xref: /titanic_52/usr/src/uts/common/c2/audit_kernel.h (revision b6c3f7863936abeae522e48a13887dddeb691a45)
1 /*
2  * CDDL HEADER START
3  *
4  * The contents of this file are subject to the terms of the
5  * Common Development and Distribution License (the "License").
6  * You may not use this file except in compliance with the License.
7  *
8  * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE
9  * or http://www.opensolaris.org/os/licensing.
10  * See the License for the specific language governing permissions
11  * and limitations under the License.
12  *
13  * When distributing Covered Code, include this CDDL HEADER in each
14  * file and include the License file at usr/src/OPENSOLARIS.LICENSE.
15  * If applicable, add the following below this CDDL HEADER, with the
16  * fields enclosed by brackets "[]" replaced with your own identifying
17  * information: Portions Copyright [yyyy] [name of copyright owner]
18  *
19  * CDDL HEADER END
20  */
21 /*
22  * Copyright 2008 Sun Microsystems, Inc.  All rights reserved.
23  * Use is subject to license terms.
24  */
25 
26 #ifndef _BSM_AUDIT_KERNEL_H
27 #define	_BSM_AUDIT_KERNEL_H
28 
29 #pragma ident	"%Z%%M%	%I%	%E% SMI"
30 
31 /*
32  * This file contains the basic auditing control structure definitions.
33  */
34 
35 #include <c2/audit_kevents.h>
36 #include <sys/priv_impl.h>
37 #include <sys/taskq.h>
38 #include <sys/zone.h>
39 
40 #include <sys/tsol/label.h>
41 
42 #ifdef __cplusplus
43 extern "C" {
44 #endif
45 
46 /*
47  * This table contains the mapping from the system call ID to a corresponding
48  * audit event.
49  *
50  *   au_init() is a function called at the beginning of the system call that
51  *   performs any necessary setup/processing. It maps the call into the
52  *   appropriate event, depending on the system call arguments. It is called
53  *   by audit_start() from trap.c .
54  *
55  *   au_event is the audit event associated with the system call. Most of the
56  *   time it will map directly from the system call i.e. There is one system
57  *   call associated with the event. In some cases, such as shmsys, or open,
58  *   the au_start() function will map the system call to more than one event,
59  *   depending on the system call arguments.
60  *
61  *   au_start() is a function that provides per system call processing at the
62  *   beginning of a system call. It is mainly concerned with preseving the
63  *   audit record components that may be altered so that we can determine
64  *   what the original paramater was before as well as after the system call.
65  *   It is possible that au_start() may be taken away. It might be cleaner to
66  *   define flags in au_ctrl to save a designated argument. For the moment we
67  *   support both mechanisms, however the use of au_start() will be reviewed
68  *   for 4.1.1 and CMW and ZEUS to see if such a general method is justified.
69  *
70  *   au_finish() is a function that provides per system call processing at the
71  *   completion of a system call. In certain circumstances, the type of audit
72  *   event depends on intermidiate results during the processing of the system
73  *   call. It is called in audit_finish() from trap.c .
74  *
75  *   au_ctrl is a control vector that indicates what processing might have to
76  *   be performed, even if there is no auditing for this system call. At
77  *   present this is mostly for path processing for chmod, chroot. We need to
78  *   process the path information in vfs_lookup, even when we are not auditing
79  *   the system call in the case of chdir and chroot.
80  */
81 /*
82  * Defines for au_ctrl
83  */
84 #define	S2E_SP  PAD_SAVPATH	/* save path for later use */
85 #define	S2E_MLD PAD_MLD		/* only one lookup per system call */
86 #define	S2E_NPT PAD_NOPATH	/* force no path in audit record */
87 #define	S2E_PUB PAD_PUBLIC_EV	/* syscall is defined as a public op */
88 
89 /*
90  * At present, we are using the audit classes imbedded with in the kernel. Each
91  * event has a bit mask determining which classes the event is associated.
92  * The table audit_e2s maps the audit event ID to the audit state.
93  *
94  * Note that this may change radically. If we use a bit vector for the audit
95  * class, we can allow granularity at the event ID for each user. In this
96  * case, the vector would be determined at user level and passed to the kernel
97  * via the setaudit system call.
98  */
99 
100 /*
101  * The audit_pad structure holds paths for the current root and directory
102  * for the process, as well as for open files and directly manipulated objects.
103  * The reference count minimizes data copies since the process's current
104  * directory changes very seldom.
105  */
106 struct audit_path {
107 	uint_t		audp_ref;	/* reference count */
108 	uint_t		audp_size;	/* allocated size of this structure */
109 	uint_t		audp_cnt;	/* number of path sections */
110 	char		*audp_sect[1];	/* path section pointers */
111 					/* audp_sect[0] is the path name */
112 					/* audp_sect[1+] are attribute paths */
113 };
114 
115 /*
116  * The structure of the terminal ID within the kernel is different from the
117  * terminal ID in user space. It is a combination of port and IP address.
118  */
119 
120 struct au_termid {
121 	dev_t	at_port;
122 	uint_t	at_type;
123 	uint_t	at_addr[4];
124 };
125 typedef struct au_termid au_termid_t;
126 
127 /*
128  * Attributes for deferring the queuing of an event.
129  */
130 typedef struct au_defer_info {
131 	struct au_defer_info	*audi_next;	/* next on linked list */
132 	void	 *audi_ad;		/* audit record */
133 	int	audi_e_type;		/* audit event id */
134 	int	audi_e_mod;		/* audit event modifier */
135 	int	audi_flag;		/* au_close*() flags */
136 	timestruc_t	audi_atime;	/* audit event timestamp */
137 } au_defer_info_t;
138 
139 /*
140  * The structure p_audit_data hangs off of the process structure. It contains
141  * all of the audit information necessary to manage the audit record generation
142  * for each process.
143  *
144  * The pad_lock is constructed in the kmem_cache; the rest is combined
145  * in a sub structure so it can be copied/zeroed in one statement.
146  *
147  * The members have been reordered for maximum packing on 64 bit Solaris.
148  */
149 struct p_audit_data {
150 	kmutex_t	pad_lock;	/* lock pad data during changes */
151 	struct _pad_data {
152 		struct audit_path	*pad_root;	/* process root path */
153 		struct audit_path	*pad_cwd;	/* process cwd path */
154 		au_mask_t		pad_newmask;	/* pending new mask */
155 		int			pad_flags;
156 	} pad_data;
157 };
158 typedef struct p_audit_data p_audit_data_t;
159 
160 #define	pad_root	pad_data.pad_root
161 #define	pad_cwd		pad_data.pad_cwd
162 #define	pad_newmask	pad_data.pad_newmask
163 #define	pad_flags	pad_data.pad_flags
164 
165 /*
166  * Defines for pad_flags
167  */
168 #define	PAD_SETMASK 	0x00000001	/* need to complete pending setmask */
169 
170 extern kmem_cache_t *au_pad_cache;
171 
172 /*
173  * Defines for pad_ctrl
174  */
175 #define	PAD_SAVPATH 	0x00000001	/* save path for further processing */
176 #define	PAD_MLD		0x00000002	/* system call involves MLD */
177 #define	PAD_NOPATH  	0x00000004	/* force no paths in audit record */
178 #define	PAD_ABSPATH 	0x00000008	/* path from lookup is absolute */
179 #define	PAD_NOATTRB 	0x00000010	/* do not automatically add attribute */
180 					/* 0x20, 0x40 unused */
181 #define	PAD_LFLOAT  	0x00000080	/* Label float */
182 #define	PAD_NOAUDIT 	0x00000100	/* discard audit record */
183 #define	PAD_PATHFND 	0x00000200	/* found path, don't retry lookup */
184 #define	PAD_SPRIV   	0x00000400	/* succ priv use. extra audit_finish */
185 #define	PAD_FPRIV   	0x00000800	/* fail priv use. extra audit_finish */
186 #define	PAD_SMAC    	0x00001000	/* succ mac use. extra audit_finish */
187 #define	PAD_FMAC    	0x00002000	/* fail mac use. extra audit_finish */
188 #define	PAD_AUDITME 	0x00004000	/* audit me because of NFS operation */
189 #define	PAD_ATPATH  	0x00008000	/* attribute file lookup */
190 #define	PAD_TRUE_CREATE 0x00010000	/* true create, file not found */
191 #define	PAD_CORE	0x00020000	/* save attribute during core dump */
192 #define	PAD_ERRJMP	0x00040000	/* abort record generation on error */
193 #define	PAD_PUBLIC_EV	0x00080000	/* syscall is defined as a public op */
194 
195 /*
196  * The structure t_audit_data hangs off of the thread structure. It contains
197  * all of the audit information necessary to manage the audit record generation
198  * for each thread.
199  *
200  */
201 
202 struct t_audit_data {
203 	kthread_id_t  tad_thread;	/* DEBUG pointer to parent thread */
204 	unsigned int  tad_scid;		/* system call ID for finish */
205 	short	tad_event;	/* event for audit record */
206 	short	tad_evmod;	/* event modifier for audit record */
207 	int	tad_ctrl;	/* audit control/status flags */
208 	void	*tad_errjmp;	/* error longjmp (audit record aborted) */
209 	int	tad_flag;	/* to audit or not to audit */
210 	struct audit_path	*tad_aupath;	/* captured at vfs_lookup */
211 	struct audit_path	*tad_atpath;	/* openat prefix, path of fd */
212 	struct vnode *tad_vn;	/* saved inode from vfs_lookup */
213 	caddr_t tad_ad;		/* base of accumulated audit data */
214 	au_defer_info_t	*tad_defer_head;	/* queue of records to defer */
215 						/* until syscall end: */
216 	au_defer_info_t	*tad_defer_tail;	/* tail of defer queue */
217 	priv_set_t tad_sprivs;	/* saved (success) used privs */
218 	priv_set_t tad_fprivs;	/* saved (failed) used privs */
219 };
220 typedef struct t_audit_data t_audit_data_t;
221 
222 /*
223  * The f_audit_data structure hangs off of the file structure. It contains
224  * three fields of data. The audit ID, the audit state, and a path name.
225  */
226 
227 struct f_audit_data {
228 	kthread_id_t	fad_thread;	/* DEBUG creating thread */
229 	int		fad_flags;	/* audit control flags */
230 	struct audit_path	*fad_aupath;	/* path from vfs_lookup */
231 };
232 typedef struct f_audit_data f_audit_data_t;
233 
234 #define	FAD_READ	0x0001		/* read system call seen */
235 #define	FAD_WRITE	0x0002		/* write system call seen */
236 
237 #define	P2A(p)	(p->p_audit_data)
238 #define	T2A(t)	(t->t_audit_data)
239 #define	U2A(u)	(curthread->t_audit_data)
240 #define	F2A(f)	(f->f_audit_data)
241 
242 #define	u_ad    ((U2A(u))->tad_ad)
243 #define	ad_ctrl ((U2A(u))->tad_ctrl)
244 #define	ad_flag ((U2A(u))->tad_flag)
245 
246 #define	AU_BUFSIZE	128		/* buffer size for the buffer pool */
247 
248 struct au_buff {
249 	char		buf[AU_BUFSIZE];
250 	struct au_buff	*next_buf;
251 	struct au_buff	*next_rec;
252 	ushort_t	rec_len;
253 	uchar_t		len;
254 	uchar_t		flag;
255 };
256 
257 typedef struct au_buff au_buff_t;
258 
259 /*
260  * Kernel audit queue structure.
261  */
262 struct audit_queue {
263 	au_buff_t *head;	/* head of queue */
264 	au_buff_t *tail;	/* tail of queue */
265 	ssize_t	cnt;		/* number elements on queue */
266 	size_t	hiwater;	/* high water mark to block */
267 	size_t	lowater;	/* low water mark to restart */
268 	size_t	bufsz;		/* audit trail write buffer size */
269 	size_t	buflen;		/* audit trail buffer length in use */
270 	clock_t	delay;		/* delay before flushing queue */
271 	int	wt_block;	/* writer is blocked (1) */
272 	int	rd_block;	/* reader is blocked (1) */
273 	kmutex_t lock;		/* mutex lock for queue modification */
274 	kcondvar_t write_cv;	/* sleep structure for write block */
275 	kcondvar_t read_cv;	/* sleep structure for read block */
276 };
277 
278 
279 union rval;
280 struct audit_s2e {
281 	au_event_t (*au_init)(au_event_t);
282 				/* convert au_event to real audit event ID */
283 
284 	int au_event;		/* default audit event for this system call */
285 	void (*au_start)(struct t_audit_data *);
286 				/* pre-system call audit processing */
287 	void (*au_finish)(struct t_audit_data *, int, union rval *);
288 				/* post-system call audit processing */
289 	int au_ctrl;		/* control flags for auditing actions */
290 };
291 
292 extern struct audit_s2e audit_s2e[];
293 
294 #define	AUK_VALID	0x5A5A5A5A
295 #define	AUK_INVALID	0
296 /*
297  * per zone audit context
298  */
299 struct au_kcontext {
300 	uint32_t		auk_valid;
301 	zoneid_t		auk_zid;
302 
303 	boolean_t		auk_hostaddr_valid;
304 	int			auk_sequence;
305 	int			auk_auditstate;
306 	int			auk_output_active;
307 	struct vnode		*auk_current_vp;
308 	int			auk_policy;
309 
310 	struct audit_queue	auk_queue;
311 
312 	au_dbuf_t		*auk_dbuffer;	/* auditdoor output */
313 
314 	au_stat_t		auk_statistics;
315 
316 	struct auditinfo_addr	auk_info;
317 	kmutex_t		auk_eagain_mutex; /* door call retry */
318 	kcondvar_t		auk_eagain_cv;
319 	kmutex_t		auk_fstat_lock;	/* audit file statistics lock */
320 	au_fstat_t		auk_file_stat;	/* file statistics */
321 
322 	taskq_t			*auk_taskq;	/* output thread */
323 
324 	/* Only one audit svc per zone at a time */
325 	/* With the elimination of auditsvc, can this also go? see 6648414 */
326 	kmutex_t 		auk_svc_lock;
327 
328 	au_state_t		auk_ets[MAX_KEVENTS + 1];
329 };
330 #ifndef AUK_CONTEXT_T
331 #define	AUK_CONTEXT_T
332 typedef struct au_kcontext au_kcontext_t;
333 #endif
334 
335 extern zone_key_t au_zone_key;
336 
337 /*
338  * Kernel auditing external variables
339  */
340 extern int audit_policy;
341 extern int audit_active;
342 extern int audit_load;
343 extern int au_auditstate;
344 
345 extern struct audit_queue au_queue;
346 extern struct p_audit_data *pad0;
347 extern struct t_audit_data *tad0;
348 
349 /*
350  * audit_path support routines
351  */
352 void au_pathhold(struct audit_path *);
353 void au_pathrele(struct audit_path *);
354 struct audit_path *au_pathdup(const struct audit_path *, int, int);
355 
356 /*
357  * Macros to hide asynchronous, non-blocking audit record start and finish
358  * processing.
359  *
360  * NOTE: must be used in (void) funcction () { ... }
361  */
362 
363 #define	AUDIT_ASYNC_START(rp, audit_event, sorf) \
364 { \
365 	label_t jb; \
366 	if (setjmp(&jb)) { \
367 		/* cleanup any residual audit data */ \
368 		audit_async_drop((caddr_t *)&(rp), 0); \
369 		return; \
370 	} \
371 	/* auditing enabled and we're preselected for this event? */ \
372 	if (audit_async_start(&jb, audit_event, sorf)) { \
373 		return; \
374 	} \
375 }
376 
377 #define	AUDIT_ASYNC_FINISH(rp, audit_event, event_modifier) \
378 	audit_async_finish((caddr_t *)&(rp), audit_event, event_modifier);
379 
380 
381 #ifdef	_KERNEL
382 au_buff_t *au_get_buff(void), *au_free_buff(au_buff_t *);
383 #endif
384 
385 /*
386  * Macro for uniform "subject" token(s) generation
387  */
388 #define	AUDIT_SETSUBJ_GENERIC(u, c, a, k, p)   	\
389 	au_write((u),				\
390 	    au_to_subject(crgetuid(c),		\
391 		crgetgid(c), crgetruid(c),	\
392 		crgetrgid(c), p,		\
393 		(a)->ai_auid, (a)->ai_asid,	\
394 		&((a)->ai_termid)));		\
395 	if (is_system_labeled())		\
396 		au_write((u),			\
397 		    au_to_label(CR_SL((c)))); 	\
398 	if ((k)->auk_policy & AUDIT_GROUP)	\
399 		au_write((u),			\
400 		    au_to_groups(crgetgroups(c),\
401 		    crgetngroups(c)))
402 
403 #define	AUDIT_SETSUBJ(u, c, a, k)      		\
404 	AUDIT_SETSUBJ_GENERIC(u, c, a, k, curproc->p_pid)
405 
406 /*
407  * Macros for type conversion
408  */
409 
410 /* au_membuf head, to typed data */
411 #define	memtod(x, t)	((t)x->buf)
412 
413 /* au_membuf types */
414 #define	MT_FREE		0	/* should be on free list */
415 #define	MT_DATA		1	/* dynamic (data) allocation */
416 
417 /* flags to au_memget */
418 #define	DONTWAIT	0
419 #define	WAIT		1
420 
421 #define	AU_PACK	1	/* pack data in au_append_rec() */
422 #define	AU_LINK 0	/* link data in au_append_rec() */
423 
424 /* flags to async routines */
425 #define	AU_BACKEND	1	/* called from softcall backend */
426 
427 #ifdef __cplusplus
428 }
429 #endif
430 
431 #endif /* _BSM_AUDIT_KERNEL_H */
432