audit_bsm.c revision 302408 
1/*
2 * Copyright (c) 1999-2009 Apple Inc.
3 * All rights reserved.
4 *
5 * Redistribution and use in source and binary forms, with or without
6 * modification, are permitted provided that the following conditions
7 * are met:
8 * 1.  Redistributions of source code must retain the above copyright
9 *     notice, this list of conditions and the following disclaimer.
10 * 2.  Redistributions in binary form must reproduce the above copyright
11 *     notice, this list of conditions and the following disclaimer in the
12 *     documentation and/or other materials provided with the distribution.
13 * 3.  Neither the name of Apple Inc. ("Apple") nor the names of
14 *     its contributors may be used to endorse or promote products derived
15 *     from this software without specific prior written permission.
16 *
17 * THIS SOFTWARE IS PROVIDED BY APPLE AND ITS CONTRIBUTORS "AS IS" AND
18 * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
19 * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
20 * ARE DISCLAIMED. IN NO EVENT SHALL APPLE OR ITS CONTRIBUTORS BE LIABLE FOR
21 * ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
22 * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
23 * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
24 * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT,
25 * STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING
26 * IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
27 * POSSIBILITY OF SUCH DAMAGE.
28 */
29
30#include <sys/cdefs.h>
31__FBSDID("$FreeBSD: stable/11/sys/security/audit/audit_bsm.c 301867 2016-06-13 09:22:20Z rwatson $");
32
33#include <sys/param.h>
34#include <sys/vnode.h>
35#include <sys/ipc.h>
36#include <sys/lock.h>
37#include <sys/malloc.h>
38#include <sys/mutex.h>
39#include <sys/socket.h>
40#include <sys/extattr.h>
41#include <sys/fcntl.h>
42#include <sys/user.h>
43#include <sys/systm.h>
44
45#include <bsm/audit.h>
46#include <bsm/audit_internal.h>
47#include <bsm/audit_record.h>
48#include <bsm/audit_kevents.h>
49
50#include <security/audit/audit.h>
51#include <security/audit/audit_private.h>
52
53#include <netinet/in_systm.h>
54#include <netinet/in.h>
55#include <netinet/ip.h>
56
57MALLOC_DEFINE(M_AUDITBSM, "audit_bsm", "Audit BSM data");
58
59static void	audit_sys_auditon(struct audit_record *ar,
60		    struct au_record *rec);
61
62/*
63 * Initialize the BSM auditing subsystem.
64 */
65void
66kau_init(void)
67{
68
69	au_evclassmap_init();
70}
71
72/*
73 * This call reserves memory for the audit record.  Memory must be guaranteed
74 * before any auditable event can be generated.  The au_record structure
75 * maintains a reference to the memory allocated above and also the list of
76 * tokens associated with this record.
77 */
78static struct au_record *
79kau_open(void)
80{
81	struct au_record *rec;
82
83	rec = malloc(sizeof(*rec), M_AUDITBSM, M_WAITOK);
84	rec->data = NULL;
85	TAILQ_INIT(&rec->token_q);
86	rec->len = 0;
87	rec->used = 1;
88
89	return (rec);
90}
91
92/*
93 * Store the token with the record descriptor.
94 */
95static void
96kau_write(struct au_record *rec, struct au_token *tok)
97{
98
99	KASSERT(tok != NULL, ("kau_write: tok == NULL"));
100
101	TAILQ_INSERT_TAIL(&rec->token_q, tok, tokens);
102	rec->len += tok->len;
103}
104
105/*
106 * Close out the audit record by adding the header token, identifying any
107 * missing tokens.  Write out the tokens to the record memory.
108 */
109static void
110kau_close(struct au_record *rec, struct timespec *ctime, short event)
111{
112	u_char *dptr;
113	size_t tot_rec_size;
114	token_t *cur, *hdr, *trail;
115	struct timeval tm;
116	size_t hdrsize;
117	struct auditinfo_addr ak;
118	struct in6_addr *ap;
119
120	audit_get_kinfo(&ak);
121	hdrsize = 0;
122	switch (ak.ai_termid.at_type) {
123	case AU_IPv4:
124		hdrsize = (ak.ai_termid.at_addr[0] == INADDR_ANY) ?
125		    AUDIT_HEADER_SIZE : AUDIT_HEADER_EX_SIZE(&ak);
126		break;
127	case AU_IPv6:
128		ap = (struct in6_addr *)&ak.ai_termid.at_addr[0];
129		hdrsize = (IN6_IS_ADDR_UNSPECIFIED(ap)) ? AUDIT_HEADER_SIZE :
130		    AUDIT_HEADER_EX_SIZE(&ak);
131		break;
132	default:
133		panic("kau_close: invalid address family");
134	}
135	tot_rec_size = rec->len + hdrsize + AUDIT_TRAILER_SIZE;
136	rec->data = malloc(tot_rec_size, M_AUDITBSM, M_WAITOK | M_ZERO);
137
138	tm.tv_usec = ctime->tv_nsec / 1000;
139	tm.tv_sec = ctime->tv_sec;
140	if (hdrsize != AUDIT_HEADER_SIZE)
141		hdr = au_to_header32_ex_tm(tot_rec_size, event, 0, tm, &ak);
142	else
143		hdr = au_to_header32_tm(tot_rec_size, event, 0, tm);
144	TAILQ_INSERT_HEAD(&rec->token_q, hdr, tokens);
145
146	trail = au_to_trailer(tot_rec_size);
147	TAILQ_INSERT_TAIL(&rec->token_q, trail, tokens);
148
149	rec->len = tot_rec_size;
150	dptr = rec->data;
151	TAILQ_FOREACH(cur, &rec->token_q, tokens) {
152		memcpy(dptr, cur->t_data, cur->len);
153		dptr += cur->len;
154	}
155}
156
157/*
158 * Free a BSM audit record by releasing all the tokens and clearing the audit
159 * record information.
160 */
161void
162kau_free(struct au_record *rec)
163{
164	struct au_token *tok;
165
166	/* Free the token list. */
167	while ((tok = TAILQ_FIRST(&rec->token_q))) {
168		TAILQ_REMOVE(&rec->token_q, tok, tokens);
169		free(tok->t_data, M_AUDITBSM);
170		free(tok, M_AUDITBSM);
171	}
172
173	rec->used = 0;
174	rec->len = 0;
175	free(rec->data, M_AUDITBSM);
176	free(rec, M_AUDITBSM);
177}
178
179/*
180 * XXX: May want turn some (or all) of these macros into functions in order
181 * to reduce the generated code size.
182 *
183 * XXXAUDIT: These macros assume that 'kar', 'ar', 'rec', and 'tok' in the
184 * caller are OK with this.
185 */
186#define	ATFD1_TOKENS(argnum) do {					\
187	if (ARG_IS_VALID(kar, ARG_ATFD1)) {				\
188		tok = au_to_arg32(argnum, "at fd 1", ar->ar_arg_atfd1);	\
189		kau_write(rec, tok);					\
190	}								\
191} while (0)
192
193#define	ATFD2_TOKENS(argnum) do {					\
194	if (ARG_IS_VALID(kar, ARG_ATFD2)) {				\
195		tok = au_to_arg32(argnum, "at fd 2", ar->ar_arg_atfd2);	\
196		kau_write(rec, tok);					\
197	}								\
198} while (0)
199
200#define	UPATH1_TOKENS do {						\
201	if (ARG_IS_VALID(kar, ARG_UPATH1)) {				\
202		tok = au_to_path(ar->ar_arg_upath1);			\
203		kau_write(rec, tok);					\
204	}								\
205} while (0)
206
207#define	UPATH2_TOKENS do {						\
208	if (ARG_IS_VALID(kar, ARG_UPATH2)) {				\
209		tok = au_to_path(ar->ar_arg_upath2);			\
210		kau_write(rec, tok);					\
211	}								\
212} while (0)
213
214#define	VNODE1_TOKENS do {						\
215	if (ARG_IS_VALID(kar, ARG_ATFD)) {				\
216		tok = au_to_arg32(1, "at fd", ar->ar_arg_atfd);		\
217		kau_write(rec, tok);					\
218	}								\
219	if (ARG_IS_VALID(kar, ARG_VNODE1)) {				\
220		tok = au_to_attr32(&ar->ar_arg_vnode1);			\
221		kau_write(rec, tok);					\
222	}								\
223} while (0)
224
225#define	UPATH1_VNODE1_TOKENS do {					\
226	UPATH1_TOKENS;							\
227	if (ARG_IS_VALID(kar, ARG_VNODE1)) {				\
228		tok = au_to_attr32(&ar->ar_arg_vnode1);			\
229		kau_write(rec, tok);					\
230	}								\
231} while (0)
232
233#define	VNODE2_TOKENS do {						\
234	if (ARG_IS_VALID(kar, ARG_VNODE2)) {				\
235		tok = au_to_attr32(&ar->ar_arg_vnode2);			\
236		kau_write(rec, tok);					\
237	}								\
238} while (0)
239
240#define	FD_VNODE1_TOKENS do {						\
241	if (ARG_IS_VALID(kar, ARG_VNODE1)) {				\
242		if (ARG_IS_VALID(kar, ARG_FD)) {			\
243			tok = au_to_arg32(1, "fd", ar->ar_arg_fd);	\
244			kau_write(rec, tok);				\
245		}							\
246		tok = au_to_attr32(&ar->ar_arg_vnode1);			\
247		kau_write(rec, tok);					\
248	} else {							\
249		if (ARG_IS_VALID(kar, ARG_FD)) {			\
250			tok = au_to_arg32(1, "non-file: fd",		\
251			    ar->ar_arg_fd);				\
252			kau_write(rec, tok);				\
253		}							\
254	}								\
255} while (0)
256
257#define	PROCESS_PID_TOKENS(argn) do {					\
258	if ((ar->ar_arg_pid > 0) /* Reference a single process */	\
259	    && (ARG_IS_VALID(kar, ARG_PROCESS))) {			\
260		tok = au_to_process32_ex(ar->ar_arg_auid,		\
261		    ar->ar_arg_euid, ar->ar_arg_egid,			\
262		    ar->ar_arg_ruid, ar->ar_arg_rgid,			\
263		    ar->ar_arg_pid, ar->ar_arg_asid,			\
264		    &ar->ar_arg_termid_addr);				\
265		kau_write(rec, tok);					\
266	} else if (ARG_IS_VALID(kar, ARG_PID)) {			\
267		tok = au_to_arg32(argn, "process", ar->ar_arg_pid);	\
268		kau_write(rec, tok);					\
269	}								\
270} while (0)
271
272#define	EXTATTR_TOKENS(namespace_argnum) do {				\
273	if (ARG_IS_VALID(kar, ARG_VALUE)) {				\
274		switch (ar->ar_arg_value) {				\
275		case EXTATTR_NAMESPACE_USER:				\
276			tok = au_to_text(EXTATTR_NAMESPACE_USER_STRING);\
277			break;						\
278		case EXTATTR_NAMESPACE_SYSTEM:				\
279			tok = au_to_text(EXTATTR_NAMESPACE_SYSTEM_STRING);\
280			break;						\
281		default:						\
282			tok = au_to_arg32((namespace_argnum),		\
283			    "attrnamespace", ar->ar_arg_value);		\
284			break;						\
285		}							\
286		kau_write(rec, tok);					\
287	}								\
288	/* attrname is in the text field */				\
289	if (ARG_IS_VALID(kar, ARG_TEXT)) {				\
290		tok = au_to_text(ar->ar_arg_text);			\
291		kau_write(rec, tok);					\
292	}								\
293} while (0)
294
295/*
296 * Not all pointer arguments to system calls are of interest, but in some
297 * cases they reflect delegation of rights, such as mmap(2) followed by
298 * minherit(2) before execve(2), so do the best we can.
299 */
300#define	ADDR_TOKEN(argnum, argname) do {				\
301	if (ARG_IS_VALID(kar, ARG_ADDR)) {				\
302		if (sizeof(void *) == sizeof(uint32_t))			\
303			tok = au_to_arg32((argnum), (argname),		\
304			    (uint32_t)(uintptr_t)ar->ar_arg_addr);	\
305		else							\
306			tok = au_to_arg64((argnum), (argname),		\
307			    (uint64_t)(uintptr_t)ar->ar_arg_addr);	\
308		kau_write(rec, tok);					\
309	}								\
310} while (0)
311
312
313/*
314 * Implement auditing for the auditon() system call. The audit tokens that
315 * are generated depend on the command that was sent into the auditon()
316 * system call.
317 */
318static void
319audit_sys_auditon(struct audit_record *ar, struct au_record *rec)
320{
321	struct au_token *tok;
322
323	tok = au_to_arg32(3, "length", ar->ar_arg_len);
324	kau_write(rec, tok);
325	switch (ar->ar_arg_cmd) {
326	case A_OLDSETPOLICY:
327		if ((size_t)ar->ar_arg_len == sizeof(int64_t)) {
328			tok = au_to_arg64(2, "policy",
329			    ar->ar_arg_auditon.au_policy64);
330			kau_write(rec, tok);
331			break;
332		}
333		/* FALLTHROUGH */
334
335	case A_SETPOLICY:
336		tok = au_to_arg32(2, "policy", ar->ar_arg_auditon.au_policy);
337		kau_write(rec, tok);
338		break;
339
340	case A_SETKMASK:
341		tok = au_to_arg32(2, "setkmask:as_success",
342		    ar->ar_arg_auditon.au_mask.am_success);
343		kau_write(rec, tok);
344		tok = au_to_arg32(2, "setkmask:as_failure",
345		    ar->ar_arg_auditon.au_mask.am_failure);
346		kau_write(rec, tok);
347		break;
348
349	case A_OLDSETQCTRL:
350		if ((size_t)ar->ar_arg_len == sizeof(au_qctrl64_t)) {
351			tok = au_to_arg64(2, "setqctrl:aq_hiwater",
352			    ar->ar_arg_auditon.au_qctrl64.aq64_hiwater);
353			kau_write(rec, tok);
354			tok = au_to_arg64(2, "setqctrl:aq_lowater",
355			    ar->ar_arg_auditon.au_qctrl64.aq64_lowater);
356			kau_write(rec, tok);
357			tok = au_to_arg64(2, "setqctrl:aq_bufsz",
358			    ar->ar_arg_auditon.au_qctrl64.aq64_bufsz);
359			kau_write(rec, tok);
360			tok = au_to_arg64(2, "setqctrl:aq_delay",
361			    ar->ar_arg_auditon.au_qctrl64.aq64_delay);
362			kau_write(rec, tok);
363			tok = au_to_arg64(2, "setqctrl:aq_minfree",
364			    ar->ar_arg_auditon.au_qctrl64.aq64_minfree);
365			kau_write(rec, tok);
366			break;
367		}
368		/* FALLTHROUGH */
369
370	case A_SETQCTRL:
371		tok = au_to_arg32(2, "setqctrl:aq_hiwater",
372		    ar->ar_arg_auditon.au_qctrl.aq_hiwater);
373		kau_write(rec, tok);
374		tok = au_to_arg32(2, "setqctrl:aq_lowater",
375		    ar->ar_arg_auditon.au_qctrl.aq_lowater);
376		kau_write(rec, tok);
377		tok = au_to_arg32(2, "setqctrl:aq_bufsz",
378		    ar->ar_arg_auditon.au_qctrl.aq_bufsz);
379		kau_write(rec, tok);
380		tok = au_to_arg32(2, "setqctrl:aq_delay",
381		    ar->ar_arg_auditon.au_qctrl.aq_delay);
382		kau_write(rec, tok);
383		tok = au_to_arg32(2, "setqctrl:aq_minfree",
384		    ar->ar_arg_auditon.au_qctrl.aq_minfree);
385		kau_write(rec, tok);
386		break;
387
388	case A_SETUMASK:
389		tok = au_to_arg32(2, "setumask:as_success",
390		    ar->ar_arg_auditon.au_auinfo.ai_mask.am_success);
391		kau_write(rec, tok);
392		tok = au_to_arg32(2, "setumask:as_failure",
393		    ar->ar_arg_auditon.au_auinfo.ai_mask.am_failure);
394		kau_write(rec, tok);
395		break;
396
397	case A_SETSMASK:
398		tok = au_to_arg32(2, "setsmask:as_success",
399		    ar->ar_arg_auditon.au_auinfo.ai_mask.am_success);
400		kau_write(rec, tok);
401		tok = au_to_arg32(2, "setsmask:as_failure",
402		    ar->ar_arg_auditon.au_auinfo.ai_mask.am_failure);
403		kau_write(rec, tok);
404		break;
405
406	case A_OLDSETCOND:
407		if ((size_t)ar->ar_arg_len == sizeof(int64_t)) {
408			tok = au_to_arg64(2, "setcond",
409			    ar->ar_arg_auditon.au_cond64);
410			kau_write(rec, tok);
411			break;
412		}
413		/* FALLTHROUGH */
414
415	case A_SETCOND:
416		tok = au_to_arg32(2, "setcond", ar->ar_arg_auditon.au_cond);
417		kau_write(rec, tok);
418		break;
419
420	case A_SETCLASS:
421		kau_write(rec, tok);
422		tok = au_to_arg32(2, "setclass:ec_event",
423		    ar->ar_arg_auditon.au_evclass.ec_number);
424		kau_write(rec, tok);
425		tok = au_to_arg32(2, "setclass:ec_class",
426		    ar->ar_arg_auditon.au_evclass.ec_class);
427		kau_write(rec, tok);
428		break;
429
430	case A_SETPMASK:
431		tok = au_to_arg32(2, "setpmask:as_success",
432		    ar->ar_arg_auditon.au_aupinfo.ap_mask.am_success);
433		kau_write(rec, tok);
434		tok = au_to_arg32(2, "setpmask:as_failure",
435		    ar->ar_arg_auditon.au_aupinfo.ap_mask.am_failure);
436		kau_write(rec, tok);
437		break;
438
439	case A_SETFSIZE:
440		tok = au_to_arg32(2, "setfsize:filesize",
441		    ar->ar_arg_auditon.au_fstat.af_filesz);
442		kau_write(rec, tok);
443		break;
444
445	default:
446		break;
447	}
448}
449
450/*
451 * Convert an internal kernel audit record to a BSM record and return a
452 * success/failure indicator. The BSM record is passed as an out parameter to
453 * this function.
454 *
455 * Return conditions:
456 *   BSM_SUCCESS: The BSM record is valid
457 *   BSM_FAILURE: Failure; the BSM record is NULL.
458 *   BSM_NOAUDIT: The event is not auditable for BSM; the BSM record is NULL.
459 */
460int
461kaudit_to_bsm(struct kaudit_record *kar, struct au_record **pau)
462{
463	struct au_token *tok, *subj_tok, *jail_tok;
464	struct au_record *rec;
465	au_tid_t tid;
466	struct audit_record *ar;
467	int ctr;
468
469	KASSERT(kar != NULL, ("kaudit_to_bsm: kar == NULL"));
470
471	*pau = NULL;
472	ar = &kar->k_ar;
473	rec = kau_open();
474
475	/*
476	 * Create the subject token.  If this credential was jailed be sure to
477	 * generate a zonename token.
478	 */
479	if (ar->ar_jailname[0] != '\0')
480		jail_tok = au_to_zonename(ar->ar_jailname);
481	else
482		jail_tok = NULL;
483	switch (ar->ar_subj_term_addr.at_type) {
484	case AU_IPv4:
485		tid.port = ar->ar_subj_term_addr.at_port;
486		tid.machine = ar->ar_subj_term_addr.at_addr[0];
487		subj_tok = au_to_subject32(ar->ar_subj_auid,  /* audit ID */
488		    ar->ar_subj_cred.cr_uid, /* eff uid */
489		    ar->ar_subj_egid,	/* eff group id */
490		    ar->ar_subj_ruid,	/* real uid */
491		    ar->ar_subj_rgid,	/* real group id */
492		    ar->ar_subj_pid,	/* process id */
493		    ar->ar_subj_asid,	/* session ID */
494		    &tid);
495		break;
496	case AU_IPv6:
497		subj_tok = au_to_subject32_ex(ar->ar_subj_auid,
498		    ar->ar_subj_cred.cr_uid,
499		    ar->ar_subj_egid,
500		    ar->ar_subj_ruid,
501		    ar->ar_subj_rgid,
502		    ar->ar_subj_pid,
503		    ar->ar_subj_asid,
504		    &ar->ar_subj_term_addr);
505		break;
506	default:
507		bzero(&tid, sizeof(tid));
508		subj_tok = au_to_subject32(ar->ar_subj_auid,
509		    ar->ar_subj_cred.cr_uid,
510		    ar->ar_subj_egid,
511		    ar->ar_subj_ruid,
512		    ar->ar_subj_rgid,
513		    ar->ar_subj_pid,
514		    ar->ar_subj_asid,
515		    &tid);
516	}
517
518	/*
519	 * The logic inside each case fills in the tokens required for the
520	 * event, except for the header, trailer, and return tokens.  The
521	 * header and trailer tokens are added by the kau_close() function.
522	 * The return token is added outside of the switch statement.
523	 */
524	switch(ar->ar_event) {
525	case AUE_ACCEPT:
526	case AUE_BIND:
527	case AUE_LISTEN:
528	case AUE_CONNECT:
529	case AUE_RECV:
530	case AUE_RECVFROM:
531	case AUE_RECVMSG:
532	case AUE_SEND:
533	case AUE_SENDFILE:
534	case AUE_SENDMSG:
535	case AUE_SENDTO:
536		/*
537		 * Socket-related events.
538		 */
539		if (ARG_IS_VALID(kar, ARG_FD)) {
540			tok = au_to_arg32(1, "fd", ar->ar_arg_fd);
541			kau_write(rec, tok);
542		}
543		if (ARG_IS_VALID(kar, ARG_SADDRINET)) {
544			tok = au_to_sock_inet((struct sockaddr_in *)
545			    &ar->ar_arg_sockaddr);
546			kau_write(rec, tok);
547		}
548		if (ARG_IS_VALID(kar, ARG_SADDRUNIX)) {
549			tok = au_to_sock_unix((struct sockaddr_un *)
550			    &ar->ar_arg_sockaddr);
551			kau_write(rec, tok);
552			UPATH1_TOKENS;
553		}
554		/* XXX Need to handle ARG_SADDRINET6 */
555		break;
556
557	case AUE_BINDAT:
558	case AUE_CONNECTAT:
559		ATFD1_TOKENS(1);
560		if (ARG_IS_VALID(kar, ARG_FD)) {
561			tok = au_to_arg32(2, "fd", ar->ar_arg_fd);
562			kau_write(rec, tok);
563		}
564		if (ARG_IS_VALID(kar, ARG_SADDRUNIX)) {
565			tok = au_to_sock_unix((struct sockaddr_un *)
566			    &ar->ar_arg_sockaddr);
567			kau_write(rec, tok);
568			UPATH1_TOKENS;
569		}
570		break;
571
572	case AUE_SOCKET:
573	case AUE_SOCKETPAIR:
574		if (ARG_IS_VALID(kar, ARG_SOCKINFO)) {
575			tok = au_to_arg32(1, "domain",
576			    ar->ar_arg_sockinfo.so_domain);
577			kau_write(rec, tok);
578			tok = au_to_arg32(2, "type",
579			    ar->ar_arg_sockinfo.so_type);
580			kau_write(rec, tok);
581			tok = au_to_arg32(3, "protocol",
582			    ar->ar_arg_sockinfo.so_protocol);
583			kau_write(rec, tok);
584		}
585		break;
586
587	case AUE_SETSOCKOPT:
588	case AUE_SHUTDOWN:
589		if (ARG_IS_VALID(kar, ARG_FD)) {
590			tok = au_to_arg32(1, "fd", ar->ar_arg_fd);
591			kau_write(rec, tok);
592		}
593		break;
594
595	case AUE_ACCT:
596		if (ARG_IS_VALID(kar, ARG_UPATH1)) {
597			UPATH1_VNODE1_TOKENS;
598		} else {
599			tok = au_to_arg32(1, "accounting off", 0);
600			kau_write(rec, tok);
601		}
602		break;
603
604	case AUE_SETAUID:
605		if (ARG_IS_VALID(kar, ARG_AUID)) {
606			tok = au_to_arg32(2, "setauid", ar->ar_arg_auid);
607			kau_write(rec, tok);
608		}
609		break;
610
611	case AUE_SETAUDIT:
612		if (ARG_IS_VALID(kar, ARG_AUID) &&
613		    ARG_IS_VALID(kar, ARG_ASID) &&
614		    ARG_IS_VALID(kar, ARG_AMASK) &&
615		    ARG_IS_VALID(kar, ARG_TERMID)) {
616			tok = au_to_arg32(1, "setaudit:auid",
617			    ar->ar_arg_auid);
618			kau_write(rec, tok);
619			tok = au_to_arg32(1, "setaudit:port",
620			    ar->ar_arg_termid.port);
621			kau_write(rec, tok);
622			tok = au_to_arg32(1, "setaudit:machine",
623			    ar->ar_arg_termid.machine);
624			kau_write(rec, tok);
625			tok = au_to_arg32(1, "setaudit:as_success",
626			    ar->ar_arg_amask.am_success);
627			kau_write(rec, tok);
628			tok = au_to_arg32(1, "setaudit:as_failure",
629			    ar->ar_arg_amask.am_failure);
630			kau_write(rec, tok);
631			tok = au_to_arg32(1, "setaudit:asid",
632			    ar->ar_arg_asid);
633			kau_write(rec, tok);
634		}
635		break;
636
637	case AUE_SETAUDIT_ADDR:
638		if (ARG_IS_VALID(kar, ARG_AUID) &&
639		    ARG_IS_VALID(kar, ARG_ASID) &&
640		    ARG_IS_VALID(kar, ARG_AMASK) &&
641		    ARG_IS_VALID(kar, ARG_TERMID_ADDR)) {
642			tok = au_to_arg32(1, "setaudit_addr:auid",
643			    ar->ar_arg_auid);
644			kau_write(rec, tok);
645			tok = au_to_arg32(1, "setaudit_addr:as_success",
646			    ar->ar_arg_amask.am_success);
647			kau_write(rec, tok);
648			tok = au_to_arg32(1, "setaudit_addr:as_failure",
649			    ar->ar_arg_amask.am_failure);
650			kau_write(rec, tok);
651			tok = au_to_arg32(1, "setaudit_addr:asid",
652			    ar->ar_arg_asid);
653			kau_write(rec, tok);
654			tok = au_to_arg32(1, "setaudit_addr:type",
655			    ar->ar_arg_termid_addr.at_type);
656			kau_write(rec, tok);
657			tok = au_to_arg32(1, "setaudit_addr:port",
658			    ar->ar_arg_termid_addr.at_port);
659			kau_write(rec, tok);
660			if (ar->ar_arg_termid_addr.at_type == AU_IPv6)
661				tok = au_to_in_addr_ex((struct in6_addr *)
662				    &ar->ar_arg_termid_addr.at_addr[0]);
663			if (ar->ar_arg_termid_addr.at_type == AU_IPv4)
664				tok = au_to_in_addr((struct in_addr *)
665				    &ar->ar_arg_termid_addr.at_addr[0]);
666			kau_write(rec, tok);
667		}
668		break;
669
670	case AUE_AUDITON:
671		/*
672		 * For AUDITON commands without own event, audit the cmd.
673		 */
674		if (ARG_IS_VALID(kar, ARG_CMD)) {
675			tok = au_to_arg32(1, "cmd", ar->ar_arg_cmd);
676			kau_write(rec, tok);
677		}
678		/* FALLTHROUGH */
679
680	case AUE_AUDITON_GETCAR:
681	case AUE_AUDITON_GETCLASS:
682	case AUE_AUDITON_GETCOND:
683	case AUE_AUDITON_GETCWD:
684	case AUE_AUDITON_GETKMASK:
685	case AUE_AUDITON_GETSTAT:
686	case AUE_AUDITON_GPOLICY:
687	case AUE_AUDITON_GQCTRL:
688	case AUE_AUDITON_SETCLASS:
689	case AUE_AUDITON_SETCOND:
690	case AUE_AUDITON_SETKMASK:
691	case AUE_AUDITON_SETSMASK:
692	case AUE_AUDITON_SETSTAT:
693	case AUE_AUDITON_SETUMASK:
694	case AUE_AUDITON_SPOLICY:
695	case AUE_AUDITON_SQCTRL:
696		if (ARG_IS_VALID(kar, ARG_AUDITON))
697			audit_sys_auditon(ar, rec);
698		break;
699
700	case AUE_AUDITCTL:
701		UPATH1_VNODE1_TOKENS;
702		break;
703
704	case AUE_EXIT:
705		if (ARG_IS_VALID(kar, ARG_EXIT)) {
706			tok = au_to_exit(ar->ar_arg_exitretval,
707			    ar->ar_arg_exitstatus);
708			kau_write(rec, tok);
709		}
710		break;
711
712	case AUE_ADJTIME:
713	case AUE_CLOCK_SETTIME:
714	case AUE_AUDIT:
715	case AUE_DUP2:
716	case AUE_GETAUDIT:
717	case AUE_GETAUDIT_ADDR:
718	case AUE_GETAUID:
719	case AUE_GETCWD:
720	case AUE_GETFSSTAT:
721	case AUE_GETRESUID:
722	case AUE_GETRESGID:
723	case AUE_KQUEUE:
724	case AUE_MODLOAD:
725	case AUE_MODUNLOAD:
726	case AUE_MSGSYS:
727	case AUE_NTP_ADJTIME:
728	case AUE_PIPE:
729	case AUE_POSIX_OPENPT:
730	case AUE_PROFILE:
731	case AUE_RTPRIO:
732	case AUE_SEMSYS:
733	case AUE_SHMSYS:
734	case AUE_SETPGRP:
735	case AUE_SETRLIMIT:
736	case AUE_SETSID:
737	case AUE_SETTIMEOFDAY:
738	case AUE_SYSARCH:
739
740		/*
741		 * Header, subject, and return tokens added at end.
742		 */
743		break;
744
745	case AUE_CHDIR:
746	case AUE_CHROOT:
747	case AUE_FSTATAT:
748	case AUE_FUTIMESAT:
749	case AUE_GETATTRLIST:
750	case AUE_JAIL:
751	case AUE_LUTIMES:
752	case AUE_NFS_GETFH:
753	case AUE_LSTAT:
754	case AUE_LPATHCONF:
755	case AUE_PATHCONF:
756	case AUE_READLINK:
757	case AUE_READLINKAT:
758	case AUE_REVOKE:
759	case AUE_RMDIR:
760	case AUE_SEARCHFS:
761	case AUE_SETATTRLIST:
762	case AUE_STAT:
763	case AUE_STATFS:
764	case AUE_SWAPON:
765	case AUE_SWAPOFF:
766	case AUE_TRUNCATE:
767	case AUE_UNDELETE:
768	case AUE_UNLINK:
769	case AUE_UNLINKAT:
770	case AUE_UTIMES:
771		ATFD1_TOKENS(1);
772		UPATH1_VNODE1_TOKENS;
773		break;
774
775	case AUE_ACCESS:
776	case AUE_EACCESS:
777	case AUE_FACCESSAT:
778		ATFD1_TOKENS(1);
779		UPATH1_VNODE1_TOKENS;
780		if (ARG_IS_VALID(kar, ARG_VALUE)) {
781			tok = au_to_arg32(2, "mode", ar->ar_arg_value);
782			kau_write(rec, tok);
783		}
784		break;
785
786	case AUE_FHSTATFS:
787	case AUE_FHOPEN:
788	case AUE_FHSTAT:
789		/* XXXRW: Need to audit vnode argument. */
790		break;
791
792	case AUE_CHFLAGS:
793	case AUE_LCHFLAGS:
794		if (ARG_IS_VALID(kar, ARG_FFLAGS)) {
795			tok = au_to_arg32(2, "flags", ar->ar_arg_fflags);
796			kau_write(rec, tok);
797		}
798		UPATH1_VNODE1_TOKENS;
799		break;
800
801	case AUE_CHMOD:
802	case AUE_LCHMOD:
803		if (ARG_IS_VALID(kar, ARG_MODE)) {
804			tok = au_to_arg32(2, "new file mode",
805			    ar->ar_arg_mode);
806			kau_write(rec, tok);
807		}
808		UPATH1_VNODE1_TOKENS;
809		break;
810
811	case AUE_FCHMODAT:
812		ATFD1_TOKENS(1);
813		if (ARG_IS_VALID(kar, ARG_MODE)) {
814			tok = au_to_arg32(3, "new file mode",
815			    ar->ar_arg_mode);
816			kau_write(rec, tok);
817		}
818		UPATH1_VNODE1_TOKENS;
819		break;
820
821	case AUE_CHOWN:
822	case AUE_LCHOWN:
823		if (ARG_IS_VALID(kar, ARG_UID)) {
824			tok = au_to_arg32(2, "new file uid", ar->ar_arg_uid);
825			kau_write(rec, tok);
826		}
827		if (ARG_IS_VALID(kar, ARG_GID)) {
828			tok = au_to_arg32(3, "new file gid", ar->ar_arg_gid);
829			kau_write(rec, tok);
830		}
831		UPATH1_VNODE1_TOKENS;
832		break;
833
834	case AUE_FCHOWNAT:
835		ATFD1_TOKENS(1);
836		if (ARG_IS_VALID(kar, ARG_UID)) {
837			tok = au_to_arg32(3, "new file uid", ar->ar_arg_uid);
838			kau_write(rec, tok);
839		}
840		if (ARG_IS_VALID(kar, ARG_GID)) {
841			tok = au_to_arg32(4, "new file gid", ar->ar_arg_gid);
842			kau_write(rec, tok);
843		}
844		UPATH1_VNODE1_TOKENS;
845		break;
846
847	case AUE_EXCHANGEDATA:
848		UPATH1_VNODE1_TOKENS;
849		UPATH2_TOKENS;
850		break;
851
852	case AUE_CLOSE:
853		if (ARG_IS_VALID(kar, ARG_FD)) {
854			tok = au_to_arg32(1, "fd", ar->ar_arg_fd);
855			kau_write(rec, tok);
856		}
857		UPATH1_VNODE1_TOKENS;
858		break;
859
860	case AUE_CLOSEFROM:
861		if (ARG_IS_VALID(kar, ARG_FD)) {
862			tok = au_to_arg32(1, "fd", ar->ar_arg_fd);
863			kau_write(rec, tok);
864		}
865		break;
866
867	case AUE_CORE:
868		if (ARG_IS_VALID(kar, ARG_SIGNUM)) {
869			tok = au_to_arg32(1, "signal", ar->ar_arg_signum);
870			kau_write(rec, tok);
871		}
872		UPATH1_VNODE1_TOKENS;
873		break;
874
875	case AUE_EXTATTRCTL:
876		UPATH1_VNODE1_TOKENS;
877		if (ARG_IS_VALID(kar, ARG_CMD)) {
878			tok = au_to_arg32(2, "cmd", ar->ar_arg_cmd);
879			kau_write(rec, tok);
880		}
881		/* extattrctl(2) filename parameter is in upath2/vnode2 */
882		UPATH2_TOKENS;
883		VNODE2_TOKENS;
884		EXTATTR_TOKENS(4);
885		break;
886
887	case AUE_EXTATTR_GET_FILE:
888	case AUE_EXTATTR_SET_FILE:
889	case AUE_EXTATTR_LIST_FILE:
890	case AUE_EXTATTR_DELETE_FILE:
891	case AUE_EXTATTR_GET_LINK:
892	case AUE_EXTATTR_SET_LINK:
893	case AUE_EXTATTR_LIST_LINK:
894	case AUE_EXTATTR_DELETE_LINK:
895		UPATH1_VNODE1_TOKENS;
896		EXTATTR_TOKENS(2);
897		break;
898
899	case AUE_EXTATTR_GET_FD:
900	case AUE_EXTATTR_SET_FD:
901	case AUE_EXTATTR_LIST_FD:
902	case AUE_EXTATTR_DELETE_FD:
903		if (ARG_IS_VALID(kar, ARG_FD)) {
904			tok = au_to_arg32(2, "fd", ar->ar_arg_fd);
905			kau_write(rec, tok);
906		}
907		EXTATTR_TOKENS(2);
908		break;
909
910	case AUE_FEXECVE:
911		if (ARG_IS_VALID(kar, ARG_FD)) {
912			tok = au_to_arg32(1, "fd", ar->ar_arg_fd);
913			kau_write(rec, tok);
914		}
915		/* FALLTHROUGH */
916
917	case AUE_EXECVE:
918	case AUE_MAC_EXECVE:
919		if (ARG_IS_VALID(kar, ARG_ARGV)) {
920			tok = au_to_exec_args(ar->ar_arg_argv,
921			    ar->ar_arg_argc);
922			kau_write(rec, tok);
923		}
924		if (ARG_IS_VALID(kar, ARG_ENVV)) {
925			tok = au_to_exec_env(ar->ar_arg_envv,
926			    ar->ar_arg_envc);
927			kau_write(rec, tok);
928		}
929		UPATH1_VNODE1_TOKENS;
930		break;
931
932	case AUE_FCHMOD:
933		if (ARG_IS_VALID(kar, ARG_MODE)) {
934			tok = au_to_arg32(2, "new file mode",
935			    ar->ar_arg_mode);
936			kau_write(rec, tok);
937		}
938		FD_VNODE1_TOKENS;
939		break;
940
941	/*
942	 * XXXRW: Some of these need to handle non-vnode cases as well.
943	 */
944	case AUE_FCHDIR:
945	case AUE_FPATHCONF:
946	case AUE_FSTAT:
947	case AUE_FSTATFS:
948	case AUE_FSYNC:
949	case AUE_FTRUNCATE:
950	case AUE_FUTIMES:
951	case AUE_GETDIRENTRIES:
952	case AUE_GETDIRENTRIESATTR:
953	case AUE_LSEEK:
954	case AUE_POLL:
955	case AUE_PREAD:
956	case AUE_PWRITE:
957	case AUE_READ:
958	case AUE_READV:
959	case AUE_WRITE:
960	case AUE_WRITEV:
961		FD_VNODE1_TOKENS;
962		break;
963
964	case AUE_FCHOWN:
965		if (ARG_IS_VALID(kar, ARG_UID)) {
966			tok = au_to_arg32(2, "new file uid", ar->ar_arg_uid);
967			kau_write(rec, tok);
968		}
969		if (ARG_IS_VALID(kar, ARG_GID)) {
970			tok = au_to_arg32(3, "new file gid", ar->ar_arg_gid);
971			kau_write(rec, tok);
972		}
973		FD_VNODE1_TOKENS;
974		break;
975
976	case AUE_FCNTL:
977		if (ARG_IS_VALID(kar, ARG_CMD)) {
978			tok = au_to_arg32(2, "cmd",
979			    au_fcntl_cmd_to_bsm(ar->ar_arg_cmd));
980			kau_write(rec, tok);
981		}
982		if (ar->ar_arg_cmd == F_GETLK || ar->ar_arg_cmd == F_SETLK ||
983		    ar->ar_arg_cmd == F_SETLKW) {
984			FD_VNODE1_TOKENS;
985		}
986		break;
987
988	case AUE_FCHFLAGS:
989		if (ARG_IS_VALID(kar, ARG_FFLAGS)) {
990			tok = au_to_arg32(2, "flags", ar->ar_arg_fflags);
991			kau_write(rec, tok);
992		}
993		FD_VNODE1_TOKENS;
994		break;
995
996	case AUE_FLOCK:
997		if (ARG_IS_VALID(kar, ARG_CMD)) {
998			tok = au_to_arg32(2, "operation", ar->ar_arg_cmd);
999			kau_write(rec, tok);
1000		}
1001		FD_VNODE1_TOKENS;
1002		break;
1003
1004	case AUE_RFORK:
1005		if (ARG_IS_VALID(kar, ARG_FFLAGS)) {
1006			tok = au_to_arg32(1, "flags", ar->ar_arg_fflags);
1007			kau_write(rec, tok);
1008		}
1009		/* FALLTHROUGH */
1010
1011	case AUE_FORK:
1012	case AUE_VFORK:
1013		if (ARG_IS_VALID(kar, ARG_PID)) {
1014			tok = au_to_arg32(0, "child PID", ar->ar_arg_pid);
1015			kau_write(rec, tok);
1016		}
1017		break;
1018
1019	case AUE_IOCTL:
1020		if (ARG_IS_VALID(kar, ARG_CMD)) {
1021			tok = au_to_arg32(2, "cmd", ar->ar_arg_cmd);
1022			kau_write(rec, tok);
1023		}
1024		if (ARG_IS_VALID(kar, ARG_VNODE1))
1025			FD_VNODE1_TOKENS;
1026		else {
1027			if (ARG_IS_VALID(kar, ARG_SOCKINFO)) {
1028				tok = kau_to_socket(&ar->ar_arg_sockinfo);
1029				kau_write(rec, tok);
1030			} else {
1031				if (ARG_IS_VALID(kar, ARG_FD)) {
1032					tok = au_to_arg32(1, "fd",
1033					    ar->ar_arg_fd);
1034					kau_write(rec, tok);
1035				}
1036			}
1037		}
1038		break;
1039
1040	case AUE_KILL:
1041	case AUE_KILLPG:
1042		if (ARG_IS_VALID(kar, ARG_SIGNUM)) {
1043			tok = au_to_arg32(2, "signal", ar->ar_arg_signum);
1044			kau_write(rec, tok);
1045		}
1046		PROCESS_PID_TOKENS(1);
1047		break;
1048
1049	case AUE_KTRACE:
1050		if (ARG_IS_VALID(kar, ARG_CMD)) {
1051			tok = au_to_arg32(2, "ops", ar->ar_arg_cmd);
1052			kau_write(rec, tok);
1053		}
1054		if (ARG_IS_VALID(kar, ARG_VALUE)) {
1055			tok = au_to_arg32(3, "trpoints", ar->ar_arg_value);
1056			kau_write(rec, tok);
1057		}
1058		PROCESS_PID_TOKENS(4);
1059		UPATH1_VNODE1_TOKENS;
1060		break;
1061
1062	case AUE_LINK:
1063	case AUE_LINKAT:
1064	case AUE_RENAME:
1065	case AUE_RENAMEAT:
1066		ATFD1_TOKENS(1);
1067		UPATH1_VNODE1_TOKENS;
1068		ATFD2_TOKENS(3);
1069		UPATH2_TOKENS;
1070		break;
1071
1072	case AUE_LOADSHFILE:
1073		ADDR_TOKEN(4, "base addr");
1074		UPATH1_VNODE1_TOKENS;
1075		break;
1076
1077	case AUE_MKDIR:
1078	case AUE_MKDIRAT:
1079	case AUE_MKFIFO:
1080	case AUE_MKFIFOAT:
1081		ATFD1_TOKENS(1);
1082		if (ARG_IS_VALID(kar, ARG_MODE)) {
1083			tok = au_to_arg32(2, "mode", ar->ar_arg_mode);
1084			kau_write(rec, tok);
1085		}
1086		UPATH1_VNODE1_TOKENS;
1087		break;
1088
1089	case AUE_MKNOD:
1090	case AUE_MKNODAT:
1091		ATFD1_TOKENS(1);
1092		if (ARG_IS_VALID(kar, ARG_MODE)) {
1093			tok = au_to_arg32(2, "mode", ar->ar_arg_mode);
1094			kau_write(rec, tok);
1095		}
1096		if (ARG_IS_VALID(kar, ARG_DEV)) {
1097			tok = au_to_arg32(3, "dev", ar->ar_arg_dev);
1098			kau_write(rec, tok);
1099		}
1100		UPATH1_VNODE1_TOKENS;
1101		break;
1102
1103	case AUE_MMAP:
1104	case AUE_MUNMAP:
1105	case AUE_MPROTECT:
1106	case AUE_MLOCK:
1107	case AUE_MUNLOCK:
1108	case AUE_MINHERIT:
1109		ADDR_TOKEN(1, "addr");
1110		if (ARG_IS_VALID(kar, ARG_LEN)) {
1111			tok = au_to_arg32(2, "len", ar->ar_arg_len);
1112			kau_write(rec, tok);
1113		}
1114		if (ar->ar_event == AUE_MMAP)
1115			FD_VNODE1_TOKENS;
1116		if (ar->ar_event == AUE_MPROTECT) {
1117			if (ARG_IS_VALID(kar, ARG_VALUE)) {
1118				tok = au_to_arg32(3, "protection",
1119				    ar->ar_arg_value);
1120				kau_write(rec, tok);
1121			}
1122		}
1123		if (ar->ar_event == AUE_MINHERIT) {
1124			if (ARG_IS_VALID(kar, ARG_VALUE)) {
1125				tok = au_to_arg32(3, "inherit",
1126				    ar->ar_arg_value);
1127				kau_write(rec, tok);
1128			}
1129		}
1130		break;
1131
1132	case AUE_MOUNT:
1133	case AUE_NMOUNT:
1134		/* XXX Need to handle NFS mounts */
1135		if (ARG_IS_VALID(kar, ARG_FFLAGS)) {
1136			tok = au_to_arg32(3, "flags", ar->ar_arg_fflags);
1137			kau_write(rec, tok);
1138		}
1139		if (ARG_IS_VALID(kar, ARG_TEXT)) {
1140			tok = au_to_text(ar->ar_arg_text);
1141			kau_write(rec, tok);
1142		}
1143		/* FALLTHROUGH */
1144
1145	case AUE_NFS_SVC:
1146		if (ARG_IS_VALID(kar, ARG_CMD)) {
1147			tok = au_to_arg32(1, "flags", ar->ar_arg_cmd);
1148			kau_write(rec, tok);
1149		}
1150		break;
1151
1152	case AUE_UMOUNT:
1153		if (ARG_IS_VALID(kar, ARG_VALUE)) {
1154			tok = au_to_arg32(2, "flags", ar->ar_arg_value);
1155			kau_write(rec, tok);
1156		}
1157		UPATH1_VNODE1_TOKENS;
1158		if (ARG_IS_VALID(kar, ARG_TEXT)) {
1159			tok = au_to_text(ar->ar_arg_text);
1160			kau_write(rec, tok);
1161		}
1162		break;
1163
1164	case AUE_MSGCTL:
1165		ar->ar_event = audit_msgctl_to_event(ar->ar_arg_svipc_cmd);
1166		/* Fall through */
1167
1168	case AUE_MSGRCV:
1169	case AUE_MSGSND:
1170		tok = au_to_arg32(1, "msg ID", ar->ar_arg_svipc_id);
1171		kau_write(rec, tok);
1172		if (ar->ar_errno != EINVAL) {
1173			tok = au_to_ipc(AT_IPC_MSG, ar->ar_arg_svipc_id);
1174			kau_write(rec, tok);
1175		}
1176		break;
1177
1178	case AUE_MSGGET:
1179		if (ar->ar_errno == 0) {
1180			if (ARG_IS_VALID(kar, ARG_SVIPC_ID)) {
1181				tok = au_to_ipc(AT_IPC_MSG,
1182				    ar->ar_arg_svipc_id);
1183				kau_write(rec, tok);
1184			}
1185		}
1186		break;
1187
1188	case AUE_RESETSHFILE:
1189		ADDR_TOKEN(1, "base addr");
1190		break;
1191
1192	case AUE_OPEN_RC:
1193	case AUE_OPEN_RTC:
1194	case AUE_OPEN_RWC:
1195	case AUE_OPEN_RWTC:
1196	case AUE_OPEN_WC:
1197	case AUE_OPEN_WTC:
1198	case AUE_CREAT:
1199		if (ARG_IS_VALID(kar, ARG_MODE)) {
1200			tok = au_to_arg32(3, "mode", ar->ar_arg_mode);
1201			kau_write(rec, tok);
1202		}
1203		/* FALLTHROUGH */
1204
1205	case AUE_OPEN_R:
1206	case AUE_OPEN_RT:
1207	case AUE_OPEN_RW:
1208	case AUE_OPEN_RWT:
1209	case AUE_OPEN_W:
1210	case AUE_OPEN_WT:
1211		if (ARG_IS_VALID(kar, ARG_FFLAGS)) {
1212			tok = au_to_arg32(2, "flags", ar->ar_arg_fflags);
1213			kau_write(rec, tok);
1214		}
1215		UPATH1_VNODE1_TOKENS;
1216		break;
1217
1218	case AUE_OPENAT_RC:
1219	case AUE_OPENAT_RTC:
1220	case AUE_OPENAT_RWC:
1221	case AUE_OPENAT_RWTC:
1222	case AUE_OPENAT_WC:
1223	case AUE_OPENAT_WTC:
1224		if (ARG_IS_VALID(kar, ARG_MODE)) {
1225			tok = au_to_arg32(3, "mode", ar->ar_arg_mode);
1226			kau_write(rec, tok);
1227		}
1228		/* FALLTHROUGH */
1229
1230	case AUE_OPENAT_R:
1231	case AUE_OPENAT_RT:
1232	case AUE_OPENAT_RW:
1233	case AUE_OPENAT_RWT:
1234	case AUE_OPENAT_W:
1235	case AUE_OPENAT_WT:
1236		if (ARG_IS_VALID(kar, ARG_FFLAGS)) {
1237			tok = au_to_arg32(2, "flags", ar->ar_arg_fflags);
1238			kau_write(rec, tok);
1239		}
1240		ATFD1_TOKENS(1);
1241		UPATH1_VNODE1_TOKENS;
1242		break;
1243
1244	case AUE_PTRACE:
1245		if (ARG_IS_VALID(kar, ARG_CMD)) {
1246			tok = au_to_arg32(1, "request", ar->ar_arg_cmd);
1247			kau_write(rec, tok);
1248		}
1249		if (ARG_IS_VALID(kar, ARG_VALUE)) {
1250			tok = au_to_arg32(4, "data", ar->ar_arg_value);
1251			kau_write(rec, tok);
1252		}
1253		PROCESS_PID_TOKENS(2);
1254		break;
1255
1256	case AUE_QUOTACTL:
1257		if (ARG_IS_VALID(kar, ARG_CMD)) {
1258			tok = au_to_arg32(2, "command", ar->ar_arg_cmd);
1259			kau_write(rec, tok);
1260		}
1261		if (ARG_IS_VALID(kar, ARG_UID)) {
1262			tok = au_to_arg32(3, "uid", ar->ar_arg_uid);
1263			kau_write(rec, tok);
1264		}
1265		if (ARG_IS_VALID(kar, ARG_GID)) {
1266			tok = au_to_arg32(3, "gid", ar->ar_arg_gid);
1267			kau_write(rec, tok);
1268		}
1269		UPATH1_VNODE1_TOKENS;
1270		break;
1271
1272	case AUE_REBOOT:
1273		if (ARG_IS_VALID(kar, ARG_CMD)) {
1274			tok = au_to_arg32(1, "howto", ar->ar_arg_cmd);
1275			kau_write(rec, tok);
1276		}
1277		break;
1278
1279	case AUE_SEMCTL:
1280		ar->ar_event = audit_semctl_to_event(ar->ar_arg_svipc_cmd);
1281		/* Fall through */
1282
1283	case AUE_SEMOP:
1284		if (ARG_IS_VALID(kar, ARG_SVIPC_ID)) {
1285			tok = au_to_arg32(1, "sem ID", ar->ar_arg_svipc_id);
1286			kau_write(rec, tok);
1287			if (ar->ar_errno != EINVAL) {
1288				tok = au_to_ipc(AT_IPC_SEM,
1289				    ar->ar_arg_svipc_id);
1290				kau_write(rec, tok);
1291			}
1292		}
1293		break;
1294
1295	case AUE_SEMGET:
1296		if (ar->ar_errno == 0) {
1297			if (ARG_IS_VALID(kar, ARG_SVIPC_ID)) {
1298				tok = au_to_ipc(AT_IPC_SEM,
1299				    ar->ar_arg_svipc_id);
1300				kau_write(rec, tok);
1301			}
1302		}
1303		break;
1304
1305	case AUE_SETEGID:
1306		if (ARG_IS_VALID(kar, ARG_EGID)) {
1307			tok = au_to_arg32(1, "egid", ar->ar_arg_egid);
1308			kau_write(rec, tok);
1309		}
1310		break;
1311
1312	case AUE_SETEUID:
1313		if (ARG_IS_VALID(kar, ARG_EUID)) {
1314			tok = au_to_arg32(1, "euid", ar->ar_arg_euid);
1315			kau_write(rec, tok);
1316		}
1317		break;
1318
1319	case AUE_SETREGID:
1320		if (ARG_IS_VALID(kar, ARG_RGID)) {
1321			tok = au_to_arg32(1, "rgid", ar->ar_arg_rgid);
1322			kau_write(rec, tok);
1323		}
1324		if (ARG_IS_VALID(kar, ARG_EGID)) {
1325			tok = au_to_arg32(2, "egid", ar->ar_arg_egid);
1326			kau_write(rec, tok);
1327		}
1328		break;
1329
1330	case AUE_SETREUID:
1331		if (ARG_IS_VALID(kar, ARG_RUID)) {
1332			tok = au_to_arg32(1, "ruid", ar->ar_arg_ruid);
1333			kau_write(rec, tok);
1334		}
1335		if (ARG_IS_VALID(kar, ARG_EUID)) {
1336			tok = au_to_arg32(2, "euid", ar->ar_arg_euid);
1337			kau_write(rec, tok);
1338		}
1339		break;
1340
1341	case AUE_SETRESGID:
1342		if (ARG_IS_VALID(kar, ARG_RGID)) {
1343			tok = au_to_arg32(1, "rgid", ar->ar_arg_rgid);
1344			kau_write(rec, tok);
1345		}
1346		if (ARG_IS_VALID(kar, ARG_EGID)) {
1347			tok = au_to_arg32(2, "egid", ar->ar_arg_egid);
1348			kau_write(rec, tok);
1349		}
1350		if (ARG_IS_VALID(kar, ARG_SGID)) {
1351			tok = au_to_arg32(3, "sgid", ar->ar_arg_sgid);
1352			kau_write(rec, tok);
1353		}
1354		break;
1355
1356	case AUE_SETRESUID:
1357		if (ARG_IS_VALID(kar, ARG_RUID)) {
1358			tok = au_to_arg32(1, "ruid", ar->ar_arg_ruid);
1359			kau_write(rec, tok);
1360		}
1361		if (ARG_IS_VALID(kar, ARG_EUID)) {
1362			tok = au_to_arg32(2, "euid", ar->ar_arg_euid);
1363			kau_write(rec, tok);
1364		}
1365		if (ARG_IS_VALID(kar, ARG_SUID)) {
1366			tok = au_to_arg32(3, "suid", ar->ar_arg_suid);
1367			kau_write(rec, tok);
1368		}
1369		break;
1370
1371	case AUE_SETGID:
1372		if (ARG_IS_VALID(kar, ARG_GID)) {
1373			tok = au_to_arg32(1, "gid", ar->ar_arg_gid);
1374			kau_write(rec, tok);
1375		}
1376		break;
1377
1378	case AUE_SETUID:
1379		if (ARG_IS_VALID(kar, ARG_UID)) {
1380			tok = au_to_arg32(1, "uid", ar->ar_arg_uid);
1381			kau_write(rec, tok);
1382		}
1383		break;
1384
1385	case AUE_SETGROUPS:
1386		if (ARG_IS_VALID(kar, ARG_GROUPSET)) {
1387			for(ctr = 0; ctr < ar->ar_arg_groups.gidset_size; ctr++)
1388			{
1389				tok = au_to_arg32(1, "setgroups",
1390				    ar->ar_arg_groups.gidset[ctr]);
1391				kau_write(rec, tok);
1392			}
1393		}
1394		break;
1395
1396	case AUE_SETLOGIN:
1397		if (ARG_IS_VALID(kar, ARG_TEXT)) {
1398			tok = au_to_text(ar->ar_arg_text);
1399			kau_write(rec, tok);
1400		}
1401		break;
1402
1403	case AUE_SETPRIORITY:
1404		if (ARG_IS_VALID(kar, ARG_CMD)) {
1405			tok = au_to_arg32(1, "which", ar->ar_arg_cmd);
1406			kau_write(rec, tok);
1407		}
1408		if (ARG_IS_VALID(kar, ARG_UID)) {
1409			tok = au_to_arg32(2, "who", ar->ar_arg_uid);
1410			kau_write(rec, tok);
1411		}
1412		PROCESS_PID_TOKENS(2);
1413		if (ARG_IS_VALID(kar, ARG_VALUE)) {
1414			tok = au_to_arg32(3, "priority", ar->ar_arg_value);
1415			kau_write(rec, tok);
1416		}
1417		break;
1418
1419	case AUE_SETPRIVEXEC:
1420		if (ARG_IS_VALID(kar, ARG_VALUE)) {
1421			tok = au_to_arg32(1, "flag", ar->ar_arg_value);
1422			kau_write(rec, tok);
1423		}
1424		break;
1425
1426	/* AUE_SHMAT, AUE_SHMCTL, AUE_SHMDT and AUE_SHMGET are SysV IPC */
1427	case AUE_SHMAT:
1428		if (ARG_IS_VALID(kar, ARG_SVIPC_ID)) {
1429			tok = au_to_arg32(1, "shmid", ar->ar_arg_svipc_id);
1430			kau_write(rec, tok);
1431			/* XXXAUDIT: Does having the ipc token make sense? */
1432			tok = au_to_ipc(AT_IPC_SHM, ar->ar_arg_svipc_id);
1433			kau_write(rec, tok);
1434		}
1435		if (ARG_IS_VALID(kar, ARG_SVIPC_ADDR)) {
1436			tok = au_to_arg32(2, "shmaddr",
1437			    (int)(uintptr_t)ar->ar_arg_svipc_addr);
1438			kau_write(rec, tok);
1439		}
1440		if (ARG_IS_VALID(kar, ARG_SVIPC_PERM)) {
1441			tok = au_to_ipc_perm(&ar->ar_arg_svipc_perm);
1442			kau_write(rec, tok);
1443		}
1444		break;
1445
1446	case AUE_SHMCTL:
1447		if (ARG_IS_VALID(kar, ARG_SVIPC_ID)) {
1448			tok = au_to_arg32(1, "shmid", ar->ar_arg_svipc_id);
1449			kau_write(rec, tok);
1450			/* XXXAUDIT: Does having the ipc token make sense? */
1451			tok = au_to_ipc(AT_IPC_SHM, ar->ar_arg_svipc_id);
1452			kau_write(rec, tok);
1453		}
1454		switch (ar->ar_arg_svipc_cmd) {
1455		case IPC_STAT:
1456			ar->ar_event = AUE_SHMCTL_STAT;
1457			break;
1458		case IPC_RMID:
1459			ar->ar_event = AUE_SHMCTL_RMID;
1460			break;
1461		case IPC_SET:
1462			ar->ar_event = AUE_SHMCTL_SET;
1463			if (ARG_IS_VALID(kar, ARG_SVIPC_PERM)) {
1464				tok = au_to_ipc_perm(&ar->ar_arg_svipc_perm);
1465				kau_write(rec, tok);
1466			}
1467			break;
1468		default:
1469			break;	/* We will audit a bad command */
1470		}
1471		break;
1472
1473	case AUE_SHMDT:
1474		if (ARG_IS_VALID(kar, ARG_SVIPC_ADDR)) {
1475			tok = au_to_arg32(1, "shmaddr",
1476			    (int)(uintptr_t)ar->ar_arg_svipc_addr);
1477			kau_write(rec, tok);
1478		}
1479		break;
1480
1481	case AUE_SHMGET:
1482		/* This is unusual; the return value is in an argument token */
1483		if (ARG_IS_VALID(kar, ARG_SVIPC_ID)) {
1484			tok = au_to_arg32(0, "shmid", ar->ar_arg_svipc_id);
1485			kau_write(rec, tok);
1486			tok = au_to_ipc(AT_IPC_SHM, ar->ar_arg_svipc_id);
1487			kau_write(rec, tok);
1488		}
1489		if (ARG_IS_VALID(kar, ARG_SVIPC_PERM)) {
1490			tok = au_to_ipc_perm(&ar->ar_arg_svipc_perm);
1491			kau_write(rec, tok);
1492		}
1493		break;
1494
1495	/* AUE_SHMOPEN, AUE_SHMUNLINK, AUE_SEMOPEN, AUE_SEMCLOSE
1496	 * and AUE_SEMUNLINK are Posix IPC */
1497	case AUE_SHMOPEN:
1498		if (ARG_IS_VALID(kar, ARG_SVIPC_ADDR)) {
1499			tok = au_to_arg32(2, "flags", ar->ar_arg_fflags);
1500			kau_write(rec, tok);
1501		}
1502		if (ARG_IS_VALID(kar, ARG_MODE)) {
1503			tok = au_to_arg32(3, "mode", ar->ar_arg_mode);
1504			kau_write(rec, tok);
1505		}
1506		/* FALLTHROUGH */
1507
1508	case AUE_SHMUNLINK:
1509		if (ARG_IS_VALID(kar, ARG_TEXT)) {
1510			tok = au_to_text(ar->ar_arg_text);
1511			kau_write(rec, tok);
1512		}
1513		if (ARG_IS_VALID(kar, ARG_POSIX_IPC_PERM)) {
1514			struct ipc_perm perm;
1515
1516			perm.uid = ar->ar_arg_pipc_perm.pipc_uid;
1517			perm.gid = ar->ar_arg_pipc_perm.pipc_gid;
1518			perm.cuid = ar->ar_arg_pipc_perm.pipc_uid;
1519			perm.cgid = ar->ar_arg_pipc_perm.pipc_gid;
1520			perm.mode = ar->ar_arg_pipc_perm.pipc_mode;
1521			perm.seq = 0;
1522			perm.key = 0;
1523			tok = au_to_ipc_perm(&perm);
1524			kau_write(rec, tok);
1525		}
1526		break;
1527
1528	case AUE_SEMOPEN:
1529		if (ARG_IS_VALID(kar, ARG_FFLAGS)) {
1530			tok = au_to_arg32(2, "flags", ar->ar_arg_fflags);
1531			kau_write(rec, tok);
1532		}
1533		if (ARG_IS_VALID(kar, ARG_MODE)) {
1534			tok = au_to_arg32(3, "mode", ar->ar_arg_mode);
1535			kau_write(rec, tok);
1536		}
1537		if (ARG_IS_VALID(kar, ARG_VALUE)) {
1538			tok = au_to_arg32(4, "value", ar->ar_arg_value);
1539			kau_write(rec, tok);
1540		}
1541		/* FALLTHROUGH */
1542
1543	case AUE_SEMUNLINK:
1544		if (ARG_IS_VALID(kar, ARG_TEXT)) {
1545			tok = au_to_text(ar->ar_arg_text);
1546			kau_write(rec, tok);
1547		}
1548		if (ARG_IS_VALID(kar, ARG_POSIX_IPC_PERM)) {
1549			struct ipc_perm perm;
1550
1551			perm.uid = ar->ar_arg_pipc_perm.pipc_uid;
1552			perm.gid = ar->ar_arg_pipc_perm.pipc_gid;
1553			perm.cuid = ar->ar_arg_pipc_perm.pipc_uid;
1554			perm.cgid = ar->ar_arg_pipc_perm.pipc_gid;
1555			perm.mode = ar->ar_arg_pipc_perm.pipc_mode;
1556			perm.seq = 0;
1557			perm.key = 0;
1558			tok = au_to_ipc_perm(&perm);
1559			kau_write(rec, tok);
1560		}
1561		break;
1562
1563	case AUE_SEMCLOSE:
1564		if (ARG_IS_VALID(kar, ARG_FD)) {
1565			tok = au_to_arg32(1, "sem", ar->ar_arg_fd);
1566			kau_write(rec, tok);
1567		}
1568		break;
1569
1570	case AUE_SYMLINK:
1571	case AUE_SYMLINKAT:
1572		if (ARG_IS_VALID(kar, ARG_TEXT)) {
1573			tok = au_to_text(ar->ar_arg_text);
1574			kau_write(rec, tok);
1575		}
1576		ATFD1_TOKENS(1);
1577		UPATH1_VNODE1_TOKENS;
1578		break;
1579
1580	case AUE_SYSCTL:
1581	case AUE_SYSCTL_NONADMIN:
1582		if (ARG_IS_VALID(kar, ARG_CTLNAME | ARG_LEN)) {
1583			for (ctr = 0; ctr < ar->ar_arg_len; ctr++) {
1584				tok = au_to_arg32(1, "name",
1585				    ar->ar_arg_ctlname[ctr]);
1586				kau_write(rec, tok);
1587			}
1588		}
1589		if (ARG_IS_VALID(kar, ARG_VALUE)) {
1590			tok = au_to_arg32(5, "newval", ar->ar_arg_value);
1591			kau_write(rec, tok);
1592		}
1593		if (ARG_IS_VALID(kar, ARG_TEXT)) {
1594			tok = au_to_text(ar->ar_arg_text);
1595			kau_write(rec, tok);
1596		}
1597		break;
1598
1599	case AUE_UMASK:
1600		if (ARG_IS_VALID(kar, ARG_MASK)) {
1601			tok = au_to_arg32(1, "new mask", ar->ar_arg_mask);
1602			kau_write(rec, tok);
1603		}
1604		tok = au_to_arg32(0, "prev mask", ar->ar_retval);
1605		kau_write(rec, tok);
1606		break;
1607
1608	case AUE_WAIT4:
1609		PROCESS_PID_TOKENS(1);
1610		if (ARG_IS_VALID(kar, ARG_VALUE)) {
1611			tok = au_to_arg32(3, "options", ar->ar_arg_value);
1612			kau_write(rec, tok);
1613		}
1614		break;
1615
1616	case AUE_CAP_RIGHTS_LIMIT:
1617		/*
1618		 * XXXRW/XXXJA: Would be nice to audit socket/etc information.
1619		 */
1620		FD_VNODE1_TOKENS;
1621		if (ARG_IS_VALID(kar, ARG_RIGHTS)) {
1622			tok = au_to_rights(&ar->ar_arg_rights);
1623			kau_write(rec, tok);
1624		}
1625		break;
1626
1627	case AUE_CAP_FCNTLS_GET:
1628	case AUE_CAP_IOCTLS_GET:
1629	case AUE_CAP_IOCTLS_LIMIT:
1630	case AUE_CAP_RIGHTS_GET:
1631		if (ARG_IS_VALID(kar, ARG_FD)) {
1632			tok = au_to_arg32(1, "fd", ar->ar_arg_fd);
1633			kau_write(rec, tok);
1634		}
1635		break;
1636
1637	case AUE_CAP_FCNTLS_LIMIT:
1638		FD_VNODE1_TOKENS;
1639		if (ARG_IS_VALID(kar, ARG_FCNTL_RIGHTS)) {
1640			tok = au_to_arg32(2, "fcntlrights",
1641			    ar->ar_arg_fcntl_rights);
1642			kau_write(rec, tok);
1643		}
1644		break;
1645
1646	case AUE_CAP_ENTER:
1647	case AUE_CAP_GETMODE:
1648		break;
1649
1650	case AUE_NULL:
1651	default:
1652		printf("BSM conversion requested for unknown event %d\n",
1653		    ar->ar_event);
1654
1655		/*
1656		 * Write the subject token so it is properly freed here.
1657		 */
1658		if (jail_tok != NULL)
1659			kau_write(rec, jail_tok);
1660		kau_write(rec, subj_tok);
1661		kau_free(rec);
1662		return (BSM_NOAUDIT);
1663	}
1664
1665	if (jail_tok != NULL)
1666		kau_write(rec, jail_tok);
1667	kau_write(rec, subj_tok);
1668	tok = au_to_return32(au_errno_to_bsm(ar->ar_errno), ar->ar_retval);
1669	kau_write(rec, tok);  /* Every record gets a return token */
1670
1671	kau_close(rec, &ar->ar_endtime, ar->ar_event);
1672
1673	*pau = rec;
1674	return (BSM_SUCCESS);
1675}
1676
1677/*
1678 * Verify that a record is a valid BSM record. This verification is simple
1679 * now, but may be expanded on sometime in the future.  Return 1 if the
1680 * record is good, 0 otherwise.
1681 */
1682int
1683bsm_rec_verify(void *rec)
1684{
1685	char c = *(char *)rec;
1686
1687	/*
1688	 * Check the token ID of the first token; it has to be a header
1689	 * token.
1690	 *
1691	 * XXXAUDIT There needs to be a token structure to map a token.
1692	 * XXXAUDIT 'Shouldn't be simply looking at the first char.
1693	 */
1694	if ((c != AUT_HEADER32) && (c != AUT_HEADER32_EX) &&
1695	    (c != AUT_HEADER64) && (c != AUT_HEADER64_EX))
1696		return (0);
1697	return (1);
1698}
1699