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view usr/src/cmd/fm/fmd/common/fmd_case.c @ 12979:ab9ae749152f
PSARC/2009/617 Software Events Notification Parameters CLI
PSARC/2009/618 snmp-notify: SNMP Notification Daemon for Software Events
PSARC/2009/619 smtp-notify: Email Notification Daemon for Software Events
PSARC/2010/225 fmd for non-global Solaris zones
PSARC/2010/226 Solaris Instance UUID
PSARC/2010/227 nvlist_nvflag(3NVPAIR)
PSARC/2010/228 libfmevent additions
PSARC/2010/257 sysevent_evc_setpropnvl and sysevent_evc_getpropnvl
PSARC/2010/265 FMRI and FMA Event Stabilty, 'ireport' category 1 event class, and the 'sw' FMRI scheme
PSARC/2010/278 FMA/SMF integration: instance state transitions
PSARC/2010/279 Modelling panics within FMA
PSARC/2010/290 logadm.conf upgrade
6392476 fmdump needs to pretty-print
6393375 userland ereport/ireport event generation interfaces
6445732 Add email notification agent for FMA and software events
6804168 RFE: Allow an efficient means to monitor SMF services status changes
6866661 scf_values_destroy(3SCF) will segfault if is passed NULL
6884709 Add snmp notification agent for FMA and software events
6884712 Add private interface to tap into libfmd_msg macro expansion capabilities
6897919 fmd to run in a non-global zone
6897937 fmd use of non-private doors is not safe
6900081 add a UUID to Solaris kernel image for use in crashdump identification
6914884 model panic events as a defect diagnosis in FMA
6944862 fmd_case_open_uuid, fmd_case_uuisresolved, fmd_nvl_create_defect
6944866 log legacy sysevents in fmd
6944867 enumerate svc scheme in topo
6944868 software-diagnosis and software-response fmd modules
6944870 model SMF maintenance state as a defect diagnosis in FMA
6944876 savecore runs in foreground for systems with zfs root and dedicated dump
6965796 Implement notification parameters for SMF state transitions and FMA events
6968287 SUN-FM-MIB.mib needs to be updated to reflect Oracle information
6972331 logadm.conf upgrade PSARC/2010/290
| author | Gavin Maltby <gavin.maltby@oracle.com> |
|---|---|
| date | Fri, 30 Jul 2010 17:04:17 +1000 |
| parents | c13e2db06244 |
| children |
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/* * 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 (c) 2004, 2010, Oracle and/or its affiliates. All rights reserved. */ /* * FMD Case Subsystem * * Diagnosis engines are expected to group telemetry events related to the * diagnosis of a particular problem on the system into a set of cases. The * diagnosis engine may have any number of cases open at a given point in time. * Some cases may eventually be *solved* by associating a suspect list of one * or more problems with the case, at which point fmd publishes a list.suspect * event for the case and it becomes visible to administrators and agents. * * Every case is named using a UUID, and is globally visible in the case hash. * Cases are reference-counted, except for the reference from the case hash * itself. Consumers of case references include modules, which store active * cases on the mod_cases list, ASRUs in the resource cache, and the RPC code. * * Cases obey the following state machine. In states UNSOLVED, SOLVED, and * CLOSE_WAIT, a case's module refers to the owning module (a diagnosis engine * or transport) and the case is referenced by the mod_cases list. Once the * case reaches the CLOSED or REPAIRED states, a case's module changes to refer * to the root module (fmd.d_rmod) and is deleted from the owner's mod_cases. * * +------------+ * +----------| UNSOLVED | * | +------------+ * | 1 | * | | * | +-------v----+ * 2 | | SOLVED | * | +------------+ * | 3 | 5 | * +------------+ | | * | | | * +-v---v----v-+ * | CLOSE_WAIT | * +------------+ * | | | * +-----------+ | +------------+ * | 4 | | * v +-----v------+ | * discard | CLOSED | 6 | * +------------+ | * | | * | +------------+ * 7 | | * +-----v----v-+ * | REPAIRED | * +------------+ * | * 8 | * +-----v------+ * | RESOLVED | * +------------+ * | * v * discard * * The state machine changes are triggered by calls to fmd_case_transition() * from various locations inside of fmd, as described below: * * [1] Called by: fmd_case_solve() * Actions: FMD_CF_SOLVED flag is set in ci_flags * conviction policy is applied to suspect list * suspects convicted are marked faulty (F) in R$ * list.suspect event logged and dispatched * * [2] Called by: fmd_case_close(), fmd_case_uuclose() * Actions: diagnosis engine fmdo_close() entry point scheduled * case discarded upon exit from CLOSE_WAIT * * [3] Called by: fmd_case_close(), fmd_case_uuclose(), fmd_xprt_event_uuclose() * Actions: FMD_CF_ISOLATED flag is set in ci_flags * suspects convicted (F) are marked unusable (U) in R$ * diagnosis engine fmdo_close() entry point scheduled * case transitions to CLOSED [4] upon exit from CLOSE_WAIT * * [4] Called by: fmd_case_delete() (after fmdo_close() entry point returns) * Actions: list.isolated event dispatched * case deleted from module's list of open cases * * [5] Called by: fmd_case_repair(), fmd_case_update() * Actions: FMD_CF_REPAIR flag is set in ci_flags * diagnosis engine fmdo_close() entry point scheduled * case transitions to REPAIRED [6] upon exit from CLOSE_WAIT * * [6] Called by: fmd_case_delete() (after fmdo_close() entry point returns) * Actions: suspects convicted are marked non faulty (!F) in R$ * list.repaired or list.updated event dispatched * * [7] Called by: fmd_case_repair(), fmd_case_update() * Actions: FMD_CF_REPAIR flag is set in ci_flags * suspects convicted are marked non faulty (!F) in R$ * list.repaired or list.updated event dispatched * * [8] Called by: fmd_case_uuresolve() * Actions: list.resolved event dispatched * case is discarded */ #include <sys/fm/protocol.h> #include <uuid/uuid.h> #include <alloca.h> #include <fmd_alloc.h> #include <fmd_module.h> #include <fmd_error.h> #include <fmd_conf.h> #include <fmd_case.h> #include <fmd_string.h> #include <fmd_subr.h> #include <fmd_protocol.h> #include <fmd_event.h> #include <fmd_eventq.h> #include <fmd_dispq.h> #include <fmd_buf.h> #include <fmd_log.h> #include <fmd_asru.h> #include <fmd_fmri.h> #include <fmd_xprt.h> #include <fmd.h> static const char *const _fmd_case_snames[] = { "UNSOLVED", /* FMD_CASE_UNSOLVED */ "SOLVED", /* FMD_CASE_SOLVED */ "CLOSE_WAIT", /* FMD_CASE_CLOSE_WAIT */ "CLOSED", /* FMD_CASE_CLOSED */ "REPAIRED", /* FMD_CASE_REPAIRED */ "RESOLVED" /* FMD_CASE_RESOLVED */ }; static fmd_case_impl_t *fmd_case_tryhold(fmd_case_impl_t *); fmd_case_hash_t * fmd_case_hash_create(void) { fmd_case_hash_t *chp = fmd_alloc(sizeof (fmd_case_hash_t), FMD_SLEEP); (void) pthread_rwlock_init(&chp->ch_lock, NULL); chp->ch_hashlen = fmd.d_str_buckets; chp->ch_hash = fmd_zalloc(sizeof (void *) * chp->ch_hashlen, FMD_SLEEP); chp->ch_code_hash = fmd_zalloc(sizeof (void *) * chp->ch_hashlen, FMD_SLEEP); chp->ch_count = 0; return (chp); } /* * Destroy the case hash. Unlike most of our hash tables, no active references * are kept by the case hash itself; all references come from other subsystems. * The hash must be destroyed after all modules are unloaded; if anything was * present in the hash it would be by definition a reference count leak. */ void fmd_case_hash_destroy(fmd_case_hash_t *chp) { fmd_free(chp->ch_hash, sizeof (void *) * chp->ch_hashlen); fmd_free(chp->ch_code_hash, sizeof (void *) * chp->ch_hashlen); fmd_free(chp, sizeof (fmd_case_hash_t)); } /* * Take a snapshot of the case hash by placing an additional hold on each * member in an auxiliary array, and then call 'func' for each case. */ void fmd_case_hash_apply(fmd_case_hash_t *chp, void (*func)(fmd_case_t *, void *), void *arg) { fmd_case_impl_t *cp, **cps, **cpp; uint_t cpc, i; (void) pthread_rwlock_rdlock(&chp->ch_lock); cps = cpp = fmd_alloc(chp->ch_count * sizeof (fmd_case_t *), FMD_SLEEP); cpc = chp->ch_count; for (i = 0; i < chp->ch_hashlen; i++) { for (cp = chp->ch_hash[i]; cp != NULL; cp = cp->ci_next) *cpp++ = fmd_case_tryhold(cp); } ASSERT(cpp == cps + cpc); (void) pthread_rwlock_unlock(&chp->ch_lock); for (i = 0; i < cpc; i++) { if (cps[i] != NULL) { func((fmd_case_t *)cps[i], arg); fmd_case_rele((fmd_case_t *)cps[i]); } } fmd_free(cps, cpc * sizeof (fmd_case_t *)); } static void fmd_case_code_hash_insert(fmd_case_hash_t *chp, fmd_case_impl_t *cip) { uint_t h = fmd_strhash(cip->ci_code) % chp->ch_hashlen; cip->ci_code_next = chp->ch_code_hash[h]; chp->ch_code_hash[h] = cip; } static void fmd_case_code_hash_delete(fmd_case_hash_t *chp, fmd_case_impl_t *cip) { fmd_case_impl_t **pp, *cp; if (cip->ci_code) { uint_t h = fmd_strhash(cip->ci_code) % chp->ch_hashlen; pp = &chp->ch_code_hash[h]; for (cp = *pp; cp != NULL; cp = cp->ci_code_next) { if (cp != cip) pp = &cp->ci_code_next; else break; } if (cp != NULL) { *pp = cp->ci_code_next; cp->ci_code_next = NULL; } } } /* * Look up the diagcode for this case and cache it in ci_code. If no suspects * were defined for this case or if the lookup fails, the event dictionary or * module code is broken, and we set the event code to a precomputed default. */ static const char * fmd_case_mkcode(fmd_case_t *cp) { fmd_case_impl_t *cip = (fmd_case_impl_t *)cp; fmd_case_susp_t *cis; fmd_case_hash_t *chp = fmd.d_cases; char **keys, **keyp; const char *s; ASSERT(MUTEX_HELD(&cip->ci_lock)); ASSERT(cip->ci_state >= FMD_CASE_SOLVED); /* * delete any existing entry from code hash if it is on it */ fmd_case_code_hash_delete(chp, cip); fmd_free(cip->ci_code, cip->ci_codelen); cip->ci_codelen = cip->ci_mod->mod_codelen; cip->ci_code = fmd_zalloc(cip->ci_codelen, FMD_SLEEP); keys = keyp = alloca(sizeof (char *) * (cip->ci_nsuspects + 1)); for (cis = cip->ci_suspects; cis != NULL; cis = cis->cis_next) { if (nvlist_lookup_string(cis->cis_nvl, FM_CLASS, keyp) == 0) keyp++; } *keyp = NULL; /* mark end of keys[] array for libdiagcode */ if (cip->ci_nsuspects == 0 || fmd_module_dc_key2code( cip->ci_mod, keys, cip->ci_code, cip->ci_codelen) != 0) { (void) fmd_conf_getprop(fmd.d_conf, "nodiagcode", &s); fmd_free(cip->ci_code, cip->ci_codelen); cip->ci_codelen = strlen(s) + 1; cip->ci_code = fmd_zalloc(cip->ci_codelen, FMD_SLEEP); (void) strcpy(cip->ci_code, s); } /* * add into hash of solved cases */ fmd_case_code_hash_insert(chp, cip); return (cip->ci_code); } typedef struct { int *fcl_countp; int fcl_maxcount; uint8_t *fcl_ba; nvlist_t **fcl_nva; int *fcl_msgp; } fmd_case_lst_t; static void fmd_case_set_lst(fmd_asru_link_t *alp, void *arg) { fmd_case_lst_t *entryp = (fmd_case_lst_t *)arg; boolean_t b; int state; if (*entryp->fcl_countp >= entryp->fcl_maxcount) return; if (nvlist_lookup_boolean_value(alp->al_event, FM_SUSPECT_MESSAGE, &b) == 0 && b == B_FALSE) *entryp->fcl_msgp = B_FALSE; entryp->fcl_ba[*entryp->fcl_countp] = 0; state = fmd_asru_al_getstate(alp); if (state & FMD_ASRU_DEGRADED) entryp->fcl_ba[*entryp->fcl_countp] |= FM_SUSPECT_DEGRADED; if (state & FMD_ASRU_UNUSABLE) entryp->fcl_ba[*entryp->fcl_countp] |= FM_SUSPECT_UNUSABLE; if (state & FMD_ASRU_FAULTY) entryp->fcl_ba[*entryp->fcl_countp] |= FM_SUSPECT_FAULTY; if (!(state & FMD_ASRU_PRESENT)) entryp->fcl_ba[*entryp->fcl_countp] |= FM_SUSPECT_NOT_PRESENT; if (alp->al_reason == FMD_ASRU_REPAIRED) entryp->fcl_ba[*entryp->fcl_countp] |= FM_SUSPECT_REPAIRED; else if (alp->al_reason == FMD_ASRU_REPLACED) entryp->fcl_ba[*entryp->fcl_countp] |= FM_SUSPECT_REPLACED; else if (alp->al_reason == FMD_ASRU_ACQUITTED) entryp->fcl_ba[*entryp->fcl_countp] |= FM_SUSPECT_ACQUITTED; entryp->fcl_nva[*entryp->fcl_countp] = alp->al_event; (*entryp->fcl_countp)++; } static void fmd_case_faulty(fmd_asru_link_t *alp, void *arg) { int *faultyp = (int *)arg; *faultyp |= (alp->al_flags & FMD_ASRU_FAULTY); } static void fmd_case_usable(fmd_asru_link_t *alp, void *arg) { int *usablep = (int *)arg; *usablep |= !(fmd_asru_al_getstate(alp) & FMD_ASRU_UNUSABLE); } static void fmd_case_not_faulty(fmd_asru_link_t *alp, void *arg) { int *not_faultyp = (int *)arg; *not_faultyp |= !(alp->al_flags & FMD_ASRU_FAULTY); } /* * Have we got any suspects with an asru that are still unusable and present? */ static void fmd_case_unusable_and_present(fmd_asru_link_t *alp, void *arg) { int *rvalp = (int *)arg; int state; nvlist_t *asru; /* * if this a proxy case and this suspect doesn't have an local asru * then state is unknown so we must assume it may still be unusable. */ if ((alp->al_flags & FMD_ASRU_PROXY) && !(alp->al_flags & FMD_ASRU_PROXY_WITH_ASRU)) { *rvalp |= B_TRUE; return; } state = fmd_asru_al_getstate(alp); if (nvlist_lookup_nvlist(alp->al_event, FM_FAULT_ASRU, &asru) != 0) return; *rvalp |= ((state & FMD_ASRU_UNUSABLE) && (state & FMD_ASRU_PRESENT)); } nvlist_t * fmd_case_mkevent(fmd_case_t *cp, const char *class) { fmd_case_impl_t *cip = (fmd_case_impl_t *)cp; nvlist_t **nva, *nvl; uint8_t *ba; int msg = B_TRUE; const char *code; fmd_case_lst_t fcl; int count = 0; (void) pthread_mutex_lock(&cip->ci_lock); ASSERT(cip->ci_state >= FMD_CASE_SOLVED); nva = alloca(sizeof (nvlist_t *) * cip->ci_nsuspects); ba = alloca(sizeof (uint8_t) * cip->ci_nsuspects); /* * For each suspect associated with the case, store its fault event * nvlist in 'nva'. We also look to see if any of the suspect faults * have asked not to be messaged. If any of them have made such a * request, propagate that attribute to the composite list.* event. * Finally, store each suspect's faulty status into the bitmap 'ba'. */ fcl.fcl_countp = &count; fcl.fcl_maxcount = cip->ci_nsuspects; fcl.fcl_msgp = &msg; fcl.fcl_ba = ba; fcl.fcl_nva = nva; fmd_asru_hash_apply_by_case(fmd.d_asrus, cp, fmd_case_set_lst, &fcl); if (cip->ci_code == NULL) (void) fmd_case_mkcode(cp); /* * For repair and updated event, we lookup diagcode from dict using key * "list.repaired" or "list.updated" or "list.resolved". */ if (strcmp(class, FM_LIST_REPAIRED_CLASS) == 0) (void) fmd_conf_getprop(fmd.d_conf, "repaircode", &code); else if (strcmp(class, FM_LIST_RESOLVED_CLASS) == 0) (void) fmd_conf_getprop(fmd.d_conf, "resolvecode", &code); else if (strcmp(class, FM_LIST_UPDATED_CLASS) == 0) (void) fmd_conf_getprop(fmd.d_conf, "updatecode", &code); else code = cip->ci_code; if (msg == B_FALSE) cip->ci_flags |= FMD_CF_INVISIBLE; /* * Use the ci_diag_de if one has been saved (eg for an injected fault). * Otherwise use the authority for the current module. */ nvl = fmd_protocol_list(class, cip->ci_diag_de == NULL ? cip->ci_mod->mod_fmri : cip->ci_diag_de, cip->ci_uuid, code, count, nva, ba, msg, &cip->ci_tv, cip->ci_injected); (void) pthread_mutex_unlock(&cip->ci_lock); return (nvl); } static int fmd_case_match_on_faulty_overlap = 1; static int fmd_case_match_on_acquit_overlap = 1; static int fmd_case_auto_acquit_isolated = 1; static int fmd_case_auto_acquit_non_acquitted = 1; static int fmd_case_too_recent = 10; /* time in seconds */ static boolean_t fmd_case_compare_elem(nvlist_t *nvl, nvlist_t *xnvl, const char *elem) { nvlist_t *new_rsrc; nvlist_t *rsrc; char *new_name = NULL; char *name = NULL; ssize_t new_namelen; ssize_t namelen; int fmri_present = 1; int new_fmri_present = 1; int match = B_FALSE; fmd_topo_t *ftp = fmd_topo_hold(); if (nvlist_lookup_nvlist(xnvl, elem, &rsrc) != 0) fmri_present = 0; else { if ((namelen = fmd_fmri_nvl2str(rsrc, NULL, 0)) == -1) goto done; name = fmd_alloc(namelen + 1, FMD_SLEEP); if (fmd_fmri_nvl2str(rsrc, name, namelen + 1) == -1) goto done; } if (nvlist_lookup_nvlist(nvl, elem, &new_rsrc) != 0) new_fmri_present = 0; else { if ((new_namelen = fmd_fmri_nvl2str(new_rsrc, NULL, 0)) == -1) goto done; new_name = fmd_alloc(new_namelen + 1, FMD_SLEEP); if (fmd_fmri_nvl2str(new_rsrc, new_name, new_namelen + 1) == -1) goto done; } match = (fmri_present == new_fmri_present && (fmri_present == 0 || topo_fmri_strcmp(ftp->ft_hdl, name, new_name))); done: if (name != NULL) fmd_free(name, namelen + 1); if (new_name != NULL) fmd_free(new_name, new_namelen + 1); fmd_topo_rele(ftp); return (match); } static int fmd_case_match_suspect(nvlist_t *nvl1, nvlist_t *nvl2) { char *class, *new_class; if (!fmd_case_compare_elem(nvl1, nvl2, FM_FAULT_ASRU)) return (0); if (!fmd_case_compare_elem(nvl1, nvl2, FM_FAULT_RESOURCE)) return (0); if (!fmd_case_compare_elem(nvl1, nvl2, FM_FAULT_FRU)) return (0); (void) nvlist_lookup_string(nvl2, FM_CLASS, &class); (void) nvlist_lookup_string(nvl1, FM_CLASS, &new_class); return (strcmp(class, new_class) == 0); } typedef struct { int *fcms_countp; int fcms_maxcount; fmd_case_impl_t *fcms_cip; uint8_t *fcms_new_susp_state; uint8_t *fcms_old_susp_state; uint8_t *fcms_old_match_state; } fcms_t; #define SUSPECT_STATE_FAULTY 0x1 #define SUSPECT_STATE_ISOLATED 0x2 #define SUSPECT_STATE_REMOVED 0x4 #define SUSPECT_STATE_ACQUITED 0x8 #define SUSPECT_STATE_REPAIRED 0x10 #define SUSPECT_STATE_REPLACED 0x20 #define SUSPECT_STATE_NO_MATCH 0x1 /* * This is called for each suspect in the old case. Compare it against each * suspect in the new case, setting fcms_old_susp_state and fcms_new_susp_state * as appropriate. fcms_new_susp_state will left as 0 if the suspect is not * found in the old case. */ static void fmd_case_match_suspects(fmd_asru_link_t *alp, void *arg) { fcms_t *fcmsp = (fcms_t *)arg; fmd_case_impl_t *cip = fcmsp->fcms_cip; fmd_case_susp_t *cis; int i = 0; int state = fmd_asru_al_getstate(alp); if (*fcmsp->fcms_countp >= fcmsp->fcms_maxcount) return; if (!(state & FMD_ASRU_PRESENT) || (!(state & FMD_ASRU_FAULTY) && alp->al_reason == FMD_ASRU_REMOVED)) fcmsp->fcms_old_susp_state[*fcmsp->fcms_countp] = SUSPECT_STATE_REMOVED; else if ((state & FMD_ASRU_UNUSABLE) && (state & FMD_ASRU_FAULTY)) fcmsp->fcms_old_susp_state[*fcmsp->fcms_countp] = SUSPECT_STATE_ISOLATED; else if (state & FMD_ASRU_FAULTY) fcmsp->fcms_old_susp_state[*fcmsp->fcms_countp] = SUSPECT_STATE_FAULTY; else if (alp->al_reason == FMD_ASRU_REPLACED) fcmsp->fcms_old_susp_state[*fcmsp->fcms_countp] = SUSPECT_STATE_REPLACED; else if (alp->al_reason == FMD_ASRU_ACQUITTED) fcmsp->fcms_old_susp_state[*fcmsp->fcms_countp] = SUSPECT_STATE_ACQUITED; else fcmsp->fcms_old_susp_state[*fcmsp->fcms_countp] = SUSPECT_STATE_REPAIRED; for (cis = cip->ci_suspects; cis != NULL; cis = cis->cis_next, i++) if (fmd_case_match_suspect(cis->cis_nvl, alp->al_event) == 1) break; if (cis != NULL) fcmsp->fcms_new_susp_state[i] = fcmsp->fcms_old_susp_state[*fcmsp->fcms_countp]; else fcmsp->fcms_old_match_state[*fcmsp->fcms_countp] |= SUSPECT_STATE_NO_MATCH; (*fcmsp->fcms_countp)++; } typedef struct { int *fca_do_update; fmd_case_impl_t *fca_cip; } fca_t; /* * Re-fault all acquitted suspects that are still present in the new list. */ static void fmd_case_fault_acquitted_matching(fmd_asru_link_t *alp, void *arg) { fca_t *fcap = (fca_t *)arg; fmd_case_impl_t *cip = fcap->fca_cip; fmd_case_susp_t *cis; int state = fmd_asru_al_getstate(alp); if (!(state & FMD_ASRU_FAULTY) && alp->al_reason == FMD_ASRU_ACQUITTED) { for (cis = cip->ci_suspects; cis != NULL; cis = cis->cis_next) if (fmd_case_match_suspect(cis->cis_nvl, alp->al_event) == 1) break; if (cis != NULL) { (void) fmd_asru_setflags(alp, FMD_ASRU_FAULTY); *fcap->fca_do_update = 1; } } } /* * Re-fault all suspects that are still present in the new list. */ static void fmd_case_fault_all_matching(fmd_asru_link_t *alp, void *arg) { fca_t *fcap = (fca_t *)arg; fmd_case_impl_t *cip = fcap->fca_cip; fmd_case_susp_t *cis; int state = fmd_asru_al_getstate(alp); if (!(state & FMD_ASRU_FAULTY)) { for (cis = cip->ci_suspects; cis != NULL; cis = cis->cis_next) if (fmd_case_match_suspect(cis->cis_nvl, alp->al_event) == 1) break; if (cis != NULL) { (void) fmd_asru_setflags(alp, FMD_ASRU_FAULTY); *fcap->fca_do_update = 1; } } } /* * Acquit all suspects that are no longer present in the new list. */ static void fmd_case_acquit_no_match(fmd_asru_link_t *alp, void *arg) { fca_t *fcap = (fca_t *)arg; fmd_case_impl_t *cip = fcap->fca_cip; fmd_case_susp_t *cis; int state = fmd_asru_al_getstate(alp); if (state & FMD_ASRU_FAULTY) { for (cis = cip->ci_suspects; cis != NULL; cis = cis->cis_next) if (fmd_case_match_suspect(cis->cis_nvl, alp->al_event) == 1) break; if (cis == NULL) { (void) fmd_asru_clrflags(alp, FMD_ASRU_FAULTY, FMD_ASRU_ACQUITTED); *fcap->fca_do_update = 1; } } } /* * Acquit all isolated suspects. */ static void fmd_case_acquit_isolated(fmd_asru_link_t *alp, void *arg) { int *do_update = (int *)arg; int state = fmd_asru_al_getstate(alp); if ((state & FMD_ASRU_PRESENT) && (state & FMD_ASRU_UNUSABLE) && (state & FMD_ASRU_FAULTY)) { (void) fmd_asru_clrflags(alp, FMD_ASRU_FAULTY, FMD_ASRU_ACQUITTED); *do_update = 1; } } /* * Acquit suspect which matches specified nvlist */ static void fmd_case_acquit_suspect(fmd_asru_link_t *alp, void *arg) { nvlist_t *nvl = (nvlist_t *)arg; int state = fmd_asru_al_getstate(alp); if ((state & FMD_ASRU_FAULTY) && fmd_case_match_suspect(nvl, alp->al_event) == 1) (void) fmd_asru_clrflags(alp, FMD_ASRU_FAULTY, FMD_ASRU_ACQUITTED); } typedef struct { fmd_case_impl_t *fccd_cip; uint8_t *fccd_new_susp_state; uint8_t *fccd_new_match_state; int *fccd_discard_new; int *fccd_adjust_new; } fccd_t; /* * see if a matching suspect list already exists in the cache */ static void fmd_case_check_for_dups(fmd_case_t *old_cp, void *arg) { fccd_t *fccdp = (fccd_t *)arg; fmd_case_impl_t *new_cip = fccdp->fccd_cip; fmd_case_impl_t *old_cip = (fmd_case_impl_t *)old_cp; int i, count = 0, do_update = 0, got_isolated_overlap = 0; int got_faulty_overlap = 0; int got_acquit_overlap = 0; boolean_t too_recent; uint64_t most_recent = 0; fcms_t fcms; fca_t fca; uint8_t *new_susp_state; uint8_t *old_susp_state; uint8_t *old_match_state; new_susp_state = alloca(new_cip->ci_nsuspects * sizeof (uint8_t)); for (i = 0; i < new_cip->ci_nsuspects; i++) new_susp_state[i] = 0; old_susp_state = alloca(old_cip->ci_nsuspects * sizeof (uint8_t)); for (i = 0; i < old_cip->ci_nsuspects; i++) old_susp_state[i] = 0; old_match_state = alloca(old_cip->ci_nsuspects * sizeof (uint8_t)); for (i = 0; i < old_cip->ci_nsuspects; i++) old_match_state[i] = 0; /* * Compare with each suspect in the existing case. */ fcms.fcms_countp = &count; fcms.fcms_maxcount = old_cip->ci_nsuspects; fcms.fcms_cip = new_cip; fcms.fcms_new_susp_state = new_susp_state; fcms.fcms_old_susp_state = old_susp_state; fcms.fcms_old_match_state = old_match_state; fmd_asru_hash_apply_by_case(fmd.d_asrus, (fmd_case_t *)old_cip, fmd_case_match_suspects, &fcms); /* * If we have some faulty, non-isolated suspects that overlap, then most * likely it is the suspects that overlap in the suspect lists that are * to blame. So we can consider this to be a match. */ for (i = 0; i < new_cip->ci_nsuspects; i++) if (new_susp_state[i] == SUSPECT_STATE_FAULTY) got_faulty_overlap = 1; if (got_faulty_overlap && fmd_case_match_on_faulty_overlap) goto got_match; /* * If we have no faulty, non-isolated suspects in the old case, but we * do have some acquitted suspects that overlap, then most likely it is * the acquitted suspects that overlap in the suspect lists that are * to blame. So we can consider this to be a match. */ for (i = 0; i < new_cip->ci_nsuspects; i++) if (new_susp_state[i] == SUSPECT_STATE_ACQUITED) got_acquit_overlap = 1; for (i = 0; i < old_cip->ci_nsuspects; i++) if (old_susp_state[i] == SUSPECT_STATE_FAULTY) got_acquit_overlap = 0; if (got_acquit_overlap && fmd_case_match_on_acquit_overlap) goto got_match; /* * Check that all suspects in the new list are present in the old list. * Return if we find one that isn't. */ for (i = 0; i < new_cip->ci_nsuspects; i++) if (new_susp_state[i] == 0) return; /* * Check that all suspects in the old list are present in the new list * *or* they are isolated or removed/replaced (which would explain why * they are not present in the new list). Return if we find one that is * faulty and unisolated or repaired or acquitted, and that is not * present in the new case. */ for (i = 0; i < old_cip->ci_nsuspects; i++) if (old_match_state[i] == SUSPECT_STATE_NO_MATCH && (old_susp_state[i] == SUSPECT_STATE_FAULTY || old_susp_state[i] == SUSPECT_STATE_ACQUITED || old_susp_state[i] == SUSPECT_STATE_REPAIRED)) return; got_match: /* * If the old case is already in repaired/resolved state, we can't * do anything more with it, so keep the new case, but acquit some * of the suspects if appropriate. */ if (old_cip->ci_state >= FMD_CASE_REPAIRED) { if (fmd_case_auto_acquit_non_acquitted) { *fccdp->fccd_adjust_new = 1; for (i = 0; i < new_cip->ci_nsuspects; i++) { fccdp->fccd_new_susp_state[i] |= new_susp_state[i]; if (new_susp_state[i] == 0) fccdp->fccd_new_susp_state[i] = SUSPECT_STATE_NO_MATCH; } } return; } /* * Otherwise discard the new case and keep the old, again updating the * state of the suspects as appropriate */ *fccdp->fccd_discard_new = 1; fca.fca_cip = new_cip; fca.fca_do_update = &do_update; /* * See if new case occurred within fmd_case_too_recent seconds of the * most recent modification to the old case and if so don't do * auto-acquit. This avoids problems if a flood of ereports come in and * they don't all get diagnosed before the first case causes some of * the devices to be isolated making it appear that an isolated device * was in the suspect list. */ fmd_asru_hash_apply_by_case(fmd.d_asrus, old_cp, fmd_asru_most_recent, &most_recent); too_recent = (new_cip->ci_tv.tv_sec - most_recent < fmd_case_too_recent); if (got_faulty_overlap) { /* * Acquit any suspects not present in the new list, plus * any that are are present but are isolated. */ fmd_asru_hash_apply_by_case(fmd.d_asrus, old_cp, fmd_case_acquit_no_match, &fca); if (fmd_case_auto_acquit_isolated && !too_recent) fmd_asru_hash_apply_by_case(fmd.d_asrus, old_cp, fmd_case_acquit_isolated, &do_update); } else if (got_acquit_overlap) { /* * Re-fault the acquitted matching suspects and acquit all * isolated suspects. */ if (fmd_case_auto_acquit_isolated && !too_recent) { fmd_asru_hash_apply_by_case(fmd.d_asrus, old_cp, fmd_case_fault_acquitted_matching, &fca); fmd_asru_hash_apply_by_case(fmd.d_asrus, old_cp, fmd_case_acquit_isolated, &do_update); } } else if (fmd_case_auto_acquit_isolated) { /* * To get here, there must be no faulty or acquitted suspects, * but there must be at least one isolated suspect. Just acquit * non-matching isolated suspects. If there are no matching * isolated suspects, then re-fault all matching suspects. */ for (i = 0; i < new_cip->ci_nsuspects; i++) if (new_susp_state[i] == SUSPECT_STATE_ISOLATED) got_isolated_overlap = 1; if (!got_isolated_overlap) fmd_asru_hash_apply_by_case(fmd.d_asrus, old_cp, fmd_case_fault_all_matching, &fca); fmd_asru_hash_apply_by_case(fmd.d_asrus, old_cp, fmd_case_acquit_no_match, &fca); } /* * If we've updated anything in the old case, call fmd_case_update() */ if (do_update) fmd_case_update(old_cp); } /* * Convict suspects in a case by applying a conviction policy and updating the * resource cache prior to emitting the list.suspect event for the given case. * At present, our policy is very simple: convict every suspect in the case. * In the future, this policy can be extended and made configurable to permit: * * - convicting the suspect with the highest FIT rate * - convicting the suspect with the cheapest FRU * - convicting the suspect with the FRU that is in a depot's inventory * - convicting the suspect with the longest lifetime * * and so forth. A word to the wise: this problem is significantly harder that * it seems at first glance. Future work should heed the following advice: * * Hacking the policy into C code here is a very bad idea. The policy needs to * be decided upon very carefully and fundamentally encodes knowledge of what * suspect list combinations can be emitted by what diagnosis engines. As such * fmd's code is the wrong location, because that would require fmd itself to * be updated for every diagnosis engine change, defeating the entire design. * The FMA Event Registry knows the suspect list combinations: policy inputs * can be derived from it and used to produce per-module policy configuration. * * If the policy needs to be dynamic and not statically fixed at either fmd * startup or module load time, any implementation of dynamic policy retrieval * must employ some kind of caching mechanism or be part of a built-in module. * The fmd_case_convict() function is called with locks held inside of fmd and * is not a place where unbounded blocking on some inter-process or inter- * system communication to another service (e.g. another daemon) can occur. */ static int fmd_case_convict(fmd_case_t *cp) { fmd_case_impl_t *cip = (fmd_case_impl_t *)cp; fmd_asru_hash_t *ahp = fmd.d_asrus; int discard_new = 0, i; fmd_case_susp_t *cis; fmd_asru_link_t *alp; uint8_t *new_susp_state; uint8_t *new_match_state; int adjust_new = 0; fccd_t fccd; fmd_case_impl_t *ncp, **cps, **cpp; uint_t cpc; fmd_case_hash_t *chp; /* * First we must see if any matching cases already exist. */ new_susp_state = alloca(cip->ci_nsuspects * sizeof (uint8_t)); for (i = 0; i < cip->ci_nsuspects; i++) new_susp_state[i] = 0; new_match_state = alloca(cip->ci_nsuspects * sizeof (uint8_t)); for (i = 0; i < cip->ci_nsuspects; i++) new_match_state[i] = 0; fccd.fccd_cip = cip; fccd.fccd_adjust_new = &adjust_new; fccd.fccd_new_susp_state = new_susp_state; fccd.fccd_new_match_state = new_match_state; fccd.fccd_discard_new = &discard_new; /* * Hold all cases */ chp = fmd.d_cases; (void) pthread_rwlock_rdlock(&chp->ch_lock); cps = cpp = fmd_alloc(chp->ch_count * sizeof (fmd_case_t *), FMD_SLEEP); cpc = chp->ch_count; for (i = 0; i < chp->ch_hashlen; i++) for (ncp = chp->ch_hash[i]; ncp != NULL; ncp = ncp->ci_next) *cpp++ = fmd_case_tryhold(ncp); ASSERT(cpp == cps + cpc); (void) pthread_rwlock_unlock(&chp->ch_lock); /* * Run fmd_case_check_for_dups() on all cases except the current one. */ for (i = 0; i < cpc; i++) { if (cps[i] != NULL) { if (cps[i] != (fmd_case_impl_t *)cp) fmd_case_check_for_dups((fmd_case_t *)cps[i], &fccd); fmd_case_rele((fmd_case_t *)cps[i]); } } fmd_free(cps, cpc * sizeof (fmd_case_t *)); (void) pthread_mutex_lock(&cip->ci_lock); if (cip->ci_code == NULL) (void) fmd_case_mkcode(cp); else if (cip->ci_precanned) fmd_case_code_hash_insert(fmd.d_cases, cip); if (discard_new) { /* * We've found an existing case that is a match and it is not * already in repaired or resolved state. So we can close this * one as a duplicate. */ (void) pthread_mutex_unlock(&cip->ci_lock); return (1); } /* * Allocate new cache entries */ for (cis = cip->ci_suspects; cis != NULL; cis = cis->cis_next) { if ((alp = fmd_asru_hash_create_entry(ahp, cp, cis->cis_nvl)) == NULL) { fmd_error(EFMD_CASE_EVENT, "cannot convict suspect in " "%s: %s\n", cip->ci_uuid, fmd_strerror(errno)); continue; } alp->al_flags |= FMD_ASRU_PRESENT; alp->al_asru->asru_flags |= FMD_ASRU_PRESENT; (void) fmd_asru_clrflags(alp, FMD_ASRU_UNUSABLE, 0); (void) fmd_asru_setflags(alp, FMD_ASRU_FAULTY); } if (adjust_new) { int some_suspect = 0, some_not_suspect = 0; /* * There is one or more matching case but they are already in * repaired or resolved state. So we need to keep the new * case, but we can adjust it. Repaired/removed/replaced * suspects are unlikely to be to blame (unless there are * actually two separate faults). So if we have a combination of * repaired/replaced/removed suspects and acquitted suspects in * the old lists, then we should acquit in the new list those * that were repaired/replaced/removed in the old. */ for (i = 0; i < cip->ci_nsuspects; i++) { if ((new_susp_state[i] & SUSPECT_STATE_REPLACED) || (new_susp_state[i] & SUSPECT_STATE_REPAIRED) || (new_susp_state[i] & SUSPECT_STATE_REMOVED) || (new_match_state[i] & SUSPECT_STATE_NO_MATCH)) some_not_suspect = 1; else some_suspect = 1; } if (some_suspect && some_not_suspect) { for (cis = cip->ci_suspects, i = 0; cis != NULL; cis = cis->cis_next, i++) if ((new_susp_state[i] & SUSPECT_STATE_REPLACED) || (new_susp_state[i] & SUSPECT_STATE_REPAIRED) || (new_susp_state[i] & SUSPECT_STATE_REMOVED) || (new_match_state[i] & SUSPECT_STATE_NO_MATCH)) fmd_asru_hash_apply_by_case(fmd.d_asrus, cp, fmd_case_acquit_suspect, cis->cis_nvl); } } (void) pthread_mutex_unlock(&cip->ci_lock); return (0); } void fmd_case_publish(fmd_case_t *cp, uint_t state) { fmd_case_impl_t *cip = (fmd_case_impl_t *)cp; fmd_event_t *e; nvlist_t *nvl; char *class; if (state == FMD_CASE_CURRENT) state = cip->ci_state; /* use current state */ switch (state) { case FMD_CASE_SOLVED: (void) pthread_mutex_lock(&cip->ci_lock); /* * If we already have a code, then case is already solved. */ if (cip->ci_precanned == 0 && cip->ci_xprt == NULL && cip->ci_code != NULL) { (void) pthread_mutex_unlock(&cip->ci_lock); break; } if (cip->ci_tv_valid == 0) { fmd_time_gettimeofday(&cip->ci_tv); cip->ci_tv_valid = 1; } (void) pthread_mutex_unlock(&cip->ci_lock); if (fmd_case_convict(cp) == 1) { /* dupclose */ cip->ci_flags &= ~FMD_CF_SOLVED; fmd_case_transition(cp, FMD_CASE_CLOSE_WAIT, 0); break; } if (cip->ci_xprt != NULL) { /* * For proxy, save some information about the transport * in the resource cache. */ int count = 0; fmd_asru_set_on_proxy_t fasp; fmd_xprt_impl_t *xip = (fmd_xprt_impl_t *)cip->ci_xprt; fasp.fasp_countp = &count; fasp.fasp_maxcount = cip->ci_nsuspects; fasp.fasp_proxy_asru = cip->ci_proxy_asru; fasp.fasp_proxy_external = xip->xi_flags & FMD_XPRT_EXTERNAL; fasp.fasp_proxy_rdonly = ((xip->xi_flags & FMD_XPRT_RDWR) == FMD_XPRT_RDONLY); fmd_asru_hash_apply_by_case(fmd.d_asrus, cp, fmd_asru_set_on_proxy, &fasp); } nvl = fmd_case_mkevent(cp, FM_LIST_SUSPECT_CLASS); (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_fltlog, e, cp); (void) pthread_rwlock_unlock(&fmd.d_log_lock); fmd_dispq_dispatch(fmd.d_disp, e, class); (void) pthread_mutex_lock(&cip->ci_mod->mod_stats_lock); cip->ci_mod->mod_stats->ms_casesolved.fmds_value.ui64++; (void) pthread_mutex_unlock(&cip->ci_mod->mod_stats_lock); break; case FMD_CASE_CLOSE_WAIT: fmd_case_hold(cp); e = fmd_event_create(FMD_EVT_CLOSE, FMD_HRT_NOW, NULL, cp); fmd_eventq_insert_at_head(cip->ci_mod->mod_queue, e); (void) pthread_mutex_lock(&cip->ci_mod->mod_stats_lock); cip->ci_mod->mod_stats->ms_caseclosed.fmds_value.ui64++; (void) pthread_mutex_unlock(&cip->ci_mod->mod_stats_lock); break; case FMD_CASE_CLOSED: nvl = fmd_case_mkevent(cp, FM_LIST_ISOLATED_CLASS); (void) nvlist_lookup_string(nvl, FM_CLASS, &class); e = fmd_event_create(FMD_EVT_PROTOCOL, FMD_HRT_NOW, nvl, class); fmd_dispq_dispatch(fmd.d_disp, e, class); break; case FMD_CASE_REPAIRED: nvl = fmd_case_mkevent(cp, FM_LIST_REPAIRED_CLASS); (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_fltlog, e, cp); (void) pthread_rwlock_unlock(&fmd.d_log_lock); fmd_dispq_dispatch(fmd.d_disp, e, class); break; case FMD_CASE_RESOLVED: nvl = fmd_case_mkevent(cp, FM_LIST_RESOLVED_CLASS); (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_fltlog, e, cp); (void) pthread_rwlock_unlock(&fmd.d_log_lock); fmd_dispq_dispatch(fmd.d_disp, e, class); break; } } fmd_case_t * fmd_case_hash_lookup(fmd_case_hash_t *chp, const char *uuid) { fmd_case_impl_t *cip; uint_t h; (void) pthread_rwlock_rdlock(&chp->ch_lock); h = fmd_strhash(uuid) % chp->ch_hashlen; for (cip = chp->ch_hash[h]; cip != NULL; cip = cip->ci_next) { if (strcmp(cip->ci_uuid, uuid) == 0) break; } /* * If deleting bit is set, treat the case as if it doesn't exist. */ if (cip != NULL) cip = fmd_case_tryhold(cip); if (cip == NULL) (void) fmd_set_errno(EFMD_CASE_INVAL); (void) pthread_rwlock_unlock(&chp->ch_lock); return ((fmd_case_t *)cip); } static fmd_case_impl_t * fmd_case_hash_insert(fmd_case_hash_t *chp, fmd_case_impl_t *cip) { fmd_case_impl_t *eip; uint_t h; (void) pthread_rwlock_wrlock(&chp->ch_lock); h = fmd_strhash(cip->ci_uuid) % chp->ch_hashlen; for (eip = chp->ch_hash[h]; eip != NULL; eip = eip->ci_next) { if (strcmp(cip->ci_uuid, eip->ci_uuid) == 0 && fmd_case_tryhold(eip) != NULL) { (void) pthread_rwlock_unlock(&chp->ch_lock); return (eip); /* uuid already present */ } } cip->ci_next = chp->ch_hash[h]; chp->ch_hash[h] = cip; chp->ch_count++; ASSERT(chp->ch_count != 0); (void) pthread_rwlock_unlock(&chp->ch_lock); return (cip); } static void fmd_case_hash_delete(fmd_case_hash_t *chp, fmd_case_impl_t *cip) { fmd_case_impl_t *cp, **pp; uint_t h; ASSERT(MUTEX_HELD(&cip->ci_lock)); cip->ci_flags |= FMD_CF_DELETING; (void) pthread_mutex_unlock(&cip->ci_lock); (void) pthread_rwlock_wrlock(&chp->ch_lock); h = fmd_strhash(cip->ci_uuid) % chp->ch_hashlen; pp = &chp->ch_hash[h]; for (cp = *pp; cp != NULL; cp = cp->ci_next) { if (cp != cip) pp = &cp->ci_next; else break; } if (cp == NULL) { fmd_panic("case %p (%s) not found on hash chain %u\n", (void *)cip, cip->ci_uuid, h); } *pp = cp->ci_next; cp->ci_next = NULL; /* * delete from code hash if it is on it */ fmd_case_code_hash_delete(chp, cip); ASSERT(chp->ch_count != 0); chp->ch_count--; (void) pthread_rwlock_unlock(&chp->ch_lock); (void) pthread_mutex_lock(&cip->ci_lock); ASSERT(cip->ci_flags & FMD_CF_DELETING); } fmd_case_t * fmd_case_create(fmd_module_t *mp, const char *uuidstr, void *data) { fmd_case_impl_t *cip = fmd_zalloc(sizeof (fmd_case_impl_t), FMD_SLEEP); fmd_case_impl_t *eip = NULL; uuid_t uuid; (void) pthread_mutex_init(&cip->ci_lock, NULL); fmd_buf_hash_create(&cip->ci_bufs); fmd_module_hold(mp); cip->ci_mod = mp; cip->ci_refs = 1; cip->ci_state = FMD_CASE_UNSOLVED; cip->ci_flags = FMD_CF_DIRTY; cip->ci_data = data; /* * Calling libuuid: get a clue. The library interfaces cleverly do not * define any constant for the length of an unparse string, and do not * permit the caller to specify a buffer length for safety. The spec * says it will be 36 bytes, but we make it tunable just in case. */ (void) fmd_conf_getprop(fmd.d_conf, "uuidlen", &cip->ci_uuidlen); cip->ci_uuid = fmd_zalloc(cip->ci_uuidlen + 1, FMD_SLEEP); if (uuidstr == NULL) { /* * We expect this loop to execute only once, but code it * defensively against the possibility of libuuid bugs. * Keep generating uuids and attempting to do a hash insert * until we get a unique one. */ do { if (eip != NULL) fmd_case_rele((fmd_case_t *)eip); uuid_generate(uuid); uuid_unparse(uuid, cip->ci_uuid); } while ((eip = fmd_case_hash_insert(fmd.d_cases, cip)) != cip); } else { /* * If a uuid was specified we must succeed with that uuid, * or return NULL indicating a case with that uuid already * exists. */ (void) strncpy(cip->ci_uuid, uuidstr, cip->ci_uuidlen + 1); if (fmd_case_hash_insert(fmd.d_cases, cip) != cip) { fmd_free(cip->ci_uuid, cip->ci_uuidlen + 1); (void) fmd_buf_hash_destroy(&cip->ci_bufs); fmd_module_rele(mp); pthread_mutex_destroy(&cip->ci_lock); fmd_free(cip, sizeof (*cip)); return (NULL); } } ASSERT(fmd_module_locked(mp)); fmd_list_append(&mp->mod_cases, cip); fmd_module_setcdirty(mp); (void) pthread_mutex_lock(&cip->ci_mod->mod_stats_lock); cip->ci_mod->mod_stats->ms_caseopen.fmds_value.ui64++; (void) pthread_mutex_unlock(&cip->ci_mod->mod_stats_lock); return ((fmd_case_t *)cip); } static void fmd_case_destroy_suspects(fmd_case_impl_t *cip) { fmd_case_susp_t *cis, *ncis; ASSERT(MUTEX_HELD(&cip->ci_lock)); if (cip->ci_proxy_asru) fmd_free(cip->ci_proxy_asru, sizeof (uint8_t) * cip->ci_nsuspects); if (cip->ci_diag_de) nvlist_free(cip->ci_diag_de); if (cip->ci_diag_asru) fmd_free(cip->ci_diag_asru, sizeof (uint8_t) * cip->ci_nsuspects); for (cis = cip->ci_suspects; cis != NULL; cis = ncis) { ncis = cis->cis_next; nvlist_free(cis->cis_nvl); fmd_free(cis, sizeof (fmd_case_susp_t)); } cip->ci_suspects = NULL; cip->ci_nsuspects = 0; } fmd_case_t * fmd_case_recreate(fmd_module_t *mp, fmd_xprt_t *xp, uint_t state, const char *uuid, const char *code) { fmd_case_impl_t *cip = fmd_zalloc(sizeof (fmd_case_impl_t), FMD_SLEEP); fmd_case_impl_t *eip; (void) pthread_mutex_init(&cip->ci_lock, NULL); fmd_buf_hash_create(&cip->ci_bufs); fmd_module_hold(mp); cip->ci_mod = mp; cip->ci_xprt = xp; cip->ci_refs = 1; cip->ci_state = state; cip->ci_uuid = fmd_strdup(uuid, FMD_SLEEP); cip->ci_uuidlen = strlen(cip->ci_uuid); cip->ci_code = fmd_strdup(code, FMD_SLEEP); cip->ci_codelen = cip->ci_code ? strlen(cip->ci_code) + 1 : 0; if (state > FMD_CASE_CLOSE_WAIT) cip->ci_flags |= FMD_CF_SOLVED; /* * Insert the case into the global case hash. If the specified UUID is * already present, check to see if it is an orphan: if so, reclaim it; * otherwise if it is owned by a different module then return NULL. */ if ((eip = fmd_case_hash_insert(fmd.d_cases, cip)) != cip) { (void) pthread_mutex_lock(&cip->ci_lock); cip->ci_refs--; /* decrement to zero */ fmd_case_destroy((fmd_case_t *)cip, B_FALSE); cip = eip; /* switch 'cip' to the existing case */ (void) pthread_mutex_lock(&cip->ci_lock); /* * If the ASRU cache is trying to recreate an orphan, then just * return the existing case that we found without changing it. */ if (mp == fmd.d_rmod) { /* * In case the case has already been created from * a checkpoint file we need to set up code now. */ if (cip->ci_state < FMD_CASE_CLOSED) { if (code != NULL && cip->ci_code == NULL) { cip->ci_code = fmd_strdup(code, FMD_SLEEP); cip->ci_codelen = cip->ci_code ? strlen(cip->ci_code) + 1 : 0; fmd_case_code_hash_insert(fmd.d_cases, cip); } } /* * When recreating an orphan case, state passed in may * be CLOSED (faulty) or REPAIRED/RESOLVED (!faulty). If * any suspects are still CLOSED (faulty) then the * overall state needs to be CLOSED. */ if ((cip->ci_state == FMD_CASE_REPAIRED || cip->ci_state == FMD_CASE_RESOLVED) && state == FMD_CASE_CLOSED) cip->ci_state = FMD_CASE_CLOSED; (void) pthread_mutex_unlock(&cip->ci_lock); fmd_case_rele((fmd_case_t *)cip); return ((fmd_case_t *)cip); } /* * If the existing case isn't an orphan or is being proxied, * then we have a UUID conflict: return failure to the caller. */ if (cip->ci_mod != fmd.d_rmod || xp != NULL) { (void) pthread_mutex_unlock(&cip->ci_lock); fmd_case_rele((fmd_case_t *)cip); return (NULL); } /* * If the new module is reclaiming an orphaned case, remove * the case from the root module, switch ci_mod, and then fall * through to adding the case to the new owner module 'mp'. */ fmd_module_lock(cip->ci_mod); fmd_list_delete(&cip->ci_mod->mod_cases, cip); fmd_module_unlock(cip->ci_mod); fmd_module_rele(cip->ci_mod); cip->ci_mod = mp; fmd_module_hold(mp); /* * It's possible that fmd crashed or was restarted during a * previous solve operation between the asru cache being created * and the ckpt file being updated to SOLVED. Thus when the DE * recreates the case here from the checkpoint file, the state * will be UNSOLVED and yet we are having to reclaim because * the case was in the asru cache. If this happens, revert the * case back to the UNSOLVED state and let the DE solve it again */ if (state == FMD_CASE_UNSOLVED) { fmd_asru_hash_delete_case(fmd.d_asrus, (fmd_case_t *)cip); fmd_case_destroy_suspects(cip); fmd_case_code_hash_delete(fmd.d_cases, cip); fmd_free(cip->ci_code, cip->ci_codelen); cip->ci_code = NULL; cip->ci_codelen = 0; cip->ci_tv_valid = 0; } cip->ci_state = state; (void) pthread_mutex_unlock(&cip->ci_lock); fmd_case_rele((fmd_case_t *)cip); } else { /* * add into hash of solved cases */ if (cip->ci_code) fmd_case_code_hash_insert(fmd.d_cases, cip); } ASSERT(fmd_module_locked(mp)); fmd_list_append(&mp->mod_cases, cip); (void) pthread_mutex_lock(&cip->ci_mod->mod_stats_lock); cip->ci_mod->mod_stats->ms_caseopen.fmds_value.ui64++; (void) pthread_mutex_unlock(&cip->ci_mod->mod_stats_lock); return ((fmd_case_t *)cip); } void fmd_case_destroy(fmd_case_t *cp, int visible) { fmd_case_impl_t *cip = (fmd_case_impl_t *)cp; fmd_case_item_t *cit, *ncit; ASSERT(MUTEX_HELD(&cip->ci_lock)); ASSERT(cip->ci_refs == 0); if (visible) { TRACE((FMD_DBG_CASE, "deleting case %s", cip->ci_uuid)); fmd_case_hash_delete(fmd.d_cases, cip); } for (cit = cip->ci_items; cit != NULL; cit = ncit) { ncit = cit->cit_next; fmd_event_rele(cit->cit_event); fmd_free(cit, sizeof (fmd_case_item_t)); } fmd_case_destroy_suspects(cip); if (cip->ci_principal != NULL) fmd_event_rele(cip->ci_principal); fmd_free(cip->ci_uuid, cip->ci_uuidlen + 1); fmd_free(cip->ci_code, cip->ci_codelen); (void) fmd_buf_hash_destroy(&cip->ci_bufs); fmd_module_rele(cip->ci_mod); fmd_free(cip, sizeof (fmd_case_impl_t)); } void fmd_case_hold(fmd_case_t *cp) { fmd_case_impl_t *cip = (fmd_case_impl_t *)cp; (void) pthread_mutex_lock(&cip->ci_lock); fmd_case_hold_locked(cp); (void) pthread_mutex_unlock(&cip->ci_lock); } void fmd_case_hold_locked(fmd_case_t *cp) { fmd_case_impl_t *cip = (fmd_case_impl_t *)cp; ASSERT(MUTEX_HELD(&cip->ci_lock)); if (cip->ci_flags & FMD_CF_DELETING) fmd_panic("attempt to hold a deleting case %p (%s)\n", (void *)cip, cip->ci_uuid); cip->ci_refs++; ASSERT(cip->ci_refs != 0); } static fmd_case_impl_t * fmd_case_tryhold(fmd_case_impl_t *cip) { /* * If the case's "deleting" bit is unset, hold and return case, * otherwise, return NULL. */ (void) pthread_mutex_lock(&cip->ci_lock); if (cip->ci_flags & FMD_CF_DELETING) { (void) pthread_mutex_unlock(&cip->ci_lock); cip = NULL; } else { fmd_case_hold_locked((fmd_case_t *)cip); (void) pthread_mutex_unlock(&cip->ci_lock); } return (cip); } void fmd_case_rele(fmd_case_t *cp) { fmd_case_impl_t *cip = (fmd_case_impl_t *)cp; (void) pthread_mutex_lock(&cip->ci_lock); ASSERT(cip->ci_refs != 0); if (--cip->ci_refs == 0) fmd_case_destroy((fmd_case_t *)cip, B_TRUE); else (void) pthread_mutex_unlock(&cip->ci_lock); } void fmd_case_rele_locked(fmd_case_t *cp) { fmd_case_impl_t *cip = (fmd_case_impl_t *)cp; ASSERT(MUTEX_HELD(&cip->ci_lock)); --cip->ci_refs; ASSERT(cip->ci_refs != 0); } int fmd_case_insert_principal(fmd_case_t *cp, fmd_event_t *ep) { fmd_case_impl_t *cip = (fmd_case_impl_t *)cp; fmd_case_item_t *cit; fmd_event_t *oep; uint_t state; int new; fmd_event_hold(ep); (void) pthread_mutex_lock(&cip->ci_lock); if (cip->ci_flags & FMD_CF_SOLVED) state = FMD_EVS_DIAGNOSED; else state = FMD_EVS_ACCEPTED; oep = cip->ci_principal; cip->ci_principal = ep; for (cit = cip->ci_items; cit != NULL; cit = cit->cit_next) { if (cit->cit_event == ep) break; } cip->ci_flags |= FMD_CF_DIRTY; new = cit == NULL && ep != oep; (void) pthread_mutex_unlock(&cip->ci_lock); fmd_module_setcdirty(cip->ci_mod); fmd_event_transition(ep, state); if (oep != NULL) fmd_event_rele(oep); return (new); } int fmd_case_insert_event(fmd_case_t *cp, fmd_event_t *ep) { fmd_case_impl_t *cip = (fmd_case_impl_t *)cp; fmd_case_item_t *cit; uint_t state; int new; boolean_t injected; (void) pthread_mutex_lock(&cip->ci_lock); if (cip->ci_flags & FMD_CF_SOLVED) state = FMD_EVS_DIAGNOSED; else state = FMD_EVS_ACCEPTED; for (cit = cip->ci_items; cit != NULL; cit = cit->cit_next) { if (cit->cit_event == ep) break; } new = cit == NULL && ep != cip->ci_principal; /* * If the event is already in the case or the case is already solved, * there is no reason to save it: just transition it appropriately. */ if (cit != NULL || (cip->ci_flags & FMD_CF_SOLVED)) { (void) pthread_mutex_unlock(&cip->ci_lock); fmd_event_transition(ep, state); return (new); } cit = fmd_alloc(sizeof (fmd_case_item_t), FMD_SLEEP); fmd_event_hold(ep); if (nvlist_lookup_boolean_value(((fmd_event_impl_t *)ep)->ev_nvl, "__injected", &injected) == 0 && injected) fmd_case_set_injected(cp); cit->cit_next = cip->ci_items; cit->cit_event = ep; cip->ci_items = cit; cip->ci_nitems++; cip->ci_flags |= FMD_CF_DIRTY; (void) pthread_mutex_unlock(&cip->ci_lock); fmd_module_setcdirty(cip->ci_mod); fmd_event_transition(ep, state); return (new); } void fmd_case_insert_suspect(fmd_case_t *cp, nvlist_t *nvl) { fmd_case_impl_t *cip = (fmd_case_impl_t *)cp; fmd_case_susp_t *cis = fmd_alloc(sizeof (fmd_case_susp_t), FMD_SLEEP); (void) pthread_mutex_lock(&cip->ci_lock); ASSERT(cip->ci_state < FMD_CASE_CLOSE_WAIT); cip->ci_flags |= FMD_CF_DIRTY; cis->cis_next = cip->ci_suspects; cis->cis_nvl = nvl; cip->ci_suspects = cis; cip->ci_nsuspects++; (void) pthread_mutex_unlock(&cip->ci_lock); if (cip->ci_xprt == NULL) fmd_module_setcdirty(cip->ci_mod); } void fmd_case_recreate_suspect(fmd_case_t *cp, nvlist_t *nvl) { fmd_case_impl_t *cip = (fmd_case_impl_t *)cp; fmd_case_susp_t *cis = fmd_alloc(sizeof (fmd_case_susp_t), FMD_SLEEP); boolean_t b; (void) pthread_mutex_lock(&cip->ci_lock); cis->cis_next = cip->ci_suspects; cis->cis_nvl = nvl; if (nvlist_lookup_boolean_value(nvl, FM_SUSPECT_MESSAGE, &b) == 0 && b == B_FALSE) cip->ci_flags |= FMD_CF_INVISIBLE; cip->ci_suspects = cis; cip->ci_nsuspects++; (void) pthread_mutex_unlock(&cip->ci_lock); } void fmd_case_reset_suspects(fmd_case_t *cp) { fmd_case_impl_t *cip = (fmd_case_impl_t *)cp; (void) pthread_mutex_lock(&cip->ci_lock); ASSERT(cip->ci_state < FMD_CASE_SOLVED); fmd_case_destroy_suspects(cip); cip->ci_flags |= FMD_CF_DIRTY; (void) pthread_mutex_unlock(&cip->ci_lock); fmd_module_setcdirty(cip->ci_mod); } /*ARGSUSED*/ static void fmd_case_unusable(fmd_asru_link_t *alp, void *arg) { (void) fmd_asru_setflags(alp, FMD_ASRU_UNUSABLE); } /* * Grab ci_lock and update the case state and set the dirty bit. Then perform * whatever actions and emit whatever events are appropriate for the state. * Refer to the topmost block comment explaining the state machine for details. */ void fmd_case_transition(fmd_case_t *cp, uint_t state, uint_t flags) { fmd_case_impl_t *cip = (fmd_case_impl_t *)cp; fmd_case_item_t *cit; fmd_event_t *e; int resolved = 0; int any_unusable_and_present = 0; ASSERT(state <= FMD_CASE_RESOLVED); (void) pthread_mutex_lock(&cip->ci_lock); if (!(cip->ci_flags & FMD_CF_SOLVED) && !(flags & FMD_CF_SOLVED)) flags &= ~(FMD_CF_ISOLATED | FMD_CF_REPAIRED | FMD_CF_RESOLVED); cip->ci_flags |= flags; if (cip->ci_state >= state) { (void) pthread_mutex_unlock(&cip->ci_lock); return; /* already in specified state */ } TRACE((FMD_DBG_CASE, "case %s %s->%s", cip->ci_uuid, _fmd_case_snames[cip->ci_state], _fmd_case_snames[state])); cip->ci_state = state; cip->ci_flags |= FMD_CF_DIRTY; if (cip->ci_xprt == NULL && cip->ci_mod != fmd.d_rmod) fmd_module_setcdirty(cip->ci_mod); switch (state) { case FMD_CASE_SOLVED: for (cit = cip->ci_items; cit != NULL; cit = cit->cit_next) fmd_event_transition(cit->cit_event, FMD_EVS_DIAGNOSED); if (cip->ci_principal != NULL) { fmd_event_transition(cip->ci_principal, FMD_EVS_DIAGNOSED); } break; case FMD_CASE_CLOSE_WAIT: /* * If the case was never solved, do not change ASRUs. * If the case was never fmd_case_closed, do not change ASRUs. * If the case was repaired, do not change ASRUs. */ if ((cip->ci_flags & (FMD_CF_SOLVED | FMD_CF_ISOLATED | FMD_CF_REPAIRED)) == (FMD_CF_SOLVED | FMD_CF_ISOLATED)) fmd_asru_hash_apply_by_case(fmd.d_asrus, cp, fmd_case_unusable, NULL); /* * If an orphaned case transitions to CLOSE_WAIT, the owning * module is no longer loaded: continue on to CASE_CLOSED or * CASE_REPAIRED as appropriate. */ if (fmd_case_orphaned(cp)) { if (cip->ci_flags & FMD_CF_REPAIRED) { state = cip->ci_state = FMD_CASE_REPAIRED; TRACE((FMD_DBG_CASE, "case %s %s->%s", cip->ci_uuid, _fmd_case_snames[FMD_CASE_CLOSE_WAIT], _fmd_case_snames[FMD_CASE_REPAIRED])); goto do_repair; } else { state = cip->ci_state = FMD_CASE_CLOSED; TRACE((FMD_DBG_CASE, "case %s %s->%s", cip->ci_uuid, _fmd_case_snames[FMD_CASE_CLOSE_WAIT], _fmd_case_snames[FMD_CASE_CLOSED])); } } break; case FMD_CASE_REPAIRED: do_repair: ASSERT(cip->ci_xprt != NULL || fmd_case_orphaned(cp)); /* * If we've been requested to transition straight on to the * RESOLVED state (which can happen with fault proxying where a * list.resolved or a uuresolved is received from the other * side), or if all suspects are already either usable or not * present then transition straight to RESOLVED state, * publishing both the list.repaired and list.resolved. For a * proxy, if we discover here that all suspects are already * either usable or not present, notify the diag side instead * using fmd_xprt_uuresolved(). */ if (flags & FMD_CF_RESOLVED) { if (cip->ci_xprt != NULL) fmd_list_delete(&cip->ci_mod->mod_cases, cip); } else { fmd_asru_hash_apply_by_case(fmd.d_asrus, cp, fmd_case_unusable_and_present, &any_unusable_and_present); if (any_unusable_and_present) break; if (cip->ci_xprt != NULL) { fmd_xprt_uuresolved(cip->ci_xprt, cip->ci_uuid); break; } } cip->ci_state = FMD_CASE_RESOLVED; (void) pthread_mutex_unlock(&cip->ci_lock); fmd_case_publish(cp, state); TRACE((FMD_DBG_CASE, "case %s %s->%s", cip->ci_uuid, _fmd_case_snames[FMD_CASE_REPAIRED], _fmd_case_snames[FMD_CASE_RESOLVED])); state = FMD_CASE_RESOLVED; resolved = 1; (void) pthread_mutex_lock(&cip->ci_lock); break; case FMD_CASE_RESOLVED: /* * For a proxy, no need to check that all suspects are already * either usable or not present - this request has come from * the diagnosing side which makes the final decision on this. */ if (cip->ci_xprt != NULL) { fmd_list_delete(&cip->ci_mod->mod_cases, cip); resolved = 1; break; } ASSERT(fmd_case_orphaned(cp)); /* * If all suspects are already either usable or not present then * carry on, publish list.resolved and discard the case. */ fmd_asru_hash_apply_by_case(fmd.d_asrus, cp, fmd_case_unusable_and_present, &any_unusable_and_present); if (any_unusable_and_present) { (void) pthread_mutex_unlock(&cip->ci_lock); return; } resolved = 1; break; } (void) pthread_mutex_unlock(&cip->ci_lock); /* * If the module has initialized, then publish the appropriate event * for the new case state. If not, we are being called from the * checkpoint code during module load, in which case the module's * _fmd_init() routine hasn't finished yet, and our event dictionaries * may not be open yet, which will prevent us from computing the event * code. Defer the call to fmd_case_publish() by enqueuing a PUBLISH * event in our queue: this won't be processed until _fmd_init is done. */ if (cip->ci_mod->mod_flags & FMD_MOD_INIT) fmd_case_publish(cp, state); else { fmd_case_hold(cp); e = fmd_event_create(FMD_EVT_PUBLISH, FMD_HRT_NOW, NULL, cp); fmd_eventq_insert_at_head(cip->ci_mod->mod_queue, e); } if (resolved) { if (cip->ci_xprt != NULL) { /* * If we transitioned to RESOLVED, adjust the reference * count to reflect our removal from * fmd.d_rmod->mod_cases above. If the caller has not * placed an additional hold on the case, it will now * be freed. */ (void) pthread_mutex_lock(&cip->ci_lock); fmd_asru_hash_delete_case(fmd.d_asrus, cp); (void) pthread_mutex_unlock(&cip->ci_lock); fmd_case_rele(cp); } else { fmd_asru_hash_apply_by_case(fmd.d_asrus, cp, fmd_asru_log_resolved, NULL); (void) pthread_mutex_lock(&cip->ci_lock); /* mark as "ready to be discarded */ cip->ci_flags |= FMD_CF_RES_CMPL; (void) pthread_mutex_unlock(&cip->ci_lock); } } } /* * Discard any case if it is in RESOLVED state (and if check_if_aged argument * is set if all suspects have passed the rsrc.aged time). */ void fmd_case_discard_resolved(fmd_case_t *cp, void *arg) { int check_if_aged = *(int *)arg; fmd_case_impl_t *cip = (fmd_case_impl_t *)cp; /* * First check if case has completed transition to resolved. */ (void) pthread_mutex_lock(&cip->ci_lock); if (!(cip->ci_flags & FMD_CF_RES_CMPL)) { (void) pthread_mutex_unlock(&cip->ci_lock); return; } /* * Now if check_is_aged is set, see if all suspects have aged. */ if (check_if_aged) { int aged = 1; fmd_asru_hash_apply_by_case(fmd.d_asrus, cp, fmd_asru_check_if_aged, &aged); if (!aged) { (void) pthread_mutex_unlock(&cip->ci_lock); return; } } /* * Finally discard the case, clearing FMD_CF_RES_CMPL so we don't * do it twice. */ fmd_module_lock(cip->ci_mod); fmd_list_delete(&cip->ci_mod->mod_cases, cip); fmd_module_unlock(cip->ci_mod); fmd_asru_hash_delete_case(fmd.d_asrus, cp); cip->ci_flags &= ~FMD_CF_RES_CMPL; (void) pthread_mutex_unlock(&cip->ci_lock); fmd_case_rele(cp); } /* * Transition the specified case to *at least* the specified state by first * re-validating the suspect list using the resource cache. This function is * employed by the checkpoint code when restoring a saved, solved case to see * if the state of the case has effectively changed while fmd was not running * or the module was not loaded. */ void fmd_case_transition_update(fmd_case_t *cp, uint_t state, uint_t flags) { fmd_case_impl_t *cip = (fmd_case_impl_t *)cp; int usable = 0; /* are any suspects usable? */ ASSERT(state >= FMD_CASE_SOLVED); (void) pthread_mutex_lock(&cip->ci_lock); fmd_asru_hash_apply_by_case(fmd.d_asrus, cp, fmd_case_usable, &usable); (void) pthread_mutex_unlock(&cip->ci_lock); if (!usable) { state = MAX(state, FMD_CASE_CLOSE_WAIT); flags |= FMD_CF_ISOLATED; } fmd_case_transition(cp, state, flags); } void fmd_case_setdirty(fmd_case_t *cp) { fmd_case_impl_t *cip = (fmd_case_impl_t *)cp; (void) pthread_mutex_lock(&cip->ci_lock); cip->ci_flags |= FMD_CF_DIRTY; (void) pthread_mutex_unlock(&cip->ci_lock); fmd_module_setcdirty(cip->ci_mod); } void fmd_case_clrdirty(fmd_case_t *cp) { fmd_case_impl_t *cip = (fmd_case_impl_t *)cp; (void) pthread_mutex_lock(&cip->ci_lock); cip->ci_flags &= ~FMD_CF_DIRTY; (void) pthread_mutex_unlock(&cip->ci_lock); } void fmd_case_commit(fmd_case_t *cp) { fmd_case_impl_t *cip = (fmd_case_impl_t *)cp; fmd_case_item_t *cit; (void) pthread_mutex_lock(&cip->ci_lock); if (cip->ci_flags & FMD_CF_DIRTY) { for (cit = cip->ci_items; cit != NULL; cit = cit->cit_next) fmd_event_commit(cit->cit_event); if (cip->ci_principal != NULL) fmd_event_commit(cip->ci_principal); fmd_buf_hash_commit(&cip->ci_bufs); cip->ci_flags &= ~FMD_CF_DIRTY; } (void) pthread_mutex_unlock(&cip->ci_lock); } /* * On proxy side, send back repair/acquit/etc request to diagnosing side */ void fmd_case_xprt_updated(fmd_case_t *cp) { fmd_case_impl_t *cip = (fmd_case_impl_t *)cp; nvlist_t **nva; uint8_t *ba; int msg = B_TRUE; int count = 0; fmd_case_lst_t fcl; ASSERT(cip->ci_xprt != NULL); (void) pthread_mutex_lock(&cip->ci_lock); ba = alloca(sizeof (uint8_t) * cip->ci_nsuspects); nva = alloca(sizeof (nvlist_t *) * cip->ci_nsuspects); fcl.fcl_countp = &count; fcl.fcl_maxcount = cip->ci_nsuspects; fcl.fcl_msgp = &msg; fcl.fcl_ba = ba; fcl.fcl_nva = nva; fmd_asru_hash_apply_by_case(fmd.d_asrus, cp, fmd_case_set_lst, &fcl); (void) pthread_mutex_unlock(&cip->ci_lock); fmd_xprt_updated(cip->ci_xprt, cip->ci_uuid, ba, cip->ci_proxy_asru, count); } /* * fmd_case_update_status() can be called on either the proxy side when a * list.suspect is received, or on the diagnosing side when an update request * is received from the proxy. It updates the status in the resource cache. */ void fmd_case_update_status(fmd_case_t *cp, uint8_t *statusp, uint8_t *proxy_asrup, uint8_t *diag_asrup) { fmd_case_impl_t *cip = (fmd_case_impl_t *)cp; int count = 0; fmd_asru_update_status_t faus; /* * update status of resource cache entries */ faus.faus_countp = &count; faus.faus_maxcount = cip->ci_nsuspects; faus.faus_ba = statusp; faus.faus_proxy_asru = proxy_asrup; faus.faus_diag_asru = diag_asrup; faus.faus_is_proxy = (cip->ci_xprt != NULL); (void) pthread_mutex_lock(&cip->ci_lock); fmd_asru_hash_apply_by_case(fmd.d_asrus, cp, fmd_asru_update_status, &faus); (void) pthread_mutex_unlock(&cip->ci_lock); } /* * Called on either the proxy side or the diag side when a repair has taken * place on the other side but this side may know the asru "contains" * relationships. */ void fmd_case_update_containees(fmd_case_t *cp) { fmd_case_impl_t *cip = (fmd_case_impl_t *)cp; (void) pthread_mutex_lock(&cip->ci_lock); fmd_asru_hash_apply_by_case(fmd.d_asrus, cp, fmd_asru_update_containees, NULL); (void) pthread_mutex_unlock(&cip->ci_lock); } /* * fmd_case_close_status() is called on diagnosing side when proxy side * has had a uuclose. It updates the status in the resource cache. */ void fmd_case_close_status(fmd_case_t *cp) { fmd_case_impl_t *cip = (fmd_case_impl_t *)cp; int count = 0; fmd_asru_close_status_t facs; /* * update status of resource cache entries */ facs.facs_countp = &count; facs.facs_maxcount = cip->ci_nsuspects; (void) pthread_mutex_lock(&cip->ci_lock); fmd_asru_hash_apply_by_case(fmd.d_asrus, cp, fmd_asru_close_status, &facs); (void) pthread_mutex_unlock(&cip->ci_lock); } /* * Indicate that the case may need to change state because one or more of the * ASRUs named as a suspect has changed state. We examine all the suspects * and if none are still faulty, we initiate a case close transition. */ void fmd_case_update(fmd_case_t *cp) { fmd_case_impl_t *cip = (fmd_case_impl_t *)cp; uint_t cstate; int faulty = 0; (void) pthread_mutex_lock(&cip->ci_lock); cstate = cip->ci_state; if (cip->ci_state < FMD_CASE_SOLVED) { (void) pthread_mutex_unlock(&cip->ci_lock); return; /* update is not appropriate */ } if (cip->ci_flags & FMD_CF_REPAIRED) { (void) pthread_mutex_unlock(&cip->ci_lock); return; /* already repaired */ } TRACE((FMD_DBG_CASE, "case update %s", cip->ci_uuid)); fmd_asru_hash_apply_by_case(fmd.d_asrus, cp, fmd_case_faulty, &faulty); (void) pthread_mutex_unlock(&cip->ci_lock); if (faulty) { nvlist_t *nvl; fmd_event_t *e; char *class; TRACE((FMD_DBG_CASE, "sending list.updated %s", cip->ci_uuid)); nvl = fmd_case_mkevent(cp, FM_LIST_UPDATED_CLASS); (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_fltlog, e, cp); (void) pthread_rwlock_unlock(&fmd.d_log_lock); fmd_dispq_dispatch(fmd.d_disp, e, class); return; /* one or more suspects are still marked faulty */ } if (cstate == FMD_CASE_CLOSED) fmd_case_transition(cp, FMD_CASE_REPAIRED, FMD_CF_REPAIRED); else fmd_case_transition(cp, FMD_CASE_CLOSE_WAIT, FMD_CF_REPAIRED); } /* * Delete a closed case from the module's case list once the fmdo_close() entry * point has run to completion. If the case is owned by a transport module, * tell the transport to proxy a case close on the other end of the transport. * Transition to the appropriate next state based on ci_flags. This * function represents the end of CLOSE_WAIT and transitions the case to either * CLOSED or REPAIRED or discards it entirely because it was never solved; * refer to the topmost block comment explaining the state machine for details. */ void fmd_case_delete(fmd_case_t *cp) { fmd_case_impl_t *cip = (fmd_case_impl_t *)cp; fmd_modstat_t *msp; size_t buftotal; TRACE((FMD_DBG_CASE, "case delete %s", cip->ci_uuid)); ASSERT(fmd_module_locked(cip->ci_mod)); fmd_list_delete(&cip->ci_mod->mod_cases, cip); buftotal = fmd_buf_hash_destroy(&cip->ci_bufs); (void) pthread_mutex_lock(&cip->ci_mod->mod_stats_lock); msp = cip->ci_mod->mod_stats; ASSERT(msp->ms_caseopen.fmds_value.ui64 != 0); msp->ms_caseopen.fmds_value.ui64--; ASSERT(msp->ms_buftotal.fmds_value.ui64 >= buftotal); msp->ms_buftotal.fmds_value.ui64 -= buftotal; (void) pthread_mutex_unlock(&cip->ci_mod->mod_stats_lock); if (cip->ci_xprt == NULL) fmd_module_setcdirty(cip->ci_mod); fmd_module_rele(cip->ci_mod); cip->ci_mod = fmd.d_rmod; fmd_module_hold(cip->ci_mod); /* * If the case has been solved, then retain it * on the root module's case list at least until we're transitioned. * Otherwise free the case with our final fmd_case_rele() below. */ if (cip->ci_flags & FMD_CF_SOLVED) { fmd_module_lock(cip->ci_mod); fmd_list_append(&cip->ci_mod->mod_cases, cip); fmd_module_unlock(cip->ci_mod); fmd_case_hold(cp); } /* * Transition onwards to REPAIRED or CLOSED as originally requested. * Note that for proxy case if we're transitioning to CLOSED it means * the case was isolated locally, so call fmd_xprt_uuclose() to notify * the diagnosing side. No need to notify the diagnosing side if we are * transitioning to REPAIRED as we only do this when requested to do * so by the diagnosing side anyway. */ if (cip->ci_flags & FMD_CF_REPAIRED) fmd_case_transition(cp, FMD_CASE_REPAIRED, 0); else if (cip->ci_flags & FMD_CF_ISOLATED) { fmd_case_transition(cp, FMD_CASE_CLOSED, 0); if (cip->ci_xprt != NULL) fmd_xprt_uuclose(cip->ci_xprt, cip->ci_uuid); } fmd_case_rele(cp); } void fmd_case_discard(fmd_case_t *cp, boolean_t delete_from_asru_cache) { fmd_case_impl_t *cip = (fmd_case_impl_t *)cp; (void) pthread_mutex_lock(&cip->ci_mod->mod_stats_lock); cip->ci_mod->mod_stats->ms_caseopen.fmds_value.ui64--; (void) pthread_mutex_unlock(&cip->ci_mod->mod_stats_lock); ASSERT(fmd_module_locked(cip->ci_mod)); fmd_list_delete(&cip->ci_mod->mod_cases, cip); if (delete_from_asru_cache) { (void) pthread_mutex_lock(&cip->ci_lock); fmd_asru_hash_delete_case(fmd.d_asrus, cp); (void) pthread_mutex_unlock(&cip->ci_lock); } fmd_case_rele(cp); } /* * Indicate that the problem corresponding to a case has been repaired by * clearing the faulty bit on each ASRU named as a suspect. If the case hasn't * already been closed, this function initiates the transition to CLOSE_WAIT. * The caller must have the case held from fmd_case_hash_lookup(), so we can * grab and drop ci_lock without the case being able to be freed in between. */ int fmd_case_repair(fmd_case_t *cp) { fmd_case_impl_t *cip = (fmd_case_impl_t *)cp; uint_t cstate; fmd_asru_rep_arg_t fara; (void) pthread_mutex_lock(&cip->ci_lock); cstate = cip->ci_state; if (cstate < FMD_CASE_SOLVED) { (void) pthread_mutex_unlock(&cip->ci_lock); return (fmd_set_errno(EFMD_CASE_STATE)); } if (cip->ci_flags & FMD_CF_REPAIRED) { (void) pthread_mutex_unlock(&cip->ci_lock); return (0); /* already repaired */ } TRACE((FMD_DBG_CASE, "case repair %s", cip->ci_uuid)); fara.fara_reason = FMD_ASRU_REPAIRED; fara.fara_bywhat = FARA_BY_CASE; fara.fara_rval = NULL; fmd_asru_hash_apply_by_case(fmd.d_asrus, cp, fmd_asru_repaired, &fara); (void) pthread_mutex_unlock(&cip->ci_lock); /* * if this is a proxied case, send the repair across the transport. * The remote side will then do the repair and send a list.repaired back * again such that we can finally repair the case on this side. */ if (cip->ci_xprt != NULL) { fmd_case_xprt_updated(cp); return (0); } if (cstate == FMD_CASE_CLOSED) fmd_case_transition(cp, FMD_CASE_REPAIRED, FMD_CF_REPAIRED); else fmd_case_transition(cp, FMD_CASE_CLOSE_WAIT, FMD_CF_REPAIRED); return (0); } int fmd_case_acquit(fmd_case_t *cp) { fmd_case_impl_t *cip = (fmd_case_impl_t *)cp; uint_t cstate; fmd_asru_rep_arg_t fara; (void) pthread_mutex_lock(&cip->ci_lock); cstate = cip->ci_state; if (cstate < FMD_CASE_SOLVED) { (void) pthread_mutex_unlock(&cip->ci_lock); return (fmd_set_errno(EFMD_CASE_STATE)); } if (cip->ci_flags & FMD_CF_REPAIRED) { (void) pthread_mutex_unlock(&cip->ci_lock); return (0); /* already repaired */ } TRACE((FMD_DBG_CASE, "case acquit %s", cip->ci_uuid)); fara.fara_reason = FMD_ASRU_ACQUITTED; fara.fara_bywhat = FARA_BY_CASE; fara.fara_rval = NULL; fmd_asru_hash_apply_by_case(fmd.d_asrus, cp, fmd_asru_repaired, &fara); (void) pthread_mutex_unlock(&cip->ci_lock); /* * if this is a proxied case, send the repair across the transport. * The remote side will then do the repair and send a list.repaired back * again such that we can finally repair the case on this side. */ if (cip->ci_xprt != NULL) { fmd_case_xprt_updated(cp); return (0); } if (cstate == FMD_CASE_CLOSED) fmd_case_transition(cp, FMD_CASE_REPAIRED, FMD_CF_REPAIRED); else fmd_case_transition(cp, FMD_CASE_CLOSE_WAIT, FMD_CF_REPAIRED); return (0); } int fmd_case_contains(fmd_case_t *cp, fmd_event_t *ep) { fmd_case_impl_t *cip = (fmd_case_impl_t *)cp; fmd_case_item_t *cit; uint_t state; int rv = 0; (void) pthread_mutex_lock(&cip->ci_lock); if (cip->ci_state >= FMD_CASE_SOLVED) state = FMD_EVS_DIAGNOSED; else state = FMD_EVS_ACCEPTED; for (cit = cip->ci_items; cit != NULL; cit = cit->cit_next) { if ((rv = fmd_event_equal(ep, cit->cit_event)) != 0) break; } if (rv == 0 && cip->ci_principal != NULL) rv = fmd_event_equal(ep, cip->ci_principal); (void) pthread_mutex_unlock(&cip->ci_lock); if (rv != 0) fmd_event_transition(ep, state); return (rv); } int fmd_case_orphaned(fmd_case_t *cp) { return (((fmd_case_impl_t *)cp)->ci_mod == fmd.d_rmod); } void fmd_case_settime(fmd_case_t *cp, time_t tv_sec, suseconds_t tv_usec) { ((fmd_case_impl_t *)cp)->ci_tv.tv_sec = tv_sec; ((fmd_case_impl_t *)cp)->ci_tv.tv_usec = tv_usec; ((fmd_case_impl_t *)cp)->ci_tv_valid = 1; } void fmd_case_set_injected(fmd_case_t *cp) { ((fmd_case_impl_t *)cp)->ci_injected = 1; } void fmd_case_set_de_fmri(fmd_case_t *cp, nvlist_t *nvl) { fmd_case_impl_t *cip = (fmd_case_impl_t *)cp; if (cip->ci_diag_de) nvlist_free(cip->ci_diag_de); cip->ci_diag_de = nvl; } void fmd_case_setcode(fmd_case_t *cp, char *code) { fmd_case_impl_t *cip = (fmd_case_impl_t *)cp; cip->ci_code = fmd_strdup(code, FMD_SLEEP); cip->ci_codelen = cip->ci_code ? strlen(cip->ci_code) + 1 : 0; } /*ARGSUSED*/ static void fmd_case_repair_replay_case(fmd_case_t *cp, void *arg) { int not_faulty = 0; int faulty = 0; nvlist_t *nvl; fmd_event_t *e; char *class; int any_unusable_and_present = 0; fmd_case_impl_t *cip = (fmd_case_impl_t *)cp; if (cip->ci_state < FMD_CASE_SOLVED || cip->ci_xprt != NULL) return; if (cip->ci_state == FMD_CASE_RESOLVED) { cip->ci_flags |= FMD_CF_RES_CMPL; return; } fmd_asru_hash_apply_by_case(fmd.d_asrus, cp, fmd_case_faulty, &faulty); fmd_asru_hash_apply_by_case(fmd.d_asrus, cp, fmd_case_not_faulty, ¬_faulty); if (cip->ci_state >= FMD_CASE_REPAIRED && !faulty) { /* * If none of the suspects is faulty, replay the list.repaired. * If all suspects are already either usable or not present then * also transition straight to RESOLVED state. */ fmd_asru_hash_apply_by_case(fmd.d_asrus, cp, fmd_case_unusable_and_present, &any_unusable_and_present); if (!any_unusable_and_present) { cip->ci_state = FMD_CASE_RESOLVED; TRACE((FMD_DBG_CASE, "replay sending list.repaired %s", cip->ci_uuid)); nvl = fmd_case_mkevent(cp, FM_LIST_REPAIRED_CLASS); (void) nvlist_lookup_string(nvl, FM_CLASS, &class); e = fmd_event_create(FMD_EVT_PROTOCOL, FMD_HRT_NOW, nvl, class); fmd_dispq_dispatch(fmd.d_disp, e, class); TRACE((FMD_DBG_CASE, "replay sending list.resolved %s", cip->ci_uuid)); fmd_case_publish(cp, FMD_CASE_RESOLVED); fmd_asru_hash_apply_by_case(fmd.d_asrus, cp, fmd_asru_log_resolved, NULL); cip->ci_flags |= FMD_CF_RES_CMPL; } else { TRACE((FMD_DBG_CASE, "replay sending list.repaired %s", cip->ci_uuid)); nvl = fmd_case_mkevent(cp, FM_LIST_REPAIRED_CLASS); (void) nvlist_lookup_string(nvl, FM_CLASS, &class); e = fmd_event_create(FMD_EVT_PROTOCOL, FMD_HRT_NOW, nvl, class); fmd_dispq_dispatch(fmd.d_disp, e, class); } } else if (faulty && not_faulty) { /* * if some but not all of the suspects are not faulty, replay * the list.updated. */ TRACE((FMD_DBG_CASE, "replay sending list.updated %s", cip->ci_uuid)); nvl = fmd_case_mkevent(cp, FM_LIST_UPDATED_CLASS); (void) nvlist_lookup_string(nvl, FM_CLASS, &class); e = fmd_event_create(FMD_EVT_PROTOCOL, FMD_HRT_NOW, nvl, class); fmd_dispq_dispatch(fmd.d_disp, e, class); } } void fmd_case_repair_replay() { fmd_case_hash_apply(fmd.d_cases, fmd_case_repair_replay_case, NULL); }