyClass, row); free(phys_name); return (NULL); } if (ps_class == SSPSC_BATTERY) { ADD_NODE(PICL_CLASS_BATTERY) add_prop(nodeh, &proph, node_name, row, PP_BATT_STATUS, snmp_syserr_p); CHECK_LINKRESET(snmp_syserr_p, NULL) } else { ADD_NODE(PICL_CLASS_POWERSUPPLY) } add_prop(nodeh, &proph, node_name, row, PP_OPSTATUS, snmp_syserr_p); CHECK_LINKRESET(snmp_syserr_p, NULL) break; case SPC_FAN: ADD_NODE(PICL_CLASS_FAN) add_prop(nodeh, &proph, node_name, row, PP_OPSTATUS, snmp_syserr_p); CHECK_LINKRESET(snmp_syserr_p, NULL) break; case SPC_SENSOR: ret = snmp_get_int(hdl, OID_sunPlatSensorClass, row, &sensor_class, snmp_syserr_p); CHECK_LINKRESET(snmp_syserr_p, NULL) if (ret < 0) { log_msg(LOG_WARNING, SNMPP_CANT_FETCH_OBJECT_VAL, *snmp_syserr_p ? *snmp_syserr_p : ret, OID_sunPlatSensorClass, row); free(phys_name); return (NULL); } ret = snmp_get_int(hdl, OID_sunPlatSensorType, row, &sensor_type, snmp_syserr_p); CHECK_LINKRESET(snmp_syserr_p, NULL) if (ret < 0) { log_msg(LOG_WARNING, SNMPP_CANT_FETCH_OBJECT_VAL, *snmp_syserr_p ? *snmp_syserr_p : ret, OID_sunPlatSensorType, row); free(phys_name); return (NULL); } if (sensor_class == SSSC_NUMERIC) { if (sensor_type == SSST_TEMPERATURE) { ADD_NODE(PICL_CLASS_TEMPERATURE_SENSOR) add_prop(nodeh, &proph, node_name, row, PP_TEMPERATURE, snmp_syserr_p); } else if (sensor_type == SSST_VOLTAGE) { ADD_NODE(PICL_CLASS_VOLTAGE_SENSOR) add_prop(nodeh, &proph, node_name, row, PP_VOLTAGE, snmp_syserr_p); } else if (sensor_type == SSST_CURRENT) { ADD_NODE(PICL_CLASS_CURRENT_SENSOR) add_prop(nodeh, &proph, node_name, row, PP_CURRENT, snmp_syserr_p); } else if (sensor_type == SSST_TACHOMETER) { ADD_NODE(PICL_CLASS_RPM_SENSOR) add_prop(nodeh, &proph, node_name, row, PP_SPEED, snmp_syserr_p); } else { ADD_NODE(PICL_CLASS_SENSOR) add_prop(nodeh, &proph, node_name, row, PP_SENSOR_VALUE, snmp_syserr_p); } CHECK_LINKRESET(snmp_syserr_p, NULL) add_prop(nodeh, &proph, node_name, row, PP_OPSTATUS, snmp_syserr_p); CHECK_LINKRESET(snmp_syserr_p, NULL) add_prop(nodeh, &proph, node_name, row, PP_BASE_UNITS, snmp_syserr_p); CHECK_LINKRESET(snmp_syserr_p, NULL) add_prop(nodeh, &proph, node_name, row, PP_EXPONENT, snmp_syserr_p); CHECK_LINKRESET(snmp_syserr_p, NULL) add_prop(nodeh, &proph, node_name, row, PP_RATE_UNITS, snmp_syserr_p); CHECK_LINKRESET(snmp_syserr_p, NULL) add_thresholds(nodeh, row, snmp_syserr_p); CHECK_LINKRESET(snmp_syserr_p, NULL) } else if (sensor_class == SSSC_BINARY) { if (sensor_type == SSST_TEMPERATURE) { ADD_NODE(PICL_CLASS_TEMPERATURE_INDICATOR) } else if (sensor_type == SSST_VOLTAGE) { ADD_NODE(PICL_CLASS_VOLTAGE_INDICATOR) } else if (sensor_type == SSST_CURRENT) { ADD_NODE(PICL_CLASS_CURRENT_INDICATOR) } else if (sensor_type == SSST_TACHOMETER) { ADD_NODE(PICL_CLASS_RPM_INDICATOR) } else if (sensor_type == SSST_PRESENCE) { ADD_NODE(PICL_CLASS_PRESENCE_INDICATOR) } else { ADD_NODE(PICL_CLASS_INDICATOR) } add_prop(nodeh, &proph, node_name, row, PP_OPSTATUS, snmp_syserr_p); CHECK_LINKRESET(snmp_syserr_p, NULL) add_prop(nodeh, &proph, node_name, row, PP_CONDITION, snmp_syserr_p); CHECK_LINKRESET(snmp_syserr_p, NULL) add_prop(nodeh, &proph, node_name, row, PP_EXPECTED, snmp_syserr_p); CHECK_LINKRESET(snmp_syserr_p, NULL) } else { log_msg(LOG_ERR, SNMPP_UNSUPP_SENSOR_CLASS, sensor_class, row); return (NULL); } break; case SPC_MODULE: ADD_NODE(PICL_CLASS_MODULE) add_prop(nodeh, &proph, node_name, row, PP_OPSTATUS, snmp_syserr_p); CHECK_LINKRESET(snmp_syserr_p, NULL) add_prop(nodeh, &proph, node_name, row, PP_REPLACEABLE, snmp_syserr_p); CHECK_LINKRESET(snmp_syserr_p, NULL) add_prop(nodeh, &proph, node_name, row, PP_HOTSWAPPABLE, snmp_syserr_p); CHECK_LINKRESET(snmp_syserr_p, NULL) break; case SPC_PORT: ADD_NODE(PICL_CLASS_PORT) break; case SPC_STACK: ADD_NODE(PICL_CLASS_STACK) break; default: log_msg(LOG_WARNING, SNMPP_UNKNOWN_ENTPHYSCLASS, ent_physclass, row); free(phys_name); return (NULL); } add_prop(nodeh, &proph, node_name, row, PP_DESCRIPTION, snmp_syserr_p); CHECK_LINKRESET(snmp_syserr_p, NULL) add_prop(nodeh, &proph, node_name, row, PP_LABEL, snmp_syserr_p); CHECK_LINKRESET(snmp_syserr_p, NULL) add_prop(nodeh, &proph, node_name, row, PP_HW_REVISION, snmp_syserr_p); CHECK_LINKRESET(snmp_syserr_p, NULL) add_prop(nodeh, &proph, node_name, row, PP_FW_REVISION, snmp_syserr_p); CHECK_LINKRESET(snmp_syserr_p, NULL) add_prop(nodeh, &proph, node_name, row, PP_SERIAL_NUM, snmp_syserr_p); CHECK_LINKRESET(snmp_syserr_p, NULL) add_prop(nodeh, &proph, node_name, row, PP_MFG_NAME, snmp_syserr_p); CHECK_LINKRESET(snmp_syserr_p, NULL) add_prop(nodeh, &proph, node_name, row, PP_MODEL_NAME, snmp_syserr_p); CHECK_LINKRESET(snmp_syserr_p, NULL) add_prop(nodeh, &proph, node_name, row, PP_IS_FRU, snmp_syserr_p); CHECK_LINKRESET(snmp_syserr_p, NULL) free(phys_name); save_nodeh(nodeh, row); return (nodeh); } /* * Saves the node handle and the row id into physplat_nodes[]. If we're * doing this in response to a hotplug event, we should've freed the * old physplat_nodes before entering here to save the first node of the * new physplat subtree. */ static void save_nodeh(picl_nodehdl_t nodeh, int row) { size_t sz, count; picl_nodehdl_t *p; if (row >= n_physplat_nodes) { count = (((size_t)row >> NODE_BLOCK_SHIFT) + 1) * N_ELEMS_IN_NODE_BLOCK; sz = count * sizeof (picl_nodehdl_t); p = (picl_nodehdl_t *)calloc(count, sizeof (picl_nodehdl_t)); if (p == NULL) { log_msg(LOG_ERR, SNMPP_NO_MEM, sz); return; } if (physplat_nodes) { (void) memcpy((void *) p, (void *) physplat_nodes, n_physplat_nodes * sizeof (picl_nodehdl_t)); free((void *) physplat_nodes); } physplat_nodes = p; n_physplat_nodes = count; } physplat_nodes[row] = nodeh; } static picl_nodehdl_t lookup_nodeh(int row) { if (row >= n_physplat_nodes) return (NULL); return (physplat_nodes[row]); } /* * We enter this routine only when we are building the physical-platform * subtree, whether for the first time or in response to a hotplug event. * If we're here for rebuilding the tree, we have already set stale_tree * to be B_TRUE, so no one else would be accessing vol_props, n_vol_props * or volprop_ndx. If we're here to build the tree for the first time, * picld hasn't yet created doors and is running single-threaded, so no * one else would be accessing them anyway. */ static void save_volprop(picl_prophdl_t prop, char *oidstr, int row, int proptype) { vol_prophdl_t *p; int count; if (volprop_ndx == n_vol_props) { count = n_vol_props + N_ELEMS_IN_VOLPROP_BLOCK; p = (vol_prophdl_t *)calloc(count, sizeof (vol_prophdl_t)); if (p == NULL) { log_msg(LOG_ERR, SNMPP_NO_MEM, count * sizeof (vol_prophdl_t)); return; } if (vol_props) { (void) memcpy((void *) p, (void *) vol_props, n_vol_props * sizeof (vol_prophdl_t)); free((void *) vol_props); } vol_props = p; n_vol_props += N_ELEMS_IN_VOLPROP_BLOCK; } vol_props[volprop_ndx].prop = prop; vol_props[volprop_ndx].oidstr = oidstr; vol_props[volprop_ndx].row = row; vol_props[volprop_ndx].proptype = proptype; volprop_ndx++; } static void check_for_stale_data(boolean_t nocache) { int cur_change_time; int ret; int snmp_syserr; (void) rw_wrlock(&stale_tree_rwlp); /* * Check if some other thread beat us to it */ if (stale_tree == B_TRUE) { (void) rw_unlock(&stale_tree_rwlp); return; } /* * Cache OID_entLastChangeTime for up to 10 seconds before * fetching it from ILOM again. This prevents us from fetching * this value from ILOM when the we're filling or refreshing a * whole bunch of items in the cache around the same time. */ if (nocache == B_FALSE && time(NULL) - change_time_check <= 10) { (void) rw_unlock(&stale_tree_rwlp); return; } /* * Check if mib data has changed (hotplug? link-reset?) */ do { snmp_syserr = 0; ret = snmp_get_int(hdl, OID_entLastChangeTime, 0, &cur_change_time, &snmp_syserr); (void) time(&change_time_check); if ((ret == 0) && (cur_change_time == change_time)) { (void) rw_unlock(&stale_tree_rwlp); return; } } while (ret != 0 && snmp_syserr == EINTR); /* * If we can't read entLastChangeTime we assume we need to rebuild * the tree. This will also cover the case when we need to rebuild * the tree because a link reset had happened. */ LOGPRINTF2("check_for_stale_data: LastChange times have changed, " "(%#x != %#x)\n", change_time, cur_change_time); /* * If the mib data has changed, we need to rebuild the physical-platform * subtree. To do this, we set a flag to mark the tree stale, * so that any future reads to get value of volatile properties will * return PICL_PROPVALUNAVAILABLE, until the stale_tree flag * is reset by the tree builder thread. */ stale_tree = B_TRUE; if (vol_props) { free(vol_props); } vol_props = NULL; volprop_ndx = 0; n_vol_props = 0; (void) rw_unlock(&stale_tree_rwlp); (void) mutex_lock(&rebuild_tree_lock); rebuild_tree = B_TRUE; (void) cond_signal(&rebuild_tree_cv); LOGPRINTF("check_for_stale_data: signalled tree builder\n"); (void) mutex_unlock(&rebuild_tree_lock); } /* * This is the critical routine. This callback is invoked by picl whenever * it needs to fetch the value of a volatile property. The first thing we * must do, however, is to see if there has been a hotplug or a link-reset * event since the last time we built the tree and whether we need to * rebuild the tree. If so, we do whatever is necessary to make that happen, * but return PICL_PROPVALUNAVAILABLE for now, without making any further * snmp requests or accessing any globals. */ static int read_volprop(ptree_rarg_t *parg, void *buf) { char *pstr; int propval; int i, ndx; int ret; int snmp_syserr = 0; /* * First check for any event that would make us throw away * the existing /physical-platform subtree and rebuild * another one. If we are rebuilding the subtree, we just * return the stale value until the tree is fully built. */ check_for_stale_data(B_FALSE); (void) rw_rdlock(&stale_tree_rwlp); if (stale_tree == B_TRUE) { (void) rw_unlock(&stale_tree_rwlp); return (PICL_PROPVALUNAVAILABLE); } for (i = 0; i < volprop_ndx; i++) { if (vol_props[i].prop == parg->proph) { ndx = i; break; } } if (i == volprop_ndx) { (void) rw_unlock(&stale_tree_rwlp); log_msg(LOG_ERR, SNMPP_CANT_FIND_VOLPROP, parg->proph); return (PICL_FAILURE); } /* * If we can't read the value, return failure. Even if this was * due to a link reset, between the check for stale data and now, * the next volatile callback by picl will initiate a tree-rebuild. */ ret = snmp_get_int(hdl, vol_props[ndx].oidstr, vol_props[ndx].row, &propval, &snmp_syserr); if (ret < 0) { (void) rw_unlock(&stale_tree_rwlp); check_for_stale_data(B_TRUE); if (stale_tree == B_TRUE) { return (PICL_PROPVALUNAVAILABLE); } log_msg(LOG_ERR, SNMPP_CANT_FETCH_OBJECT_VAL, snmp_syserr ? snmp_syserr : ret, vol_props[ndx].oidstr, vol_props[ndx].row); return (PICL_FAILURE); } switch (vol_props[ndx].proptype) { case VPT_PLATOPSTATE: if (propval == SSOS_DISABLED) { (void) strlcpy(buf, STR_SSOS_DISABLED, MAX_OPSTATE_LEN); } else if (propval == SSOS_ENABLED) { (void) strlcpy(buf, STR_SSOS_ENABLED, MAX_OPSTATE_LEN); } else { (void) rw_unlock(&stale_tree_rwlp); log_msg(LOG_ERR, SNMPP_INV_PLAT_EQUIP_OPSTATE, propval, vol_props[ndx].row); return (PICL_FAILURE); } break; case VPT_NUMSENSOR: (void) memcpy(buf, &propval, sizeof (propval)); break; case VPT_BINSENSOR: if (propval == ST_TRUE) { ret = snmp_get_str(hdl, OID_sunPlatBinarySensorInterpretTrue, vol_props[ndx].row, &pstr, &snmp_syserr); if (snmp_syserr == ECANCELED) { (void) rw_unlock(&stale_tree_rwlp); if (pstr) free(pstr); return (PICL_FAILURE); } if (ret < 0 || pstr == NULL) { log_msg(LOG_ERR, SNMPP_CANT_FETCH_OBJECT_VAL, snmp_syserr ? snmp_syserr : ret, OID_sunPlatBinarySensorInterpretTrue, vol_props[ndx].row); (void) strlcpy(buf, STR_ST_TRUE, MAX_TRUTHVAL_LEN); } else { (void) strlcpy(buf, pstr, MAX_TRUTHVAL_LEN); } if (pstr) free(pstr); } else if (propval == ST_FALSE) { ret = snmp_get_str(hdl, OID_sunPlatBinarySensorInterpretFalse, vol_props[ndx].row, &pstr, &snmp_syserr); if (snmp_syserr == ECANCELED) { (void) rw_unlock(&stale_tree_rwlp); if (pstr) free(pstr); return (PICL_FAILURE); } if (ret < 0 || pstr == NULL) { log_msg(LOG_ERR, SNMPP_CANT_FETCH_OBJECT_VAL, snmp_syserr ? snmp_syserr : ret, OID_sunPlatBinarySensorInterpretFalse, vol_props[ndx].row); (void) strlcpy(buf, STR_ST_FALSE, MAX_TRUTHVAL_LEN); } else { (void) strlcpy(buf, pstr, MAX_TRUTHVAL_LEN); } if (pstr) free(pstr); } else { (void) rw_unlock(&stale_tree_rwlp); log_msg(LOG_ERR, SNMPP_INV_PLAT_BINSNSR_CURRENT, propval, vol_props[ndx].row); return (PICL_FAILURE); } break; case VPT_ALARMSTATE: if (propval == SSAS_OFF) { (void) strlcpy(buf, STR_SSAS_OFF, MAX_ALARMSTATE_LEN); } else if (propval == SSAS_STEADY) { (void) strlcpy(buf, STR_SSAS_STEADY, MAX_ALARMSTATE_LEN); } else if (propval == SSAS_ALTERNATING) { (void) strlcpy(buf, STR_SSAS_ALTERNATING, MAX_ALARMSTATE_LEN); } else { (void) strlcpy(buf, STR_SSAS_UNKNOWN, MAX_ALARMSTATE_LEN); } break; case VPT_BATTERYSTATUS: switch (propval) { case SSBS_OTHER: (void) strlcpy(buf, STR_SSBS_OTHER, MAX_BATTERYSTATUS_LEN); break; case SSBS_FULLYCHARGED: (void) strlcpy(buf, STR_SSBS_FULLYCHARGED, MAX_BATTERYSTATUS_LEN); break; case SSBS_LOW: (void) strlcpy(buf, STR_SSBS_LOW, MAX_BATTERYSTATUS_LEN); break; case SSBS_CRITICAL: (void) strlcpy(buf, STR_SSBS_CRITICAL, MAX_BATTERYSTATUS_LEN); break; case SSBS_CHARGING: (void) strlcpy(buf, STR_SSBS_CHARGING, MAX_BATTERYSTATUS_LEN); break; case SSBS_CHARGING_AND_LOW: (void) strlcpy(buf, STR_SSBS_CHARGING_AND_LOW, MAX_BATTERYSTATUS_LEN); break; case SSBS_CHARGING_AND_HIGH: (void) strlcpy(buf, STR_SSBS_CHARGING_AND_HIGH, MAX_BATTERYSTATUS_LEN); break; case SSBS_CHARGING_AND_CRITICAL: (void) strlcpy(buf, STR_SSBS_CHARGING_AND_CRITICAL, MAX_BATTERYSTATUS_LEN); break; case SSBS_UNDEFINED: (void) strlcpy(buf, STR_SSBS_UNDEFINED, MAX_BATTERYSTATUS_LEN); break; case SSBS_PARTIALLY_CHARGED: (void) strlcpy(buf, STR_SSBS_PARTIALLY_CHARGED, MAX_BATTERYSTATUS_LEN); break; case SSBS_UNKNOWN: default: (void) strlcpy(buf, STR_SSBS_UNKNOWN, MAX_BATTERYSTATUS_LEN); break; } break; } (void) rw_unlock(&stale_tree_rwlp); return (PICL_SUCCESS); } static void threshold(picl_nodehdl_t node, char *oidstr, int row, char *propname, int *snmp_syserr_p) { picl_prophdl_t prop; int err; int val; if ((err = snmp_get_int(hdl, oidstr, row, &val, snmp_syserr_p)) != -1) { err = add_volatile_prop(node, propname, PICL_PTYPE_INT, PICL_READ, sizeof (int), read_volprop, NULL, &prop); if (err == PICL_SUCCESS) save_volprop(prop, oidstr, row, VPT_NUMSENSOR); } else log_msg(LOG_ERR, SNMPP_CANT_FETCH_OBJECT_VAL, *snmp_syserr_p ? *snmp_syserr_p : err, oidstr, row); } static void add_thresholds(picl_nodehdl_t node, int row, int *snmp_syserr_p) { uchar_t *bitstr = NULL; uchar_t enabled; uint_t nbytes; int ret; ret = snmp_get_str(hdl, OID_sunPlatNumericSensorEnabledThresholds, row, (char **)&bitstr, snmp_syserr_p); if (ret == -1) { log_msg(LOG_ERR, SNMPP_CANT_FETCH_OBJECT_VAL, *snmp_syserr_p ? *snmp_syserr_p : ret, OID_sunPlatNumericSensorEnabledThresholds, row); } else { nbytes = strlen((const char *)bitstr); } CHECK_LINKRESET_VOID(snmp_syserr_p); /* * No bit string of threshold masks was returned, so we can't * assume that any thresholds exist. * * This mask prevents us from attempting to fetch thresholds * which don't apply to the sensor or that aren't there anyway, * That speeds up the plug-in significantly since otherwise it * takes several seconds to time out. */ if (ret < 0 || bitstr == NULL || nbytes == 0 || 2 < nbytes) { if (bitstr) free(bitstr); return; } else if (nbytes == 1) { /* * The ALOM snmp agent doesn't adhere to the BER rules for * encoding bit strings. While the BER states that bitstrings * must begin from the second octet after length, and the * first octet after length must indicate the number of unused * bits in the last octet, the snmp agent simply sends the * bitstring data as if it were octet string -- that is, the * "unused bits" octet is missing. */ enabled = bitstr[0]; } else if (nbytes == 2) enabled = bitstr[1]; if (bitstr) { free(bitstr); } if (enabled & LOWER_FATAL) { threshold(node, OID_sunPlatNumericSensorLowerThresholdFatal, row, PICL_PROP_LOW_POWER_OFF, snmp_syserr_p); CHECK_LINKRESET_VOID(snmp_syserr_p) } if (enabled & LOWER_CRITICAL) { threshold(node, OID_sunPlatNumericSensorLowerThresholdCritical, row, PICL_PROP_LOW_SHUTDOWN, snmp_syserr_p); CHECK_LINKRESET_VOID(snmp_syserr_p) } if (enabled & LOWER_NON_CRITICAL) { threshold(node, OID_sunPlatNumericSensorLowerThresholdNonCritical, row, PICL_PROP_LOW_WARNING, snmp_syserr_p); CHECK_LINKRESET_VOID(snmp_syserr_p) } if (enabled & UPPER_NON_CRITICAL) { threshold(node, OID_sunPlatNumericSensorUpperThresholdNonCritical, row, PICL_PROP_HIGH_WARNING, snmp_syserr_p); CHECK_LINKRESET_VOID(snmp_syserr_p) } if (enabled & UPPER_CRITICAL) { threshold(node, OID_sunPlatNumericSensorUpperThresholdCritical, row, PICL_PROP_HIGH_SHUTDOWN, snmp_syserr_p); CHECK_LINKRESET_VOID(snmp_syserr_p) } if (enabled & UPPER_FATAL) { threshold(node, OID_sunPlatNumericSensorUpperThresholdFatal, row, PICL_PROP_HIGH_POWER_OFF, snmp_syserr_p); CHECK_LINKRESET_VOID(snmp_syserr_p) } } static char * get_slot_type(int row, int *snmp_syserr_p) { char *p; char *slott = NULL; int ret; ret = snmp_get_str(hdl, OID_sunPlatEquipmentHolderAcceptableTypes, row, &p, snmp_syserr_p); CHECK_LINKRESET(snmp_syserr_p, NULL) if ((ret == 0) && p && *p) { slott = p; if ((p = strchr(slott, '\n')) != NULL) *p = 0; } else { log_msg(LOG_WARNING, SNMPP_NO_SLOT_TYPE, row); if (p) { free(p); } } return (slott); } /* * Create and add the specified volatile property */ static int add_volatile_prop(picl_nodehdl_t node, char *name, int type, int access, int size, int (*rdfunc)(ptree_rarg_t *, void *), int (*wrfunc)(ptree_warg_t *, const void *), picl_prophdl_t *propp) { ptree_propinfo_t propinfo; picl_prophdl_t prop; int err; err = ptree_init_propinfo(&propinfo, PTREE_PROPINFO_VERSION, type, (access|PICL_VOLATILE), size, name, rdfunc, wrfunc); if (err != PICL_SUCCESS) { log_msg(LOG_ERR, SNMPP_CANT_INIT_PROPINFO, err); return (err); } err = ptree_create_and_add_prop(node, &propinfo, NULL, &prop); if (err != PICL_SUCCESS) { log_msg(LOG_ERR, SNMPP_CANT_ADD_PROP, err, node); return (err); } if (propp) *propp = prop; return (PICL_SUCCESS); } /* * Add the specified string property to the node */ static int add_string_prop(picl_nodehdl_t node, char *propname, char *propval) { ptree_propinfo_t propinfo; int err; if (*propval == '\0') return (PICL_SUCCESS); err = ptree_init_propinfo(&propinfo, PTREE_PROPINFO_VERSION, PICL_PTYPE_CHARSTRING, PICL_READ, strlen(propval) + 1, propname, NULL, NULL); if (err != PICL_SUCCESS) { log_msg(LOG_ERR, SNMPP_CANT_INIT_STR_PROPINFO, err); return (err); } err = ptree_create_and_add_prop(node, &propinfo, propval, NULL); if (err != PICL_SUCCESS) { log_msg(LOG_ERR, SNMPP_CANT_ADD_STR_PROP, err, node); return (err); } return (PICL_SUCCESS); } /* * Add the specified void property to the node */ static int add_void_prop(picl_nodehdl_t node, char *propname) { ptree_propinfo_t propinfo; int err; err = ptree_init_propinfo(&propinfo, PTREE_PROPINFO_VERSION, PICL_PTYPE_VOID, PICL_READ, 0, propname, NULL, NULL); if (err != PICL_SUCCESS) { log_msg(LOG_ERR, SNMPP_CANT_INIT_VOID_PROPINFO, err); return (err); } err = ptree_create_and_add_prop(node, &propinfo, NULL, NULL); if (err != PICL_SUCCESS) { log_msg(LOG_ERR, SNMPP_CANT_ADD_VOID_PROP, err, node); return (err); } return (PICL_SUCCESS); } static void add_prop(picl_nodehdl_t nodeh, picl_prophdl_t *php, char *label, int row, sp_propid_t pp, int *snmp_syserr_p) { char *serial_num; char *slot_type; char *fw_revision, *hw_revision; char *mfg_name, *model_name; char *phys_descr; int val; int ret; switch (pp) { case PP_SERIAL_NUM: ret = snmp_get_str(hdl, OID_entPhysicalSerialNum, row, &serial_num, snmp_syserr_p); CHECK_LINKRESET_VOID(snmp_syserr_p) if ((ret == 0) && serial_num) { (void) add_string_prop(nodeh, PICL_PROP_SERIAL_NUMBER, serial_num); free((void *) serial_num); } if (ret == -1) log_msg(LOG_ERR, SNMPP_CANT_FETCH_OBJECT_VAL, *snmp_syserr_p ? *snmp_syserr_p : ret, OID_entPhysicalSerialNum, row); break; case PP_SLOT_TYPE: if ((slot_type = get_slot_type(row, snmp_syserr_p)) == NULL) { CHECK_LINKRESET_VOID(snmp_syserr_p) (void) add_string_prop(nodeh, PICL_PROP_SLOT_TYPE, DEFAULT_SLOT_TYPE); } else { (void) add_string_prop(nodeh, PICL_PROP_SLOT_TYPE, slot_type); free((void *) slot_type); } break; case PP_STATE: ret = add_volatile_prop(nodeh, PICL_PROP_STATE, PICL_PTYPE_CHARSTRING, PICL_READ, MAX_ALARMSTATE_LEN, read_volprop, NULL, php); if (ret == PICL_SUCCESS) { save_volprop(*php, OID_sunPlatAlarmState, row, VPT_ALARMSTATE); } break; case PP_OPSTATUS: ret = add_volatile_prop(nodeh, PICL_PROP_OPERATIONAL_STATUS, PICL_PTYPE_CHARSTRING, PICL_READ, MAX_OPSTATE_LEN, read_volprop, NULL, php); if (ret == PICL_SUCCESS) { save_volprop(*php, OID_sunPlatEquipmentOperationalState, row, VPT_PLATOPSTATE); } break; case PP_BATT_STATUS: ret = add_volatile_prop(nodeh, PICL_PROP_BATTERY_STATUS, PICL_PTYPE_CHARSTRING, PICL_READ, MAX_BATTERYSTATUS_LEN, read_volprop, NULL, php); if (ret == PICL_SUCCESS) { save_volprop(*php, OID_sunPlatBatteryStatus, row, VPT_BATTERYSTATUS); } break; case PP_TEMPERATURE: ret = add_volatile_prop(nodeh, PICL_PROP_TEMPERATURE, PICL_PTYPE_INT, PICL_READ, sizeof (int), read_volprop, NULL, php); if (ret == PICL_SUCCESS) { save_volprop(*php, OID_sunPlatNumericSensorCurrent, row, VPT_NUMSENSOR); } break; case PP_VOLTAGE: ret = add_volatile_prop(nodeh, PICL_PROP_VOLTAGE, PICL_PTYPE_INT, PICL_READ, sizeof (int), read_volprop, NULL, php); if (ret == PICL_SUCCESS) { save_volprop(*php, OID_sunPlatNumericSensorCurrent, row, VPT_NUMSENSOR); } break; case PP_CURRENT: ret = add_volatile_prop(nodeh, PICL_PROP_CURRENT, PICL_PTYPE_INT, PICL_READ, sizeof (int), read_volprop, NULL, php); if (ret == PICL_SUCCESS) { save_volprop(*php, OID_sunPlatNumericSensorCurrent, row, VPT_NUMSENSOR); } break; case PP_SPEED: ret = add_volatile_prop(nodeh, PICL_PROP_SPEED, PICL_PTYPE_INT, PICL_READ, sizeof (int), read_volprop, NULL, php); if (ret == PICL_SUCCESS) { save_volprop(*php, OID_sunPlatNumericSensorCurrent, row, VPT_NUMSENSOR); } break; case PP_SENSOR_VALUE: ret = add_volatile_prop(nodeh, PICL_PROP_SENSOR_VALUE, PICL_PTYPE_INT, PICL_READ, sizeof (int), read_volprop, NULL, php); if (ret == PICL_SUCCESS) { save_volprop(*php, OID_sunPlatNumericSensorCurrent, row, VPT_NUMSENSOR); } break; case PP_CONDITION: ret = add_volatile_prop(nodeh, PICL_PROP_CONDITION, PICL_PTYPE_CHARSTRING, PICL_READ, MAX_TRUTHVAL_LEN, read_volprop, NULL, php); if (ret == PICL_SUCCESS) { save_volprop(*php, OID_sunPlatBinarySensorCurrent, row, VPT_BINSENSOR); } break; case PP_EXPECTED: ret = add_volatile_prop(nodeh, PICL_PROP_EXPECTED, PICL_PTYPE_CHARSTRING, PICL_READ, MAX_TRUTHVAL_LEN, read_volprop, NULL, php); if (ret == PICL_SUCCESS) { save_volprop(*php, OID_sunPlatBinarySensorExpected, row, VPT_BINSENSOR); } break; case PP_EXPONENT: ret = add_volatile_prop(nodeh, PICL_PROP_EXPONENT, PICL_PTYPE_INT, PICL_READ, sizeof (int), read_volprop, NULL, php); if (ret == PICL_SUCCESS) { save_volprop(*php, OID_sunPlatNumericSensorExponent, row, VPT_NUMSENSOR); } break; case PP_REPLACEABLE: ret = snmp_get_int(hdl, OID_sunPlatCircuitPackReplaceable, row, &val, snmp_syserr_p); CHECK_LINKRESET_VOID(snmp_syserr_p) if ((ret == 0) && (val == ST_TRUE)) (void) add_void_prop(nodeh, PICL_PROP_IS_REPLACEABLE); if (ret == -1) log_msg(LOG_ERR, SNMPP_CANT_FETCH_OBJECT_VAL, *snmp_syserr_p ? *snmp_syserr_p : ret, OID_sunPlatCircuitPackReplaceable, row); break; case PP_HOTSWAPPABLE: ret = snmp_get_int(hdl, OID_sunPlatCircuitPackHotSwappable, row, &val, snmp_syserr_p); CHECK_LINKRESET_VOID(snmp_syserr_p) if ((ret == 0) && (val == ST_TRUE)) (void) add_void_prop(nodeh, PICL_PROP_IS_HOT_SWAPPABLE); if (ret == -1) log_msg(LOG_ERR, SNMPP_CANT_FETCH_OBJECT_VAL, *snmp_syserr_p ? *snmp_syserr_p : ret, OID_sunPlatCircuitPackHotSwappable, row); break; case PP_IS_FRU: ret = snmp_get_int(hdl, OID_entPhysicalIsFRU, row, &val, snmp_syserr_p); CHECK_LINKRESET_VOID(snmp_syserr_p) if ((ret == 0) && (val == ST_TRUE)) (void) add_void_prop(nodeh, PICL_PROP_IS_FRU); if (ret == -1) log_msg(LOG_ERR, SNMPP_CANT_FETCH_OBJECT_VAL, *snmp_syserr_p ? *snmp_syserr_p : ret, OID_entPhysicalIsFRU, row); break; case PP_HW_REVISION: ret = snmp_get_str(hdl, OID_entPhysicalHardwareRev, row, &hw_revision, snmp_syserr_p); CHECK_LINKRESET_VOID(snmp_syserr_p) if ((ret == 0) && hw_revision) { (void) add_string_prop(nodeh, PICL_PROP_HW_REVISION, hw_revision); free((void *) hw_revision); } if (ret == -1) log_msg(LOG_ERR, SNMPP_CANT_FETCH_OBJECT_VAL, *snmp_syserr_p ? *snmp_syserr_p : ret, OID_entPhysicalHardwareRev, row); break; case PP_FW_REVISION: ret = snmp_get_str(hdl, OID_entPhysicalFirmwareRev, row, &fw_revision, snmp_syserr_p); CHECK_LINKRESET_VOID(snmp_syserr_p) if ((ret == 0) && fw_revision) { (void) add_string_prop(nodeh, PICL_PROP_FW_REVISION, fw_revision); free((void *) fw_revision); } if (ret == -1) log_msg(LOG_ERR, SNMPP_CANT_FETCH_OBJECT_VAL, *snmp_syserr_p ? *snmp_syserr_p : ret, OID_entPhysicalFirmwareRev, row); break; case PP_MFG_NAME: ret = snmp_get_str(hdl, OID_entPhysicalMfgName, row, &mfg_name, snmp_syserr_p); CHECK_LINKRESET_VOID(snmp_syserr_p) if ((ret == 0) && mfg_name) { (void) add_string_prop(nodeh, PICL_PROP_MFG_NAME, mfg_name); free((void *) mfg_name); } if (ret == -1) log_msg(LOG_ERR, SNMPP_CANT_FETCH_OBJECT_VAL, *snmp_syserr_p ? *snmp_syserr_p : ret, OID_entPhysicalMfgName, row); break; case PP_MODEL_NAME: ret = snmp_get_str(hdl, OID_entPhysicalModelName, row, &model_name, snmp_syserr_p); CHECK_LINKRESET_VOID(snmp_syserr_p) if ((ret == 0) && model_name) { (void) add_string_prop(nodeh, PICL_PROP_MODEL_NAME, model_name); free((void *) model_name); } if (ret == -1) log_msg(LOG_ERR, SNMPP_CANT_FETCH_OBJECT_VAL, *snmp_syserr_p ? *snmp_syserr_p : ret, OID_entPhysicalModelName, row); break; case PP_DESCRIPTION: ret = snmp_get_str(hdl, OID_entPhysicalDescr, row, &phys_descr, snmp_syserr_p); CHECK_LINKRESET_VOID(snmp_syserr_p) if ((ret == 0) && phys_descr) { (void) add_string_prop(nodeh, PICL_PROP_PHYS_DESCRIPTION, phys_descr); free((void *) phys_descr); } if (ret == -1) log_msg(LOG_ERR, SNMPP_CANT_FETCH_OBJECT_VAL, *snmp_syserr_p ? *snmp_syserr_p : ret, OID_entPhysicalDescr, row); break; case PP_LABEL: if (label && *label) (void) add_string_prop(nodeh, PICL_PROP_LABEL, label); break; case PP_BASE_UNITS: ret = snmp_get_int(hdl, OID_sunPlatNumericSensorBaseUnits, row, &val, snmp_syserr_p); CHECK_LINKRESET_VOID(snmp_syserr_p) if ((ret == 0) && (val > 0) && (val < n_baseunits)) { (void) add_string_prop(nodeh, PICL_PROP_BASE_UNITS, sensor_baseunits[val]); } if (ret == -1) log_msg(LOG_ERR, SNMPP_CANT_FETCH_OBJECT_VAL, *snmp_syserr_p ? *snmp_syserr_p : ret, OID_sunPlatNumericSensorBaseUnits, row); break; case PP_RATE_UNITS: ret = snmp_get_int(hdl, OID_sunPlatNumericSensorRateUnits, row, &val, snmp_syserr_p); CHECK_LINKRESET_VOID(snmp_syserr_p) if ((ret == 0) && (val > 0) && (val < n_rateunits)) { (void) add_string_prop(nodeh, PICL_PROP_RATE_UNITS, sensor_rateunits[val]); } if (ret == -1) log_msg(LOG_ERR, SNMPP_CANT_FETCH_OBJECT_VAL, *snmp_syserr_p ? *snmp_syserr_p : ret, OID_sunPlatNumericSensorRateUnits, row); break; } } /* * Initialize the SNMP library's cache refresh subsystem, then periodically * process refresh job to prevent cache entries from expiring. */ /*ARGSUSED*/ static void * cache_refresher(void *arg) { int jobs; int next_expiration; timestruc_t to; hrtime_t cycle_start, cycle_elapsed; /* * Initialize refresh subsystem */ LOGPRINTF("Initializing SNMP refresh subsystem.\n"); if (snmp_refresh_init() < 0) { return ((void *)-1); } (void) mutex_lock(&cache_refresh_lock); for (;;) { cycle_start = gethrtime(); /* * Process jobs from the snmp cache refresh work queue until one * of the following conditions is true: * 1) we are told to exit, or * 2) we have processed at least as many jobs as recommended by * the library, and the next job expiration is at least * CACHE_REFRESH_MIN_WINDOW * seconds away. */ jobs = snmp_refresh_get_cycle_hint(CACHE_REFRESH_CYCLE); while ((cache_refresh_thr_exit == B_FALSE) && (jobs > 0)) { (void) snmp_refresh_process_job(); jobs--; } next_expiration = snmp_refresh_get_next_expiration(); while ((cache_refresh_thr_exit == B_FALSE) && ((next_expiration >= 0) && (next_expiration < CACHE_REFRESH_MIN_WINDOW))) { (void) snmp_refresh_process_job(); next_expiration = snmp_refresh_get_next_expiration(); } /* * As long as we haven't been told to exit, sleep for * CACHE_REFRESH_CYCLE seconds minus the amount of time that has * elapsed since this cycle started. If the elapsed time is * equal to or greater than 60 seconds, skip sleeping entirely. */ cycle_elapsed = (gethrtime() - cycle_start) / NANOSEC; if ((cache_refresh_thr_exit == B_FALSE) && (cycle_elapsed < CACHE_REFRESH_CYCLE)) { to.tv_sec = CACHE_REFRESH_CYCLE - cycle_elapsed; to.tv_nsec = 0; (void) cond_reltimedwait(&cache_refresh_cv, &cache_refresh_lock, &to); } /* * If we have been told to exit, clean up and bail out. */ if (cache_refresh_thr_exit == B_TRUE) { snmp_refresh_fini(); (void) mutex_unlock(&cache_refresh_lock); LOGPRINTF("cache_refresher: time to exit\n"); return (NULL); } } /*NOTREACHED*/ return (NULL); } /* * Check to see if the cache_refresher thread is running. If it is, signal it * to terminate and clean up associated data structures. */ void cache_refresher_fini(void) { /* if the thread isn't running, there is nothing to do */ if (cache_refresh_thr_exit == B_TRUE) return; /* wake up the cache_refresher thread, tell it to exit */ (void) mutex_lock(&cache_refresh_lock); cache_refresh_thr_exit = B_TRUE; (void) cond_signal(&cache_refresh_cv); (void) mutex_unlock(&cache_refresh_lock); /* reap the thread */ (void) thr_join(cache_refresh_thr_id, NULL, NULL); /* finish cleanup... */ (void) cond_destroy(&cache_refresh_cv); (void) mutex_destroy(&cache_refresh_lock); } /*VARARGS2*/ static void log_msg(int pri, const char *fmt, ...) { va_list ap; va_start(ap, fmt); vsyslog(pri, fmt, ap); va_end(ap); } #ifdef SNMPPLUGIN_DEBUG static void snmpplugin_log_init(void) { (void) mutex_init(&snmpplugin_dbuf_lock, USYNC_THREAD, NULL); } static void snmpplugin_log(const char *fmt, ...) { va_list ap; (void) mutex_lock(&snmpplugin_dbuf_lock); va_start(ap, fmt); (void) vsnprintf(snmpplugin_lbuf, SNMPPLUGIN_DMAX_LINE, fmt, ap); snmpplugin_log_append(); va_end(ap); (void) mutex_unlock(&snmpplugin_dbuf_lock); } static void snmpplugin_log_append(void) { int len; len = strlen(snmpplugin_lbuf); if ((snmpplugin_dbuf_curp + len) >= (snmpplugin_dbuf + snmpplugin_dbuf_sz)) { snmpplugin_dbuf_realloc(); if (snmpplugin_dbuf == NULL) { return; } } (void) strcpy(snmpplugin_dbuf_curp, snmpplugin_lbuf); snmpplugin_dbuf_curp += len; } static void snmpplugin_dbuf_realloc(void) { char *p; size_t offset = 0; size_t count; count = snmpplugin_dbuf_sz + SNMPPLUGIN_DBLOCK_SZ; if ((p = (char *)calloc(count, 1)) == NULL) { snmpplugin_dbuf_overflow++; snmpplugin_dbuf_curp = snmpplugin_dbuf; return; } if (snmpplugin_dbuf) { offset = snmpplugin_dbuf_curp - snmpplugin_dbuf; (void) memcpy(p, snmpplugin_dbuf, snmpplugin_dbuf_sz); free(snmpplugin_dbuf); } snmpplugin_dbuf = p; snmpplugin_dbuf_sz += SNMPPLUGIN_DBLOCK_SZ; snmpplugin_dbuf_curp = snmpplugin_dbuf + offset; } #endif