/* * 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 */ /* * Routines for writing audit records. * * Copyright 2004 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ #pragma ident "%Z%%M% %I% %E% SMI" #include #include #include #include #include /* for statfs */ #include #include #include #include #include #include #include /* for KM_SLEEP */ #include /* for RLIM_INFINITY */ #include /* panic */ #include #include #include #include #include #include #include #include #include #include static void au_dequeue(au_kcontext_t *, au_buff_t *); static void audit_async_finish_backend(void *); static int audit_sync_block(au_kcontext_t *); /* * each of these two tables are indexed by the values AU_DBUF_COMPLETE * through AU_DBUF_LAST; the content is the next state value. The * first table determines the next state for a buffer which is not the * end of a record and the second table determines the state for a * buffer which is the end of a record. The initial state is * AU_DBUF_COMPLETE. */ static int state_if_part[] = { AU_DBUF_FIRST, AU_DBUF_MIDDLE, AU_DBUF_MIDDLE, AU_DBUF_FIRST}; static int state_if_not_part[] = { AU_DBUF_COMPLETE, AU_DBUF_LAST, AU_DBUF_LAST, AU_DBUF_COMPLETE}; /* * Write to an audit descriptor. * Add the au_membuf to the descriptor chain and free the chain passed in. */ void au_uwrite(m) token_t *m; { au_write(&(u_ad), m); } void au_write(caddr_t *d, token_t *m) { if (d == NULL) { au_toss_token(m); return; } if (m == (token_t *)0) { printf("au_write: null token\n"); return; } if (*d == NULL) *d = (caddr_t)m; else (void) au_append_rec((au_buff_t *)*d, m, AU_PACK); } #define AU_INTERVAL 120 /* * Write audit information to the disk. * Called from auditsvc(); EOL'd as of Sol 10. * Local zones are not allowed; the caller (auditsvc()) enforces the * restriction. */ int au_doio(vp, limit) struct vnode *vp; int limit; { /* AU_DOIO */ off_t off; /* space used in buffer */ size_t used; /* space used in au_membuf */ token_t *cAR; /* current AR being processed */ token_t *cMB; /* current au_membuf being processed */ token_t *sp; /* last AR processed */ char *bp; /* start of free space in staging buffer */ unsigned char *cp; /* ptr to data to be moved */ au_kcontext_t *kctx; /* * size (data left in au_membuf - space in buffer) */ ssize_t sz; ssize_t len; /* len of data to move, size of AR */ int error; /* error return */ ssize_t left; /* data not xfered by write to disk */ statvfs64_t sb; /* buffer for statfs */ size_t curr_sz = 0; /* amount of data written during now */ int part = 0; /* partial audit record written */ int partial = 0; /* flag to force partial AR to file */ /* 0 - idle, ignore */ /* 1 - force write of audit record */ /* 2 - finished writing AR, commit */ kctx = SET_KCTX_GZ; ASSERT(kctx != NULL); /* * Check to ensure enough free space on audit device. */ bzero(&sb, sizeof (statvfs64_t)); (void) VFS_STATVFS(vp->v_vfsp, &sb); /* * Large Files: We do not convert any of this part of kernel * to be large file aware. Original behaviour should be * maintained. This function is called from audit_svc and * it already checks for negative values of limit. */ if (sb.f_blocks && (fsblkcnt64_t)limit > sb.f_bavail) return (ENOSPC); if (kctx->auk_file_stat.af_filesz && (kctx->auk_file_stat.af_currsz >= kctx->auk_file_stat.af_filesz)) return (EFBIG); /* * has the write buffer changed length due to a auditctl(2)? * (remember that auk_buffer is an element of auk_dbuffer) */ if (kctx->auk_queue.bufsz != kctx->auk_queue.buflen) { kmem_free(kctx->auk_buffer, kctx->auk_queue.buflen); /* bad, should not sleep here. Testing only */ kctx->auk_buffer = kmem_alloc(kctx->auk_queue.bufsz, KM_SLEEP); kctx->auk_queue.buflen = kctx->auk_queue.bufsz; } if (!kctx->auk_queue.head) { goto nodata; } sp = (token_t *)0; /* no AR copied */ off = 0; /* no space used in buffer */ used = 0; /* no data processed in au_membuf */ cAR = kctx->auk_queue.head; /* start at head of queue */ cMB = cAR; /* start with first au_membuf of record */ bp = &(kctx->auk_buffer[0]); /* start at beginning of buffer */ while (cMB) { ASSERT(kctx->auk_queue.head != NULL); /* indicate audit record being processed */ part = 1; /* pointer to buffer data */ cp = memtod(cMB, unsigned char *); /* data left in au_membuf */ sz = (ssize_t)cMB->len - used; /* len to move */ len = (ssize_t)MIN(sz, kctx->auk_queue.buflen - off); /* move the data */ bcopy(cp + used, bp + off, len); used += len; /* update used au_membuf */ off += len; /* update offset into buffer */ if (used >= (ssize_t)cMB->len) { /* advance to next au_membuf */ used = 0; cMB = cMB->next_buf; } if (cMB == (au_buff_t *)0) { /* advance to next AR */ sp = cAR; cAR = cAR->next_rec; cMB = cAR; /* reached end of an audit record */ part = 0; /* force abort at end of audit record? */ if (partial == 1) partial = 2; } /* * If we've reached end of buffer, or have run out of * audit records on the queue or we've processed a * partial audit record to complete the audit file, * then its time to flush the holding buffer to the * audit trail. */ if ((kctx->auk_queue.buflen == off) || (cAR == (au_buff_t *)0) || (partial == 2)) { left = 0; /* * Largefiles: We purposely pass a value of * MAXOFF_T as we do not want any of the * auditing files to exceed 2GB. May be we will * support this in future. */ error = vn_rdwr(UIO_WRITE, vp, kctx->auk_buffer, off, 0LL, UIO_SYSSPACE, FAPPEND, (rlim64_t)MAXOFF_T, CRED(), &left); /* error on write */ if (error != 0) { if (error == EDQUOT) error = ENOSPC; return (error); } /* end of file system? */ if (left) { au_buff_t *b = NULL; sz = off - left; /* how much written */ /* update space counters */ kctx->auk_file_stat.af_currsz += sz; /* which AR are done */ cAR = kctx->auk_queue.head; while (sz) { cp = memtod(cAR, unsigned char *); len = (ssize_t)((cp[1]<<24 | cp[2]<<16 | cp[3]<<8 | cp[4]) & 0xffffffffU); if (len > sz) break; b = cAR; cAR = cAR->next_rec; sz -= len; } if (b != NULL) au_dequeue(kctx, b); return (ENOSPC); } else { /* still space in file system */ /* if we've written an AR */ if (sp) { /* * free records up to last one copied. */ au_dequeue(kctx, sp); } /* Update sizes */ curr_sz += off; kctx->auk_file_stat.af_currsz += (uint_t)off; /* reset auk_buffer pointers */ sp = (token_t *)0; off = 0; bp = &(kctx->auk_buffer[0]); /* check exit conditions */ if (sb.f_blocks) { ulong_t blks_used; blks_used = (curr_sz / sb.f_bsize); if ((fsblkcnt64_t)limit > (sb.f_bavail - (fsblkcnt64_t)blks_used)) { /* * if we haven't put out a * complete audit record, * continue to process the * audit queue until we reach * the end of the record. */ if (part && (partial == 0)) { partial = 1; continue; } /* * exit if complete record */ if (partial != 1) return (ENOSPC); } } if (kctx->auk_file_stat.af_filesz && (kctx->auk_file_stat.af_currsz >= kctx->auk_file_stat.af_filesz)) { /* * force a complete audit * record to the trail. */ if (partial == 0) partial = 1; /* * Written data to AR boundry. */ if (partial != 1) return (EFBIG); } } } } /* while(cMB) */ nodata: return (0); } /* * Close an audit descriptor. * Use the second parameter to indicate if it should be written or not. */ void au_close(au_kcontext_t *kctx, caddr_t *d, int flag, short e_type, short e_mod) { token_t *dchain; /* au_membuf chain which is the tokens */ t_audit_data_t *tad = U2A(u); ASSERT(tad != NULL); ASSERT(d != NULL); ASSERT(kctx != NULL); if ((dchain = (token_t *)*d) == (token_t *)NULL) return; *d = NULL; /* * If async then defer; or if requested, defer the closing/queueing to * syscall end, unless no syscall is active or the syscall is _exit. */ if ((flag & AU_DONTBLOCK) || ((flag & AU_DEFER) && (tad->tad_scid != 0) && (tad->tad_scid != SYS_exit))) { au_close_defer(dchain, flag, e_type, e_mod); return; } au_close_time(kctx, dchain, flag, e_type, e_mod, NULL); } /* * Defer closing/queueing of an audit descriptor. For async events, queue * via softcall. Otherwise, defer by queueing the record onto the tad; at * syscall end time it will be pulled off. */ void au_close_defer(token_t *dchain, int flag, short e_type, short e_mod) { au_defer_info_t *attr; t_audit_data_t *tad = U2A(u); ASSERT(tad != NULL); /* If not to be written, toss the record. */ if ((flag & AU_OK) == 0) { au_toss_token(dchain); return; } attr = kmem_alloc(sizeof (au_defer_info_t), KM_NOSLEEP); /* If no mem available, failing silently is the best recourse */ if (attr == NULL) { au_toss_token(dchain); return; } attr->audi_next = NULL; attr->audi_ad = dchain; attr->audi_e_type = e_type; attr->audi_e_mod = e_mod; attr->audi_flag = flag; gethrestime(&attr->audi_atime); /* * All async events must be queued via softcall to avoid possible * sleeping in high interrupt context. softcall will ensure it's * done on a dedicated software-level interrupt thread. */ if (flag & AU_DONTBLOCK) { softcall(audit_async_finish_backend, attr); audit_async_done(NULL, 0); return; } /* * If not an async event, defer by queuing onto the tad until * syscall end. No locking is needed because the tad is per-thread. */ if (tad->tad_defer_head) tad->tad_defer_tail->audi_next = attr; else tad->tad_defer_head = attr; tad->tad_defer_tail = attr; } /* * Save the time in the event header. If time is not specified (i.e., pointer * is NULL), use the current time. This code is fairly ugly since it needs * to support both 32- and 64-bit environments and can be called indirectly * from both au_close() (for kernel audit) and from audit() (userland audit). */ /*ARGSUSED*/ static void au_save_time(adr_t *hadrp, timestruc_t *time, int size) { struct { uint32_t sec; uint32_t usec; } tv; timestruc_t now; if (time == NULL) { gethrestime(&now); time = &now; } #ifdef _LP64 if (size) adr_int64(hadrp, (int64_t *)time, 2); else #endif { tv.sec = (uint32_t)time->tv_sec; tv.usec = (uint32_t)time->tv_nsec; adr_int32(hadrp, (int32_t *)&tv, 2); } } /* * Close an audit descriptor. * If time of event is specified, use it in the record, otherwise use the * current time. */ void au_close_time(au_kcontext_t *kctx, token_t *dchain, int flag, short e_type, short e_mod, timestruc_t *etime) { token_t *record; /* au_membuf chain == the record */ int byte_count; token_t *m; /* for potential sequence token */ adr_t hadr; /* handle for header token */ adr_t sadr; /* handle for sequence token */ size_t zone_length; /* length of zonename token */ ASSERT(dchain != NULL); /* If not to be written, toss the record */ if ((flag & AU_OK) == 0) { au_toss_token(dchain); return; } /* if auditing not enabled, then don't generate an audit record */ ASSERT(kctx != NULL); if ((kctx->auk_auditstate != AUC_AUDITING) && (kctx->auk_auditstate != AUC_INIT_AUDIT)) { /* * at system boot, neither is set yet we want to generate * an audit record. */ if (e_type != AUE_SYSTEMBOOT) { au_toss_token(dchain); return; } } /* Count up the bytes used in the record. */ byte_count = au_token_size(dchain); /* * add in size of header token (always present). */ byte_count += sizeof (char) + sizeof (int32_t) + sizeof (char) + 2 * sizeof (short) + sizeof (timestruc_t); if (kctx->auk_hostaddr_valid) byte_count += sizeof (int32_t) + kctx->auk_info.ai_termid.at_type; /* * add in size of zonename token (zero if !AUDIT_ZONENAME) */ if (kctx->auk_policy & AUDIT_ZONENAME) { zone_length = au_zonename_length(); byte_count += zone_length; } else { zone_length = 0; } /* add in size of (optional) trailer token */ if (kctx->auk_policy & AUDIT_TRAIL) byte_count += 7; /* add in size of (optional) sequence token */ if (kctx->auk_policy & AUDIT_SEQ) byte_count += 5; /* build the header */ if (kctx->auk_hostaddr_valid) record = au_to_header_ex(byte_count, e_type, e_mod); else record = au_to_header(byte_count, e_type, e_mod); /* * If timestamp was specified, save it in header now. Otherwise, * save reference to header so we can update time/data later * and artificially adjust pointer to the time/date field of header. */ adr_start(&hadr, memtod(record, char *)); hadr.adr_now += sizeof (char) + sizeof (int32_t) + sizeof (char) + 2 * sizeof (short); if (kctx->auk_hostaddr_valid) hadr.adr_now += sizeof (int32_t) + kctx->auk_info.ai_termid.at_type; if (etime != NULL) { au_save_time(&hadr, etime, 1); hadr.adr_now = (char *)NULL; } /* append body of audit record */ (void) au_append_rec(record, dchain, AU_PACK); /* add (optional) zonename token */ if (zone_length > 0) { m = au_to_zonename(zone_length); (void) au_append_rec(record, m, AU_PACK); } /* Add an (optional) sequence token. NULL offset if none */ if (kctx->auk_policy & AUDIT_SEQ) { /* get the sequence token */ m = au_to_seq(); /* link to audit record (i.e. don't pack the data) */ (void) au_append_rec(record, m, AU_LINK); /* * advance to count field of sequence token by skipping * the token type byte. */ adr_start(&sadr, memtod(m, char *)); sadr.adr_now += 1; } else { sadr.adr_now = NULL; } /* add (optional) trailer token */ if (kctx->auk_policy & AUDIT_TRAIL) { (void) au_append_rec(record, au_to_trailer(byte_count), AU_PACK); } /* * 1 - use 64 bit version of audit tokens for 64 bit kernels. * 0 - use 32 bit version of audit tokens for 32 bit kernels. */ #ifdef _LP64 au_enqueue(kctx, record, &hadr, &sadr, 1, flag & AU_DONTBLOCK); #else au_enqueue(kctx, record, &hadr, &sadr, 0, flag & AU_DONTBLOCK); #endif AS_INC(as_totalsize, byte_count, kctx); } /*ARGSUSED*/ void au_enqueue(au_kcontext_t *kctx, au_buff_t *m, adr_t *hadrp, adr_t *sadrp, int size, int dontblock) { if (kctx == NULL) return; mutex_enter(&(kctx->auk_queue.lock)); if (!dontblock && (kctx->auk_queue.cnt >= kctx->auk_queue.hiwater) && audit_sync_block(kctx)) { mutex_exit(&(kctx->auk_queue.lock)); au_free_rec(m); return; } /* Fill in date and time if needed */ if (hadrp->adr_now) { au_save_time(hadrp, NULL, size); } /* address will be non-zero only if AUDIT_SEQ set */ if (sadrp->adr_now) { kctx->auk_sequence++; adr_int32(sadrp, (int32_t *)&(kctx->auk_sequence), 1); } if (kctx->auk_queue.head) kctx->auk_queue.tail->next_rec = m; else kctx->auk_queue.head = m; kctx->auk_queue.tail = m; if (++(kctx->auk_queue.cnt) > kctx->auk_queue.lowater && kctx->auk_queue.rd_block) cv_broadcast(&(kctx->auk_queue.read_cv)); mutex_exit(&(kctx->auk_queue.lock)); /* count # audit records put onto kernel audit queue */ AS_INC(as_enqueue, 1, kctx); } /* * Dequeue and free buffers upto and including "freeto" * Keeps the queue lock long but acquires it only once when doing * bulk dequeueing. */ static void au_dequeue(au_kcontext_t *kctx, au_buff_t *freeto) { au_buff_t *m, *l, *lastl; int n = 0; ASSERT(kctx != NULL); mutex_enter(&(kctx->auk_queue.lock)); ASSERT(kctx->auk_queue.head != NULL); ASSERT(freeto != NULL); l = m = kctx->auk_queue.head; do { n++; lastl = l; l = l->next_rec; } while (l != NULL && freeto != lastl); kctx->auk_queue.cnt -= n; lastl->next_rec = NULL; kctx->auk_queue.head = l; /* Freeto must exist in the list */ ASSERT(freeto == lastl); if (kctx->auk_queue.cnt <= kctx->auk_queue.lowater && kctx->auk_queue.wt_block) cv_broadcast(&(kctx->auk_queue.write_cv)); mutex_exit(&(kctx->auk_queue.lock)); while (m) { l = m->next_rec; au_free_rec(m); m = l; } AS_INC(as_written, n, kctx); } /* * audit_sync_block() * If we've reached the high water mark, we look at the policy to see * if we sleep or we should drop the audit record. * This function is called with the auk_queue.lock held and the check * performed one time already as an optimization. Caller should unlock. * Returns 1 if the caller needs to free the record. */ static int audit_sync_block(au_kcontext_t *kctx) { ASSERT(MUTEX_HELD(&(kctx->auk_queue.lock))); /* * Loop while we are at the high watermark. */ do { if ((kctx->auk_auditstate != AUC_AUDITING) || (kctx->auk_policy & AUDIT_CNT)) { /* just count # of dropped audit records */ AS_INC(as_dropped, 1, kctx); return (1); } /* kick reader awake if its asleep */ if (kctx->auk_queue.rd_block && kctx->auk_queue.cnt > kctx->auk_queue.lowater) cv_broadcast(&(kctx->auk_queue.read_cv)); /* keep count of # times blocked */ AS_INC(as_wblocked, 1, kctx); /* sleep now, until woken by reader */ kctx->auk_queue.wt_block++; cv_wait(&(kctx->auk_queue.write_cv), &(kctx->auk_queue.lock)); kctx->auk_queue.wt_block--; } while (kctx->auk_queue.cnt >= kctx->auk_queue.hiwater); return (0); } /* * audit_async_block() * if we've reached the high water mark, we look at the ahlt policy to see * if we reboot we should drop the audit record. * Returns 1 if blocked. */ static int audit_async_block(au_kcontext_t *kctx, caddr_t *rpp) { ASSERT(kctx != NULL); mutex_enter(&(kctx->auk_queue.lock)); /* see if we've reached high water mark */ if (kctx->auk_queue.cnt >= kctx->auk_queue.hiwater) { mutex_exit(&(kctx->auk_queue.lock)); audit_async_drop(rpp, AU_BACKEND); return (1); } mutex_exit(&(kctx->auk_queue.lock)); return (0); } /* * au_door_upcall. auditdoor() may change vp without notice, so * some locking seems in order. * */ #define AGAIN_TICKS 10 static int au_door_upcall(au_kcontext_t *kctx, au_dbuf_t *aubuf) { int rc; door_arg_t darg; int retry = 1; int ticks_to_wait; darg.data_ptr = (char *)aubuf; darg.data_size = AU_DBUF_HEADER + aubuf->aub_size; darg.desc_ptr = NULL; darg.desc_num = 0; while (retry == 1) { /* non-zero means return results expected */ darg.rbuf = (char *)aubuf; darg.rsize = darg.data_size; retry = 0; mutex_enter(&(kctx->auk_svc_lock)); if ((rc = door_upcall(kctx->auk_current_vp, &darg)) != 0) { mutex_exit(&(kctx->auk_svc_lock)); if (rc == EAGAIN) ticks_to_wait = AGAIN_TICKS; else return (rc); mutex_enter(&(kctx->auk_eagain_mutex)); (void) cv_timedwait(&(kctx->auk_eagain_cv), &(kctx->auk_eagain_mutex), lbolt + ticks_to_wait); mutex_exit(&(kctx->auk_eagain_mutex)); retry = 1; } else mutex_exit(&(kctx->auk_svc_lock)); /* no retry */ } /* end while (retry == 1) */ if (darg.rbuf == NULL) return (-1); /* return code from door server */ return (*(int *)darg.rbuf); } /* * Write an audit control message to the door handle. The message * structure depends on message_code and at present the only control * message defined is for a policy change. These are infrequent, * so no memory is held for control messages. */ int au_doormsg(au_kcontext_t *kctx, uint32_t message_code, void *message) { int rc; au_dbuf_t *buf; size_t alloc_size; switch (message_code) { case AU_DBUF_POLICY: alloc_size = AU_DBUF_HEADER + sizeof (uint32_t); buf = kmem_alloc(alloc_size, KM_SLEEP); buf->aub_size = sizeof (uint32_t); *(uint32_t *)buf->aub_buf = *(uint32_t *)message; break; case AU_DBUF_SHUTDOWN: alloc_size = AU_DBUF_HEADER; buf = kmem_alloc(alloc_size, KM_SLEEP); buf->aub_size = 0; break; default: return (1); } buf->aub_type = AU_DBUF_NOTIFY | message_code; rc = au_door_upcall(kctx, buf); kmem_free(buf, alloc_size); return (rc); } /* * Write audit information to the door handle. au_doorio is called with * one or more complete audit records on the queue and outputs those * records in buffers of up to auk_queue.buflen in size. */ int au_doorio(au_kcontext_t *kctx) { off_t off; /* space used in buffer */ ssize_t used; /* space used in au_membuf */ token_t *cAR; /* current AR being processed */ token_t *cMB; /* current au_membuf being processed */ token_t *sp; /* last AR processed */ char *bp; /* start of free space in staging buffer */ unsigned char *cp; /* ptr to data to be moved */ int error; /* return from door upcall */ /* * size (data left in au_membuf - space in buffer) */ ssize_t sz; ssize_t len; /* len of data to move, size of AR */ ssize_t curr_sz = 0; /* amount of data written during now */ /* * partial_state is AU_DBUF_COMPLETE...LAST; see audit_door_infc.h */ int part = 0; /* partial audit record written */ int partial_state = AU_DBUF_COMPLETE; /* * Has the write buffer changed length due to a auditctl(2)? * Initial allocation is from audit_start.c/audit_init() */ if (kctx->auk_queue.bufsz != kctx->auk_queue.buflen) { kmem_free(kctx->auk_dbuffer, AU_DBUF_HEADER + kctx->auk_queue.buflen); kctx->auk_dbuffer = kmem_alloc(AU_DBUF_HEADER + kctx->auk_queue.bufsz, KM_SLEEP); /* omit the 64 bit header */ kctx->auk_queue.buflen = kctx->auk_queue.bufsz; } if (!kctx->auk_queue.head) goto nodata; sp = NULL; /* no record copied */ off = 0; /* no space used in buffer */ used = 0; /* no data processed in au_membuf */ cAR = kctx->auk_queue.head; /* start at head of queue */ cMB = cAR; /* start with first au_membuf of record */ /* start at beginning of buffer */ bp = &(kctx->auk_dbuffer->aub_buf[0]); while (cMB) { part = 1; /* indicate audit record being processed */ cp = memtod(cMB, unsigned char *); /* buffer ptr */ sz = (ssize_t)cMB->len - used; /* data left in au_membuf */ /* len to move */ len = (ssize_t)MIN(sz, kctx->auk_queue.buflen - off); /* move the data */ bcopy(cp + used, bp + off, len); used += len; /* update used au_membuf */ off += len; /* update offset into buffer */ if (used >= (ssize_t)cMB->len) { /* advance to next au_membuf */ used = 0; cMB = cMB->next_buf; } if (cMB == NULL) { /* advance to next audit record */ sp = cAR; cAR = cAR->next_rec; cMB = cAR; part = 0; /* have a complete record */ } error = 0; if ((kctx->auk_queue.buflen == off) || (part == 0)) { if (part) partial_state = state_if_part[partial_state]; else partial_state = state_if_not_part[partial_state]; kctx->auk_dbuffer->aub_type = partial_state; kctx->auk_dbuffer->aub_size = off; error = au_door_upcall(kctx, kctx->auk_dbuffer); if (error != 0) goto nodata; /* * if we've successfully written an audit record, * free records up to last full record copied */ if (sp) au_dequeue(kctx, sp); /* Update size */ curr_sz += off; /* reset auk_dbuffer pointers */ sp = NULL; off = 0; } } /* while(cMB) */ nodata: return (error); } /* * Clean up thread audit state to clear out asynchronous audit record * generation error recovery processing. Note that this is done on a * per-thread basis and thus does not need any locking. */ void audit_async_done(caddr_t *rpp, int flags) { t_audit_data_t *tad = U2A(u); /* clean up the tad unless called from softcall backend */ if (!(flags & AU_BACKEND)) { ASSERT(tad != NULL); ASSERT(tad->tad_ctrl & PAD_ERRJMP); tad->tad_ctrl &= ~PAD_ERRJMP; tad->tad_errjmp = NULL; } /* clean out partial audit record */ if ((rpp != NULL) && (*rpp != NULL)) { au_toss_token((au_buff_t *)*rpp); *rpp = NULL; } } /* * implement the audit policy for asynchronous events generated within * the kernel. * XXX might need locks around audit_policy check. */ void audit_async_drop(caddr_t *rpp, int flags) { au_kcontext_t *kctx; /* could not generate audit record, clean up */ audit_async_done((caddr_t *)rpp, flags); kctx = SET_KCTX_GZ; ASSERT(kctx != NULL); /* just drop the record and return */ if (((audit_policy & AUDIT_AHLT) == 0) || (kctx->auk_auditstate == AUC_INIT_AUDIT)) { /* just count # of dropped audit records */ AS_INC(as_dropped, 1, kctx); return; } /* * There can be a lot of data in the audit queue. We * will first sync the file systems then attempt to * shutdown the kernel so that a memory dump is * performed. */ sync(); sync(); /* * now shut down. What a cruel world it has been */ panic("non-attributable halt. should dump core"); /* No return */ } int audit_async_start(label_t *jb, int event, int sorf) { t_audit_data_t *tad = U2A(u); au_state_t estate; int success = 0, failure = 0; au_kcontext_t *kctx = SET_KCTX_GZ; ASSERT(kctx != NULL); /* if audit state off, then no audit record generation */ if ((kctx->auk_auditstate != AUC_AUDITING) && (kctx->auk_auditstate != AUC_INIT_AUDIT)) return (1); /* * preselect asynchronous event * XXX should we check for out-of-range??? */ estate = kctx->auk_ets[event]; if (sorf & AUM_SUCC) success = kctx->auk_info.ai_mask.as_success & estate; if (sorf & AUM_FAIL) failure = kctx->auk_info.ai_mask.as_failure & estate; if ((success | failure) == NULL) return (1); ASSERT(tad->tad_errjmp == NULL); tad->tad_errjmp = (void *)jb; tad->tad_ctrl |= PAD_ERRJMP; return (0); } /* * Complete auditing of an async event. The AU_DONTBLOCK flag to au_close will * result in the backend routine being invoked from softcall, so all the real * work can be done in a safe context. */ void audit_async_finish(caddr_t *ad, int aid, int amod) { au_kcontext_t *kctx; kctx = SET_KCTX_GZ; ASSERT(kctx != NULL); au_close(kctx, ad, AU_DONTBLOCK | AU_OK, aid, PAD_NONATTR|amod); } /* * Backend routine to complete an async audit. Invoked from softcall. * (Note: the blocking and the queuing below both involve locking which can't * be done safely in high interrupt context due to the chance of sleeping on * the corresponding adaptive mutex. Hence the softcall.) */ static void audit_async_finish_backend(void *addr) { au_kcontext_t *kctx; au_defer_info_t *attr = (au_defer_info_t *)addr; if (attr == NULL) return; /* won't happen unless softcall is broken */ kctx = SET_KCTX_GZ; ASSERT(kctx != NULL); if (audit_async_block(kctx, (caddr_t *)&attr->audi_ad)) { kmem_free(attr, sizeof (au_defer_info_t)); return; } /* * Call au_close_time to complete the audit with the saved values. * * For the exit-prom event, use the current time instead of the * saved time as a better approximation. (Because the time saved via * gethrestime during prom-exit handling would not yet be caught up * after the system was idled in the debugger for a period of time.) */ if (attr->audi_e_type == AUE_EXITPROM) { au_close_time(kctx, (token_t *)attr->audi_ad, attr->audi_flag, attr->audi_e_type, attr->audi_e_mod, NULL); } else { au_close_time(kctx, (token_t *)attr->audi_ad, attr->audi_flag, attr->audi_e_type, attr->audi_e_mod, &attr->audi_atime); } AS_INC(as_generated, 1, kctx); AS_INC(as_nonattrib, 1, kctx); kmem_free(attr, sizeof (au_defer_info_t)); }