/* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License, Version 1.0 only * (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 2004 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ #pragma ident "%Z%%M% %I% %E% SMI" /* * FMD Control Event Subsystem * * This file provides a simple and extensible subsystem for the processing of * synchronous control events that can be received from the event transport * and used to control the behavior of the fault manager itself. At present * this feature is used for the implementation of simulation controls such as * advancing the simulated clock using events sent by the fminject utility. * Control events are assigned a class of the form "resource.sunos.fmd.*" and * are assigned a callback function defined in the _fmd_ctls[] table below. * As control events are received by the event transport, they are assigned a * special event type (ev_type = FMD_EVT_CTL) and the ev_data member is used * to refer to a fmd_ctl_t data structure, managed by the functions below. * * Control events are implemented so that they are synchronous with respect to * the rest of the fault manager event stream, which is usually asynchronous * (that is, the transport dispatch thread and the module receive threads all * execute in parallel). Synchronous processing is required for control events * so that they can affect global state (e.g. the simulated clock) and ensure * that the results of any state changes are seen by *all* subsequent events. * * To achieve synchronization, the event itself implements a thread barrier: * the fmd_ctl_t maintains a reference count that mirrors the fmd_event_t * reference count (which for ctls counts the number of modules the event * was dispatched to). As each module receive thread dequeues the event, it * calls fmd_event_rele() to discard the event, which calls fmd_ctl_rele(). * fmd_ctl_rele() decrements the ctl's reference count but blocks there waiting * for *all* other references to be released. When all threads have reached * the barrier, the final caller of fmd_ctl_rele() executes the control event * callback function and then wakes everyone else up. The transport dispatch * thread, blocked in fmd_modhash_dispatch(), is typically this final caller. */ #include #include #include #include #include #include #include #include #include #include #include #include static void fmd_ctl_addhrt(nvlist_t *nvl) { int64_t delta = 0; (void) nvlist_lookup_int64(nvl, FMD_RSRC_ADDHRT_DELTA, &delta); fmd_time_addhrtime(delta); /* * If the non-adjustable clock has reached the apocalypse, fmd(1M) * should exit gracefully: queue a SIGTERM for the main thread. */ if (fmd_time_gethrtime() == INT64_MAX) (void) pthread_kill(fmd.d_rmod->mod_thread->thr_tid, SIGTERM); } static void fmd_ctl_inval(nvlist_t *nvl) { char *class = ""; (void) nvlist_lookup_string(nvl, FM_CLASS, &class); fmd_error(EFMD_CTL_INVAL, "ignoring invalid control event %s\n", class); } static const fmd_ctl_desc_t _fmd_ctls[] = { { FMD_RSRC_ADDHRT, FMD_RSRC_ADDHRT_VERS1, fmd_ctl_addhrt }, { NULL, UINT_MAX, fmd_ctl_inval } }; fmd_ctl_t * fmd_ctl_init(nvlist_t *nvl) { fmd_ctl_t *cp = fmd_alloc(sizeof (fmd_ctl_t), FMD_SLEEP); const fmd_ctl_desc_t *dp; uint8_t vers; char *class; (void) pthread_mutex_init(&cp->ctl_lock, NULL); (void) pthread_cond_init(&cp->ctl_cv, NULL); if (nvlist_lookup_string(nvl, FM_CLASS, &class) != 0 || nvlist_lookup_uint8(nvl, FM_VERSION, &vers) != 0) fmd_panic("ctl_init called with bad nvlist %p", (void *)nvl); for (dp = _fmd_ctls; dp->cde_class != NULL; dp++) { if (strcmp(class, dp->cde_class) == 0) break; } cp->ctl_func = vers > dp->cde_vers ? &fmd_ctl_inval : dp->cde_func; cp->ctl_nvl = nvl; cp->ctl_refs = 0; return (cp); } void fmd_ctl_fini(fmd_ctl_t *cp) { fmd_free(cp, sizeof (fmd_ctl_t)); } /* * Increment the ref count on the fmd_ctl_t to correspond to a reference to the * fmd_event_t. This count is used to implement a barrier in fmd_ctl_rele(). */ void fmd_ctl_hold(fmd_ctl_t *cp) { (void) pthread_mutex_lock(&cp->ctl_lock); cp->ctl_refs++; ASSERT(cp->ctl_refs != 0); (void) pthread_mutex_unlock(&cp->ctl_lock); } /* * Decrement the reference count on the fmd_ctl_t. If this rele() is the last * one, then execute the callback function and release all the other callers. * Otherwise enter a loop waiting on ctl_cv for other threads to call rele(). */ void fmd_ctl_rele(fmd_ctl_t *cp) { (void) pthread_mutex_lock(&cp->ctl_lock); ASSERT(cp->ctl_refs != 0); cp->ctl_refs--; if (cp->ctl_refs == 0) { cp->ctl_func(cp->ctl_nvl); (void) pthread_cond_broadcast(&cp->ctl_cv); } else { while (cp->ctl_refs != 0) (void) pthread_cond_wait(&cp->ctl_cv, &cp->ctl_lock); } (void) pthread_mutex_unlock(&cp->ctl_lock); }