/* * 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. */ /* * Subscription event access interfaces. */ #include #include #include #include #include #include #include #include "fmev_impl.h" #define API_ENTERV1(iep) \ ((void) fmev_api_enter(fmev_shdl_cmn(((iep)->ei_hdl)), \ LIBFMEVENT_VERSION_1)) typedef struct { uint32_t ei_magic; /* _FMEVMAGIC */ volatile uint32_t ei_refcnt; /* reference count */ fmev_shdl_t ei_hdl; /* handle received on */ nvlist_t *ei_nvl; /* (duped) sysevent attribute list */ uint64_t ei_fmtime[2]; /* embedded protocol event time */ } fmev_impl_t; #define FMEV2IMPL(ev) ((fmev_impl_t *)(ev)) #define IMPL2FMEV(iep) ((fmev_t)(iep)) #define _FMEVMAGIC 0x466d4576 /* "FmEv" */ #define EVENT_VALID(iep) ((iep)->ei_magic == _FMEVMAGIC && \ (iep)->ei_refcnt > 0 && fmev_shdl_valid((iep)->ei_hdl)) #define FM_TIME_SEC 0 #define FM_TIME_NSEC 1 /* * Transform a received sysevent_t into an fmev_t. */ uint64_t fmev_bad_attr, fmev_bad_tod, fmev_bad_class; fmev_t fmev_sysev2fmev(fmev_shdl_t hdl, sysevent_t *sep, char **clsp, nvlist_t **nvlp) { fmev_impl_t *iep; uint64_t *tod; uint_t nelem; if ((iep = fmev_shdl_alloc(hdl, sizeof (*iep))) == NULL) return (NULL); /* * sysevent_get_attr_list duplicates the nvlist - we free it * in fmev_free when the reference count hits zero. */ if (sysevent_get_attr_list(sep, &iep->ei_nvl) != 0) { fmev_shdl_free(hdl, iep, sizeof (*iep)); fmev_bad_attr++; return (NULL); } *nvlp = iep->ei_nvl; if (nvlist_lookup_string(iep->ei_nvl, FM_CLASS, clsp) != 0) { nvlist_free(iep->ei_nvl); fmev_shdl_free(hdl, iep, sizeof (*iep)); fmev_bad_class++; return (NULL); } if (nvlist_lookup_uint64_array(iep->ei_nvl, "__tod", &tod, &nelem) != 0 || nelem != 2) { nvlist_free(iep->ei_nvl); fmev_shdl_free(hdl, iep, sizeof (*iep)); fmev_bad_tod++; return (NULL); } iep->ei_fmtime[FM_TIME_SEC] = tod[0]; iep->ei_fmtime[FM_TIME_NSEC] = tod[1]; /* * Now remove the fmd-private __tod and __ttl members. */ (void) nvlist_remove_all(iep->ei_nvl, "__tod"); (void) nvlist_remove_all(iep->ei_nvl, "__ttl"); iep->ei_magic = _FMEVMAGIC; iep->ei_hdl = hdl; iep->ei_refcnt = 1; ASSERT(EVENT_VALID(iep)); return (IMPL2FMEV(iep)); } static void fmev_free(fmev_impl_t *iep) { ASSERT(iep->ei_refcnt == 0); nvlist_free(iep->ei_nvl); fmev_shdl_free(iep->ei_hdl, iep, sizeof (*iep)); } void fmev_hold(fmev_t ev) { fmev_impl_t *iep = FMEV2IMPL(ev); ASSERT(EVENT_VALID(iep)); API_ENTERV1(iep); atomic_inc_32(&iep->ei_refcnt); } void fmev_rele(fmev_t ev) { fmev_impl_t *iep = FMEV2IMPL(ev); ASSERT(EVENT_VALID(iep)); API_ENTERV1(iep); if (atomic_dec_32_nv(&iep->ei_refcnt) == 0) fmev_free(iep); } fmev_t fmev_dup(fmev_t ev) { fmev_impl_t *iep = FMEV2IMPL(ev); fmev_impl_t *cp; ASSERT(EVENT_VALID(iep)); API_ENTERV1(iep); if (ev == NULL) { (void) fmev_seterr(FMEVERR_API); return (NULL); } if ((cp = fmev_shdl_alloc(iep->ei_hdl, sizeof (*iep))) == NULL) { (void) fmev_seterr(FMEVERR_ALLOC); return (NULL); } if (nvlist_dup(iep->ei_nvl, &cp->ei_nvl, 0) != 0) { fmev_shdl_free(iep->ei_hdl, cp, sizeof (*cp)); (void) fmev_seterr(FMEVERR_ALLOC); return (NULL); } cp->ei_magic = _FMEVMAGIC; cp->ei_hdl = iep->ei_hdl; cp->ei_refcnt = 1; return (IMPL2FMEV(cp)); } nvlist_t * fmev_attr_list(fmev_t ev) { fmev_impl_t *iep = FMEV2IMPL(ev); ASSERT(EVENT_VALID(iep)); API_ENTERV1(iep); if (ev == NULL) { (void) fmev_seterr(FMEVERR_API); return (NULL); } else if (iep->ei_nvl == NULL) { (void) fmev_seterr(FMEVERR_MALFORMED_EVENT); return (NULL); } return (iep->ei_nvl); } const char * fmev_class(fmev_t ev) { fmev_impl_t *iep = FMEV2IMPL(ev); const char *class; ASSERT(EVENT_VALID(iep)); API_ENTERV1(iep); if (ev == NULL) { (void) fmev_seterr(FMEVERR_API); return (""); } if (nvlist_lookup_string(iep->ei_nvl, FM_CLASS, (char **)&class) != 0 || *class == '\0') { (void) fmev_seterr(FMEVERR_MALFORMED_EVENT); return (""); } return (class); } fmev_err_t fmev_timespec(fmev_t ev, struct timespec *tp) { fmev_impl_t *iep = FMEV2IMPL(ev); uint64_t timetlimit; ASSERT(EVENT_VALID(iep)); API_ENTERV1(iep); #ifdef _LP64 timetlimit = INT64_MAX; #else timetlimit = INT32_MAX; #endif if (iep->ei_fmtime[FM_TIME_SEC] > timetlimit) return (FMEVERR_OVERFLOW); tp->tv_sec = (time_t)iep->ei_fmtime[FM_TIME_SEC]; tp->tv_nsec = (long)iep->ei_fmtime[FM_TIME_NSEC]; return (FMEV_SUCCESS); } uint64_t fmev_time_sec(fmev_t ev) { return (FMEV2IMPL(ev)->ei_fmtime[FM_TIME_SEC]); } uint64_t fmev_time_nsec(fmev_t ev) { return (FMEV2IMPL(ev)->ei_fmtime[FM_TIME_NSEC]); } struct tm * fmev_localtime(fmev_t ev, struct tm *tm) { time_t seconds; seconds = (time_t)fmev_time_sec(ev); return (localtime_r(&seconds, tm)); }