xref: /illumos-gate/usr/src/uts/common/fs/mntfs/mntvnops.c (revision aedf2b3bb56b025fcaf87b49ec6c8aeea07f16d7)
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 2009 Sun Microsystems, Inc.  All rights reserved.
23  * Use is subject to license terms.
24  */
25 
26 #include <sys/file.h>
27 #include <sys/stat.h>
28 #include <sys/atomic.h>
29 #include <sys/mntio.h>
30 #include <sys/mnttab.h>
31 #include <sys/mount.h>
32 #include <sys/sunddi.h>
33 #include <sys/sysmacros.h>
34 #include <sys/systm.h>
35 #include <sys/vfs.h>
36 #include <sys/vfs_opreg.h>
37 #include <sys/fs/mntdata.h>
38 #include <fs/fs_subr.h>
39 #include <sys/vmsystm.h>
40 #include <vm/seg_vn.h>
41 #include <sys/time.h>
42 #include <sys/ksynch.h>
43 #include <sys/sdt.h>
44 
45 #define	MNTROOTINO	2
46 
47 static mntnode_t *mntgetnode(vnode_t *);
48 
49 vnodeops_t *mntvnodeops;
50 extern void vfs_mnttab_readop(void);
51 
52 /*
53  * Design of kernel mnttab accounting.
54  *
55  * mntfs provides two methods of reading the in-kernel mnttab, i.e. the state of
56  * the mounted resources: the read-only file /etc/mnttab, and a collection of
57  * ioctl() commands. Most of these interfaces are public and are described in
58  * mnttab(4). Three private ioctl() commands, MNTIOC_GETMNTENT,
59  * MNTIOC_GETEXTMNTENT and MNTIOC_GETMNTANY, provide for the getmntent(3C)
60  * family of functions, allowing them to support white space in mount names.
61  *
62  * A significant feature of mntfs is that it provides a file descriptor with a
63  * snapshot once it begins to consume mnttab data. Thus, as the process
64  * continues to consume data, its view of the in-kernel mnttab does not change
65  * even if resources are mounted or unmounted. The intent is to ensure that
66  * processes are guaranteed to read self-consistent data even as the system
67  * changes.
68  *
69  * The snapshot is implemented by a "database", unique to each zone, that
70  * comprises a linked list of mntelem_ts. The database is identified by
71  * zone_mntfs_db and is protected by zone_mntfs_db_lock. Each element contains
72  * the text entry in /etc/mnttab for a mounted resource, i.e. a vfs_t, and is
73  * marked with its time of "birth", i.e. creation. An element is "killed", and
74  * marked with its time of death, when it is found to be out of date, e.g. when
75  * the corresponding resource has been unmounted.
76  *
77  * When a process performs the first read() or ioctl() for a file descriptor for
78  * /etc/mnttab, the database is updated by a call to mntfs_snapshot() to ensure
79  * that an element exists for each currently mounted resource. Following this,
80  * the current time is written into a snapshot structure, a mntsnap_t, embedded
81  * in the descriptor's mntnode_t.
82  *
83  * mntfs is able to enumerate the /etc/mnttab entries corresponding to a
84  * particular file descriptor by searching the database for entries that were
85  * born before the appropriate snapshot and that either are still alive or died
86  * after the snapshot was created. Consumers use the iterator function
87  * mntfs_get_next_elem() to identify the next suitable element in the database.
88  *
89  * Each snapshot has a hold on its corresponding database elements, effected by
90  * a per-element reference count. At last close(), a snapshot is destroyed in
91  * mntfs_freesnap() by releasing all of its holds; an element is destroyed if
92  * its reference count becomes zero. Therefore the database never exists unless
93  * there is at least one active consumer of /etc/mnttab.
94  *
95  * getmntent(3C) et al. "do not open, close or rewind the file." This implies
96  * that getmntent() and read() must be able to operate without interaction on
97  * the same file descriptor; this is accomplished by the use of separate
98  * mntsnap_ts for both read() and ioctl().
99  *
100  * NOTE: The following variable enables the generation of the "dev=xxx"
101  * in the option string for a mounted file system.  Really this should
102  * be gotten rid of altogether, but for the sake of backwards compatibility
103  * we had to leave it in.  It is defined as a 32-bit device number.  This
104  * means that when 64-bit device numbers are in use, if either the major or
105  * minor part of the device number will not fit in a 16 bit quantity, the
106  * "dev=" will be set to NODEV (0x7fffffff).  See PSARC 1999/566 and
107  * 1999/131 for details.  The cmpldev() function used to generate the 32-bit
108  * device number handles this check and assigns the proper value.
109  */
110 int mntfs_enabledev = 1;	/* enable old "dev=xxx" option */
111 
112 extern void vfs_mono_time(timespec_t *);
113 enum { MNTFS_FIRST, MNTFS_SECOND, MNTFS_NEITHER };
114 
115 /*
116  * Determine whether a field within a line from /etc/mnttab contains actual
117  * content or simply the marker string "-". This never applies to the time,
118  * therefore the delimiter must be a tab.
119  */
120 #define	MNTFS_REAL_FIELD(x)	(*(x) != '-' || *((x) + 1) != '\t')
121 
122 static int
123 mntfs_devsize(struct vfs *vfsp)
124 {
125 	dev32_t odev;
126 
127 	(void) cmpldev(&odev, vfsp->vfs_dev);
128 	return (snprintf(NULL, 0, "dev=%x", odev));
129 }
130 
131 static int
132 mntfs_devprint(struct vfs *vfsp, char *buf)
133 {
134 	dev32_t odev;
135 
136 	(void) cmpldev(&odev, vfsp->vfs_dev);
137 	return (snprintf(buf, MAX_MNTOPT_STR, "dev=%x", odev));
138 }
139 
140 /* Identify which, if either, of two supplied timespec structs is newer. */
141 static int
142 mntfs_newest(timespec_t *a, timespec_t *b)
143 {
144 	if (a->tv_sec == b->tv_sec &&
145 	    a->tv_nsec == b->tv_nsec) {
146 		return (MNTFS_NEITHER);
147 	} else if (b->tv_sec > a->tv_sec ||
148 	    (b->tv_sec == a->tv_sec &&
149 	    b->tv_nsec > a->tv_nsec)) {
150 		return (MNTFS_SECOND);
151 	} else {
152 		return (MNTFS_FIRST);
153 	}
154 }
155 
156 static int
157 mntfs_optsize(struct vfs *vfsp)
158 {
159 	int i, size = 0;
160 	mntopt_t *mop;
161 
162 	for (i = 0; i < vfsp->vfs_mntopts.mo_count; i++) {
163 		mop = &vfsp->vfs_mntopts.mo_list[i];
164 		if (mop->mo_flags & MO_NODISPLAY)
165 			continue;
166 		if (mop->mo_flags & MO_SET) {
167 			if (size)
168 				size++; /* space for comma */
169 			size += strlen(mop->mo_name);
170 			/*
171 			 * count option value if there is one
172 			 */
173 			if (mop->mo_arg != NULL) {
174 				size += strlen(mop->mo_arg) + 1;
175 			}
176 		}
177 	}
178 	if (vfsp->vfs_zone != NULL && vfsp->vfs_zone != global_zone) {
179 		/*
180 		 * Add space for "zone=<zone_name>" if required.
181 		 */
182 		if (size)
183 			size++;	/* space for comma */
184 		size += sizeof ("zone=") - 1;
185 		size += strlen(vfsp->vfs_zone->zone_name);
186 	}
187 	if (mntfs_enabledev) {
188 		if (size != 0)
189 			size++; /* space for comma */
190 		size += mntfs_devsize(vfsp);
191 	}
192 	if (size == 0)
193 		size = strlen("-");
194 	return (size);
195 }
196 
197 static int
198 mntfs_optprint(struct vfs *vfsp, char *buf)
199 {
200 	int i, optinbuf = 0;
201 	mntopt_t *mop;
202 	char *origbuf = buf;
203 
204 	for (i = 0; i < vfsp->vfs_mntopts.mo_count; i++) {
205 		mop = &vfsp->vfs_mntopts.mo_list[i];
206 		if (mop->mo_flags & MO_NODISPLAY)
207 			continue;
208 		if (mop->mo_flags & MO_SET) {
209 			if (optinbuf)
210 				*buf++ = ',';
211 			else
212 				optinbuf = 1;
213 			buf += snprintf(buf, MAX_MNTOPT_STR,
214 			    "%s", mop->mo_name);
215 			/*
216 			 * print option value if there is one
217 			 */
218 			if (mop->mo_arg != NULL) {
219 				buf += snprintf(buf, MAX_MNTOPT_STR, "=%s",
220 				    mop->mo_arg);
221 			}
222 		}
223 	}
224 	if (vfsp->vfs_zone != NULL && vfsp->vfs_zone != global_zone) {
225 		if (optinbuf)
226 			*buf++ = ',';
227 		else
228 			optinbuf = 1;
229 		buf += snprintf(buf, MAX_MNTOPT_STR, "zone=%s",
230 		    vfsp->vfs_zone->zone_name);
231 	}
232 	if (mntfs_enabledev) {
233 		if (optinbuf++)
234 			*buf++ = ',';
235 		buf += mntfs_devprint(vfsp, buf);
236 	}
237 	if (!optinbuf) {
238 		buf += snprintf(buf, MAX_MNTOPT_STR, "-");
239 	}
240 	return (buf - origbuf);
241 }
242 
243 void
244 mntfs_populate_text(vfs_t *vfsp, zone_t *zonep, mntelem_t *elemp)
245 {
246 	struct extmnttab *tabp = &elemp->mnte_tab;
247 	const char *resource, *mntpt;
248 	char *cp = elemp->mnte_text;
249 	mntpt = refstr_value(vfsp->vfs_mntpt);
250 	resource = refstr_value(vfsp->vfs_resource);
251 
252 	tabp->mnt_special = 0;
253 	if (resource != NULL && resource[0] != '\0') {
254 		if (resource[0] != '/') {
255 			cp += snprintf(cp, MAXPATHLEN, "%s\t", resource);
256 		} else if (!ZONE_PATH_VISIBLE(resource, zonep)) {
257 			/*
258 			 * Use the mount point as the resource.
259 			 */
260 			cp += snprintf(cp, MAXPATHLEN, "%s\t",
261 			    ZONE_PATH_TRANSLATE(mntpt, zonep));
262 		} else {
263 			cp += snprintf(cp, MAXPATHLEN, "%s\t",
264 			    ZONE_PATH_TRANSLATE(resource, zonep));
265 		}
266 	} else {
267 		cp += snprintf(cp, MAXPATHLEN, "-\t");
268 	}
269 
270 	tabp->mnt_mountp = (char *)(cp - elemp->mnte_text);
271 	if (mntpt != NULL && mntpt[0] != '\0') {
272 		/*
273 		 * We know the mount point is visible from within the zone,
274 		 * otherwise it wouldn't be on the zone's vfs list.
275 		 */
276 		cp += snprintf(cp, MAXPATHLEN, "%s\t",
277 		    ZONE_PATH_TRANSLATE(mntpt, zonep));
278 	} else {
279 		cp += snprintf(cp, MAXPATHLEN, "-\t");
280 	}
281 
282 	tabp->mnt_fstype = (char *)(cp - elemp->mnte_text);
283 	cp += snprintf(cp, MAXPATHLEN, "%s\t",
284 	    vfssw[vfsp->vfs_fstype].vsw_name);
285 
286 	tabp->mnt_mntopts = (char *)(cp - elemp->mnte_text);
287 	cp += mntfs_optprint(vfsp, cp);
288 	*cp++ = '\t';
289 
290 	tabp->mnt_time = (char *)(cp - elemp->mnte_text);
291 	cp += snprintf(cp, MAX_MNTOPT_STR, "%ld", vfsp->vfs_mtime);
292 	*cp++ = '\n'; /* over-write snprintf's trailing null-byte */
293 
294 	tabp->mnt_major = getmajor(vfsp->vfs_dev);
295 	tabp->mnt_minor = getminor(vfsp->vfs_dev);
296 
297 	elemp->mnte_text_size = cp - elemp->mnte_text;
298 	elemp->mnte_vfs_ctime = vfsp->vfs_hrctime;
299 	elemp->mnte_hidden = vfsp->vfs_flag & VFS_NOMNTTAB;
300 }
301 
302 /* Determine the length of the /etc/mnttab entry for this vfs_t. */
303 static size_t
304 mntfs_text_len(vfs_t *vfsp, zone_t *zone)
305 {
306 	size_t size = 0;
307 	const char *resource, *mntpt;
308 	size_t mntsize;
309 
310 	mntpt = refstr_value(vfsp->vfs_mntpt);
311 	if (mntpt != NULL && mntpt[0] != '\0') {
312 		mntsize = strlen(ZONE_PATH_TRANSLATE(mntpt, zone)) + 1;
313 	} else {
314 		mntsize = 2;	/* "-\t" */
315 	}
316 	size += mntsize;
317 
318 	resource = refstr_value(vfsp->vfs_resource);
319 	if (resource != NULL && resource[0] != '\0') {
320 		if (resource[0] != '/') {
321 			size += strlen(resource) + 1;
322 		} else if (!ZONE_PATH_VISIBLE(resource, zone)) {
323 			/*
324 			 * Same as the zone's view of the mount point.
325 			 */
326 			size += mntsize;
327 		} else {
328 			size += strlen(ZONE_PATH_TRANSLATE(resource, zone)) + 1;
329 		}
330 	} else {
331 		size += 2;	/* "-\t" */
332 	}
333 	size += strlen(vfssw[vfsp->vfs_fstype].vsw_name) + 1;
334 	size += mntfs_optsize(vfsp);
335 	size += snprintf(NULL, 0, "\t%ld\n", vfsp->vfs_mtime);
336 	return (size);
337 }
338 
339 /* Destroy the resources associated with a snapshot element. */
340 static void
341 mntfs_destroy_elem(mntelem_t *elemp)
342 {
343 	kmem_free(elemp->mnte_text, elemp->mnte_text_size);
344 	kmem_free(elemp, sizeof (mntelem_t));
345 }
346 
347 /*
348  * Return 1 if the given snapshot is in the range of the given element; return
349  * 0 otherwise.
350  */
351 static int
352 mntfs_elem_in_range(mntsnap_t *snapp, mntelem_t *elemp)
353 {
354 	timespec_t	*stimep = &snapp->mnts_time;
355 	timespec_t	*btimep = &elemp->mnte_birth;
356 	timespec_t	*dtimep = &elemp->mnte_death;
357 
358 	/*
359 	 * If a snapshot is in range of an element then the snapshot must have
360 	 * been created after the birth of the element, and either the element
361 	 * is still alive or it died after the snapshot was created.
362 	 */
363 	if (mntfs_newest(btimep, stimep) == MNTFS_SECOND &&
364 	    (MNTFS_ELEM_IS_ALIVE(elemp) ||
365 	    mntfs_newest(stimep, dtimep) == MNTFS_SECOND))
366 		return (1);
367 	else
368 		return (0);
369 }
370 
371 /*
372  * Return the next valid database element, after the one provided, for a given
373  * snapshot; return NULL if none exists. The caller must hold the zone's
374  * database lock as a reader before calling this function.
375  */
376 static mntelem_t *
377 mntfs_get_next_elem(mntsnap_t *snapp, mntelem_t *elemp)
378 {
379 	int show_hidden = snapp->mnts_flags & MNTS_SHOWHIDDEN;
380 
381 	do {
382 		elemp = elemp->mnte_next;
383 	} while (elemp &&
384 	    (!mntfs_elem_in_range(snapp, elemp) ||
385 	    (!show_hidden && elemp->mnte_hidden)));
386 	return (elemp);
387 }
388 
389 /*
390  * This function frees the resources associated with a mntsnap_t. It walks
391  * through the database, decrementing the reference count of any element that
392  * satisfies the snapshot. If the reference count of an element becomes zero
393  * then it is removed from the database.
394  */
395 static void
396 mntfs_freesnap(mntnode_t *mnp, mntsnap_t *snapp)
397 {
398 	zone_t *zonep = MTOD(mnp)->mnt_zone;
399 	krwlock_t *dblockp = &zonep->zone_mntfs_db_lock;
400 	mntelem_t **elempp = &zonep->zone_mntfs_db;
401 	mntelem_t *elemp;
402 	int show_hidden = snapp->mnts_flags & MNTS_SHOWHIDDEN;
403 	size_t number_decremented = 0;
404 
405 	ASSERT(RW_WRITE_HELD(&mnp->mnt_contents));
406 
407 	/* Ignore an uninitialised snapshot. */
408 	if (snapp->mnts_nmnts == 0)
409 		return;
410 
411 	/* Drop the holds on any matching database elements. */
412 	rw_enter(dblockp, RW_WRITER);
413 	while ((elemp = *elempp) != NULL) {
414 		if (mntfs_elem_in_range(snapp, elemp) &&
415 		    (!elemp->mnte_hidden || show_hidden) &&
416 		    ++number_decremented && --elemp->mnte_refcnt == 0) {
417 			if ((*elempp = elemp->mnte_next) != NULL)
418 				(*elempp)->mnte_prev = elemp->mnte_prev;
419 			mntfs_destroy_elem(elemp);
420 		} else {
421 			elempp = &elemp->mnte_next;
422 		}
423 	}
424 	rw_exit(dblockp);
425 	ASSERT(number_decremented == snapp->mnts_nmnts);
426 
427 	/* Clear the snapshot data. */
428 	bzero(snapp, sizeof (mntsnap_t));
429 }
430 
431 /* Insert the new database element newp after the existing element prevp. */
432 static void
433 mntfs_insert_after(mntelem_t *newp, mntelem_t *prevp)
434 {
435 	newp->mnte_prev = prevp;
436 	newp->mnte_next = prevp->mnte_next;
437 	prevp->mnte_next = newp;
438 	if (newp->mnte_next != NULL)
439 		newp->mnte_next->mnte_prev = newp;
440 }
441 
442 /* Create and return a copy of a given database element. */
443 static mntelem_t *
444 mntfs_copy(mntelem_t *origp)
445 {
446 	mntelem_t *copyp;
447 
448 	copyp = kmem_zalloc(sizeof (mntelem_t), KM_SLEEP);
449 	copyp->mnte_vfs_ctime = origp->mnte_vfs_ctime;
450 	copyp->mnte_text_size = origp->mnte_text_size;
451 	copyp->mnte_text = kmem_alloc(copyp->mnte_text_size, KM_SLEEP);
452 	bcopy(origp->mnte_text, copyp->mnte_text, copyp->mnte_text_size);
453 	copyp->mnte_tab = origp->mnte_tab;
454 	copyp->mnte_hidden = origp->mnte_hidden;
455 
456 	return (copyp);
457 }
458 
459 /*
460  * Compare two database elements and determine whether or not the vfs_t payload
461  * data of each are the same. Return 1 if so and 0 otherwise.
462  */
463 static int
464 mntfs_is_same_element(mntelem_t *a, mntelem_t *b)
465 {
466 	if (a->mnte_hidden == b->mnte_hidden &&
467 	    a->mnte_text_size == b->mnte_text_size &&
468 	    bcmp(a->mnte_text, b->mnte_text, a->mnte_text_size) == 0 &&
469 	    bcmp(&a->mnte_tab, &b->mnte_tab, sizeof (struct extmnttab)) == 0)
470 		return (1);
471 	else
472 		return (0);
473 }
474 
475 /*
476  * mntfs_snapshot() updates the database, creating it if necessary, so that it
477  * accurately reflects the state of the in-kernel mnttab. It also increments
478  * the reference count on all database elements that correspond to currently-
479  * mounted resources. Finally, it initialises the appropriate snapshot
480  * structure.
481  *
482  * Each vfs_t is given a high-resolution time stamp, for the benefit of mntfs,
483  * when it is inserted into the in-kernel mnttab. This time stamp is copied into
484  * the corresponding database element when it is created, allowing the element
485  * and the vfs_t to be identified as a pair. It is possible that some file
486  * systems may make unadvertised changes to, for example, a resource's mount
487  * options. Therefore, in order to determine whether a database element is an
488  * up-to-date representation of a given vfs_t, it is compared with a temporary
489  * element generated for this purpose. Although less efficient, this is safer
490  * than implementing an mtime for a vfs_t.
491  *
492  * Some mounted resources are marked as "hidden" with a VFS_NOMNTTAB flag. These
493  * are considered invisible unless the user has already set the MNT_SHOWHIDDEN
494  * flag in the vnode using the MNTIOC_SHOWHIDDEN ioctl.
495  */
496 static void
497 mntfs_snapshot(mntnode_t *mnp, mntsnap_t *snapp)
498 {
499 	zone_t		*zonep = MTOD(mnp)->mnt_zone;
500 	int		is_global_zone = (zonep == global_zone);
501 	int		show_hidden = mnp->mnt_flags & MNT_SHOWHIDDEN;
502 	vfs_t		*vfsp, *firstvfsp, *lastvfsp;
503 	vfs_t		dummyvfs;
504 	vfs_t		*dummyvfsp = NULL;
505 	krwlock_t	*dblockp = &zonep->zone_mntfs_db_lock;
506 	mntelem_t	**headpp = &zonep->zone_mntfs_db;
507 	mntelem_t	*elemp;
508 	mntelem_t	*prevp = NULL;
509 	int		order;
510 	mntelem_t	*tempelemp;
511 	mntelem_t	*newp;
512 	mntelem_t	*firstp = NULL;
513 	size_t		nmnts = 0;
514 	size_t		text_size = 0;
515 	int		insert_before;
516 	timespec_t	last_mtime;
517 	size_t		entry_length, new_entry_length;
518 
519 
520 	ASSERT(RW_WRITE_HELD(&mnp->mnt_contents));
521 	vfs_list_read_lock();
522 	vfs_mnttab_modtime(&last_mtime);
523 
524 	/*
525 	 * If this snapshot already exists then we must have been asked to
526 	 * rewind the file, i.e. discard the snapshot and create a new one in
527 	 * its place. In this case we first see if the in-kernel mnttab has
528 	 * advertised a change; if not then we simply reinitialise the metadata.
529 	 */
530 	if (snapp->mnts_nmnts) {
531 		if (mntfs_newest(&last_mtime, &snapp->mnts_last_mtime) ==
532 		    MNTFS_NEITHER) {
533 			/*
534 			 * An unchanged mtime is no guarantee that the
535 			 * in-kernel mnttab is unchanged; for example, a
536 			 * concurrent remount may be between calls to
537 			 * vfs_setmntopt_nolock() and vfs_mnttab_modtimeupd().
538 			 * It follows that the database may have changed, and
539 			 * in particular that some elements in this snapshot
540 			 * may have been killed by another call to
541 			 * mntfs_snapshot(). It is therefore not merely
542 			 * unnecessary to update the snapshot's time but in
543 			 * fact dangerous; it needs to be left alone.
544 			 */
545 			snapp->mnts_next = snapp->mnts_first;
546 			snapp->mnts_flags &= ~MNTS_REWIND;
547 			snapp->mnts_foffset = snapp->mnts_ieoffset = 0;
548 			vfs_list_unlock();
549 			return;
550 		} else {
551 			mntfs_freesnap(mnp, snapp);
552 		}
553 	}
554 
555 	/*
556 	 * Create a temporary database element. For each vfs_t, the temporary
557 	 * element will be populated with the corresponding text. If the vfs_t
558 	 * does not have a corresponding element within the database, or if
559 	 * there is such an element but it is stale, a copy of the temporary
560 	 * element is inserted into the database at the appropriate location.
561 	 */
562 	tempelemp = kmem_alloc(sizeof (mntelem_t), KM_SLEEP);
563 	entry_length = MNT_LINE_MAX;
564 	tempelemp->mnte_text = kmem_alloc(entry_length, KM_SLEEP);
565 
566 	/* Find the first and last vfs_t for the given zone. */
567 	if (is_global_zone) {
568 		firstvfsp = rootvfs;
569 		lastvfsp = firstvfsp->vfs_prev;
570 	} else {
571 		firstvfsp = zonep->zone_vfslist;
572 		/*
573 		 * If there isn't already a vfs_t for root then we create a
574 		 * dummy which will be used as the head of the list (which will
575 		 * therefore no longer be circular).
576 		 */
577 		if (firstvfsp == NULL ||
578 		    strcmp(refstr_value(firstvfsp->vfs_mntpt),
579 		    zonep->zone_rootpath) != 0) {
580 			/*
581 			 * The zone's vfs_ts will have mount points relative to
582 			 * the zone's root path. The vfs_t for the zone's
583 			 * root file system would therefore have a mount point
584 			 * equal to the zone's root path. Since the zone's root
585 			 * path isn't a mount point, we copy the vfs_t of the
586 			 * zone's root vnode, and provide it with a fake mount
587 			 * point and resource.
588 			 *
589 			 * Note that by cloning another vfs_t we also acquire
590 			 * its high-resolution ctime. This might appear to
591 			 * violate the requirement that the ctimes in the list
592 			 * of vfs_ts are unique and monotonically increasing;
593 			 * this is not the case. The dummy vfs_t appears in only
594 			 * a non-global zone's vfs_t list, where the cloned
595 			 * vfs_t would not ordinarily be visible; the ctimes are
596 			 * therefore unique. The zone's root path must be
597 			 * available before the zone boots, and so its root
598 			 * vnode's vfs_t's ctime must be lower than those of any
599 			 * resources subsequently mounted by the zone. The
600 			 * ctimes are therefore monotonically increasing.
601 			 */
602 			dummyvfs = *zonep->zone_rootvp->v_vfsp;
603 			dummyvfs.vfs_mntpt = refstr_alloc(zonep->zone_rootpath);
604 			dummyvfs.vfs_resource = dummyvfs.vfs_mntpt;
605 			dummyvfsp = &dummyvfs;
606 			if (firstvfsp == NULL) {
607 				lastvfsp = dummyvfsp;
608 			} else {
609 				lastvfsp = firstvfsp->vfs_zone_prev;
610 				dummyvfsp->vfs_zone_next = firstvfsp;
611 			}
612 			firstvfsp = dummyvfsp;
613 		} else {
614 			lastvfsp = firstvfsp->vfs_zone_prev;
615 		}
616 	}
617 
618 	/*
619 	 * Now walk through all the vfs_ts for this zone. For each one, find the
620 	 * corresponding database element, creating it first if necessary, and
621 	 * increment its reference count.
622 	 */
623 	rw_enter(dblockp, RW_WRITER);
624 	elemp = zonep->zone_mntfs_db;
625 	/* CSTYLED */
626 	for (vfsp = firstvfsp;;
627 	    vfsp = is_global_zone ? vfsp->vfs_next : vfsp->vfs_zone_next) {
628 		DTRACE_PROBE1(new__vfs, vfs_t *, vfsp);
629 		/* Consider only visible entries. */
630 		if ((vfsp->vfs_flag & VFS_NOMNTTAB) == 0 || show_hidden) {
631 			/*
632 			 * Walk through the existing database looking for either
633 			 * an element that matches the current vfs_t, or for the
634 			 * correct place in which to insert a new element.
635 			 */
636 			insert_before = 0;
637 			for (; elemp; prevp = elemp, elemp = elemp->mnte_next) {
638 				DTRACE_PROBE1(considering__elem, mntelem_t *,
639 				    elemp);
640 
641 				/* Compare the vfs_t with the element. */
642 				order = mntfs_newest(&elemp->mnte_vfs_ctime,
643 				    &vfsp->vfs_hrctime);
644 
645 				/*
646 				 * If we encounter a database element newer than
647 				 * this vfs_t then we've stepped over a gap
648 				 * where the element for this vfs_t must be
649 				 * inserted.
650 				 */
651 				if (order == MNTFS_FIRST) {
652 					insert_before = 1;
653 					break;
654 				}
655 
656 				/* Dead elements no longer interest us. */
657 				if (MNTFS_ELEM_IS_DEAD(elemp))
658 					continue;
659 
660 				/*
661 				 * If the time stamps are the same then the
662 				 * element is potential match for the vfs_t,
663 				 * although it may later prove to be stale.
664 				 */
665 				if (order == MNTFS_NEITHER)
666 					break;
667 
668 				/*
669 				 * This element must be older than the vfs_t.
670 				 * It must, therefore, correspond to a vfs_t
671 				 * that has been unmounted. Since the element is
672 				 * still alive, we kill it if it is visible.
673 				 */
674 				if (!elemp->mnte_hidden || show_hidden)
675 					vfs_mono_time(&elemp->mnte_death);
676 			}
677 			DTRACE_PROBE2(possible__match, vfs_t *, vfsp,
678 			    mntelem_t *, elemp);
679 
680 			/* Create a new database element if required. */
681 			new_entry_length = mntfs_text_len(vfsp, zonep);
682 			if (new_entry_length > entry_length) {
683 				kmem_free(tempelemp->mnte_text, entry_length);
684 				tempelemp->mnte_text =
685 				    kmem_alloc(new_entry_length, KM_SLEEP);
686 				entry_length = new_entry_length;
687 			}
688 			mntfs_populate_text(vfsp, zonep, tempelemp);
689 			ASSERT(tempelemp->mnte_text_size == new_entry_length);
690 			if (elemp == NULL) {
691 				/*
692 				 * We ran off the end of the database. Insert a
693 				 * new element at the end.
694 				 */
695 				newp = mntfs_copy(tempelemp);
696 				vfs_mono_time(&newp->mnte_birth);
697 				if (prevp) {
698 					mntfs_insert_after(newp, prevp);
699 				} else {
700 					newp->mnte_next = NULL;
701 					newp->mnte_prev = NULL;
702 					ASSERT(*headpp == NULL);
703 					*headpp = newp;
704 				}
705 				elemp = newp;
706 			} else if (insert_before) {
707 				/*
708 				 * Insert a new element before the current one.
709 				 */
710 				newp = mntfs_copy(tempelemp);
711 				vfs_mono_time(&newp->mnte_birth);
712 				if (prevp) {
713 					mntfs_insert_after(newp, prevp);
714 				} else {
715 					newp->mnte_next = elemp;
716 					newp->mnte_prev = NULL;
717 					elemp->mnte_prev = newp;
718 					ASSERT(*headpp == elemp);
719 					*headpp = newp;
720 				}
721 				elemp = newp;
722 			} else if (!mntfs_is_same_element(elemp, tempelemp)) {
723 				/*
724 				 * The element corresponds to the vfs_t, but the
725 				 * vfs_t has changed; it must have been
726 				 * remounted. Kill the old element and insert a
727 				 * new one after it.
728 				 */
729 				vfs_mono_time(&elemp->mnte_death);
730 				newp = mntfs_copy(tempelemp);
731 				vfs_mono_time(&newp->mnte_birth);
732 				mntfs_insert_after(newp, elemp);
733 				elemp = newp;
734 			}
735 
736 			/* We've found the corresponding element. Hold it. */
737 			DTRACE_PROBE1(incrementing, mntelem_t *, elemp);
738 			elemp->mnte_refcnt++;
739 
740 			/*
741 			 * Update the parameters used to initialise the
742 			 * snapshot.
743 			 */
744 			nmnts++;
745 			text_size += elemp->mnte_text_size;
746 			if (!firstp)
747 				firstp = elemp;
748 
749 			prevp = elemp;
750 			elemp = elemp->mnte_next;
751 		}
752 
753 		if (vfsp == lastvfsp)
754 			break;
755 	}
756 
757 	/*
758 	 * Any remaining visible database elements that are still alive must be
759 	 * killed now, because their corresponding vfs_ts must have been
760 	 * unmounted.
761 	 */
762 	for (; elemp; elemp = elemp->mnte_next) {
763 		if (MNTFS_ELEM_IS_ALIVE(elemp) &&
764 		    (!elemp->mnte_hidden || show_hidden))
765 			vfs_mono_time(&elemp->mnte_death);
766 	}
767 
768 	/* Initialise the snapshot. */
769 	vfs_mono_time(&snapp->mnts_time);
770 	snapp->mnts_last_mtime = last_mtime;
771 	snapp->mnts_first = snapp->mnts_next = firstp;
772 	snapp->mnts_flags = show_hidden ? MNTS_SHOWHIDDEN : 0;
773 	snapp->mnts_nmnts = nmnts;
774 	snapp->mnts_text_size = MTOD(mnp)->mnt_size = text_size;
775 	snapp->mnts_foffset = snapp->mnts_ieoffset = 0;
776 
777 	/* Clean up. */
778 	rw_exit(dblockp);
779 	vfs_list_unlock();
780 	if (dummyvfsp != NULL)
781 		refstr_rele(dummyvfsp->vfs_mntpt);
782 	kmem_free(tempelemp->mnte_text, entry_length);
783 	kmem_free(tempelemp, sizeof (mntelem_t));
784 }
785 
786 /*
787  * Public function to convert vfs_mntopts into a string.
788  * A buffer of sufficient size is allocated, which is returned via bufp,
789  * and whose length is returned via lenp.
790  */
791 void
792 mntfs_getmntopts(struct vfs *vfsp, char **bufp, size_t *lenp)
793 {
794 	size_t len;
795 	char *buf;
796 
797 	vfs_list_read_lock();
798 
799 	len = mntfs_optsize(vfsp) + 1;
800 	buf = kmem_alloc(len, KM_NOSLEEP);
801 	if (buf == NULL) {
802 		*bufp = NULL;
803 		vfs_list_unlock();
804 		return;
805 	}
806 	buf[len - 1] = '\0';
807 	(void) mntfs_optprint(vfsp, buf);
808 	ASSERT(buf[len - 1] == '\0');
809 
810 	vfs_list_unlock();
811 	*bufp = buf;
812 	*lenp = len;
813 }
814 
815 /* ARGSUSED */
816 static int
817 mntopen(vnode_t **vpp, int flag, cred_t *cr, caller_context_t *ct)
818 {
819 	vnode_t *vp = *vpp;
820 	mntnode_t *nmnp;
821 
822 	/*
823 	 * Not allowed to open for writing, return error.
824 	 */
825 	if (flag & FWRITE)
826 		return (EPERM);
827 	/*
828 	 * Create a new mnt/vnode for each open, this will give us a handle to
829 	 * hang the snapshot on.
830 	 */
831 	nmnp = mntgetnode(vp);
832 
833 	*vpp = MTOV(nmnp);
834 	atomic_add_32(&MTOD(nmnp)->mnt_nopen, 1);
835 	VN_RELE(vp);
836 	return (0);
837 }
838 
839 /* ARGSUSED */
840 static int
841 mntclose(vnode_t *vp, int flag, int count, offset_t offset, cred_t *cr,
842 	caller_context_t *ct)
843 {
844 	mntnode_t *mnp = VTOM(vp);
845 
846 	/* Clean up any locks or shares held by the current process */
847 	cleanlocks(vp, ttoproc(curthread)->p_pid, 0);
848 	cleanshares(vp, ttoproc(curthread)->p_pid);
849 
850 	if (count > 1)
851 		return (0);
852 	if (vp->v_count == 1) {
853 		rw_enter(&mnp->mnt_contents, RW_WRITER);
854 		mntfs_freesnap(mnp, &mnp->mnt_read);
855 		mntfs_freesnap(mnp, &mnp->mnt_ioctl);
856 		rw_exit(&mnp->mnt_contents);
857 		atomic_add_32(&MTOD(mnp)->mnt_nopen, -1);
858 	}
859 	return (0);
860 }
861 
862 /* ARGSUSED */
863 static int
864 mntread(vnode_t *vp, uio_t *uio, int ioflag, cred_t *cred, caller_context_t *ct)
865 {
866 	mntnode_t *mnp = VTOM(vp);
867 	zone_t *zonep = MTOD(mnp)->mnt_zone;
868 	mntsnap_t *snapp = &mnp->mnt_read;
869 	off_t off = uio->uio_offset;
870 	size_t len = uio->uio_resid;
871 	char *bufferp;
872 	size_t available, copylen;
873 	size_t written = 0;
874 	mntelem_t *elemp;
875 	krwlock_t *dblockp = &zonep->zone_mntfs_db_lock;
876 	int error = 0;
877 	off_t	ieoffset;
878 
879 	rw_enter(&mnp->mnt_contents, RW_WRITER);
880 	if (snapp->mnts_nmnts == 0 || (off == (off_t)0))
881 		mntfs_snapshot(mnp, snapp);
882 
883 	if ((size_t)(off + len) > snapp->mnts_text_size)
884 		len = snapp->mnts_text_size - off;
885 
886 	if (off < 0 || len > snapp->mnts_text_size) {
887 		rw_exit(&mnp->mnt_contents);
888 		return (EFAULT);
889 	}
890 
891 	if (len == 0) {
892 		rw_exit(&mnp->mnt_contents);
893 		return (0);
894 	}
895 
896 	/*
897 	 * For the file offset provided, locate the corresponding database
898 	 * element and calculate the corresponding offset within its text. If
899 	 * the file offset is the same as that reached during the last read(2)
900 	 * then use the saved element and intra-element offset.
901 	 */
902 	rw_enter(dblockp, RW_READER);
903 	if (off == 0 || (off == snapp->mnts_foffset)) {
904 		elemp = snapp->mnts_next;
905 		ieoffset = snapp->mnts_ieoffset;
906 	} else {
907 		off_t total_off;
908 		/*
909 		 * Find the element corresponding to the requested file offset
910 		 * by walking through the database and summing the text sizes
911 		 * of the individual elements. If the requested file offset is
912 		 * greater than that reached on the last visit then we can start
913 		 * at the last seen element; otherwise, we have to start at the
914 		 * beginning.
915 		 */
916 		if (off > snapp->mnts_foffset) {
917 			elemp = snapp->mnts_next;
918 			total_off = snapp->mnts_foffset - snapp->mnts_ieoffset;
919 		} else {
920 			elemp = snapp->mnts_first;
921 			total_off = 0;
922 		}
923 		while (off > total_off + elemp->mnte_text_size) {
924 			total_off += elemp->mnte_text_size;
925 			elemp = mntfs_get_next_elem(snapp, elemp);
926 			ASSERT(elemp != NULL);
927 		}
928 		/* Calculate the intra-element offset. */
929 		if (off > total_off)
930 			ieoffset = off - total_off;
931 		else
932 			ieoffset = 0;
933 	}
934 
935 	/*
936 	 * Create a buffer and populate it with the text from successive
937 	 * database elements until it is full.
938 	 */
939 	bufferp = kmem_alloc(len, KM_SLEEP);
940 	while (written < len) {
941 		available = elemp->mnte_text_size - ieoffset;
942 		copylen = MIN(len - written, available);
943 		bcopy(elemp->mnte_text + ieoffset, bufferp + written, copylen);
944 		written += copylen;
945 		if (copylen == available) {
946 			elemp = mntfs_get_next_elem(snapp, elemp);
947 			ASSERT(elemp != NULL || written == len);
948 			ieoffset = 0;
949 		} else {
950 			ieoffset += copylen;
951 		}
952 	}
953 	rw_exit(dblockp);
954 
955 	/*
956 	 * Write the populated buffer, update the snapshot's state if
957 	 * successful and then advertise our read.
958 	 */
959 	error = uiomove(bufferp, len, UIO_READ, uio);
960 	if (error == 0) {
961 		snapp->mnts_next = elemp;
962 		snapp->mnts_foffset = off + len;
963 		snapp->mnts_ieoffset = ieoffset;
964 	}
965 	vfs_mnttab_readop();
966 	rw_exit(&mnp->mnt_contents);
967 
968 	/* Clean up. */
969 	kmem_free(bufferp, len);
970 	return (error);
971 }
972 
973 static int
974 mntgetattr(vnode_t *vp, vattr_t *vap, int flags, cred_t *cr,
975 	caller_context_t *ct)
976 {
977 	mntnode_t *mnp = VTOM(vp);
978 	int error;
979 	vnode_t *rvp;
980 	extern timespec_t vfs_mnttab_ctime;
981 	mntdata_t *mntdata = MTOD(VTOM(vp));
982 	mntsnap_t *snap;
983 
984 	rw_enter(&mnp->mnt_contents, RW_READER);
985 	snap = mnp->mnt_read.mnts_nmnts ? &mnp->mnt_read : &mnp->mnt_ioctl;
986 	/*
987 	 * Return all the attributes.  Should be refined
988 	 * so that it returns only those asked for.
989 	 * Most of this is complete fakery anyway.
990 	 */
991 	rvp = mnp->mnt_mountvp;
992 	/*
993 	 * Attributes are same as underlying file with modifications
994 	 */
995 	if (error = VOP_GETATTR(rvp, vap, flags, cr, ct)) {
996 		rw_exit(&mnp->mnt_contents);
997 		return (error);
998 	}
999 
1000 	/*
1001 	 * We always look like a regular file
1002 	 */
1003 	vap->va_type = VREG;
1004 	/*
1005 	 * mode should basically be read only
1006 	 */
1007 	vap->va_mode &= 07444;
1008 	vap->va_fsid = vp->v_vfsp->vfs_dev;
1009 	vap->va_blksize = DEV_BSIZE;
1010 	vap->va_rdev = 0;
1011 	vap->va_seq = 0;
1012 	/*
1013 	 * Set nlink to the number of open vnodes for mnttab info
1014 	 * plus one for existing.
1015 	 */
1016 	vap->va_nlink = mntdata->mnt_nopen + 1;
1017 	/*
1018 	 * If we haven't taken a snapshot yet, set the
1019 	 * size to the size of the latest snapshot.
1020 	 */
1021 	vap->va_size = snap->mnts_text_size ? snap->mnts_text_size :
1022 	    mntdata->mnt_size;
1023 	rw_exit(&mnp->mnt_contents);
1024 	/*
1025 	 * Fetch mtime from the vfs mnttab timestamp
1026 	 */
1027 	vap->va_ctime = vfs_mnttab_ctime;
1028 	vfs_list_read_lock();
1029 	vfs_mnttab_modtime(&vap->va_mtime);
1030 	vap->va_atime = vap->va_mtime;
1031 	vfs_list_unlock();
1032 	/*
1033 	 * Nodeid is always ROOTINO;
1034 	 */
1035 	vap->va_nodeid = (ino64_t)MNTROOTINO;
1036 	vap->va_nblocks = btod(vap->va_size);
1037 	return (0);
1038 }
1039 
1040 
1041 static int
1042 mntaccess(vnode_t *vp, int mode, int flags, cred_t *cr,
1043 	caller_context_t *ct)
1044 {
1045 	mntnode_t *mnp = VTOM(vp);
1046 
1047 	if (mode & (VWRITE|VEXEC))
1048 		return (EROFS);
1049 
1050 	/*
1051 	 * Do access check on the underlying directory vnode.
1052 	 */
1053 	return (VOP_ACCESS(mnp->mnt_mountvp, mode, flags, cr, ct));
1054 }
1055 
1056 
1057 /*
1058  * New /mntfs vnode required; allocate it and fill in most of the fields.
1059  */
1060 static mntnode_t *
1061 mntgetnode(vnode_t *dp)
1062 {
1063 	mntnode_t *mnp;
1064 	vnode_t *vp;
1065 
1066 	mnp = kmem_zalloc(sizeof (mntnode_t), KM_SLEEP);
1067 	mnp->mnt_vnode = vn_alloc(KM_SLEEP);
1068 	mnp->mnt_mountvp = VTOM(dp)->mnt_mountvp;
1069 	rw_init(&mnp->mnt_contents, NULL, RW_DEFAULT, NULL);
1070 	vp = MTOV(mnp);
1071 	vp->v_flag = VNOCACHE|VNOMAP|VNOSWAP|VNOMOUNT;
1072 	vn_setops(vp, mntvnodeops);
1073 	vp->v_vfsp = dp->v_vfsp;
1074 	vp->v_type = VREG;
1075 	vp->v_data = (caddr_t)mnp;
1076 
1077 	return (mnp);
1078 }
1079 
1080 /*
1081  * Free the storage obtained from mntgetnode().
1082  */
1083 static void
1084 mntfreenode(mntnode_t *mnp)
1085 {
1086 	vnode_t *vp = MTOV(mnp);
1087 
1088 	rw_destroy(&mnp->mnt_contents);
1089 	vn_invalid(vp);
1090 	vn_free(vp);
1091 	kmem_free(mnp, sizeof (*mnp));
1092 }
1093 
1094 
1095 /* ARGSUSED */
1096 static int
1097 mntfsync(vnode_t *vp, int syncflag, cred_t *cr, caller_context_t *ct)
1098 {
1099 	return (0);
1100 }
1101 
1102 /* ARGSUSED */
1103 static void
1104 mntinactive(vnode_t *vp, cred_t *cr, caller_context_t *ct)
1105 {
1106 	mntnode_t *mnp = VTOM(vp);
1107 
1108 	mntfreenode(mnp);
1109 }
1110 
1111 /*
1112  * lseek(2) is supported only to rewind the file. Rewinding has a special
1113  * meaning for /etc/mnttab: it forces mntfs to refresh the snapshot at the next
1114  * read() or ioctl().
1115  *
1116  * The generic lseek() code will have already changed the file offset. Therefore
1117  * mntread() can detect a rewind simply by looking for a zero offset. For the
1118  * benefit of mntioctl() we advertise a rewind with a specific flag.
1119  */
1120 /* ARGSUSED */
1121 static int
1122 mntseek(vnode_t *vp, offset_t ooff, offset_t *noffp, caller_context_t *ct)
1123 {
1124 	mntnode_t *mnp = VTOM(vp);
1125 
1126 	if (*noffp == 0) {
1127 		rw_enter(&mnp->mnt_contents, RW_WRITER);
1128 		mnp->mnt_ioctl.mnts_flags |= MNTS_REWIND;
1129 		rw_exit(&mnp->mnt_contents);
1130 	}
1131 
1132 	return (0);
1133 }
1134 
1135 /*
1136  * Return the answer requested to poll().
1137  * POLLRDBAND will return when the mtime of the mnttab
1138  * information is newer than the latest one read for this open.
1139  */
1140 /* ARGSUSED */
1141 static int
1142 mntpoll(vnode_t *vp, short ev, int any, short *revp, pollhead_t **phpp,
1143 	caller_context_t *ct)
1144 {
1145 	mntnode_t *mnp = VTOM(vp);
1146 	mntsnap_t *snapp;
1147 
1148 	rw_enter(&mnp->mnt_contents, RW_READER);
1149 	if (mntfs_newest(&mnp->mnt_ioctl.mnts_last_mtime,
1150 	    &mnp->mnt_read.mnts_last_mtime) == MNTFS_FIRST)
1151 		snapp = &mnp->mnt_ioctl;
1152 	else
1153 		snapp = &mnp->mnt_read;
1154 
1155 	*revp = 0;
1156 	*phpp = (pollhead_t *)NULL;
1157 	if (ev & POLLIN)
1158 		*revp |= POLLIN;
1159 
1160 	if (ev & POLLRDNORM)
1161 		*revp |= POLLRDNORM;
1162 
1163 	if (ev & POLLRDBAND) {
1164 		vfs_mnttab_poll(&snapp->mnts_last_mtime, phpp);
1165 		if (*phpp == (pollhead_t *)NULL)
1166 			*revp |= POLLRDBAND;
1167 	}
1168 	rw_exit(&mnp->mnt_contents);
1169 
1170 	if (*revp || *phpp != NULL || any) {
1171 		return (0);
1172 	}
1173 	/*
1174 	 * If someone is polling an unsupported poll events (e.g.
1175 	 * POLLOUT, POLLPRI, etc.), just return POLLERR revents.
1176 	 * That way we will ensure that we don't return a 0
1177 	 * revents with a NULL pollhead pointer.
1178 	 */
1179 	*revp = POLLERR;
1180 	return (0);
1181 }
1182 
1183 /*
1184  * mntfs_same_word() returns 1 if two words are the same in the context of
1185  * MNTIOC_GETMNTANY and 0 otherwise.
1186  *
1187  * worda is a memory address that lies somewhere in the buffer bufa; it cannot
1188  * be NULL since this is used to indicate to getmntany(3C) that the user does
1189  * not wish to match a particular field. The text to which worda points is
1190  * supplied by the user; if it is not null-terminated then it cannot match.
1191  *
1192  * Buffer bufb contains a line from /etc/mnttab, in which the fields are
1193  * delimited by tab or new-line characters. offb is the offset of the second
1194  * word within this buffer.
1195  *
1196  * mntfs_same_word() returns 1 if the words are the same and 0 otherwise.
1197  */
1198 int
1199 mntfs_same_word(char *worda, char *bufa, size_t sizea, off_t offb, char *bufb,
1200     size_t sizeb)
1201 {
1202 	char *wordb = bufb + offb;
1203 	int bytes_remaining;
1204 
1205 	ASSERT(worda != NULL);
1206 
1207 	bytes_remaining = MIN(((bufa + sizea) - worda),
1208 	    ((bufb + sizeb) - wordb));
1209 	while (bytes_remaining && *worda == *wordb) {
1210 		worda++;
1211 		wordb++;
1212 		bytes_remaining--;
1213 	}
1214 	if (bytes_remaining &&
1215 	    *worda == '\0' && (*wordb == '\t' || *wordb == '\n'))
1216 		return (1);
1217 	else
1218 		return (0);
1219 }
1220 
1221 /*
1222  * mntfs_special_info_string() returns which, if either, of VBLK or VCHR
1223  * corresponds to a supplied path. If the path is a special device then the
1224  * function optionally sets the major and minor numbers.
1225  */
1226 vtype_t
1227 mntfs_special_info_string(char *path, uint_t *major, uint_t *minor, cred_t *cr)
1228 {
1229 	vattr_t vattr;
1230 	vnode_t *vp;
1231 	vtype_t type;
1232 	int error;
1233 
1234 	if (path == NULL || *path != '/' ||
1235 	    lookupnameat(path + 1, UIO_SYSSPACE, FOLLOW, NULLVPP, &vp, rootdir))
1236 		return (0);
1237 
1238 	vattr.va_mask = AT_TYPE | AT_RDEV;
1239 	error = VOP_GETATTR(vp, &vattr, ATTR_REAL, cr, NULL);
1240 	VN_RELE(vp);
1241 
1242 	if (error == 0 && ((type = vattr.va_type) == VBLK || type == VCHR)) {
1243 		if (major && minor) {
1244 			*major = getmajor(vattr.va_rdev);
1245 			*minor = getminor(vattr.va_rdev);
1246 		}
1247 		return (type);
1248 	} else {
1249 		return (0);
1250 	}
1251 }
1252 
1253 /*
1254  * mntfs_special_info_element() extracts the name of the mounted resource
1255  * for a given element and copies it into a null-terminated string, which it
1256  * then passes to mntfs_special_info_string().
1257  */
1258 vtype_t
1259 mntfs_special_info_element(mntelem_t *elemp, cred_t *cr)
1260 {
1261 	char *newpath;
1262 	vtype_t type;
1263 
1264 	newpath = kmem_alloc(elemp->mnte_text_size, KM_SLEEP);
1265 	bcopy(elemp->mnte_text, newpath, (off_t)(elemp->mnte_tab.mnt_mountp));
1266 	*(newpath + (off_t)elemp->mnte_tab.mnt_mountp - 1) = '\0';
1267 	type = mntfs_special_info_string(newpath, NULL, NULL, cr);
1268 	kmem_free(newpath, elemp->mnte_text_size);
1269 
1270 	return (type);
1271 }
1272 
1273 /*
1274  * Convert an address that points to a byte within a user buffer into an
1275  * address that points to the corresponding offset within a kernel buffer. If
1276  * the user address is NULL then make no conversion. If the address does not
1277  * lie within the buffer then reset it to NULL.
1278  */
1279 char *
1280 mntfs_import_addr(char *uaddr, char *ubufp, char *kbufp, size_t bufsize)
1281 {
1282 	if (uaddr < ubufp || uaddr >= ubufp + bufsize)
1283 		return (NULL);
1284 	else
1285 		return (kbufp + (uaddr - ubufp));
1286 }
1287 
1288 /*
1289  * These 32-bit versions are to support STRUCT_DECL(9F) etc. in
1290  * mntfs_copyout_element() and mntioctl().
1291  */
1292 #ifdef _SYSCALL32_IMPL
1293 typedef struct extmnttab32 {
1294 	uint32_t	mnt_special;
1295 	uint32_t	mnt_mountp;
1296 	uint32_t	mnt_fstype;
1297 	uint32_t	mnt_mntopts;
1298 	uint32_t	mnt_time;
1299 	uint_t		mnt_major;
1300 	uint_t		mnt_minor;
1301 } extmnttab32_t;
1302 
1303 typedef struct mnttab32 {
1304 	uint32_t	mnt_special;
1305 	uint32_t	mnt_mountp;
1306 	uint32_t	mnt_fstype;
1307 	uint32_t	mnt_mntopts;
1308 	uint32_t	mnt_time;
1309 } mnttab32_t;
1310 
1311 struct mntentbuf32 {
1312 	uint32_t	mbuf_emp;
1313 	uint_t		mbuf_bufsize;
1314 	uint32_t	mbuf_buf;
1315 };
1316 #endif
1317 
1318 /*
1319  * mntfs_copyout_element() is common code for the MNTIOC_GETMNTENT,
1320  * MNTIOC_GETEXTMNTENT and MNTIOC_GETMNTANY ioctls. Having identifed the
1321  * database element desired by the user, this function copies out the text and
1322  * the pointers to the relevant userland addresses. It returns 0 on success
1323  * and non-zero otherwise.
1324  */
1325 int
1326 mntfs_copyout_elem(mntelem_t *elemp, struct extmnttab *uemp,
1327     char *ubufp, int cmd, int datamodel)
1328 {
1329 		STRUCT_DECL(extmnttab, ktab);
1330 		char *dbbufp = elemp->mnte_text;
1331 		size_t dbbufsize = elemp->mnte_text_size;
1332 		struct extmnttab *dbtabp = &elemp->mnte_tab;
1333 		size_t ssize;
1334 		char *kbufp;
1335 		int error = 0;
1336 
1337 
1338 		/*
1339 		 * We create a struct extmnttab within the kernel of the size
1340 		 * determined by the user's data model. We then populate its
1341 		 * fields by combining the start address of the text buffer
1342 		 * supplied by the user, ubufp, with the offsets stored for
1343 		 * this database element within dbtabp, a pointer to a struct
1344 		 * extmnttab.
1345 		 *
1346 		 * Note that if the corresponding field is "-" this signifies
1347 		 * no real content, and we set the address to NULL. This does
1348 		 * not apply to mnt_time.
1349 		 */
1350 		STRUCT_INIT(ktab, datamodel);
1351 		STRUCT_FSETP(ktab, mnt_special,
1352 		    MNTFS_REAL_FIELD(dbbufp) ? ubufp : NULL);
1353 		STRUCT_FSETP(ktab, mnt_mountp,
1354 		    MNTFS_REAL_FIELD(dbbufp + (off_t)dbtabp->mnt_mountp) ?
1355 		    ubufp + (off_t)dbtabp->mnt_mountp : NULL);
1356 		STRUCT_FSETP(ktab, mnt_fstype,
1357 		    MNTFS_REAL_FIELD(dbbufp + (off_t)dbtabp->mnt_fstype) ?
1358 		    ubufp + (off_t)dbtabp->mnt_fstype : NULL);
1359 		STRUCT_FSETP(ktab, mnt_mntopts,
1360 		    MNTFS_REAL_FIELD(dbbufp + (off_t)dbtabp->mnt_mntopts) ?
1361 		    ubufp + (off_t)dbtabp->mnt_mntopts : NULL);
1362 		STRUCT_FSETP(ktab, mnt_time,
1363 		    ubufp + (off_t)dbtabp->mnt_time);
1364 		if (cmd == MNTIOC_GETEXTMNTENT) {
1365 			STRUCT_FSETP(ktab, mnt_major, dbtabp->mnt_major);
1366 			STRUCT_FSETP(ktab, mnt_minor, dbtabp->mnt_minor);
1367 			ssize = SIZEOF_STRUCT(extmnttab, datamodel);
1368 		} else {
1369 			ssize = SIZEOF_STRUCT(mnttab, datamodel);
1370 		}
1371 		if (copyout(STRUCT_BUF(ktab), uemp, ssize))
1372 			return (EFAULT);
1373 
1374 		/*
1375 		 * We create a text buffer in the kernel into which we copy the
1376 		 * /etc/mnttab entry for this element. We change the tab and
1377 		 * new-line delimiters to null bytes before copying out the
1378 		 * buffer.
1379 		 */
1380 		kbufp = kmem_alloc(dbbufsize, KM_SLEEP);
1381 		bcopy(elemp->mnte_text, kbufp, dbbufsize);
1382 		*(kbufp + (off_t)dbtabp->mnt_mountp - 1) =
1383 		    *(kbufp + (off_t)dbtabp->mnt_fstype - 1) =
1384 		    *(kbufp + (off_t)dbtabp->mnt_mntopts - 1) =
1385 		    *(kbufp + (off_t)dbtabp->mnt_time - 1) =
1386 		    *(kbufp + dbbufsize - 1) = '\0';
1387 		if (copyout(kbufp, ubufp, dbbufsize))
1388 			error = EFAULT;
1389 
1390 		kmem_free(kbufp, dbbufsize);
1391 		return (error);
1392 }
1393 
1394 /* ARGSUSED */
1395 static int
1396 mntioctl(struct vnode *vp, int cmd, intptr_t arg, int flag, cred_t *cr,
1397     int *rvalp, caller_context_t *ct)
1398 {
1399 	uint_t *up = (uint_t *)arg;
1400 	mntnode_t *mnp = VTOM(vp);
1401 	mntsnap_t *snapp = &mnp->mnt_ioctl;
1402 	int error = 0;
1403 	zone_t *zonep = MTOD(mnp)->mnt_zone;
1404 	krwlock_t *dblockp = &zonep->zone_mntfs_db_lock;
1405 	model_t datamodel = flag & DATAMODEL_MASK;
1406 
1407 	switch (cmd) {
1408 
1409 	case MNTIOC_NMNTS:  		/* get no. of mounted resources */
1410 	{
1411 		rw_enter(&mnp->mnt_contents, RW_READER);
1412 		if (snapp->mnts_nmnts == 0 ||
1413 		    (snapp->mnts_flags & MNTS_REWIND)) {
1414 			if (!rw_tryupgrade(&mnp->mnt_contents)) {
1415 				rw_exit(&mnp->mnt_contents);
1416 				rw_enter(&mnp->mnt_contents, RW_WRITER);
1417 			}
1418 			if (snapp->mnts_nmnts == 0 ||
1419 			    (snapp->mnts_flags & MNTS_REWIND))
1420 				mntfs_snapshot(mnp, snapp);
1421 		}
1422 		rw_exit(&mnp->mnt_contents);
1423 
1424 		if (suword32(up, snapp->mnts_nmnts) != 0)
1425 			error = EFAULT;
1426 		break;
1427 	}
1428 
1429 	case MNTIOC_GETDEVLIST:  	/* get mounted device major/minor nos */
1430 	{
1431 		size_t len;
1432 		uint_t *devlist;
1433 		mntelem_t *elemp;
1434 		int i = 0;
1435 
1436 		rw_enter(&mnp->mnt_contents, RW_READER);
1437 		if (snapp->mnts_nmnts == 0 ||
1438 		    (snapp->mnts_flags & MNTS_REWIND)) {
1439 			if (!rw_tryupgrade(&mnp->mnt_contents)) {
1440 				rw_exit(&mnp->mnt_contents);
1441 				rw_enter(&mnp->mnt_contents, RW_WRITER);
1442 			}
1443 			if (snapp->mnts_nmnts == 0 ||
1444 			    (snapp->mnts_flags & MNTS_REWIND))
1445 				mntfs_snapshot(mnp, snapp);
1446 			rw_downgrade(&mnp->mnt_contents);
1447 		}
1448 
1449 		/* Create a local buffer to hold the device numbers. */
1450 		len = 2 * snapp->mnts_nmnts * sizeof (uint_t);
1451 		devlist = kmem_alloc(len, KM_SLEEP);
1452 
1453 		/*
1454 		 * Walk the database elements for this snapshot and add their
1455 		 * major and minor numbers.
1456 		 */
1457 		rw_enter(dblockp, RW_READER);
1458 		for (elemp = snapp->mnts_first; elemp;
1459 		    elemp = mntfs_get_next_elem(snapp, elemp)) {
1460 				devlist[2 * i] = elemp->mnte_tab.mnt_major;
1461 				devlist[2 * i + 1] = elemp->mnte_tab.mnt_minor;
1462 				i++;
1463 		}
1464 		rw_exit(dblockp);
1465 		ASSERT(i == snapp->mnts_nmnts);
1466 		rw_exit(&mnp->mnt_contents);
1467 
1468 		error = xcopyout(devlist, up, len);
1469 		kmem_free(devlist, len);
1470 		break;
1471 	}
1472 
1473 	case MNTIOC_SETTAG:		/* set tag on mounted file system */
1474 	case MNTIOC_CLRTAG:		/* clear tag on mounted file system */
1475 	{
1476 		struct mnttagdesc *dp = (struct mnttagdesc *)arg;
1477 		STRUCT_DECL(mnttagdesc, tagdesc);
1478 		char *cptr;
1479 		uint32_t major, minor;
1480 		char tagbuf[MAX_MNTOPT_TAG];
1481 		char *pbuf;
1482 		size_t len;
1483 		uint_t start = 0;
1484 		mntdata_t *mntdata = MTOD(mnp);
1485 		zone_t *zone = mntdata->mnt_zone;
1486 
1487 		STRUCT_INIT(tagdesc, flag & DATAMODEL_MASK);
1488 		if (copyin(dp, STRUCT_BUF(tagdesc), STRUCT_SIZE(tagdesc))) {
1489 			error = EFAULT;
1490 			break;
1491 		}
1492 		pbuf = kmem_alloc(MAXPATHLEN, KM_SLEEP);
1493 		if (zone != global_zone) {
1494 			(void) strcpy(pbuf, zone->zone_rootpath);
1495 			/* truncate "/" and nul */
1496 			start = zone->zone_rootpathlen - 2;
1497 			ASSERT(pbuf[start] == '/');
1498 		}
1499 		cptr = STRUCT_FGETP(tagdesc, mtd_mntpt);
1500 		error = copyinstr(cptr, pbuf + start, MAXPATHLEN - start, &len);
1501 		if (error) {
1502 			kmem_free(pbuf, MAXPATHLEN);
1503 			break;
1504 		}
1505 		if (start != 0 && pbuf[start] != '/') {
1506 			kmem_free(pbuf, MAXPATHLEN);
1507 			error = EINVAL;
1508 			break;
1509 		}
1510 		cptr = STRUCT_FGETP(tagdesc, mtd_tag);
1511 		if ((error = copyinstr(cptr, tagbuf, MAX_MNTOPT_TAG, &len))) {
1512 			kmem_free(pbuf, MAXPATHLEN);
1513 			break;
1514 		}
1515 		major = STRUCT_FGET(tagdesc, mtd_major);
1516 		minor = STRUCT_FGET(tagdesc, mtd_minor);
1517 		if (cmd == MNTIOC_SETTAG)
1518 			error = vfs_settag(major, minor, pbuf, tagbuf, cr);
1519 		else
1520 			error = vfs_clrtag(major, minor, pbuf, tagbuf, cr);
1521 		kmem_free(pbuf, MAXPATHLEN);
1522 		break;
1523 	}
1524 
1525 	case MNTIOC_SHOWHIDDEN:
1526 	{
1527 		mutex_enter(&vp->v_lock);
1528 		mnp->mnt_flags |= MNT_SHOWHIDDEN;
1529 		mutex_exit(&vp->v_lock);
1530 		break;
1531 	}
1532 
1533 	case MNTIOC_GETMNTANY:
1534 	{
1535 		STRUCT_DECL(mntentbuf, embuf);	/* Our copy of user's embuf */
1536 		STRUCT_DECL(extmnttab, ktab);	/* Out copy of user's emp */
1537 		struct extmnttab *uemp;		/* uaddr of user's emp */
1538 		char *ubufp;			/* uaddr of user's text buf */
1539 		size_t ubufsize;		/* size of the above */
1540 		struct extmnttab preftab;	/* our version of user's emp */
1541 		char *prefbuf;			/* our copy of user's text */
1542 		mntelem_t *elemp;		/* a database element */
1543 		struct extmnttab *dbtabp;	/* element's extmnttab */
1544 		char *dbbufp;			/* element's text buf */
1545 		size_t dbbufsize;		/* size of the above */
1546 		vtype_t type;			/* type, if any, of special */
1547 
1548 
1549 		/*
1550 		 * embuf is a struct embuf within the kernel. We copy into it
1551 		 * the struct embuf supplied by the user.
1552 		 */
1553 		STRUCT_INIT(embuf, datamodel);
1554 		if (copyin((void *) arg, STRUCT_BUF(embuf),
1555 		    STRUCT_SIZE(embuf))) {
1556 			error = EFAULT;
1557 			break;
1558 		}
1559 		uemp = STRUCT_FGETP(embuf, mbuf_emp);
1560 		ubufp = STRUCT_FGETP(embuf, mbuf_buf);
1561 		ubufsize = STRUCT_FGET(embuf, mbuf_bufsize);
1562 
1563 		/*
1564 		 * Check that the text buffer offered by the user is the
1565 		 * agreed size.
1566 		 */
1567 		if (ubufsize != MNT_LINE_MAX) {
1568 			error = EINVAL;
1569 			break;
1570 		}
1571 
1572 		/* Copy the user-supplied entry into a local buffer. */
1573 		prefbuf = kmem_alloc(MNT_LINE_MAX, KM_SLEEP);
1574 		if (copyin(ubufp, prefbuf, MNT_LINE_MAX)) {
1575 			kmem_free(prefbuf, MNT_LINE_MAX);
1576 			error = EFAULT;
1577 			break;
1578 		}
1579 
1580 		/* Ensure that any string within it is null-terminated. */
1581 		*(prefbuf + MNT_LINE_MAX - 1) = 0;
1582 
1583 		/* Copy in the user-supplied mpref */
1584 		STRUCT_INIT(ktab, datamodel);
1585 		if (copyin(uemp, STRUCT_BUF(ktab),
1586 		    SIZEOF_STRUCT(mnttab, datamodel))) {
1587 			kmem_free(prefbuf, MNT_LINE_MAX);
1588 			error = EFAULT;
1589 			break;
1590 		}
1591 
1592 		/*
1593 		 * Copy the members of the user's pref struct into a local
1594 		 * struct. The pointers need to be offset and verified to
1595 		 * ensure that they lie within the bounds of the buffer.
1596 		 */
1597 		preftab.mnt_special = mntfs_import_addr(STRUCT_FGETP(ktab,
1598 		    mnt_special), ubufp, prefbuf, MNT_LINE_MAX);
1599 		preftab.mnt_mountp = mntfs_import_addr(STRUCT_FGETP(ktab,
1600 		    mnt_mountp), ubufp, prefbuf, MNT_LINE_MAX);
1601 		preftab.mnt_fstype = mntfs_import_addr(STRUCT_FGETP(ktab,
1602 		    mnt_fstype), ubufp, prefbuf, MNT_LINE_MAX);
1603 		preftab.mnt_mntopts = mntfs_import_addr(STRUCT_FGETP(ktab,
1604 		    mnt_mntopts), ubufp, prefbuf, MNT_LINE_MAX);
1605 		preftab.mnt_time = mntfs_import_addr(STRUCT_FGETP(ktab,
1606 		    mnt_time), ubufp, prefbuf, MNT_LINE_MAX);
1607 
1608 		/*
1609 		 * If the user specifies a mounted resource that is a special
1610 		 * device then we capture its mode and major and minor numbers;
1611 		 * c.f. the block comment below.
1612 		 */
1613 		type = mntfs_special_info_string(preftab.mnt_special,
1614 		    &preftab.mnt_major, &preftab.mnt_minor, cr);
1615 
1616 		rw_enter(&mnp->mnt_contents, RW_WRITER);
1617 		if (snapp->mnts_nmnts == 0 ||
1618 		    (snapp->mnts_flags & MNTS_REWIND))
1619 			mntfs_snapshot(mnp, snapp);
1620 
1621 		/*
1622 		 * This is the core functionality that implements getmntany().
1623 		 * We walk through the mntfs database until we find an element
1624 		 * matching the user's preferences that are contained in
1625 		 * preftab. Typically, this means checking that the text
1626 		 * matches. However, the mounted resource is special: if the
1627 		 * user is looking for a special device then we must find a
1628 		 * database element with the same major and minor numbers and
1629 		 * the same type, i.e. VBLK or VCHR. The type is not recorded
1630 		 * in the element because it cannot be inferred from the vfs_t.
1631 		 * We therefore check the type of suitable candidates via
1632 		 * mntfs_special_info_element(); since this calls into the
1633 		 * underlying file system we make sure to drop the database lock
1634 		 * first.
1635 		 */
1636 		elemp = snapp->mnts_next;
1637 		rw_enter(dblockp, RW_READER);
1638 		for (;;) {
1639 			for (; elemp; elemp = mntfs_get_next_elem(snapp,
1640 			    elemp)) {
1641 				dbtabp = &elemp->mnte_tab;
1642 				dbbufp = elemp->mnte_text;
1643 				dbbufsize = elemp->mnte_text_size;
1644 
1645 				if (((type &&
1646 				    dbtabp->mnt_major == preftab.mnt_major &&
1647 				    dbtabp->mnt_minor == preftab.mnt_minor &&
1648 				    MNTFS_REAL_FIELD(dbbufp)) ||
1649 				    (!type && (!preftab.mnt_special ||
1650 				    mntfs_same_word(preftab.mnt_special,
1651 				    prefbuf, MNT_LINE_MAX, (off_t)0, dbbufp,
1652 				    dbbufsize)))) &&
1653 
1654 				    (!preftab.mnt_mountp || mntfs_same_word(
1655 				    preftab.mnt_mountp, prefbuf, MNT_LINE_MAX,
1656 				    (off_t)dbtabp->mnt_mountp, dbbufp,
1657 				    dbbufsize)) &&
1658 
1659 				    (!preftab.mnt_fstype || mntfs_same_word(
1660 				    preftab.mnt_fstype, prefbuf, MNT_LINE_MAX,
1661 				    (off_t)dbtabp->mnt_fstype, dbbufp,
1662 				    dbbufsize)) &&
1663 
1664 				    (!preftab.mnt_mntopts || mntfs_same_word(
1665 				    preftab.mnt_mntopts, prefbuf, MNT_LINE_MAX,
1666 				    (off_t)dbtabp->mnt_mntopts, dbbufp,
1667 				    dbbufsize)) &&
1668 
1669 				    (!preftab.mnt_time || mntfs_same_word(
1670 				    preftab.mnt_time, prefbuf, MNT_LINE_MAX,
1671 				    (off_t)dbtabp->mnt_time, dbbufp,
1672 				    dbbufsize)))
1673 					break;
1674 			}
1675 			rw_exit(dblockp);
1676 
1677 			if (elemp == NULL || type == 0 ||
1678 			    type == mntfs_special_info_element(elemp, cr))
1679 				break;
1680 
1681 			rw_enter(dblockp, RW_READER);
1682 			elemp = mntfs_get_next_elem(snapp, elemp);
1683 		}
1684 
1685 		kmem_free(prefbuf, MNT_LINE_MAX);
1686 
1687 		/* If we failed to find a match then return EOF. */
1688 		if (elemp == NULL) {
1689 			rw_exit(&mnp->mnt_contents);
1690 			*rvalp = MNTFS_EOF;
1691 			break;
1692 		}
1693 
1694 		/*
1695 		 * Check that the text buffer offered by the user will be large
1696 		 * enough to accommodate the text for this entry.
1697 		 */
1698 		if (elemp->mnte_text_size > MNT_LINE_MAX) {
1699 			rw_exit(&mnp->mnt_contents);
1700 			*rvalp = MNTFS_TOOLONG;
1701 			break;
1702 		}
1703 
1704 		/*
1705 		 * Populate the user's struct mnttab and text buffer using the
1706 		 * element's contents.
1707 		 */
1708 		if (mntfs_copyout_elem(elemp, uemp, ubufp, cmd, datamodel)) {
1709 			error = EFAULT;
1710 		} else {
1711 			rw_enter(dblockp, RW_READER);
1712 			elemp = mntfs_get_next_elem(snapp, elemp);
1713 			rw_exit(dblockp);
1714 			snapp->mnts_next = elemp;
1715 		}
1716 		rw_exit(&mnp->mnt_contents);
1717 		break;
1718 	}
1719 
1720 	case MNTIOC_GETMNTENT:
1721 	case MNTIOC_GETEXTMNTENT:
1722 	{
1723 		STRUCT_DECL(mntentbuf, embuf);	/* Our copy of user's embuf */
1724 		struct extmnttab *uemp;		/* uaddr of user's emp */
1725 		char *ubufp;			/* uaddr of user's text buf */
1726 		size_t ubufsize;		/* size of the above */
1727 		mntelem_t *elemp;		/* a database element */
1728 
1729 
1730 		rw_enter(&mnp->mnt_contents, RW_WRITER);
1731 		if (snapp->mnts_nmnts == 0 ||
1732 		    (snapp->mnts_flags & MNTS_REWIND))
1733 			mntfs_snapshot(mnp, snapp);
1734 		if ((elemp = snapp->mnts_next) == NULL) {
1735 			rw_exit(&mnp->mnt_contents);
1736 			*rvalp = MNTFS_EOF;
1737 			break;
1738 		}
1739 
1740 		/*
1741 		 * embuf is a struct embuf within the kernel. We copy into it
1742 		 * the struct embuf supplied by the user.
1743 		 */
1744 		STRUCT_INIT(embuf, datamodel);
1745 		if (copyin((void *) arg, STRUCT_BUF(embuf),
1746 		    STRUCT_SIZE(embuf))) {
1747 			rw_exit(&mnp->mnt_contents);
1748 			error = EFAULT;
1749 			break;
1750 		}
1751 		uemp = STRUCT_FGETP(embuf, mbuf_emp);
1752 		ubufp = STRUCT_FGETP(embuf, mbuf_buf);
1753 		ubufsize = STRUCT_FGET(embuf, mbuf_bufsize);
1754 
1755 		/*
1756 		 * Check that the text buffer offered by the user will be large
1757 		 * enough to accommodate the text for this entry.
1758 		 */
1759 		if (elemp->mnte_text_size > ubufsize) {
1760 			rw_exit(&mnp->mnt_contents);
1761 			*rvalp = MNTFS_TOOLONG;
1762 			break;
1763 		}
1764 
1765 		/*
1766 		 * Populate the user's struct mnttab and text buffer using the
1767 		 * element's contents.
1768 		 */
1769 		if (mntfs_copyout_elem(elemp, uemp, ubufp, cmd, datamodel)) {
1770 			error = EFAULT;
1771 		} else {
1772 			rw_enter(dblockp, RW_READER);
1773 			elemp = mntfs_get_next_elem(snapp, elemp);
1774 			rw_exit(dblockp);
1775 			snapp->mnts_next = elemp;
1776 		}
1777 		rw_exit(&mnp->mnt_contents);
1778 		break;
1779 	}
1780 
1781 	default:
1782 		error = EINVAL;
1783 		break;
1784 	}
1785 
1786 	return (error);
1787 }
1788 
1789 /*
1790  * /mntfs vnode operations vector
1791  */
1792 const fs_operation_def_t mnt_vnodeops_template[] = {
1793 	VOPNAME_OPEN,		{ .vop_open = mntopen },
1794 	VOPNAME_CLOSE,		{ .vop_close = mntclose },
1795 	VOPNAME_READ,		{ .vop_read = mntread },
1796 	VOPNAME_IOCTL,		{ .vop_ioctl = mntioctl },
1797 	VOPNAME_GETATTR,	{ .vop_getattr = mntgetattr },
1798 	VOPNAME_ACCESS,		{ .vop_access = mntaccess },
1799 	VOPNAME_FSYNC,		{ .vop_fsync = mntfsync },
1800 	VOPNAME_INACTIVE,	{ .vop_inactive = mntinactive },
1801 	VOPNAME_SEEK,		{ .vop_seek = mntseek },
1802 	VOPNAME_POLL,		{ .vop_poll = mntpoll },
1803 	VOPNAME_DISPOSE,	{ .error = fs_error },
1804 	VOPNAME_SHRLOCK,	{ .error = fs_error },
1805 	NULL,			NULL
1806 };
1807