Print this page
patch as-lock-macro-simplification
Split |
Close |
Expand all |
Collapse all |
--- old/usr/src/uts/common/fs/ufs/ufs_vnops.c
+++ new/usr/src/uts/common/fs/ufs/ufs_vnops.c
1 1 /*
2 2 * CDDL HEADER START
3 3 *
4 4 * The contents of this file are subject to the terms of the
5 5 * Common Development and Distribution License (the "License").
6 6 * You may not use this file except in compliance with the License.
7 7 *
8 8 * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE
9 9 * or http://www.opensolaris.org/os/licensing.
10 10 * See the License for the specific language governing permissions
11 11 * and limitations under the License.
12 12 *
13 13 * When distributing Covered Code, include this CDDL HEADER in each
14 14 * file and include the License file at usr/src/OPENSOLARIS.LICENSE.
15 15 * If applicable, add the following below this CDDL HEADER, with the
16 16 * fields enclosed by brackets "[]" replaced with your own identifying
17 17 * information: Portions Copyright [yyyy] [name of copyright owner]
18 18 *
19 19 * CDDL HEADER END
20 20 */
21 21
22 22 /*
23 23 * Copyright (c) 1984, 2010, Oracle and/or its affiliates. All rights reserved.
24 24 * Copyright (c) 2013, Joyent, Inc. All rights reserved.
25 25 */
26 26
27 27 /* Copyright (c) 1983, 1984, 1985, 1986, 1987, 1988, 1989 AT&T */
28 28 /* All Rights Reserved */
29 29
30 30 /*
31 31 * Portions of this source code were derived from Berkeley 4.3 BSD
32 32 * under license from the Regents of the University of California.
33 33 */
34 34
35 35 #include <sys/types.h>
36 36 #include <sys/t_lock.h>
37 37 #include <sys/ksynch.h>
38 38 #include <sys/param.h>
39 39 #include <sys/time.h>
40 40 #include <sys/systm.h>
41 41 #include <sys/sysmacros.h>
42 42 #include <sys/resource.h>
43 43 #include <sys/signal.h>
44 44 #include <sys/cred.h>
45 45 #include <sys/user.h>
46 46 #include <sys/buf.h>
47 47 #include <sys/vfs.h>
48 48 #include <sys/vfs_opreg.h>
49 49 #include <sys/vnode.h>
50 50 #include <sys/proc.h>
51 51 #include <sys/disp.h>
52 52 #include <sys/file.h>
53 53 #include <sys/fcntl.h>
54 54 #include <sys/flock.h>
55 55 #include <sys/atomic.h>
56 56 #include <sys/kmem.h>
57 57 #include <sys/uio.h>
58 58 #include <sys/dnlc.h>
59 59 #include <sys/conf.h>
60 60 #include <sys/mman.h>
61 61 #include <sys/pathname.h>
62 62 #include <sys/debug.h>
63 63 #include <sys/vmsystm.h>
64 64 #include <sys/cmn_err.h>
65 65 #include <sys/filio.h>
66 66 #include <sys/policy.h>
67 67
68 68 #include <sys/fs/ufs_fs.h>
69 69 #include <sys/fs/ufs_lockfs.h>
70 70 #include <sys/fs/ufs_filio.h>
71 71 #include <sys/fs/ufs_inode.h>
72 72 #include <sys/fs/ufs_fsdir.h>
73 73 #include <sys/fs/ufs_quota.h>
74 74 #include <sys/fs/ufs_log.h>
75 75 #include <sys/fs/ufs_snap.h>
76 76 #include <sys/fs/ufs_trans.h>
77 77 #include <sys/fs/ufs_panic.h>
78 78 #include <sys/fs/ufs_bio.h>
79 79 #include <sys/dirent.h> /* must be AFTER <sys/fs/fsdir.h>! */
80 80 #include <sys/errno.h>
81 81 #include <sys/fssnap_if.h>
82 82 #include <sys/unistd.h>
83 83 #include <sys/sunddi.h>
84 84
85 85 #include <sys/filio.h> /* _FIOIO */
86 86
87 87 #include <vm/hat.h>
88 88 #include <vm/page.h>
89 89 #include <vm/pvn.h>
90 90 #include <vm/as.h>
91 91 #include <vm/seg.h>
92 92 #include <vm/seg_map.h>
93 93 #include <vm/seg_vn.h>
94 94 #include <vm/seg_kmem.h>
95 95 #include <vm/rm.h>
96 96 #include <sys/swap.h>
97 97
98 98 #include <fs/fs_subr.h>
99 99
100 100 #include <sys/fs/decomp.h>
101 101
102 102 static struct instats ins;
103 103
104 104 static int ufs_getpage_ra(struct vnode *, u_offset_t, struct seg *, caddr_t);
105 105 static int ufs_getpage_miss(struct vnode *, u_offset_t, size_t, struct seg *,
106 106 caddr_t, struct page **, size_t, enum seg_rw, int);
107 107 static int ufs_open(struct vnode **, int, struct cred *, caller_context_t *);
108 108 static int ufs_close(struct vnode *, int, int, offset_t, struct cred *,
109 109 caller_context_t *);
110 110 static int ufs_read(struct vnode *, struct uio *, int, struct cred *,
111 111 struct caller_context *);
112 112 static int ufs_write(struct vnode *, struct uio *, int, struct cred *,
113 113 struct caller_context *);
114 114 static int ufs_ioctl(struct vnode *, int, intptr_t, int, struct cred *,
115 115 int *, caller_context_t *);
116 116 static int ufs_getattr(struct vnode *, struct vattr *, int, struct cred *,
117 117 caller_context_t *);
118 118 static int ufs_setattr(struct vnode *, struct vattr *, int, struct cred *,
119 119 caller_context_t *);
120 120 static int ufs_access(struct vnode *, int, int, struct cred *,
121 121 caller_context_t *);
122 122 static int ufs_lookup(struct vnode *, char *, struct vnode **,
123 123 struct pathname *, int, struct vnode *, struct cred *,
124 124 caller_context_t *, int *, pathname_t *);
125 125 static int ufs_create(struct vnode *, char *, struct vattr *, enum vcexcl,
126 126 int, struct vnode **, struct cred *, int,
127 127 caller_context_t *, vsecattr_t *);
128 128 static int ufs_remove(struct vnode *, char *, struct cred *,
129 129 caller_context_t *, int);
130 130 static int ufs_link(struct vnode *, struct vnode *, char *, struct cred *,
131 131 caller_context_t *, int);
132 132 static int ufs_rename(struct vnode *, char *, struct vnode *, char *,
133 133 struct cred *, caller_context_t *, int);
134 134 static int ufs_mkdir(struct vnode *, char *, struct vattr *, struct vnode **,
135 135 struct cred *, caller_context_t *, int, vsecattr_t *);
136 136 static int ufs_rmdir(struct vnode *, char *, struct vnode *, struct cred *,
137 137 caller_context_t *, int);
138 138 static int ufs_readdir(struct vnode *, struct uio *, struct cred *, int *,
139 139 caller_context_t *, int);
140 140 static int ufs_symlink(struct vnode *, char *, struct vattr *, char *,
141 141 struct cred *, caller_context_t *, int);
142 142 static int ufs_readlink(struct vnode *, struct uio *, struct cred *,
143 143 caller_context_t *);
144 144 static int ufs_fsync(struct vnode *, int, struct cred *, caller_context_t *);
145 145 static void ufs_inactive(struct vnode *, struct cred *, caller_context_t *);
146 146 static int ufs_fid(struct vnode *, struct fid *, caller_context_t *);
147 147 static int ufs_rwlock(struct vnode *, int, caller_context_t *);
148 148 static void ufs_rwunlock(struct vnode *, int, caller_context_t *);
149 149 static int ufs_seek(struct vnode *, offset_t, offset_t *, caller_context_t *);
150 150 static int ufs_frlock(struct vnode *, int, struct flock64 *, int, offset_t,
151 151 struct flk_callback *, struct cred *,
152 152 caller_context_t *);
153 153 static int ufs_space(struct vnode *, int, struct flock64 *, int, offset_t,
154 154 cred_t *, caller_context_t *);
155 155 static int ufs_getpage(struct vnode *, offset_t, size_t, uint_t *,
156 156 struct page **, size_t, struct seg *, caddr_t,
157 157 enum seg_rw, struct cred *, caller_context_t *);
158 158 static int ufs_putpage(struct vnode *, offset_t, size_t, int, struct cred *,
159 159 caller_context_t *);
160 160 static int ufs_putpages(struct vnode *, offset_t, size_t, int, struct cred *);
161 161 static int ufs_map(struct vnode *, offset_t, struct as *, caddr_t *, size_t,
162 162 uchar_t, uchar_t, uint_t, struct cred *, caller_context_t *);
163 163 static int ufs_addmap(struct vnode *, offset_t, struct as *, caddr_t, size_t,
164 164 uchar_t, uchar_t, uint_t, struct cred *, caller_context_t *);
165 165 static int ufs_delmap(struct vnode *, offset_t, struct as *, caddr_t, size_t,
166 166 uint_t, uint_t, uint_t, struct cred *, caller_context_t *);
167 167 static int ufs_poll(vnode_t *, short, int, short *, struct pollhead **,
168 168 caller_context_t *);
169 169 static int ufs_dump(vnode_t *, caddr_t, offset_t, offset_t,
170 170 caller_context_t *);
171 171 static int ufs_l_pathconf(struct vnode *, int, ulong_t *, struct cred *,
172 172 caller_context_t *);
173 173 static int ufs_pageio(struct vnode *, struct page *, u_offset_t, size_t, int,
174 174 struct cred *, caller_context_t *);
175 175 static int ufs_dumpctl(vnode_t *, int, offset_t *, caller_context_t *);
176 176 static daddr32_t *save_dblks(struct inode *, struct ufsvfs *, daddr32_t *,
177 177 daddr32_t *, int, int);
178 178 static int ufs_getsecattr(struct vnode *, vsecattr_t *, int, struct cred *,
179 179 caller_context_t *);
180 180 static int ufs_setsecattr(struct vnode *, vsecattr_t *, int, struct cred *,
181 181 caller_context_t *);
182 182 static int ufs_priv_access(void *, int, struct cred *);
183 183 static int ufs_eventlookup(struct vnode *, char *, struct cred *,
184 184 struct vnode **);
185 185 extern int as_map_locked(struct as *, caddr_t, size_t, int ((*)()), void *);
186 186
187 187 /*
188 188 * For lockfs: ulockfs begin/end is now inlined in the ufs_xxx functions.
189 189 *
190 190 * XXX - ULOCKFS in fs_pathconf and ufs_ioctl is not inlined yet.
191 191 */
192 192 struct vnodeops *ufs_vnodeops;
193 193
194 194 /* NOTE: "not blkd" below means that the operation isn't blocked by lockfs */
195 195 const fs_operation_def_t ufs_vnodeops_template[] = {
196 196 VOPNAME_OPEN, { .vop_open = ufs_open }, /* not blkd */
197 197 VOPNAME_CLOSE, { .vop_close = ufs_close }, /* not blkd */
198 198 VOPNAME_READ, { .vop_read = ufs_read },
199 199 VOPNAME_WRITE, { .vop_write = ufs_write },
200 200 VOPNAME_IOCTL, { .vop_ioctl = ufs_ioctl },
201 201 VOPNAME_GETATTR, { .vop_getattr = ufs_getattr },
202 202 VOPNAME_SETATTR, { .vop_setattr = ufs_setattr },
203 203 VOPNAME_ACCESS, { .vop_access = ufs_access },
204 204 VOPNAME_LOOKUP, { .vop_lookup = ufs_lookup },
205 205 VOPNAME_CREATE, { .vop_create = ufs_create },
206 206 VOPNAME_REMOVE, { .vop_remove = ufs_remove },
207 207 VOPNAME_LINK, { .vop_link = ufs_link },
208 208 VOPNAME_RENAME, { .vop_rename = ufs_rename },
209 209 VOPNAME_MKDIR, { .vop_mkdir = ufs_mkdir },
210 210 VOPNAME_RMDIR, { .vop_rmdir = ufs_rmdir },
211 211 VOPNAME_READDIR, { .vop_readdir = ufs_readdir },
212 212 VOPNAME_SYMLINK, { .vop_symlink = ufs_symlink },
213 213 VOPNAME_READLINK, { .vop_readlink = ufs_readlink },
214 214 VOPNAME_FSYNC, { .vop_fsync = ufs_fsync },
215 215 VOPNAME_INACTIVE, { .vop_inactive = ufs_inactive }, /* not blkd */
216 216 VOPNAME_FID, { .vop_fid = ufs_fid },
217 217 VOPNAME_RWLOCK, { .vop_rwlock = ufs_rwlock }, /* not blkd */
218 218 VOPNAME_RWUNLOCK, { .vop_rwunlock = ufs_rwunlock }, /* not blkd */
219 219 VOPNAME_SEEK, { .vop_seek = ufs_seek },
220 220 VOPNAME_FRLOCK, { .vop_frlock = ufs_frlock },
221 221 VOPNAME_SPACE, { .vop_space = ufs_space },
222 222 VOPNAME_GETPAGE, { .vop_getpage = ufs_getpage },
223 223 VOPNAME_PUTPAGE, { .vop_putpage = ufs_putpage },
224 224 VOPNAME_MAP, { .vop_map = ufs_map },
225 225 VOPNAME_ADDMAP, { .vop_addmap = ufs_addmap }, /* not blkd */
226 226 VOPNAME_DELMAP, { .vop_delmap = ufs_delmap }, /* not blkd */
227 227 VOPNAME_POLL, { .vop_poll = ufs_poll }, /* not blkd */
228 228 VOPNAME_DUMP, { .vop_dump = ufs_dump },
229 229 VOPNAME_PATHCONF, { .vop_pathconf = ufs_l_pathconf },
230 230 VOPNAME_PAGEIO, { .vop_pageio = ufs_pageio },
231 231 VOPNAME_DUMPCTL, { .vop_dumpctl = ufs_dumpctl },
232 232 VOPNAME_GETSECATTR, { .vop_getsecattr = ufs_getsecattr },
233 233 VOPNAME_SETSECATTR, { .vop_setsecattr = ufs_setsecattr },
234 234 VOPNAME_VNEVENT, { .vop_vnevent = fs_vnevent_support },
235 235 NULL, NULL
236 236 };
237 237
238 238 #define MAX_BACKFILE_COUNT 9999
239 239
240 240 /*
241 241 * Created by ufs_dumpctl() to store a file's disk block info into memory.
242 242 * Used by ufs_dump() to dump data to disk directly.
243 243 */
244 244 struct dump {
245 245 struct inode *ip; /* the file we contain */
246 246 daddr_t fsbs; /* number of blocks stored */
247 247 struct timeval32 time; /* time stamp for the struct */
248 248 daddr32_t dblk[1]; /* place holder for block info */
249 249 };
250 250
251 251 static struct dump *dump_info = NULL;
252 252
253 253 /*
254 254 * Previously there was no special action required for ordinary files.
255 255 * (Devices are handled through the device file system.)
256 256 * Now we support Large Files and Large File API requires open to
257 257 * fail if file is large.
258 258 * We could take care to prevent data corruption
259 259 * by doing an atomic check of size and truncate if file is opened with
260 260 * FTRUNC flag set but traditionally this is being done by the vfs/vnode
261 261 * layers. So taking care of truncation here is a change in the existing
262 262 * semantics of VOP_OPEN and therefore we chose not to implement any thing
263 263 * here. The check for the size of the file > 2GB is being done at the
264 264 * vfs layer in routine vn_open().
265 265 */
266 266
267 267 /* ARGSUSED */
268 268 static int
269 269 ufs_open(struct vnode **vpp, int flag, struct cred *cr, caller_context_t *ct)
270 270 {
271 271 return (0);
272 272 }
273 273
274 274 /*ARGSUSED*/
275 275 static int
276 276 ufs_close(struct vnode *vp, int flag, int count, offset_t offset,
277 277 struct cred *cr, caller_context_t *ct)
278 278 {
279 279 cleanlocks(vp, ttoproc(curthread)->p_pid, 0);
280 280 cleanshares(vp, ttoproc(curthread)->p_pid);
281 281
282 282 /*
283 283 * Push partially filled cluster at last close.
284 284 * ``last close'' is approximated because the dnlc
285 285 * may have a hold on the vnode.
286 286 * Checking for VBAD here will also act as a forced umount check.
287 287 */
288 288 if (vp->v_count <= 2 && vp->v_type != VBAD) {
289 289 struct inode *ip = VTOI(vp);
290 290 if (ip->i_delaylen) {
291 291 ins.in_poc.value.ul++;
292 292 (void) ufs_putpages(vp, ip->i_delayoff, ip->i_delaylen,
293 293 B_ASYNC | B_FREE, cr);
294 294 ip->i_delaylen = 0;
295 295 }
296 296 }
297 297
298 298 return (0);
299 299 }
300 300
301 301 /*ARGSUSED*/
302 302 static int
303 303 ufs_read(struct vnode *vp, struct uio *uiop, int ioflag, struct cred *cr,
304 304 struct caller_context *ct)
305 305 {
306 306 struct inode *ip = VTOI(vp);
307 307 struct ufsvfs *ufsvfsp;
308 308 struct ulockfs *ulp = NULL;
309 309 int error = 0;
310 310 int intrans = 0;
311 311
312 312 ASSERT(RW_READ_HELD(&ip->i_rwlock));
313 313
314 314 /*
315 315 * Mandatory locking needs to be done before ufs_lockfs_begin()
316 316 * and TRANS_BEGIN_SYNC() calls since mandatory locks can sleep.
317 317 */
318 318 if (MANDLOCK(vp, ip->i_mode)) {
319 319 /*
320 320 * ufs_getattr ends up being called by chklock
321 321 */
322 322 error = chklock(vp, FREAD, uiop->uio_loffset,
323 323 uiop->uio_resid, uiop->uio_fmode, ct);
324 324 if (error)
325 325 goto out;
326 326 }
327 327
328 328 ufsvfsp = ip->i_ufsvfs;
329 329 error = ufs_lockfs_begin(ufsvfsp, &ulp, ULOCKFS_READ_MASK);
330 330 if (error)
331 331 goto out;
332 332
333 333 /*
334 334 * In the case that a directory is opened for reading as a file
335 335 * (eg "cat .") with the O_RSYNC, O_SYNC and O_DSYNC flags set.
336 336 * The locking order had to be changed to avoid a deadlock with
337 337 * an update taking place on that directory at the same time.
338 338 */
339 339 if ((ip->i_mode & IFMT) == IFDIR) {
340 340
341 341 rw_enter(&ip->i_contents, RW_READER);
342 342 error = rdip(ip, uiop, ioflag, cr);
343 343 rw_exit(&ip->i_contents);
344 344
345 345 if (error) {
346 346 if (ulp)
347 347 ufs_lockfs_end(ulp);
348 348 goto out;
349 349 }
350 350
351 351 if (ulp && (ioflag & FRSYNC) && (ioflag & (FSYNC | FDSYNC)) &&
352 352 TRANS_ISTRANS(ufsvfsp)) {
353 353 rw_exit(&ip->i_rwlock);
354 354 TRANS_BEGIN_SYNC(ufsvfsp, TOP_READ_SYNC, TOP_READ_SIZE,
355 355 error);
356 356 ASSERT(!error);
357 357 TRANS_END_SYNC(ufsvfsp, error, TOP_READ_SYNC,
358 358 TOP_READ_SIZE);
359 359 rw_enter(&ip->i_rwlock, RW_READER);
360 360 }
361 361 } else {
362 362 /*
363 363 * Only transact reads to files opened for sync-read and
364 364 * sync-write on a file system that is not write locked.
365 365 *
366 366 * The ``not write locked'' check prevents problems with
367 367 * enabling/disabling logging on a busy file system. E.g.,
368 368 * logging exists at the beginning of the read but does not
369 369 * at the end.
370 370 *
371 371 */
372 372 if (ulp && (ioflag & FRSYNC) && (ioflag & (FSYNC | FDSYNC)) &&
373 373 TRANS_ISTRANS(ufsvfsp)) {
374 374 TRANS_BEGIN_SYNC(ufsvfsp, TOP_READ_SYNC, TOP_READ_SIZE,
375 375 error);
376 376 ASSERT(!error);
377 377 intrans = 1;
378 378 }
379 379
380 380 rw_enter(&ip->i_contents, RW_READER);
381 381 error = rdip(ip, uiop, ioflag, cr);
382 382 rw_exit(&ip->i_contents);
383 383
384 384 if (intrans) {
385 385 TRANS_END_SYNC(ufsvfsp, error, TOP_READ_SYNC,
386 386 TOP_READ_SIZE);
387 387 }
388 388 }
389 389
390 390 if (ulp) {
391 391 ufs_lockfs_end(ulp);
392 392 }
393 393 out:
394 394
395 395 return (error);
396 396 }
397 397
398 398 extern int ufs_HW; /* high water mark */
399 399 extern int ufs_LW; /* low water mark */
400 400 int ufs_WRITES = 1; /* XXX - enable/disable */
401 401 int ufs_throttles = 0; /* throttling count */
402 402 int ufs_allow_shared_writes = 1; /* directio shared writes */
403 403
404 404 static int
405 405 ufs_check_rewrite(struct inode *ip, struct uio *uiop, int ioflag)
406 406 {
407 407 int shared_write;
408 408
409 409 /*
410 410 * If the FDSYNC flag is set then ignore the global
411 411 * ufs_allow_shared_writes in this case.
412 412 */
413 413 shared_write = (ioflag & FDSYNC) | ufs_allow_shared_writes;
414 414
415 415 /*
416 416 * Filter to determine if this request is suitable as a
417 417 * concurrent rewrite. This write must not allocate blocks
418 418 * by extending the file or filling in holes. No use trying
419 419 * through FSYNC descriptors as the inode will be synchronously
420 420 * updated after the write. The uio structure has not yet been
421 421 * checked for sanity, so assume nothing.
422 422 */
423 423 return (((ip->i_mode & IFMT) == IFREG) && !(ioflag & FAPPEND) &&
424 424 (uiop->uio_loffset >= (offset_t)0) &&
425 425 (uiop->uio_loffset < ip->i_size) && (uiop->uio_resid > 0) &&
426 426 ((ip->i_size - uiop->uio_loffset) >= uiop->uio_resid) &&
427 427 !(ioflag & FSYNC) && !bmap_has_holes(ip) &&
428 428 shared_write);
429 429 }
430 430
431 431 /*ARGSUSED*/
432 432 static int
433 433 ufs_write(struct vnode *vp, struct uio *uiop, int ioflag, cred_t *cr,
434 434 caller_context_t *ct)
435 435 {
436 436 struct inode *ip = VTOI(vp);
437 437 struct ufsvfs *ufsvfsp;
438 438 struct ulockfs *ulp;
439 439 int retry = 1;
440 440 int error, resv, resid = 0;
441 441 int directio_status;
442 442 int exclusive;
443 443 int rewriteflg;
444 444 long start_resid = uiop->uio_resid;
445 445
446 446 ASSERT(RW_LOCK_HELD(&ip->i_rwlock));
447 447
448 448 retry_mandlock:
449 449 /*
450 450 * Mandatory locking needs to be done before ufs_lockfs_begin()
451 451 * and TRANS_BEGIN_[A]SYNC() calls since mandatory locks can sleep.
452 452 * Check for forced unmounts normally done in ufs_lockfs_begin().
453 453 */
454 454 if ((ufsvfsp = ip->i_ufsvfs) == NULL) {
455 455 error = EIO;
456 456 goto out;
457 457 }
458 458 if (MANDLOCK(vp, ip->i_mode)) {
459 459
460 460 ASSERT(RW_WRITE_HELD(&ip->i_rwlock));
461 461
462 462 /*
463 463 * ufs_getattr ends up being called by chklock
464 464 */
465 465 error = chklock(vp, FWRITE, uiop->uio_loffset,
466 466 uiop->uio_resid, uiop->uio_fmode, ct);
467 467 if (error)
468 468 goto out;
469 469 }
470 470
471 471 /* i_rwlock can change in chklock */
472 472 exclusive = rw_write_held(&ip->i_rwlock);
473 473 rewriteflg = ufs_check_rewrite(ip, uiop, ioflag);
474 474
475 475 /*
476 476 * Check for fast-path special case of directio re-writes.
477 477 */
478 478 if ((ip->i_flag & IDIRECTIO || ufsvfsp->vfs_forcedirectio) &&
479 479 !exclusive && rewriteflg) {
480 480
481 481 error = ufs_lockfs_begin(ufsvfsp, &ulp, ULOCKFS_WRITE_MASK);
482 482 if (error)
483 483 goto out;
484 484
485 485 rw_enter(&ip->i_contents, RW_READER);
486 486 error = ufs_directio_write(ip, uiop, ioflag, 1, cr,
487 487 &directio_status);
488 488 if (directio_status == DIRECTIO_SUCCESS) {
489 489 uint_t i_flag_save;
490 490
491 491 if (start_resid != uiop->uio_resid)
492 492 error = 0;
493 493 /*
494 494 * Special treatment of access times for re-writes.
495 495 * If IMOD is not already set, then convert it
496 496 * to IMODACC for this operation. This defers
497 497 * entering a delta into the log until the inode
498 498 * is flushed. This mimics what is done for read
499 499 * operations and inode access time.
500 500 */
501 501 mutex_enter(&ip->i_tlock);
502 502 i_flag_save = ip->i_flag;
503 503 ip->i_flag |= IUPD | ICHG;
504 504 ip->i_seq++;
505 505 ITIMES_NOLOCK(ip);
506 506 if ((i_flag_save & IMOD) == 0) {
507 507 ip->i_flag &= ~IMOD;
508 508 ip->i_flag |= IMODACC;
509 509 }
510 510 mutex_exit(&ip->i_tlock);
511 511 rw_exit(&ip->i_contents);
512 512 if (ulp)
513 513 ufs_lockfs_end(ulp);
514 514 goto out;
515 515 }
516 516 rw_exit(&ip->i_contents);
517 517 if (ulp)
518 518 ufs_lockfs_end(ulp);
519 519 }
520 520
521 521 if (!exclusive && !rw_tryupgrade(&ip->i_rwlock)) {
522 522 rw_exit(&ip->i_rwlock);
523 523 rw_enter(&ip->i_rwlock, RW_WRITER);
524 524 /*
525 525 * Mandatory locking could have been enabled
526 526 * after dropping the i_rwlock.
527 527 */
528 528 if (MANDLOCK(vp, ip->i_mode))
529 529 goto retry_mandlock;
530 530 }
531 531
532 532 error = ufs_lockfs_begin(ufsvfsp, &ulp, ULOCKFS_WRITE_MASK);
533 533 if (error)
534 534 goto out;
535 535
536 536 /*
537 537 * Amount of log space needed for this write
538 538 */
539 539 if (!rewriteflg || !(ioflag & FDSYNC))
540 540 TRANS_WRITE_RESV(ip, uiop, ulp, &resv, &resid);
541 541
542 542 /*
543 543 * Throttle writes.
544 544 */
545 545 if (ufs_WRITES && (ip->i_writes > ufs_HW)) {
546 546 mutex_enter(&ip->i_tlock);
547 547 while (ip->i_writes > ufs_HW) {
548 548 ufs_throttles++;
549 549 cv_wait(&ip->i_wrcv, &ip->i_tlock);
550 550 }
551 551 mutex_exit(&ip->i_tlock);
552 552 }
553 553
554 554 /*
555 555 * Enter Transaction
556 556 *
557 557 * If the write is a rewrite there is no need to open a transaction
558 558 * if the FDSYNC flag is set and not the FSYNC. In this case just
559 559 * set the IMODACC flag to modify do the update at a later time
560 560 * thus avoiding the overhead of the logging transaction that is
561 561 * not required.
562 562 */
563 563 if (ioflag & (FSYNC|FDSYNC)) {
564 564 if (ulp) {
565 565 if (rewriteflg) {
566 566 uint_t i_flag_save;
567 567
568 568 rw_enter(&ip->i_contents, RW_READER);
569 569 mutex_enter(&ip->i_tlock);
570 570 i_flag_save = ip->i_flag;
571 571 ip->i_flag |= IUPD | ICHG;
572 572 ip->i_seq++;
573 573 ITIMES_NOLOCK(ip);
574 574 if ((i_flag_save & IMOD) == 0) {
575 575 ip->i_flag &= ~IMOD;
576 576 ip->i_flag |= IMODACC;
577 577 }
578 578 mutex_exit(&ip->i_tlock);
579 579 rw_exit(&ip->i_contents);
580 580 } else {
581 581 int terr = 0;
582 582 TRANS_BEGIN_SYNC(ufsvfsp, TOP_WRITE_SYNC, resv,
583 583 terr);
584 584 ASSERT(!terr);
585 585 }
586 586 }
587 587 } else {
588 588 if (ulp)
589 589 TRANS_BEGIN_ASYNC(ufsvfsp, TOP_WRITE, resv);
590 590 }
591 591
592 592 /*
593 593 * Write the file
594 594 */
595 595 rw_enter(&ufsvfsp->vfs_dqrwlock, RW_READER);
596 596 rw_enter(&ip->i_contents, RW_WRITER);
597 597 if ((ioflag & FAPPEND) != 0 && (ip->i_mode & IFMT) == IFREG) {
598 598 /*
599 599 * In append mode start at end of file.
600 600 */
601 601 uiop->uio_loffset = ip->i_size;
602 602 }
603 603
604 604 /*
605 605 * Mild optimisation, don't call ufs_trans_write() unless we have to
606 606 * Also, suppress file system full messages if we will retry.
607 607 */
608 608 if (retry)
609 609 ip->i_flag |= IQUIET;
610 610 if (resid) {
611 611 TRANS_WRITE(ip, uiop, ioflag, error, ulp, cr, resv, resid);
612 612 } else {
613 613 error = wrip(ip, uiop, ioflag, cr);
614 614 }
615 615 ip->i_flag &= ~IQUIET;
616 616
617 617 rw_exit(&ip->i_contents);
618 618 rw_exit(&ufsvfsp->vfs_dqrwlock);
619 619
620 620 /*
621 621 * Leave Transaction
622 622 */
623 623 if (ulp) {
624 624 if (ioflag & (FSYNC|FDSYNC)) {
625 625 if (!rewriteflg) {
626 626 int terr = 0;
627 627
628 628 TRANS_END_SYNC(ufsvfsp, terr, TOP_WRITE_SYNC,
629 629 resv);
630 630 if (error == 0)
631 631 error = terr;
632 632 }
633 633 } else {
634 634 TRANS_END_ASYNC(ufsvfsp, TOP_WRITE, resv);
635 635 }
636 636 ufs_lockfs_end(ulp);
637 637 }
638 638 out:
639 639 if ((error == ENOSPC) && retry && TRANS_ISTRANS(ufsvfsp)) {
640 640 /*
641 641 * Any blocks tied up in pending deletes?
642 642 */
643 643 ufs_delete_drain_wait(ufsvfsp, 1);
644 644 retry = 0;
645 645 goto retry_mandlock;
646 646 }
647 647
648 648 if (error == ENOSPC && (start_resid != uiop->uio_resid))
649 649 error = 0;
650 650
651 651 return (error);
652 652 }
653 653
654 654 /*
655 655 * Don't cache write blocks to files with the sticky bit set.
656 656 * Used to keep swap files from blowing the page cache on a server.
657 657 */
658 658 int stickyhack = 1;
659 659
660 660 /*
661 661 * Free behind hacks. The pager is busted.
662 662 * XXX - need to pass the information down to writedone() in a flag like B_SEQ
663 663 * or B_FREE_IF_TIGHT_ON_MEMORY.
664 664 */
665 665 int freebehind = 1;
666 666 int smallfile = 0;
667 667 u_offset_t smallfile64 = 32 * 1024;
668 668
669 669 /*
670 670 * While we should, in most cases, cache the pages for write, we
671 671 * may also want to cache the pages for read as long as they are
672 672 * frequently re-usable.
673 673 *
674 674 * If cache_read_ahead = 1, the pages for read will go to the tail
675 675 * of the cache list when they are released, otherwise go to the head.
676 676 */
677 677 int cache_read_ahead = 0;
678 678
679 679 /*
680 680 * Freebehind exists so that as we read large files sequentially we
681 681 * don't consume most of memory with pages from a few files. It takes
682 682 * longer to re-read from disk multiple small files as it does reading
683 683 * one large one sequentially. As system memory grows customers need
684 684 * to retain bigger chunks of files in memory. The advent of the
685 685 * cachelist opens up of the possibility freeing pages to the head or
686 686 * tail of the list.
687 687 *
688 688 * Not freeing a page is a bet that the page will be read again before
689 689 * it's segmap slot is needed for something else. If we loose the bet,
690 690 * it means some other thread is burdened with the page free we did
691 691 * not do. If we win we save a free and reclaim.
692 692 *
693 693 * Freeing it at the tail vs the head of cachelist is a bet that the
694 694 * page will survive until the next read. It's also saying that this
695 695 * page is more likely to be re-used than a page freed some time ago
696 696 * and never reclaimed.
697 697 *
698 698 * Freebehind maintains a range of file offset [smallfile1; smallfile2]
699 699 *
700 700 * 0 < offset < smallfile1 : pages are not freed.
701 701 * smallfile1 < offset < smallfile2 : pages freed to tail of cachelist.
702 702 * smallfile2 < offset : pages freed to head of cachelist.
703 703 *
704 704 * The range is computed at most once per second and depends on
705 705 * freemem and ncpus_online. Both parameters are bounded to be
706 706 * >= smallfile && >= smallfile64.
707 707 *
708 708 * smallfile1 = (free memory / ncpu) / 1000
709 709 * smallfile2 = (free memory / ncpu) / 10
710 710 *
711 711 * A few examples values:
712 712 *
713 713 * Free Mem (in Bytes) [smallfile1; smallfile2] [smallfile1; smallfile2]
714 714 * ncpus_online = 4 ncpus_online = 64
715 715 * ------------------ ----------------------- -----------------------
716 716 * 1G [256K; 25M] [32K; 1.5M]
717 717 * 10G [2.5M; 250M] [156K; 15M]
718 718 * 100G [25M; 2.5G] [1.5M; 150M]
719 719 *
720 720 */
721 721
722 722 #define SMALLFILE1_D 1000
723 723 #define SMALLFILE2_D 10
724 724 static u_offset_t smallfile1 = 32 * 1024;
725 725 static u_offset_t smallfile2 = 32 * 1024;
726 726 static clock_t smallfile_update = 0; /* lbolt value of when to recompute */
727 727 uint_t smallfile1_d = SMALLFILE1_D;
728 728 uint_t smallfile2_d = SMALLFILE2_D;
729 729
730 730 /*
731 731 * wrip does the real work of write requests for ufs.
732 732 */
733 733 int
734 734 wrip(struct inode *ip, struct uio *uio, int ioflag, struct cred *cr)
735 735 {
736 736 rlim64_t limit = uio->uio_llimit;
737 737 u_offset_t off;
738 738 u_offset_t old_i_size;
739 739 struct fs *fs;
740 740 struct vnode *vp;
741 741 struct ufsvfs *ufsvfsp;
742 742 caddr_t base;
743 743 long start_resid = uio->uio_resid; /* save starting resid */
744 744 long premove_resid; /* resid before uiomove() */
745 745 uint_t flags;
746 746 int newpage;
747 747 int iupdat_flag, directio_status;
748 748 int n, on, mapon;
749 749 int error, pagecreate;
750 750 int do_dqrwlock; /* drop/reacquire vfs_dqrwlock */
751 751 int32_t iblocks;
752 752 int new_iblocks;
753 753
754 754 /*
755 755 * ip->i_size is incremented before the uiomove
756 756 * is done on a write. If the move fails (bad user
757 757 * address) reset ip->i_size.
758 758 * The better way would be to increment ip->i_size
759 759 * only if the uiomove succeeds.
760 760 */
761 761 int i_size_changed = 0;
762 762 o_mode_t type;
763 763 int i_seq_needed = 0;
764 764
765 765 vp = ITOV(ip);
766 766
767 767 /*
768 768 * check for forced unmount - should not happen as
769 769 * the request passed the lockfs checks.
770 770 */
771 771 if ((ufsvfsp = ip->i_ufsvfs) == NULL)
772 772 return (EIO);
773 773
774 774 fs = ip->i_fs;
775 775
776 776 ASSERT(RW_WRITE_HELD(&ip->i_contents));
777 777
778 778 /* check for valid filetype */
779 779 type = ip->i_mode & IFMT;
780 780 if ((type != IFREG) && (type != IFDIR) && (type != IFATTRDIR) &&
781 781 (type != IFLNK) && (type != IFSHAD)) {
782 782 return (EIO);
783 783 }
784 784
785 785 /*
786 786 * the actual limit of UFS file size
787 787 * is UFS_MAXOFFSET_T
788 788 */
789 789 if (limit == RLIM64_INFINITY || limit > MAXOFFSET_T)
790 790 limit = MAXOFFSET_T;
791 791
792 792 if (uio->uio_loffset >= limit) {
793 793 proc_t *p = ttoproc(curthread);
794 794
795 795 mutex_enter(&p->p_lock);
796 796 (void) rctl_action(rctlproc_legacy[RLIMIT_FSIZE], p->p_rctls,
797 797 p, RCA_UNSAFE_SIGINFO);
798 798 mutex_exit(&p->p_lock);
799 799 return (EFBIG);
800 800 }
801 801
802 802 /*
803 803 * if largefiles are disallowed, the limit is
804 804 * the pre-largefiles value of 2GB
805 805 */
806 806 if (ufsvfsp->vfs_lfflags & UFS_LARGEFILES)
807 807 limit = MIN(UFS_MAXOFFSET_T, limit);
808 808 else
809 809 limit = MIN(MAXOFF32_T, limit);
810 810
811 811 if (uio->uio_loffset < (offset_t)0) {
812 812 return (EINVAL);
813 813 }
814 814 if (uio->uio_resid == 0) {
815 815 return (0);
816 816 }
817 817
818 818 if (uio->uio_loffset >= limit)
819 819 return (EFBIG);
820 820
821 821 ip->i_flag |= INOACC; /* don't update ref time in getpage */
822 822
823 823 if (ioflag & (FSYNC|FDSYNC)) {
824 824 ip->i_flag |= ISYNC;
825 825 iupdat_flag = 1;
826 826 }
827 827 /*
828 828 * Try to go direct
829 829 */
830 830 if (ip->i_flag & IDIRECTIO || ufsvfsp->vfs_forcedirectio) {
831 831 uio->uio_llimit = limit;
832 832 error = ufs_directio_write(ip, uio, ioflag, 0, cr,
833 833 &directio_status);
834 834 /*
835 835 * If ufs_directio wrote to the file or set the flags,
836 836 * we need to update i_seq, but it may be deferred.
837 837 */
838 838 if (start_resid != uio->uio_resid ||
839 839 (ip->i_flag & (ICHG|IUPD))) {
840 840 i_seq_needed = 1;
841 841 ip->i_flag |= ISEQ;
842 842 }
843 843 if (directio_status == DIRECTIO_SUCCESS)
844 844 goto out;
845 845 }
846 846
847 847 /*
848 848 * Behavior with respect to dropping/reacquiring vfs_dqrwlock:
849 849 *
850 850 * o shadow inodes: vfs_dqrwlock is not held at all
851 851 * o quota updates: vfs_dqrwlock is read or write held
852 852 * o other updates: vfs_dqrwlock is read held
853 853 *
854 854 * The first case is the only one where we do not hold
855 855 * vfs_dqrwlock at all while entering wrip().
856 856 * We must make sure not to downgrade/drop vfs_dqrwlock if we
857 857 * have it as writer, i.e. if we are updating the quota inode.
858 858 * There is no potential deadlock scenario in this case as
859 859 * ufs_getpage() takes care of this and avoids reacquiring
860 860 * vfs_dqrwlock in that case.
861 861 *
862 862 * This check is done here since the above conditions do not change
863 863 * and we possibly loop below, so save a few cycles.
864 864 */
865 865 if ((type == IFSHAD) ||
866 866 (rw_owner(&ufsvfsp->vfs_dqrwlock) == curthread)) {
867 867 do_dqrwlock = 0;
868 868 } else {
869 869 do_dqrwlock = 1;
870 870 }
871 871
872 872 /*
873 873 * Large Files: We cast MAXBMASK to offset_t
874 874 * inorder to mask out the higher bits. Since offset_t
875 875 * is a signed value, the high order bit set in MAXBMASK
876 876 * value makes it do the right thing by having all bits 1
877 877 * in the higher word. May be removed for _SOLARIS64_.
878 878 */
879 879
880 880 fs = ip->i_fs;
881 881 do {
882 882 u_offset_t uoff = uio->uio_loffset;
883 883 off = uoff & (offset_t)MAXBMASK;
884 884 mapon = (int)(uoff & (offset_t)MAXBOFFSET);
885 885 on = (int)blkoff(fs, uoff);
886 886 n = (int)MIN(fs->fs_bsize - on, uio->uio_resid);
887 887 new_iblocks = 1;
888 888
889 889 if (type == IFREG && uoff + n >= limit) {
890 890 if (uoff >= limit) {
891 891 error = EFBIG;
892 892 goto out;
893 893 }
894 894 /*
895 895 * since uoff + n >= limit,
896 896 * therefore n >= limit - uoff, and n is an int
897 897 * so it is safe to cast it to an int
898 898 */
899 899 n = (int)(limit - (rlim64_t)uoff);
900 900 }
901 901 if (uoff + n > ip->i_size) {
902 902 /*
903 903 * We are extending the length of the file.
904 904 * bmap is used so that we are sure that
905 905 * if we need to allocate new blocks, that it
906 906 * is done here before we up the file size.
907 907 */
908 908 error = bmap_write(ip, uoff, (int)(on + n),
909 909 mapon == 0, NULL, cr);
910 910 /*
911 911 * bmap_write never drops i_contents so if
912 912 * the flags are set it changed the file.
913 913 */
914 914 if (ip->i_flag & (ICHG|IUPD)) {
915 915 i_seq_needed = 1;
916 916 ip->i_flag |= ISEQ;
917 917 }
918 918 if (error)
919 919 break;
920 920 /*
921 921 * There is a window of vulnerability here.
922 922 * The sequence of operations: allocate file
923 923 * system blocks, uiomove the data into pages,
924 924 * and then update the size of the file in the
925 925 * inode, must happen atomically. However, due
926 926 * to current locking constraints, this can not
927 927 * be done.
928 928 */
929 929 ASSERT(ip->i_writer == NULL);
930 930 ip->i_writer = curthread;
931 931 i_size_changed = 1;
932 932 /*
933 933 * If we are writing from the beginning of
934 934 * the mapping, we can just create the
935 935 * pages without having to read them.
936 936 */
937 937 pagecreate = (mapon == 0);
938 938 } else if (n == MAXBSIZE) {
939 939 /*
940 940 * Going to do a whole mappings worth,
941 941 * so we can just create the pages w/o
942 942 * having to read them in. But before
943 943 * we do that, we need to make sure any
944 944 * needed blocks are allocated first.
945 945 */
946 946 iblocks = ip->i_blocks;
947 947 error = bmap_write(ip, uoff, (int)(on + n),
948 948 BI_ALLOC_ONLY, NULL, cr);
949 949 /*
950 950 * bmap_write never drops i_contents so if
951 951 * the flags are set it changed the file.
952 952 */
953 953 if (ip->i_flag & (ICHG|IUPD)) {
954 954 i_seq_needed = 1;
955 955 ip->i_flag |= ISEQ;
956 956 }
957 957 if (error)
958 958 break;
959 959 pagecreate = 1;
960 960 /*
961 961 * check if the new created page needed the
962 962 * allocation of new disk blocks.
963 963 */
964 964 if (iblocks == ip->i_blocks)
965 965 new_iblocks = 0; /* no new blocks allocated */
966 966 } else {
967 967 pagecreate = 0;
968 968 /*
969 969 * In sync mode flush the indirect blocks which
970 970 * may have been allocated and not written on
971 971 * disk. In above cases bmap_write will allocate
972 972 * in sync mode.
973 973 */
974 974 if (ioflag & (FSYNC|FDSYNC)) {
975 975 error = ufs_indirblk_sync(ip, uoff);
976 976 if (error)
977 977 break;
978 978 }
979 979 }
980 980
981 981 /*
982 982 * At this point we can enter ufs_getpage() in one
983 983 * of two ways:
984 984 * 1) segmap_getmapflt() calls ufs_getpage() when the
985 985 * forcefault parameter is true (pagecreate == 0)
986 986 * 2) uiomove() causes a page fault.
987 987 *
988 988 * We have to drop the contents lock to prevent the VM
989 989 * system from trying to reacquire it in ufs_getpage()
990 990 * should the uiomove cause a pagefault.
991 991 *
992 992 * We have to drop the reader vfs_dqrwlock here as well.
993 993 */
994 994 rw_exit(&ip->i_contents);
995 995 if (do_dqrwlock) {
996 996 ASSERT(RW_LOCK_HELD(&ufsvfsp->vfs_dqrwlock));
997 997 ASSERT(!(RW_WRITE_HELD(&ufsvfsp->vfs_dqrwlock)));
998 998 rw_exit(&ufsvfsp->vfs_dqrwlock);
999 999 }
1000 1000
1001 1001 newpage = 0;
1002 1002 premove_resid = uio->uio_resid;
1003 1003
1004 1004 /*
1005 1005 * Touch the page and fault it in if it is not in core
1006 1006 * before segmap_getmapflt or vpm_data_copy can lock it.
1007 1007 * This is to avoid the deadlock if the buffer is mapped
1008 1008 * to the same file through mmap which we want to write.
1009 1009 */
1010 1010 uio_prefaultpages((long)n, uio);
1011 1011
1012 1012 if (vpm_enable) {
1013 1013 /*
1014 1014 * Copy data. If new pages are created, part of
1015 1015 * the page that is not written will be initizliazed
1016 1016 * with zeros.
1017 1017 */
1018 1018 error = vpm_data_copy(vp, (off + mapon), (uint_t)n,
1019 1019 uio, !pagecreate, &newpage, 0, S_WRITE);
1020 1020 } else {
1021 1021
1022 1022 base = segmap_getmapflt(segkmap, vp, (off + mapon),
1023 1023 (uint_t)n, !pagecreate, S_WRITE);
1024 1024
1025 1025 /*
1026 1026 * segmap_pagecreate() returns 1 if it calls
1027 1027 * page_create_va() to allocate any pages.
1028 1028 */
1029 1029
1030 1030 if (pagecreate)
1031 1031 newpage = segmap_pagecreate(segkmap, base,
1032 1032 (size_t)n, 0);
1033 1033
1034 1034 error = uiomove(base + mapon, (long)n, UIO_WRITE, uio);
1035 1035 }
1036 1036
1037 1037 /*
1038 1038 * If "newpage" is set, then a new page was created and it
1039 1039 * does not contain valid data, so it needs to be initialized
1040 1040 * at this point.
1041 1041 * Otherwise the page contains old data, which was overwritten
1042 1042 * partially or as a whole in uiomove.
1043 1043 * If there is only one iovec structure within uio, then
1044 1044 * on error uiomove will not be able to update uio->uio_loffset
1045 1045 * and we would zero the whole page here!
1046 1046 *
1047 1047 * If uiomove fails because of an error, the old valid data
1048 1048 * is kept instead of filling the rest of the page with zero's.
1049 1049 */
1050 1050 if (!vpm_enable && newpage &&
1051 1051 uio->uio_loffset < roundup(off + mapon + n, PAGESIZE)) {
1052 1052 /*
1053 1053 * We created pages w/o initializing them completely,
1054 1054 * thus we need to zero the part that wasn't set up.
1055 1055 * This happens on most EOF write cases and if
1056 1056 * we had some sort of error during the uiomove.
1057 1057 */
1058 1058 int nzero, nmoved;
1059 1059
1060 1060 nmoved = (int)(uio->uio_loffset - (off + mapon));
1061 1061 ASSERT(nmoved >= 0 && nmoved <= n);
1062 1062 nzero = roundup(on + n, PAGESIZE) - nmoved;
1063 1063 ASSERT(nzero > 0 && mapon + nmoved + nzero <= MAXBSIZE);
1064 1064 (void) kzero(base + mapon + nmoved, (uint_t)nzero);
1065 1065 }
1066 1066
1067 1067 /*
1068 1068 * Unlock the pages allocated by page_create_va()
1069 1069 * in segmap_pagecreate()
1070 1070 */
1071 1071 if (!vpm_enable && newpage)
1072 1072 segmap_pageunlock(segkmap, base, (size_t)n, S_WRITE);
1073 1073
1074 1074 /*
1075 1075 * If the size of the file changed, then update the
1076 1076 * size field in the inode now. This can't be done
1077 1077 * before the call to segmap_pageunlock or there is
1078 1078 * a potential deadlock with callers to ufs_putpage().
1079 1079 * They will be holding i_contents and trying to lock
1080 1080 * a page, while this thread is holding a page locked
1081 1081 * and trying to acquire i_contents.
1082 1082 */
1083 1083 if (i_size_changed) {
1084 1084 rw_enter(&ip->i_contents, RW_WRITER);
1085 1085 old_i_size = ip->i_size;
1086 1086 UFS_SET_ISIZE(uoff + n, ip);
1087 1087 TRANS_INODE(ufsvfsp, ip);
1088 1088 /*
1089 1089 * file has grown larger than 2GB. Set flag
1090 1090 * in superblock to indicate this, if it
1091 1091 * is not already set.
1092 1092 */
1093 1093 if ((ip->i_size > MAXOFF32_T) &&
1094 1094 !(fs->fs_flags & FSLARGEFILES)) {
1095 1095 ASSERT(ufsvfsp->vfs_lfflags & UFS_LARGEFILES);
1096 1096 mutex_enter(&ufsvfsp->vfs_lock);
1097 1097 fs->fs_flags |= FSLARGEFILES;
1098 1098 ufs_sbwrite(ufsvfsp);
1099 1099 mutex_exit(&ufsvfsp->vfs_lock);
1100 1100 }
1101 1101 mutex_enter(&ip->i_tlock);
1102 1102 ip->i_writer = NULL;
1103 1103 cv_broadcast(&ip->i_wrcv);
1104 1104 mutex_exit(&ip->i_tlock);
1105 1105 rw_exit(&ip->i_contents);
1106 1106 }
1107 1107
1108 1108 if (error) {
1109 1109 /*
1110 1110 * If we failed on a write, we may have already
1111 1111 * allocated file blocks as well as pages. It's
1112 1112 * hard to undo the block allocation, but we must
1113 1113 * be sure to invalidate any pages that may have
1114 1114 * been allocated.
1115 1115 *
1116 1116 * If the page was created without initialization
1117 1117 * then we must check if it should be possible
1118 1118 * to destroy the new page and to keep the old data
1119 1119 * on the disk.
1120 1120 *
1121 1121 * It is possible to destroy the page without
1122 1122 * having to write back its contents only when
1123 1123 * - the size of the file keeps unchanged
1124 1124 * - bmap_write() did not allocate new disk blocks
1125 1125 * it is possible to create big files using "seek" and
1126 1126 * write to the end of the file. A "write" to a
1127 1127 * position before the end of the file would not
1128 1128 * change the size of the file but it would allocate
1129 1129 * new disk blocks.
1130 1130 * - uiomove intended to overwrite the whole page.
1131 1131 * - a new page was created (newpage == 1).
1132 1132 */
1133 1133
1134 1134 if (i_size_changed == 0 && new_iblocks == 0 &&
1135 1135 newpage) {
1136 1136
1137 1137 /* unwind what uiomove eventually last did */
1138 1138 uio->uio_resid = premove_resid;
1139 1139
1140 1140 /*
1141 1141 * destroy the page, do not write ambiguous
1142 1142 * data to the disk.
1143 1143 */
1144 1144 flags = SM_DESTROY;
1145 1145 } else {
1146 1146 /*
1147 1147 * write the page back to the disk, if dirty,
1148 1148 * and remove the page from the cache.
1149 1149 */
1150 1150 flags = SM_INVAL;
1151 1151 }
1152 1152
1153 1153 if (vpm_enable) {
1154 1154 /*
1155 1155 * Flush pages.
1156 1156 */
1157 1157 (void) vpm_sync_pages(vp, off, n, flags);
1158 1158 } else {
1159 1159 (void) segmap_release(segkmap, base, flags);
1160 1160 }
1161 1161 } else {
1162 1162 flags = 0;
1163 1163 /*
1164 1164 * Force write back for synchronous write cases.
1165 1165 */
1166 1166 if ((ioflag & (FSYNC|FDSYNC)) || type == IFDIR) {
1167 1167 /*
1168 1168 * If the sticky bit is set but the
1169 1169 * execute bit is not set, we do a
1170 1170 * synchronous write back and free
1171 1171 * the page when done. We set up swap
1172 1172 * files to be handled this way to
1173 1173 * prevent servers from keeping around
1174 1174 * the client's swap pages too long.
1175 1175 * XXX - there ought to be a better way.
1176 1176 */
1177 1177 if (IS_SWAPVP(vp)) {
1178 1178 flags = SM_WRITE | SM_FREE |
1179 1179 SM_DONTNEED;
1180 1180 iupdat_flag = 0;
1181 1181 } else {
1182 1182 flags = SM_WRITE;
1183 1183 }
1184 1184 } else if (n + on == MAXBSIZE || IS_SWAPVP(vp)) {
1185 1185 /*
1186 1186 * Have written a whole block.
1187 1187 * Start an asynchronous write and
1188 1188 * mark the buffer to indicate that
1189 1189 * it won't be needed again soon.
1190 1190 */
1191 1191 flags = SM_WRITE | SM_ASYNC | SM_DONTNEED;
1192 1192 }
1193 1193 if (vpm_enable) {
1194 1194 /*
1195 1195 * Flush pages.
1196 1196 */
1197 1197 error = vpm_sync_pages(vp, off, n, flags);
1198 1198 } else {
1199 1199 error = segmap_release(segkmap, base, flags);
1200 1200 }
1201 1201 /*
1202 1202 * If the operation failed and is synchronous,
1203 1203 * then we need to unwind what uiomove() last
1204 1204 * did so we can potentially return an error to
1205 1205 * the caller. If this write operation was
1206 1206 * done in two pieces and the first succeeded,
1207 1207 * then we won't return an error for the second
1208 1208 * piece that failed. However, we only want to
1209 1209 * return a resid value that reflects what was
1210 1210 * really done.
1211 1211 *
1212 1212 * Failures for non-synchronous operations can
1213 1213 * be ignored since the page subsystem will
1214 1214 * retry the operation until it succeeds or the
1215 1215 * file system is unmounted.
1216 1216 */
1217 1217 if (error) {
1218 1218 if ((ioflag & (FSYNC | FDSYNC)) ||
1219 1219 type == IFDIR) {
1220 1220 uio->uio_resid = premove_resid;
1221 1221 } else {
1222 1222 error = 0;
1223 1223 }
1224 1224 }
1225 1225 }
1226 1226
1227 1227 /*
1228 1228 * Re-acquire contents lock.
1229 1229 * If it was dropped, reacquire reader vfs_dqrwlock as well.
1230 1230 */
1231 1231 if (do_dqrwlock)
1232 1232 rw_enter(&ufsvfsp->vfs_dqrwlock, RW_READER);
1233 1233 rw_enter(&ip->i_contents, RW_WRITER);
1234 1234
1235 1235 /*
1236 1236 * If the uiomove() failed or if a synchronous
1237 1237 * page push failed, fix up i_size.
1238 1238 */
1239 1239 if (error) {
1240 1240 if (i_size_changed) {
1241 1241 /*
1242 1242 * The uiomove failed, and we
1243 1243 * allocated blocks,so get rid
1244 1244 * of them.
1245 1245 */
1246 1246 (void) ufs_itrunc(ip, old_i_size, 0, cr);
1247 1247 }
1248 1248 } else {
1249 1249 /*
1250 1250 * XXX - Can this be out of the loop?
1251 1251 */
1252 1252 ip->i_flag |= IUPD | ICHG;
1253 1253 /*
1254 1254 * Only do one increase of i_seq for multiple
1255 1255 * pieces. Because we drop locks, record
1256 1256 * the fact that we changed the timestamp and
1257 1257 * are deferring the increase in case another thread
1258 1258 * pushes our timestamp update.
1259 1259 */
1260 1260 i_seq_needed = 1;
1261 1261 ip->i_flag |= ISEQ;
1262 1262 if (i_size_changed)
1263 1263 ip->i_flag |= IATTCHG;
1264 1264 if ((ip->i_mode & (IEXEC | (IEXEC >> 3) |
1265 1265 (IEXEC >> 6))) != 0 &&
1266 1266 (ip->i_mode & (ISUID | ISGID)) != 0 &&
1267 1267 secpolicy_vnode_setid_retain(cr,
1268 1268 (ip->i_mode & ISUID) != 0 && ip->i_uid == 0) != 0) {
1269 1269 /*
1270 1270 * Clear Set-UID & Set-GID bits on
1271 1271 * successful write if not privileged
1272 1272 * and at least one of the execute bits
1273 1273 * is set. If we always clear Set-GID,
1274 1274 * mandatory file and record locking is
1275 1275 * unuseable.
1276 1276 */
1277 1277 ip->i_mode &= ~(ISUID | ISGID);
1278 1278 }
1279 1279 }
1280 1280 /*
1281 1281 * In the case the FDSYNC flag is set and this is a
1282 1282 * "rewrite" we won't log a delta.
1283 1283 * The FSYNC flag overrides all cases.
1284 1284 */
1285 1285 if (!ufs_check_rewrite(ip, uio, ioflag) || !(ioflag & FDSYNC)) {
1286 1286 TRANS_INODE(ufsvfsp, ip);
1287 1287 }
1288 1288 } while (error == 0 && uio->uio_resid > 0 && n != 0);
1289 1289
1290 1290 out:
1291 1291 /*
1292 1292 * Make sure i_seq is increased at least once per write
1293 1293 */
1294 1294 if (i_seq_needed) {
1295 1295 ip->i_seq++;
1296 1296 ip->i_flag &= ~ISEQ; /* no longer deferred */
1297 1297 }
1298 1298
1299 1299 /*
1300 1300 * Inode is updated according to this table -
1301 1301 *
1302 1302 * FSYNC FDSYNC(posix.4)
1303 1303 * --------------------------
1304 1304 * always@ IATTCHG|IBDWRITE
1305 1305 *
1306 1306 * @ - If we are doing synchronous write the only time we should
1307 1307 * not be sync'ing the ip here is if we have the stickyhack
1308 1308 * activated, the file is marked with the sticky bit and
1309 1309 * no exec bit, the file length has not been changed and
1310 1310 * no new blocks have been allocated during this write.
1311 1311 */
1312 1312
1313 1313 if ((ip->i_flag & ISYNC) != 0) {
1314 1314 /*
1315 1315 * we have eliminated nosync
1316 1316 */
1317 1317 if ((ip->i_flag & (IATTCHG|IBDWRITE)) ||
1318 1318 ((ioflag & FSYNC) && iupdat_flag)) {
1319 1319 ufs_iupdat(ip, 1);
1320 1320 }
1321 1321 }
1322 1322
1323 1323 /*
1324 1324 * If we've already done a partial-write, terminate
1325 1325 * the write but return no error unless the error is ENOSPC
1326 1326 * because the caller can detect this and free resources and
1327 1327 * try again.
1328 1328 */
1329 1329 if ((start_resid != uio->uio_resid) && (error != ENOSPC))
1330 1330 error = 0;
1331 1331
1332 1332 ip->i_flag &= ~(INOACC | ISYNC);
1333 1333 ITIMES_NOLOCK(ip);
1334 1334 return (error);
1335 1335 }
1336 1336
1337 1337 /*
1338 1338 * rdip does the real work of read requests for ufs.
1339 1339 */
1340 1340 int
1341 1341 rdip(struct inode *ip, struct uio *uio, int ioflag, cred_t *cr)
1342 1342 {
1343 1343 u_offset_t off;
1344 1344 caddr_t base;
1345 1345 struct fs *fs;
1346 1346 struct ufsvfs *ufsvfsp;
1347 1347 struct vnode *vp;
1348 1348 long oresid = uio->uio_resid;
1349 1349 u_offset_t n, on, mapon;
1350 1350 int error = 0;
1351 1351 int doupdate = 1;
1352 1352 uint_t flags;
1353 1353 int dofree, directio_status;
1354 1354 krw_t rwtype;
1355 1355 o_mode_t type;
1356 1356 clock_t now;
1357 1357
1358 1358 vp = ITOV(ip);
1359 1359
1360 1360 ASSERT(RW_LOCK_HELD(&ip->i_contents));
1361 1361
1362 1362 ufsvfsp = ip->i_ufsvfs;
1363 1363
1364 1364 if (ufsvfsp == NULL)
1365 1365 return (EIO);
1366 1366
1367 1367 fs = ufsvfsp->vfs_fs;
1368 1368
1369 1369 /* check for valid filetype */
1370 1370 type = ip->i_mode & IFMT;
1371 1371 if ((type != IFREG) && (type != IFDIR) && (type != IFATTRDIR) &&
1372 1372 (type != IFLNK) && (type != IFSHAD)) {
1373 1373 return (EIO);
1374 1374 }
1375 1375
1376 1376 if (uio->uio_loffset > UFS_MAXOFFSET_T) {
1377 1377 error = 0;
1378 1378 goto out;
1379 1379 }
1380 1380 if (uio->uio_loffset < (offset_t)0) {
1381 1381 return (EINVAL);
1382 1382 }
1383 1383 if (uio->uio_resid == 0) {
1384 1384 return (0);
1385 1385 }
1386 1386
1387 1387 if (!ULOCKFS_IS_NOIACC(ITOUL(ip)) && (fs->fs_ronly == 0) &&
1388 1388 (!ufsvfsp->vfs_noatime)) {
1389 1389 mutex_enter(&ip->i_tlock);
1390 1390 ip->i_flag |= IACC;
1391 1391 mutex_exit(&ip->i_tlock);
1392 1392 }
1393 1393 /*
1394 1394 * Try to go direct
1395 1395 */
1396 1396 if (ip->i_flag & IDIRECTIO || ufsvfsp->vfs_forcedirectio) {
1397 1397 error = ufs_directio_read(ip, uio, cr, &directio_status);
1398 1398 if (directio_status == DIRECTIO_SUCCESS)
1399 1399 goto out;
1400 1400 }
1401 1401
1402 1402 rwtype = (rw_write_held(&ip->i_contents)?RW_WRITER:RW_READER);
1403 1403
1404 1404 do {
1405 1405 offset_t diff;
1406 1406 u_offset_t uoff = uio->uio_loffset;
1407 1407 off = uoff & (offset_t)MAXBMASK;
1408 1408 mapon = (u_offset_t)(uoff & (offset_t)MAXBOFFSET);
1409 1409 on = (u_offset_t)blkoff(fs, uoff);
1410 1410 n = MIN((u_offset_t)fs->fs_bsize - on,
1411 1411 (u_offset_t)uio->uio_resid);
1412 1412
1413 1413 diff = ip->i_size - uoff;
1414 1414
1415 1415 if (diff <= (offset_t)0) {
1416 1416 error = 0;
1417 1417 goto out;
1418 1418 }
1419 1419 if (diff < (offset_t)n)
1420 1420 n = (int)diff;
1421 1421
1422 1422 /*
1423 1423 * We update smallfile2 and smallfile1 at most every second.
1424 1424 */
1425 1425 now = ddi_get_lbolt();
1426 1426 if (now >= smallfile_update) {
1427 1427 uint64_t percpufreeb;
1428 1428 if (smallfile1_d == 0) smallfile1_d = SMALLFILE1_D;
1429 1429 if (smallfile2_d == 0) smallfile2_d = SMALLFILE2_D;
1430 1430 percpufreeb = ptob((uint64_t)freemem) / ncpus_online;
1431 1431 smallfile1 = percpufreeb / smallfile1_d;
1432 1432 smallfile2 = percpufreeb / smallfile2_d;
1433 1433 smallfile1 = MAX(smallfile1, smallfile);
1434 1434 smallfile1 = MAX(smallfile1, smallfile64);
1435 1435 smallfile2 = MAX(smallfile1, smallfile2);
1436 1436 smallfile_update = now + hz;
1437 1437 }
1438 1438
1439 1439 dofree = freebehind &&
1440 1440 ip->i_nextr == (off & PAGEMASK) && off > smallfile1;
1441 1441
1442 1442 /*
1443 1443 * At this point we can enter ufs_getpage() in one of two
1444 1444 * ways:
1445 1445 * 1) segmap_getmapflt() calls ufs_getpage() when the
1446 1446 * forcefault parameter is true (value of 1 is passed)
1447 1447 * 2) uiomove() causes a page fault.
1448 1448 *
1449 1449 * We cannot hold onto an i_contents reader lock without
1450 1450 * risking deadlock in ufs_getpage() so drop a reader lock.
1451 1451 * The ufs_getpage() dolock logic already allows for a
1452 1452 * thread holding i_contents as writer to work properly
1453 1453 * so we keep a writer lock.
1454 1454 */
1455 1455 if (rwtype == RW_READER)
1456 1456 rw_exit(&ip->i_contents);
1457 1457
1458 1458 if (vpm_enable) {
1459 1459 /*
1460 1460 * Copy data.
1461 1461 */
1462 1462 error = vpm_data_copy(vp, (off + mapon), (uint_t)n,
1463 1463 uio, 1, NULL, 0, S_READ);
1464 1464 } else {
1465 1465 base = segmap_getmapflt(segkmap, vp, (off + mapon),
1466 1466 (uint_t)n, 1, S_READ);
1467 1467 error = uiomove(base + mapon, (long)n, UIO_READ, uio);
1468 1468 }
1469 1469
1470 1470 flags = 0;
1471 1471 if (!error) {
1472 1472 /*
1473 1473 * If reading sequential we won't need this
1474 1474 * buffer again soon. For offsets in range
1475 1475 * [smallfile1, smallfile2] release the pages
1476 1476 * at the tail of the cache list, larger
1477 1477 * offsets are released at the head.
1478 1478 */
1479 1479 if (dofree) {
1480 1480 flags = SM_FREE | SM_ASYNC;
1481 1481 if ((cache_read_ahead == 0) &&
1482 1482 (off > smallfile2))
1483 1483 flags |= SM_DONTNEED;
1484 1484 }
1485 1485 /*
1486 1486 * In POSIX SYNC (FSYNC and FDSYNC) read mode,
1487 1487 * we want to make sure that the page which has
1488 1488 * been read, is written on disk if it is dirty.
1489 1489 * And corresponding indirect blocks should also
1490 1490 * be flushed out.
1491 1491 */
1492 1492 if ((ioflag & FRSYNC) && (ioflag & (FSYNC|FDSYNC))) {
1493 1493 flags &= ~SM_ASYNC;
1494 1494 flags |= SM_WRITE;
1495 1495 }
1496 1496 if (vpm_enable) {
1497 1497 error = vpm_sync_pages(vp, off, n, flags);
1498 1498 } else {
1499 1499 error = segmap_release(segkmap, base, flags);
1500 1500 }
1501 1501 } else {
1502 1502 if (vpm_enable) {
1503 1503 (void) vpm_sync_pages(vp, off, n, flags);
1504 1504 } else {
1505 1505 (void) segmap_release(segkmap, base, flags);
1506 1506 }
1507 1507 }
1508 1508
1509 1509 if (rwtype == RW_READER)
1510 1510 rw_enter(&ip->i_contents, rwtype);
1511 1511 } while (error == 0 && uio->uio_resid > 0 && n != 0);
1512 1512 out:
1513 1513 /*
1514 1514 * Inode is updated according to this table if FRSYNC is set.
1515 1515 *
1516 1516 * FSYNC FDSYNC(posix.4)
1517 1517 * --------------------------
1518 1518 * always IATTCHG|IBDWRITE
1519 1519 */
1520 1520 /*
1521 1521 * The inode is not updated if we're logging and the inode is a
1522 1522 * directory with FRSYNC, FSYNC and FDSYNC flags set.
1523 1523 */
1524 1524 if (ioflag & FRSYNC) {
1525 1525 if (TRANS_ISTRANS(ufsvfsp) && ((ip->i_mode & IFMT) == IFDIR)) {
1526 1526 doupdate = 0;
1527 1527 }
1528 1528 if (doupdate) {
1529 1529 if ((ioflag & FSYNC) ||
1530 1530 ((ioflag & FDSYNC) &&
1531 1531 (ip->i_flag & (IATTCHG|IBDWRITE)))) {
1532 1532 ufs_iupdat(ip, 1);
1533 1533 }
1534 1534 }
1535 1535 }
1536 1536 /*
1537 1537 * If we've already done a partial read, terminate
1538 1538 * the read but return no error.
1539 1539 */
1540 1540 if (oresid != uio->uio_resid)
1541 1541 error = 0;
1542 1542 ITIMES(ip);
1543 1543
1544 1544 return (error);
1545 1545 }
1546 1546
1547 1547 /* ARGSUSED */
1548 1548 static int
1549 1549 ufs_ioctl(
1550 1550 struct vnode *vp,
1551 1551 int cmd,
1552 1552 intptr_t arg,
1553 1553 int flag,
1554 1554 struct cred *cr,
1555 1555 int *rvalp,
1556 1556 caller_context_t *ct)
1557 1557 {
1558 1558 struct lockfs lockfs, lockfs_out;
1559 1559 struct ufsvfs *ufsvfsp = VTOI(vp)->i_ufsvfs;
1560 1560 char *comment, *original_comment;
1561 1561 struct fs *fs;
1562 1562 struct ulockfs *ulp;
1563 1563 offset_t off;
1564 1564 extern int maxphys;
1565 1565 int error;
1566 1566 int issync;
1567 1567 int trans_size;
1568 1568
1569 1569
1570 1570 /*
1571 1571 * forcibly unmounted
1572 1572 */
1573 1573 if (ufsvfsp == NULL || vp->v_vfsp == NULL ||
1574 1574 vp->v_vfsp->vfs_flag & VFS_UNMOUNTED)
1575 1575 return (EIO);
1576 1576 fs = ufsvfsp->vfs_fs;
1577 1577
1578 1578 if (cmd == Q_QUOTACTL) {
1579 1579 error = ufs_lockfs_begin(ufsvfsp, &ulp, ULOCKFS_QUOTA_MASK);
1580 1580 if (error)
1581 1581 return (error);
1582 1582
1583 1583 if (ulp) {
1584 1584 TRANS_BEGIN_ASYNC(ufsvfsp, TOP_QUOTA,
1585 1585 TOP_SETQUOTA_SIZE(fs));
1586 1586 }
1587 1587
1588 1588 error = quotactl(vp, arg, flag, cr);
1589 1589
1590 1590 if (ulp) {
1591 1591 TRANS_END_ASYNC(ufsvfsp, TOP_QUOTA,
1592 1592 TOP_SETQUOTA_SIZE(fs));
1593 1593 ufs_lockfs_end(ulp);
1594 1594 }
1595 1595 return (error);
1596 1596 }
1597 1597
1598 1598 switch (cmd) {
1599 1599 case _FIOLFS:
1600 1600 /*
1601 1601 * file system locking
1602 1602 */
1603 1603 if (secpolicy_fs_config(cr, ufsvfsp->vfs_vfs) != 0)
1604 1604 return (EPERM);
1605 1605
1606 1606 if ((flag & DATAMODEL_MASK) == DATAMODEL_NATIVE) {
1607 1607 if (copyin((caddr_t)arg, &lockfs,
1608 1608 sizeof (struct lockfs)))
1609 1609 return (EFAULT);
1610 1610 }
1611 1611 #ifdef _SYSCALL32_IMPL
1612 1612 else {
1613 1613 struct lockfs32 lockfs32;
1614 1614 /* Translate ILP32 lockfs to LP64 lockfs */
1615 1615 if (copyin((caddr_t)arg, &lockfs32,
1616 1616 sizeof (struct lockfs32)))
1617 1617 return (EFAULT);
1618 1618 lockfs.lf_lock = (ulong_t)lockfs32.lf_lock;
1619 1619 lockfs.lf_flags = (ulong_t)lockfs32.lf_flags;
1620 1620 lockfs.lf_key = (ulong_t)lockfs32.lf_key;
1621 1621 lockfs.lf_comlen = (ulong_t)lockfs32.lf_comlen;
1622 1622 lockfs.lf_comment =
1623 1623 (caddr_t)(uintptr_t)lockfs32.lf_comment;
1624 1624 }
1625 1625 #endif /* _SYSCALL32_IMPL */
1626 1626
1627 1627 if (lockfs.lf_comlen) {
1628 1628 if (lockfs.lf_comlen > LOCKFS_MAXCOMMENTLEN)
1629 1629 return (ENAMETOOLONG);
1630 1630 comment =
1631 1631 kmem_alloc(lockfs.lf_comlen, KM_SLEEP);
1632 1632 if (copyin(lockfs.lf_comment, comment,
1633 1633 lockfs.lf_comlen)) {
1634 1634 kmem_free(comment, lockfs.lf_comlen);
1635 1635 return (EFAULT);
1636 1636 }
1637 1637 original_comment = lockfs.lf_comment;
1638 1638 lockfs.lf_comment = comment;
1639 1639 }
1640 1640 if ((error = ufs_fiolfs(vp, &lockfs, 0)) == 0) {
1641 1641 lockfs.lf_comment = original_comment;
1642 1642
1643 1643 if ((flag & DATAMODEL_MASK) ==
1644 1644 DATAMODEL_NATIVE) {
1645 1645 (void) copyout(&lockfs, (caddr_t)arg,
1646 1646 sizeof (struct lockfs));
1647 1647 }
1648 1648 #ifdef _SYSCALL32_IMPL
1649 1649 else {
1650 1650 struct lockfs32 lockfs32;
1651 1651 /* Translate LP64 to ILP32 lockfs */
1652 1652 lockfs32.lf_lock =
1653 1653 (uint32_t)lockfs.lf_lock;
1654 1654 lockfs32.lf_flags =
1655 1655 (uint32_t)lockfs.lf_flags;
1656 1656 lockfs32.lf_key =
1657 1657 (uint32_t)lockfs.lf_key;
1658 1658 lockfs32.lf_comlen =
1659 1659 (uint32_t)lockfs.lf_comlen;
1660 1660 lockfs32.lf_comment =
1661 1661 (uint32_t)(uintptr_t)
1662 1662 lockfs.lf_comment;
1663 1663 (void) copyout(&lockfs32, (caddr_t)arg,
1664 1664 sizeof (struct lockfs32));
1665 1665 }
1666 1666 #endif /* _SYSCALL32_IMPL */
1667 1667
1668 1668 } else {
1669 1669 if (lockfs.lf_comlen)
1670 1670 kmem_free(comment, lockfs.lf_comlen);
1671 1671 }
1672 1672 return (error);
1673 1673
1674 1674 case _FIOLFSS:
1675 1675 /*
1676 1676 * get file system locking status
1677 1677 */
1678 1678
1679 1679 if ((flag & DATAMODEL_MASK) == DATAMODEL_NATIVE) {
1680 1680 if (copyin((caddr_t)arg, &lockfs,
1681 1681 sizeof (struct lockfs)))
1682 1682 return (EFAULT);
1683 1683 }
1684 1684 #ifdef _SYSCALL32_IMPL
1685 1685 else {
1686 1686 struct lockfs32 lockfs32;
1687 1687 /* Translate ILP32 lockfs to LP64 lockfs */
1688 1688 if (copyin((caddr_t)arg, &lockfs32,
1689 1689 sizeof (struct lockfs32)))
1690 1690 return (EFAULT);
1691 1691 lockfs.lf_lock = (ulong_t)lockfs32.lf_lock;
1692 1692 lockfs.lf_flags = (ulong_t)lockfs32.lf_flags;
1693 1693 lockfs.lf_key = (ulong_t)lockfs32.lf_key;
1694 1694 lockfs.lf_comlen = (ulong_t)lockfs32.lf_comlen;
1695 1695 lockfs.lf_comment =
1696 1696 (caddr_t)(uintptr_t)lockfs32.lf_comment;
1697 1697 }
1698 1698 #endif /* _SYSCALL32_IMPL */
1699 1699
1700 1700 if (error = ufs_fiolfss(vp, &lockfs_out))
1701 1701 return (error);
1702 1702 lockfs.lf_lock = lockfs_out.lf_lock;
1703 1703 lockfs.lf_key = lockfs_out.lf_key;
1704 1704 lockfs.lf_flags = lockfs_out.lf_flags;
1705 1705 lockfs.lf_comlen = MIN(lockfs.lf_comlen,
1706 1706 lockfs_out.lf_comlen);
1707 1707
1708 1708 if ((flag & DATAMODEL_MASK) == DATAMODEL_NATIVE) {
1709 1709 if (copyout(&lockfs, (caddr_t)arg,
1710 1710 sizeof (struct lockfs)))
1711 1711 return (EFAULT);
1712 1712 }
1713 1713 #ifdef _SYSCALL32_IMPL
1714 1714 else {
1715 1715 /* Translate LP64 to ILP32 lockfs */
1716 1716 struct lockfs32 lockfs32;
1717 1717 lockfs32.lf_lock = (uint32_t)lockfs.lf_lock;
1718 1718 lockfs32.lf_flags = (uint32_t)lockfs.lf_flags;
1719 1719 lockfs32.lf_key = (uint32_t)lockfs.lf_key;
1720 1720 lockfs32.lf_comlen = (uint32_t)lockfs.lf_comlen;
1721 1721 lockfs32.lf_comment =
1722 1722 (uint32_t)(uintptr_t)lockfs.lf_comment;
1723 1723 if (copyout(&lockfs32, (caddr_t)arg,
1724 1724 sizeof (struct lockfs32)))
1725 1725 return (EFAULT);
1726 1726 }
1727 1727 #endif /* _SYSCALL32_IMPL */
1728 1728
1729 1729 if (lockfs.lf_comlen &&
1730 1730 lockfs.lf_comment && lockfs_out.lf_comment)
1731 1731 if (copyout(lockfs_out.lf_comment,
1732 1732 lockfs.lf_comment, lockfs.lf_comlen))
1733 1733 return (EFAULT);
1734 1734 return (0);
1735 1735
1736 1736 case _FIOSATIME:
1737 1737 /*
1738 1738 * set access time
1739 1739 */
1740 1740
1741 1741 /*
1742 1742 * if mounted w/o atime, return quietly.
1743 1743 * I briefly thought about returning ENOSYS, but
1744 1744 * figured that most apps would consider this fatal
1745 1745 * but the idea is to make this as seamless as poss.
1746 1746 */
1747 1747 if (ufsvfsp->vfs_noatime)
1748 1748 return (0);
1749 1749
1750 1750 error = ufs_lockfs_begin(ufsvfsp, &ulp,
1751 1751 ULOCKFS_SETATTR_MASK);
1752 1752 if (error)
1753 1753 return (error);
1754 1754
1755 1755 if (ulp) {
1756 1756 trans_size = (int)TOP_SETATTR_SIZE(VTOI(vp));
1757 1757 TRANS_BEGIN_CSYNC(ufsvfsp, issync,
1758 1758 TOP_SETATTR, trans_size);
1759 1759 }
1760 1760
1761 1761 error = ufs_fiosatime(vp, (struct timeval *)arg,
1762 1762 flag, cr);
1763 1763
1764 1764 if (ulp) {
1765 1765 TRANS_END_CSYNC(ufsvfsp, error, issync,
1766 1766 TOP_SETATTR, trans_size);
1767 1767 ufs_lockfs_end(ulp);
1768 1768 }
1769 1769 return (error);
1770 1770
1771 1771 case _FIOSDIO:
1772 1772 /*
1773 1773 * set delayed-io
1774 1774 */
1775 1775 return (ufs_fiosdio(vp, (uint_t *)arg, flag, cr));
1776 1776
1777 1777 case _FIOGDIO:
1778 1778 /*
1779 1779 * get delayed-io
1780 1780 */
1781 1781 return (ufs_fiogdio(vp, (uint_t *)arg, flag, cr));
1782 1782
1783 1783 case _FIOIO:
1784 1784 /*
1785 1785 * inode open
1786 1786 */
1787 1787 error = ufs_lockfs_begin(ufsvfsp, &ulp,
1788 1788 ULOCKFS_VGET_MASK);
1789 1789 if (error)
1790 1790 return (error);
1791 1791
1792 1792 error = ufs_fioio(vp, (struct fioio *)arg, flag, cr);
1793 1793
1794 1794 if (ulp) {
1795 1795 ufs_lockfs_end(ulp);
1796 1796 }
1797 1797 return (error);
1798 1798
1799 1799 case _FIOFFS:
1800 1800 /*
1801 1801 * file system flush (push w/invalidate)
1802 1802 */
1803 1803 if ((caddr_t)arg != NULL)
1804 1804 return (EINVAL);
1805 1805 return (ufs_fioffs(vp, NULL, cr));
1806 1806
1807 1807 case _FIOISBUSY:
1808 1808 /*
1809 1809 * Contract-private interface for Legato
1810 1810 * Purge this vnode from the DNLC and decide
1811 1811 * if this vnode is busy (*arg == 1) or not
1812 1812 * (*arg == 0)
1813 1813 */
1814 1814 if (secpolicy_fs_config(cr, ufsvfsp->vfs_vfs) != 0)
1815 1815 return (EPERM);
1816 1816 error = ufs_fioisbusy(vp, (int *)arg, cr);
1817 1817 return (error);
1818 1818
1819 1819 case _FIODIRECTIO:
1820 1820 return (ufs_fiodirectio(vp, (int)arg, cr));
1821 1821
1822 1822 case _FIOTUNE:
1823 1823 /*
1824 1824 * Tune the file system (aka setting fs attributes)
1825 1825 */
1826 1826 error = ufs_lockfs_begin(ufsvfsp, &ulp,
1827 1827 ULOCKFS_SETATTR_MASK);
1828 1828 if (error)
1829 1829 return (error);
1830 1830
1831 1831 error = ufs_fiotune(vp, (struct fiotune *)arg, cr);
1832 1832
1833 1833 if (ulp)
1834 1834 ufs_lockfs_end(ulp);
1835 1835 return (error);
1836 1836
1837 1837 case _FIOLOGENABLE:
1838 1838 if (secpolicy_fs_config(cr, ufsvfsp->vfs_vfs) != 0)
1839 1839 return (EPERM);
1840 1840 return (ufs_fiologenable(vp, (void *)arg, cr, flag));
1841 1841
1842 1842 case _FIOLOGDISABLE:
1843 1843 if (secpolicy_fs_config(cr, ufsvfsp->vfs_vfs) != 0)
1844 1844 return (EPERM);
1845 1845 return (ufs_fiologdisable(vp, (void *)arg, cr, flag));
1846 1846
1847 1847 case _FIOISLOG:
1848 1848 return (ufs_fioislog(vp, (void *)arg, cr, flag));
1849 1849
1850 1850 case _FIOSNAPSHOTCREATE_MULTI:
1851 1851 {
1852 1852 struct fiosnapcreate_multi fc, *fcp;
1853 1853 size_t fcm_size;
1854 1854
1855 1855 if (copyin((void *)arg, &fc, sizeof (fc)))
1856 1856 return (EFAULT);
1857 1857 if (fc.backfilecount > MAX_BACKFILE_COUNT)
1858 1858 return (EINVAL);
1859 1859 fcm_size = sizeof (struct fiosnapcreate_multi) +
1860 1860 (fc.backfilecount - 1) * sizeof (int);
1861 1861 fcp = (struct fiosnapcreate_multi *)
1862 1862 kmem_alloc(fcm_size, KM_SLEEP);
1863 1863 if (copyin((void *)arg, fcp, fcm_size)) {
1864 1864 kmem_free(fcp, fcm_size);
1865 1865 return (EFAULT);
1866 1866 }
1867 1867 error = ufs_snap_create(vp, fcp, cr);
1868 1868 /*
1869 1869 * Do copyout even if there is an error because
1870 1870 * the details of error is stored in fcp.
1871 1871 */
1872 1872 if (copyout(fcp, (void *)arg, fcm_size))
1873 1873 error = EFAULT;
1874 1874 kmem_free(fcp, fcm_size);
1875 1875 return (error);
1876 1876 }
1877 1877
1878 1878 case _FIOSNAPSHOTDELETE:
1879 1879 {
1880 1880 struct fiosnapdelete fc;
1881 1881
1882 1882 if (copyin((void *)arg, &fc, sizeof (fc)))
1883 1883 return (EFAULT);
1884 1884 error = ufs_snap_delete(vp, &fc, cr);
1885 1885 if (!error && copyout(&fc, (void *)arg, sizeof (fc)))
1886 1886 error = EFAULT;
1887 1887 return (error);
1888 1888 }
1889 1889
1890 1890 case _FIOGETSUPERBLOCK:
1891 1891 if (copyout(fs, (void *)arg, SBSIZE))
1892 1892 return (EFAULT);
1893 1893 return (0);
1894 1894
1895 1895 case _FIOGETMAXPHYS:
1896 1896 if (copyout(&maxphys, (void *)arg, sizeof (maxphys)))
1897 1897 return (EFAULT);
1898 1898 return (0);
1899 1899
1900 1900 /*
1901 1901 * The following 3 ioctls are for TSufs support
1902 1902 * although could potentially be used elsewhere
1903 1903 */
1904 1904 case _FIO_SET_LUFS_DEBUG:
1905 1905 if (secpolicy_fs_config(cr, ufsvfsp->vfs_vfs) != 0)
1906 1906 return (EPERM);
1907 1907 lufs_debug = (uint32_t)arg;
1908 1908 return (0);
1909 1909
1910 1910 case _FIO_SET_LUFS_ERROR:
1911 1911 if (secpolicy_fs_config(cr, ufsvfsp->vfs_vfs) != 0)
1912 1912 return (EPERM);
1913 1913 TRANS_SETERROR(ufsvfsp);
1914 1914 return (0);
1915 1915
1916 1916 case _FIO_GET_TOP_STATS:
1917 1917 {
1918 1918 fio_lufs_stats_t *ls;
1919 1919 ml_unit_t *ul = ufsvfsp->vfs_log;
1920 1920
1921 1921 ls = kmem_zalloc(sizeof (*ls), KM_SLEEP);
1922 1922 ls->ls_debug = ul->un_debug; /* return debug value */
1923 1923 /* Copy stucture if statistics are being kept */
1924 1924 if (ul->un_logmap->mtm_tops) {
1925 1925 ls->ls_topstats = *(ul->un_logmap->mtm_tops);
1926 1926 }
1927 1927 error = 0;
1928 1928 if (copyout(ls, (void *)arg, sizeof (*ls)))
1929 1929 error = EFAULT;
1930 1930 kmem_free(ls, sizeof (*ls));
1931 1931 return (error);
1932 1932 }
1933 1933
1934 1934 case _FIO_SEEK_DATA:
1935 1935 case _FIO_SEEK_HOLE:
1936 1936 if (ddi_copyin((void *)arg, &off, sizeof (off), flag))
1937 1937 return (EFAULT);
1938 1938 /* offset paramater is in/out */
1939 1939 error = ufs_fio_holey(vp, cmd, &off);
1940 1940 if (error)
1941 1941 return (error);
1942 1942 if (ddi_copyout(&off, (void *)arg, sizeof (off), flag))
1943 1943 return (EFAULT);
1944 1944 return (0);
1945 1945
1946 1946 case _FIO_COMPRESSED:
1947 1947 {
1948 1948 /*
1949 1949 * This is a project private ufs ioctl() to mark
1950 1950 * the inode as that belonging to a compressed
1951 1951 * file. This is used to mark individual
1952 1952 * compressed files in a miniroot archive.
1953 1953 * The files compressed in this manner are
1954 1954 * automatically decompressed by the dcfs filesystem
1955 1955 * (via an interception in ufs_lookup - see decompvp())
1956 1956 * which is layered on top of ufs on a system running
1957 1957 * from the archive. See uts/common/fs/dcfs for details.
1958 1958 * This ioctl only marks the file as compressed - the
1959 1959 * actual compression is done by fiocompress (a
1960 1960 * userland utility) which invokes this ioctl().
1961 1961 */
1962 1962 struct inode *ip = VTOI(vp);
1963 1963
1964 1964 error = ufs_lockfs_begin(ufsvfsp, &ulp,
1965 1965 ULOCKFS_SETATTR_MASK);
1966 1966 if (error)
1967 1967 return (error);
1968 1968
1969 1969 if (ulp) {
1970 1970 TRANS_BEGIN_ASYNC(ufsvfsp, TOP_IUPDAT,
1971 1971 TOP_IUPDAT_SIZE(ip));
1972 1972 }
1973 1973
1974 1974 error = ufs_mark_compressed(vp);
1975 1975
1976 1976 if (ulp) {
1977 1977 TRANS_END_ASYNC(ufsvfsp, TOP_IUPDAT,
1978 1978 TOP_IUPDAT_SIZE(ip));
1979 1979 ufs_lockfs_end(ulp);
1980 1980 }
1981 1981
1982 1982 return (error);
1983 1983
1984 1984 }
1985 1985
1986 1986 default:
1987 1987 return (ENOTTY);
1988 1988 }
1989 1989 }
1990 1990
1991 1991
1992 1992 /* ARGSUSED */
1993 1993 static int
1994 1994 ufs_getattr(struct vnode *vp, struct vattr *vap, int flags,
1995 1995 struct cred *cr, caller_context_t *ct)
1996 1996 {
1997 1997 struct inode *ip = VTOI(vp);
1998 1998 struct ufsvfs *ufsvfsp;
1999 1999 int err;
2000 2000
2001 2001 if (vap->va_mask == AT_SIZE) {
2002 2002 /*
2003 2003 * for performance, if only the size is requested don't bother
2004 2004 * with anything else.
2005 2005 */
2006 2006 UFS_GET_ISIZE(&vap->va_size, ip);
2007 2007 return (0);
2008 2008 }
2009 2009
2010 2010 /*
2011 2011 * inlined lockfs checks
2012 2012 */
2013 2013 ufsvfsp = ip->i_ufsvfs;
2014 2014 if ((ufsvfsp == NULL) || ULOCKFS_IS_HLOCK(&ufsvfsp->vfs_ulockfs)) {
2015 2015 err = EIO;
2016 2016 goto out;
2017 2017 }
2018 2018
2019 2019 rw_enter(&ip->i_contents, RW_READER);
2020 2020 /*
2021 2021 * Return all the attributes. This should be refined so
2022 2022 * that it only returns what's asked for.
2023 2023 */
2024 2024
2025 2025 /*
2026 2026 * Copy from inode table.
2027 2027 */
2028 2028 vap->va_type = vp->v_type;
2029 2029 vap->va_mode = ip->i_mode & MODEMASK;
2030 2030 /*
2031 2031 * If there is an ACL and there is a mask entry, then do the
2032 2032 * extra work that completes the equivalent of an acltomode(3)
2033 2033 * call. According to POSIX P1003.1e, the acl mask should be
2034 2034 * returned in the group permissions field.
2035 2035 *
2036 2036 * - start with the original permission and mode bits (from above)
2037 2037 * - clear the group owner bits
2038 2038 * - add in the mask bits.
2039 2039 */
2040 2040 if (ip->i_ufs_acl && ip->i_ufs_acl->aclass.acl_ismask) {
2041 2041 vap->va_mode &= ~((VREAD | VWRITE | VEXEC) >> 3);
2042 2042 vap->va_mode |=
2043 2043 (ip->i_ufs_acl->aclass.acl_maskbits & PERMMASK) << 3;
2044 2044 }
2045 2045 vap->va_uid = ip->i_uid;
2046 2046 vap->va_gid = ip->i_gid;
2047 2047 vap->va_fsid = ip->i_dev;
2048 2048 vap->va_nodeid = (ino64_t)ip->i_number;
2049 2049 vap->va_nlink = ip->i_nlink;
2050 2050 vap->va_size = ip->i_size;
2051 2051 if (vp->v_type == VCHR || vp->v_type == VBLK)
2052 2052 vap->va_rdev = ip->i_rdev;
2053 2053 else
2054 2054 vap->va_rdev = 0; /* not a b/c spec. */
2055 2055 mutex_enter(&ip->i_tlock);
2056 2056 ITIMES_NOLOCK(ip); /* mark correct time in inode */
2057 2057 vap->va_seq = ip->i_seq;
2058 2058 vap->va_atime.tv_sec = (time_t)ip->i_atime.tv_sec;
2059 2059 vap->va_atime.tv_nsec = ip->i_atime.tv_usec*1000;
2060 2060 vap->va_mtime.tv_sec = (time_t)ip->i_mtime.tv_sec;
2061 2061 vap->va_mtime.tv_nsec = ip->i_mtime.tv_usec*1000;
2062 2062 vap->va_ctime.tv_sec = (time_t)ip->i_ctime.tv_sec;
2063 2063 vap->va_ctime.tv_nsec = ip->i_ctime.tv_usec*1000;
2064 2064 mutex_exit(&ip->i_tlock);
2065 2065
2066 2066 switch (ip->i_mode & IFMT) {
2067 2067
2068 2068 case IFBLK:
2069 2069 vap->va_blksize = MAXBSIZE; /* was BLKDEV_IOSIZE */
2070 2070 break;
2071 2071
2072 2072 case IFCHR:
2073 2073 vap->va_blksize = MAXBSIZE;
2074 2074 break;
2075 2075
2076 2076 default:
2077 2077 vap->va_blksize = ip->i_fs->fs_bsize;
2078 2078 break;
2079 2079 }
2080 2080 vap->va_nblocks = (fsblkcnt64_t)ip->i_blocks;
2081 2081 rw_exit(&ip->i_contents);
2082 2082 err = 0;
2083 2083
2084 2084 out:
2085 2085 return (err);
2086 2086 }
2087 2087
2088 2088 /*
2089 2089 * Special wrapper to provide a callback for secpolicy_vnode_setattr().
2090 2090 * The i_contents lock is already held by the caller and we need to
2091 2091 * declare the inode as 'void *' argument.
2092 2092 */
2093 2093 static int
2094 2094 ufs_priv_access(void *vip, int mode, struct cred *cr)
2095 2095 {
2096 2096 struct inode *ip = vip;
2097 2097
2098 2098 return (ufs_iaccess(ip, mode, cr, 0));
2099 2099 }
2100 2100
2101 2101 /*ARGSUSED4*/
2102 2102 static int
2103 2103 ufs_setattr(
2104 2104 struct vnode *vp,
2105 2105 struct vattr *vap,
2106 2106 int flags,
2107 2107 struct cred *cr,
2108 2108 caller_context_t *ct)
2109 2109 {
2110 2110 struct inode *ip = VTOI(vp);
2111 2111 struct ufsvfs *ufsvfsp = ip->i_ufsvfs;
2112 2112 struct fs *fs;
2113 2113 struct ulockfs *ulp;
2114 2114 char *errmsg1;
2115 2115 char *errmsg2;
2116 2116 long blocks;
2117 2117 long int mask = vap->va_mask;
2118 2118 size_t len1, len2;
2119 2119 int issync;
2120 2120 int trans_size;
2121 2121 int dotrans;
2122 2122 int dorwlock;
2123 2123 int error;
2124 2124 int owner_change;
2125 2125 int dodqlock;
2126 2126 timestruc_t now;
2127 2127 vattr_t oldva;
2128 2128 int retry = 1;
2129 2129 int indeadlock;
2130 2130
2131 2131 /*
2132 2132 * Cannot set these attributes.
2133 2133 */
2134 2134 if ((mask & AT_NOSET) || (mask & AT_XVATTR))
2135 2135 return (EINVAL);
2136 2136
2137 2137 /*
2138 2138 * check for forced unmount
2139 2139 */
2140 2140 if (ufsvfsp == NULL)
2141 2141 return (EIO);
2142 2142
2143 2143 fs = ufsvfsp->vfs_fs;
2144 2144 if (fs->fs_ronly != 0)
2145 2145 return (EROFS);
2146 2146
2147 2147 again:
2148 2148 errmsg1 = NULL;
2149 2149 errmsg2 = NULL;
2150 2150 dotrans = 0;
2151 2151 dorwlock = 0;
2152 2152 dodqlock = 0;
2153 2153
2154 2154 error = ufs_lockfs_begin(ufsvfsp, &ulp, ULOCKFS_SETATTR_MASK);
2155 2155 if (error)
2156 2156 goto out;
2157 2157
2158 2158 /*
2159 2159 * Acquire i_rwlock before TRANS_BEGIN_CSYNC() if this is a file.
2160 2160 * This follows the protocol for read()/write().
2161 2161 */
2162 2162 if (vp->v_type != VDIR) {
2163 2163 /*
2164 2164 * ufs_tryirwlock uses rw_tryenter and checks for SLOCK to
2165 2165 * avoid i_rwlock, ufs_lockfs_begin deadlock. If deadlock
2166 2166 * possible, retries the operation.
2167 2167 */
2168 2168 ufs_tryirwlock(&ip->i_rwlock, RW_WRITER, retry_file);
2169 2169 if (indeadlock) {
2170 2170 if (ulp)
2171 2171 ufs_lockfs_end(ulp);
2172 2172 goto again;
2173 2173 }
2174 2174 dorwlock = 1;
2175 2175 }
2176 2176
2177 2177 /*
2178 2178 * Truncate file. Must have write permission and not be a directory.
2179 2179 */
2180 2180 if (mask & AT_SIZE) {
2181 2181 rw_enter(&ip->i_contents, RW_WRITER);
2182 2182 if (vp->v_type == VDIR) {
2183 2183 error = EISDIR;
2184 2184 goto update_inode;
2185 2185 }
2186 2186 if (error = ufs_iaccess(ip, IWRITE, cr, 0))
2187 2187 goto update_inode;
2188 2188
2189 2189 rw_exit(&ip->i_contents);
2190 2190 error = TRANS_ITRUNC(ip, vap->va_size, 0, cr);
2191 2191 if (error) {
2192 2192 rw_enter(&ip->i_contents, RW_WRITER);
2193 2193 goto update_inode;
2194 2194 }
2195 2195
2196 2196 if (error == 0 && vap->va_size)
2197 2197 vnevent_truncate(vp, ct);
2198 2198 }
2199 2199
2200 2200 if (ulp) {
2201 2201 trans_size = (int)TOP_SETATTR_SIZE(ip);
2202 2202 TRANS_BEGIN_CSYNC(ufsvfsp, issync, TOP_SETATTR, trans_size);
2203 2203 ++dotrans;
2204 2204 }
2205 2205
2206 2206 /*
2207 2207 * Acquire i_rwlock after TRANS_BEGIN_CSYNC() if this is a directory.
2208 2208 * This follows the protocol established by
2209 2209 * ufs_link/create/remove/rename/mkdir/rmdir/symlink.
2210 2210 */
2211 2211 if (vp->v_type == VDIR) {
2212 2212 ufs_tryirwlock_trans(&ip->i_rwlock, RW_WRITER, TOP_SETATTR,
2213 2213 retry_dir);
2214 2214 if (indeadlock)
2215 2215 goto again;
2216 2216 dorwlock = 1;
2217 2217 }
2218 2218
2219 2219 /*
2220 2220 * Grab quota lock if we are changing the file's owner.
2221 2221 */
2222 2222 if (mask & AT_UID) {
2223 2223 rw_enter(&ufsvfsp->vfs_dqrwlock, RW_READER);
2224 2224 dodqlock = 1;
2225 2225 }
2226 2226 rw_enter(&ip->i_contents, RW_WRITER);
2227 2227
2228 2228 oldva.va_mode = ip->i_mode;
2229 2229 oldva.va_uid = ip->i_uid;
2230 2230 oldva.va_gid = ip->i_gid;
2231 2231
2232 2232 vap->va_mask &= ~AT_SIZE;
2233 2233
2234 2234 error = secpolicy_vnode_setattr(cr, vp, vap, &oldva, flags,
2235 2235 ufs_priv_access, ip);
2236 2236 if (error)
2237 2237 goto update_inode;
2238 2238
2239 2239 mask = vap->va_mask;
2240 2240
2241 2241 /*
2242 2242 * Change file access modes.
2243 2243 */
2244 2244 if (mask & AT_MODE) {
2245 2245 ip->i_mode = (ip->i_mode & IFMT) | (vap->va_mode & ~IFMT);
2246 2246 TRANS_INODE(ufsvfsp, ip);
2247 2247 ip->i_flag |= ICHG;
2248 2248 if (stickyhack) {
2249 2249 mutex_enter(&vp->v_lock);
2250 2250 if ((ip->i_mode & (ISVTX | IEXEC | IFDIR)) == ISVTX)
2251 2251 vp->v_flag |= VSWAPLIKE;
2252 2252 else
2253 2253 vp->v_flag &= ~VSWAPLIKE;
2254 2254 mutex_exit(&vp->v_lock);
2255 2255 }
2256 2256 }
2257 2257 if (mask & (AT_UID|AT_GID)) {
2258 2258 if (mask & AT_UID) {
2259 2259 /*
2260 2260 * Don't change ownership of the quota inode.
2261 2261 */
2262 2262 if (ufsvfsp->vfs_qinod == ip) {
2263 2263 ASSERT(ufsvfsp->vfs_qflags & MQ_ENABLED);
2264 2264 error = EINVAL;
2265 2265 goto update_inode;
2266 2266 }
2267 2267
2268 2268 /*
2269 2269 * No real ownership change.
2270 2270 */
2271 2271 if (ip->i_uid == vap->va_uid) {
2272 2272 blocks = 0;
2273 2273 owner_change = 0;
2274 2274 }
2275 2275 /*
2276 2276 * Remove the blocks and the file, from the old user's
2277 2277 * quota.
2278 2278 */
2279 2279 else {
2280 2280 blocks = ip->i_blocks;
2281 2281 owner_change = 1;
2282 2282
2283 2283 (void) chkdq(ip, -blocks, /* force */ 1, cr,
2284 2284 (char **)NULL, (size_t *)NULL);
2285 2285 (void) chkiq(ufsvfsp, /* change */ -1, ip,
2286 2286 (uid_t)ip->i_uid, /* force */ 1, cr,
2287 2287 (char **)NULL, (size_t *)NULL);
2288 2288 dqrele(ip->i_dquot);
2289 2289 }
2290 2290
2291 2291 ip->i_uid = vap->va_uid;
2292 2292
2293 2293 /*
2294 2294 * There is a real ownership change.
2295 2295 */
2296 2296 if (owner_change) {
2297 2297 /*
2298 2298 * Add the blocks and the file to the new
2299 2299 * user's quota.
2300 2300 */
2301 2301 ip->i_dquot = getinoquota(ip);
2302 2302 (void) chkdq(ip, blocks, /* force */ 1, cr,
2303 2303 &errmsg1, &len1);
2304 2304 (void) chkiq(ufsvfsp, /* change */ 1,
2305 2305 (struct inode *)NULL, (uid_t)ip->i_uid,
2306 2306 /* force */ 1, cr, &errmsg2, &len2);
2307 2307 }
2308 2308 }
2309 2309 if (mask & AT_GID) {
2310 2310 ip->i_gid = vap->va_gid;
2311 2311 }
2312 2312 TRANS_INODE(ufsvfsp, ip);
2313 2313 ip->i_flag |= ICHG;
2314 2314 }
2315 2315 /*
2316 2316 * Change file access or modified times.
2317 2317 */
2318 2318 if (mask & (AT_ATIME|AT_MTIME)) {
2319 2319 /* Check that the time value is within ufs range */
2320 2320 if (((mask & AT_ATIME) && TIMESPEC_OVERFLOW(&vap->va_atime)) ||
2321 2321 ((mask & AT_MTIME) && TIMESPEC_OVERFLOW(&vap->va_mtime))) {
2322 2322 error = EOVERFLOW;
2323 2323 goto update_inode;
2324 2324 }
2325 2325
2326 2326 /*
2327 2327 * if the "noaccess" mount option is set and only atime
2328 2328 * update is requested, do nothing. No error is returned.
2329 2329 */
2330 2330 if ((ufsvfsp->vfs_noatime) &&
2331 2331 ((mask & (AT_ATIME|AT_MTIME)) == AT_ATIME))
2332 2332 goto skip_atime;
2333 2333
2334 2334 if (mask & AT_ATIME) {
2335 2335 ip->i_atime.tv_sec = vap->va_atime.tv_sec;
2336 2336 ip->i_atime.tv_usec = vap->va_atime.tv_nsec / 1000;
2337 2337 ip->i_flag &= ~IACC;
2338 2338 }
2339 2339 if (mask & AT_MTIME) {
2340 2340 ip->i_mtime.tv_sec = vap->va_mtime.tv_sec;
2341 2341 ip->i_mtime.tv_usec = vap->va_mtime.tv_nsec / 1000;
2342 2342 gethrestime(&now);
2343 2343 if (now.tv_sec > TIME32_MAX) {
2344 2344 /*
2345 2345 * In 2038, ctime sticks forever..
2346 2346 */
2347 2347 ip->i_ctime.tv_sec = TIME32_MAX;
2348 2348 ip->i_ctime.tv_usec = 0;
2349 2349 } else {
2350 2350 ip->i_ctime.tv_sec = now.tv_sec;
2351 2351 ip->i_ctime.tv_usec = now.tv_nsec / 1000;
2352 2352 }
2353 2353 ip->i_flag &= ~(IUPD|ICHG);
2354 2354 ip->i_flag |= IMODTIME;
2355 2355 }
2356 2356 TRANS_INODE(ufsvfsp, ip);
2357 2357 ip->i_flag |= IMOD;
2358 2358 }
2359 2359
2360 2360 skip_atime:
2361 2361 /*
2362 2362 * The presence of a shadow inode may indicate an ACL, but does
2363 2363 * not imply an ACL. Future FSD types should be handled here too
2364 2364 * and check for the presence of the attribute-specific data
2365 2365 * before referencing it.
2366 2366 */
2367 2367 if (ip->i_shadow) {
2368 2368 /*
2369 2369 * XXX if ufs_iupdat is changed to sandbagged write fix
2370 2370 * ufs_acl_setattr to push ip to keep acls consistent
2371 2371 *
2372 2372 * Suppress out of inodes messages if we will retry.
2373 2373 */
2374 2374 if (retry)
2375 2375 ip->i_flag |= IQUIET;
2376 2376 error = ufs_acl_setattr(ip, vap, cr);
2377 2377 ip->i_flag &= ~IQUIET;
2378 2378 }
2379 2379
2380 2380 update_inode:
2381 2381 /*
2382 2382 * Setattr always increases the sequence number
2383 2383 */
2384 2384 ip->i_seq++;
2385 2385
2386 2386 /*
2387 2387 * if nfsd and not logging; push synchronously
2388 2388 */
2389 2389 if ((curthread->t_flag & T_DONTPEND) && !TRANS_ISTRANS(ufsvfsp)) {
2390 2390 ufs_iupdat(ip, 1);
2391 2391 } else {
2392 2392 ITIMES_NOLOCK(ip);
2393 2393 }
2394 2394
2395 2395 rw_exit(&ip->i_contents);
2396 2396 if (dodqlock) {
2397 2397 rw_exit(&ufsvfsp->vfs_dqrwlock);
2398 2398 }
2399 2399 if (dorwlock)
2400 2400 rw_exit(&ip->i_rwlock);
2401 2401
2402 2402 if (ulp) {
2403 2403 if (dotrans) {
2404 2404 int terr = 0;
2405 2405 TRANS_END_CSYNC(ufsvfsp, terr, issync, TOP_SETATTR,
2406 2406 trans_size);
2407 2407 if (error == 0)
2408 2408 error = terr;
2409 2409 }
2410 2410 ufs_lockfs_end(ulp);
2411 2411 }
2412 2412 out:
2413 2413 /*
2414 2414 * If out of inodes or blocks, see if we can free something
2415 2415 * up from the delete queue.
2416 2416 */
2417 2417 if ((error == ENOSPC) && retry && TRANS_ISTRANS(ufsvfsp)) {
2418 2418 ufs_delete_drain_wait(ufsvfsp, 1);
2419 2419 retry = 0;
2420 2420 if (errmsg1 != NULL)
2421 2421 kmem_free(errmsg1, len1);
2422 2422 if (errmsg2 != NULL)
2423 2423 kmem_free(errmsg2, len2);
2424 2424 goto again;
2425 2425 }
2426 2426 if (errmsg1 != NULL) {
2427 2427 uprintf(errmsg1);
2428 2428 kmem_free(errmsg1, len1);
2429 2429 }
2430 2430 if (errmsg2 != NULL) {
2431 2431 uprintf(errmsg2);
2432 2432 kmem_free(errmsg2, len2);
2433 2433 }
2434 2434 return (error);
2435 2435 }
2436 2436
2437 2437 /*ARGSUSED*/
2438 2438 static int
2439 2439 ufs_access(struct vnode *vp, int mode, int flags, struct cred *cr,
2440 2440 caller_context_t *ct)
2441 2441 {
2442 2442 struct inode *ip = VTOI(vp);
2443 2443
2444 2444 if (ip->i_ufsvfs == NULL)
2445 2445 return (EIO);
2446 2446
2447 2447 /*
2448 2448 * The ufs_iaccess function wants to be called with
2449 2449 * mode bits expressed as "ufs specific" bits.
2450 2450 * I.e., VWRITE|VREAD|VEXEC do not make sense to
2451 2451 * ufs_iaccess() but IWRITE|IREAD|IEXEC do.
2452 2452 * But since they're the same we just pass the vnode mode
2453 2453 * bit but just verify that assumption at compile time.
2454 2454 */
2455 2455 #if IWRITE != VWRITE || IREAD != VREAD || IEXEC != VEXEC
2456 2456 #error "ufs_access needs to map Vmodes to Imodes"
2457 2457 #endif
2458 2458 return (ufs_iaccess(ip, mode, cr, 1));
2459 2459 }
2460 2460
2461 2461 /* ARGSUSED */
2462 2462 static int
2463 2463 ufs_readlink(struct vnode *vp, struct uio *uiop, struct cred *cr,
2464 2464 caller_context_t *ct)
2465 2465 {
2466 2466 struct inode *ip = VTOI(vp);
2467 2467 struct ufsvfs *ufsvfsp;
2468 2468 struct ulockfs *ulp;
2469 2469 int error;
2470 2470 int fastsymlink;
2471 2471
2472 2472 if (vp->v_type != VLNK) {
2473 2473 error = EINVAL;
2474 2474 goto nolockout;
2475 2475 }
2476 2476
2477 2477 /*
2478 2478 * If the symbolic link is empty there is nothing to read.
2479 2479 * Fast-track these empty symbolic links
2480 2480 */
2481 2481 if (ip->i_size == 0) {
2482 2482 error = 0;
2483 2483 goto nolockout;
2484 2484 }
2485 2485
2486 2486 ufsvfsp = ip->i_ufsvfs;
2487 2487 error = ufs_lockfs_begin(ufsvfsp, &ulp, ULOCKFS_READLINK_MASK);
2488 2488 if (error)
2489 2489 goto nolockout;
2490 2490 /*
2491 2491 * The ip->i_rwlock protects the data blocks used for FASTSYMLINK
2492 2492 */
2493 2493 again:
2494 2494 fastsymlink = 0;
2495 2495 if (ip->i_flag & IFASTSYMLNK) {
2496 2496 rw_enter(&ip->i_rwlock, RW_READER);
2497 2497 rw_enter(&ip->i_contents, RW_READER);
2498 2498 if (ip->i_flag & IFASTSYMLNK) {
2499 2499 if (!ULOCKFS_IS_NOIACC(ITOUL(ip)) &&
2500 2500 (ip->i_fs->fs_ronly == 0) &&
2501 2501 (!ufsvfsp->vfs_noatime)) {
2502 2502 mutex_enter(&ip->i_tlock);
2503 2503 ip->i_flag |= IACC;
2504 2504 mutex_exit(&ip->i_tlock);
2505 2505 }
2506 2506 error = uiomove((caddr_t)&ip->i_db[1],
2507 2507 MIN(ip->i_size, uiop->uio_resid),
2508 2508 UIO_READ, uiop);
2509 2509 ITIMES(ip);
2510 2510 ++fastsymlink;
2511 2511 }
2512 2512 rw_exit(&ip->i_contents);
2513 2513 rw_exit(&ip->i_rwlock);
2514 2514 }
2515 2515 if (!fastsymlink) {
2516 2516 ssize_t size; /* number of bytes read */
2517 2517 caddr_t basep; /* pointer to input data */
2518 2518 ino_t ino;
2519 2519 long igen;
2520 2520 struct uio tuio; /* temp uio struct */
2521 2521 struct uio *tuiop;
2522 2522 iovec_t tiov; /* temp iovec struct */
2523 2523 char kbuf[FSL_SIZE]; /* buffer to hold fast symlink */
2524 2524 int tflag = 0; /* flag to indicate temp vars used */
2525 2525
2526 2526 ino = ip->i_number;
2527 2527 igen = ip->i_gen;
2528 2528 size = uiop->uio_resid;
2529 2529 basep = uiop->uio_iov->iov_base;
2530 2530 tuiop = uiop;
2531 2531
2532 2532 rw_enter(&ip->i_rwlock, RW_WRITER);
2533 2533 rw_enter(&ip->i_contents, RW_WRITER);
2534 2534 if (ip->i_flag & IFASTSYMLNK) {
2535 2535 rw_exit(&ip->i_contents);
2536 2536 rw_exit(&ip->i_rwlock);
2537 2537 goto again;
2538 2538 }
2539 2539
2540 2540 /* can this be a fast symlink and is it a user buffer? */
2541 2541 if (ip->i_size <= FSL_SIZE &&
2542 2542 (uiop->uio_segflg == UIO_USERSPACE ||
2543 2543 uiop->uio_segflg == UIO_USERISPACE)) {
2544 2544
2545 2545 bzero(&tuio, sizeof (struct uio));
2546 2546 /*
2547 2547 * setup a kernel buffer to read link into. this
2548 2548 * is to fix a race condition where the user buffer
2549 2549 * got corrupted before copying it into the inode.
2550 2550 */
2551 2551 size = ip->i_size;
2552 2552 tiov.iov_len = size;
2553 2553 tiov.iov_base = kbuf;
2554 2554 tuio.uio_iov = &tiov;
2555 2555 tuio.uio_iovcnt = 1;
2556 2556 tuio.uio_offset = uiop->uio_offset;
2557 2557 tuio.uio_segflg = UIO_SYSSPACE;
2558 2558 tuio.uio_fmode = uiop->uio_fmode;
2559 2559 tuio.uio_extflg = uiop->uio_extflg;
2560 2560 tuio.uio_limit = uiop->uio_limit;
2561 2561 tuio.uio_resid = size;
2562 2562
2563 2563 basep = tuio.uio_iov->iov_base;
2564 2564 tuiop = &tuio;
2565 2565 tflag = 1;
2566 2566 }
2567 2567
2568 2568 error = rdip(ip, tuiop, 0, cr);
2569 2569 if (!(error == 0 && ip->i_number == ino && ip->i_gen == igen)) {
2570 2570 rw_exit(&ip->i_contents);
2571 2571 rw_exit(&ip->i_rwlock);
2572 2572 goto out;
2573 2573 }
2574 2574
2575 2575 if (tflag == 0)
2576 2576 size -= uiop->uio_resid;
2577 2577
2578 2578 if ((tflag == 0 && ip->i_size <= FSL_SIZE &&
2579 2579 ip->i_size == size) || (tflag == 1 &&
2580 2580 tuio.uio_resid == 0)) {
2581 2581 error = kcopy(basep, &ip->i_db[1], ip->i_size);
2582 2582 if (error == 0) {
2583 2583 ip->i_flag |= IFASTSYMLNK;
2584 2584 /*
2585 2585 * free page
2586 2586 */
2587 2587 (void) VOP_PUTPAGE(ITOV(ip),
2588 2588 (offset_t)0, PAGESIZE,
2589 2589 (B_DONTNEED | B_FREE | B_FORCE | B_ASYNC),
2590 2590 cr, ct);
2591 2591 } else {
2592 2592 int i;
2593 2593 /* error, clear garbage left behind */
2594 2594 for (i = 1; i < NDADDR; i++)
2595 2595 ip->i_db[i] = 0;
2596 2596 for (i = 0; i < NIADDR; i++)
2597 2597 ip->i_ib[i] = 0;
2598 2598 }
2599 2599 }
2600 2600 if (tflag == 1) {
2601 2601 /* now, copy it into the user buffer */
2602 2602 error = uiomove((caddr_t)kbuf,
2603 2603 MIN(size, uiop->uio_resid),
2604 2604 UIO_READ, uiop);
2605 2605 }
2606 2606 rw_exit(&ip->i_contents);
2607 2607 rw_exit(&ip->i_rwlock);
2608 2608 }
2609 2609 out:
2610 2610 if (ulp) {
2611 2611 ufs_lockfs_end(ulp);
2612 2612 }
2613 2613 nolockout:
2614 2614 return (error);
2615 2615 }
2616 2616
2617 2617 /* ARGSUSED */
2618 2618 static int
2619 2619 ufs_fsync(struct vnode *vp, int syncflag, struct cred *cr,
2620 2620 caller_context_t *ct)
2621 2621 {
2622 2622 struct inode *ip = VTOI(vp);
2623 2623 struct ufsvfs *ufsvfsp = ip->i_ufsvfs;
2624 2624 struct ulockfs *ulp;
2625 2625 int error;
2626 2626
2627 2627 error = ufs_lockfs_begin(ufsvfsp, &ulp, ULOCKFS_FSYNC_MASK);
2628 2628 if (error)
2629 2629 return (error);
2630 2630
2631 2631 if (TRANS_ISTRANS(ufsvfsp)) {
2632 2632 /*
2633 2633 * First push out any data pages
2634 2634 */
2635 2635 if (vn_has_cached_data(vp) && !(syncflag & FNODSYNC) &&
2636 2636 (vp->v_type != VCHR) && !(IS_SWAPVP(vp))) {
2637 2637 error = VOP_PUTPAGE(vp, (offset_t)0, (size_t)0,
2638 2638 0, CRED(), ct);
2639 2639 if (error)
2640 2640 goto out;
2641 2641 }
2642 2642
2643 2643 /*
2644 2644 * Delta any delayed inode times updates
2645 2645 * and push inode to log.
2646 2646 * All other inode deltas will have already been delta'd
2647 2647 * and will be pushed during the commit.
2648 2648 */
2649 2649 if (!(syncflag & FDSYNC) &&
2650 2650 ((ip->i_flag & (IMOD|IMODACC)) == IMODACC)) {
2651 2651 if (ulp) {
2652 2652 TRANS_BEGIN_ASYNC(ufsvfsp, TOP_FSYNC,
2653 2653 TOP_SYNCIP_SIZE);
2654 2654 }
2655 2655 rw_enter(&ip->i_contents, RW_READER);
2656 2656 mutex_enter(&ip->i_tlock);
2657 2657 ip->i_flag &= ~IMODTIME;
2658 2658 mutex_exit(&ip->i_tlock);
2659 2659 ufs_iupdat(ip, I_SYNC);
2660 2660 rw_exit(&ip->i_contents);
2661 2661 if (ulp) {
2662 2662 TRANS_END_ASYNC(ufsvfsp, TOP_FSYNC,
2663 2663 TOP_SYNCIP_SIZE);
2664 2664 }
2665 2665 }
2666 2666
2667 2667 /*
2668 2668 * Commit the Moby transaction
2669 2669 *
2670 2670 * Deltas have already been made so we just need to
2671 2671 * commit them with a synchronous transaction.
2672 2672 * TRANS_BEGIN_SYNC() will return an error
2673 2673 * if there are no deltas to commit, for an
2674 2674 * empty transaction.
2675 2675 */
2676 2676 if (ulp) {
2677 2677 TRANS_BEGIN_SYNC(ufsvfsp, TOP_FSYNC, TOP_COMMIT_SIZE,
2678 2678 error);
2679 2679 if (error) {
2680 2680 error = 0; /* commit wasn't needed */
2681 2681 goto out;
2682 2682 }
2683 2683 TRANS_END_SYNC(ufsvfsp, error, TOP_FSYNC,
2684 2684 TOP_COMMIT_SIZE);
2685 2685 }
2686 2686 } else { /* not logging */
2687 2687 if (!(IS_SWAPVP(vp)))
2688 2688 if (syncflag & FNODSYNC) {
2689 2689 /* Just update the inode only */
2690 2690 TRANS_IUPDAT(ip, 1);
2691 2691 error = 0;
2692 2692 } else if (syncflag & FDSYNC)
2693 2693 /* Do data-synchronous writes */
2694 2694 error = TRANS_SYNCIP(ip, 0, I_DSYNC, TOP_FSYNC);
2695 2695 else
2696 2696 /* Do synchronous writes */
2697 2697 error = TRANS_SYNCIP(ip, 0, I_SYNC, TOP_FSYNC);
2698 2698
2699 2699 rw_enter(&ip->i_contents, RW_WRITER);
2700 2700 if (!error)
2701 2701 error = ufs_sync_indir(ip);
2702 2702 rw_exit(&ip->i_contents);
2703 2703 }
2704 2704 out:
2705 2705 if (ulp) {
2706 2706 ufs_lockfs_end(ulp);
2707 2707 }
2708 2708 return (error);
2709 2709 }
2710 2710
2711 2711 /*ARGSUSED*/
2712 2712 static void
2713 2713 ufs_inactive(struct vnode *vp, struct cred *cr, caller_context_t *ct)
2714 2714 {
2715 2715 ufs_iinactive(VTOI(vp));
2716 2716 }
2717 2717
2718 2718 /*
2719 2719 * Unix file system operations having to do with directory manipulation.
2720 2720 */
2721 2721 int ufs_lookup_idle_count = 2; /* Number of inodes to idle each time */
2722 2722 /* ARGSUSED */
2723 2723 static int
2724 2724 ufs_lookup(struct vnode *dvp, char *nm, struct vnode **vpp,
2725 2725 struct pathname *pnp, int flags, struct vnode *rdir, struct cred *cr,
2726 2726 caller_context_t *ct, int *direntflags, pathname_t *realpnp)
2727 2727 {
2728 2728 struct inode *ip;
2729 2729 struct inode *sip;
2730 2730 struct inode *xip;
2731 2731 struct ufsvfs *ufsvfsp;
2732 2732 struct ulockfs *ulp;
2733 2733 struct vnode *vp;
2734 2734 int error;
2735 2735
2736 2736 /*
2737 2737 * Check flags for type of lookup (regular file or attribute file)
2738 2738 */
2739 2739
2740 2740 ip = VTOI(dvp);
2741 2741
2742 2742 if (flags & LOOKUP_XATTR) {
2743 2743
2744 2744 /*
2745 2745 * If not mounted with XATTR support then return EINVAL
2746 2746 */
2747 2747
2748 2748 if (!(ip->i_ufsvfs->vfs_vfs->vfs_flag & VFS_XATTR))
2749 2749 return (EINVAL);
2750 2750 /*
2751 2751 * We don't allow recursive attributes...
2752 2752 * Maybe someday we will.
2753 2753 */
2754 2754 if ((ip->i_cflags & IXATTR)) {
2755 2755 return (EINVAL);
2756 2756 }
2757 2757
2758 2758 if ((vp = dnlc_lookup(dvp, XATTR_DIR_NAME)) == NULL) {
2759 2759 error = ufs_xattr_getattrdir(dvp, &sip, flags, cr);
2760 2760 if (error) {
2761 2761 *vpp = NULL;
2762 2762 goto out;
2763 2763 }
2764 2764
2765 2765 vp = ITOV(sip);
2766 2766 dnlc_update(dvp, XATTR_DIR_NAME, vp);
2767 2767 }
2768 2768
2769 2769 /*
2770 2770 * Check accessibility of directory.
2771 2771 */
2772 2772 if (vp == DNLC_NO_VNODE) {
2773 2773 VN_RELE(vp);
2774 2774 error = ENOENT;
2775 2775 goto out;
2776 2776 }
2777 2777 if ((error = ufs_iaccess(VTOI(vp), IEXEC, cr, 1)) != 0) {
2778 2778 VN_RELE(vp);
2779 2779 goto out;
2780 2780 }
2781 2781
2782 2782 *vpp = vp;
2783 2783 return (0);
2784 2784 }
2785 2785
2786 2786 /*
2787 2787 * Check for a null component, which we should treat as
2788 2788 * looking at dvp from within it's parent, so we don't
2789 2789 * need a call to ufs_iaccess(), as it has already been
2790 2790 * done.
2791 2791 */
2792 2792 if (nm[0] == 0) {
2793 2793 VN_HOLD(dvp);
2794 2794 error = 0;
2795 2795 *vpp = dvp;
2796 2796 goto out;
2797 2797 }
2798 2798
2799 2799 /*
2800 2800 * Check for "." ie itself. this is a quick check and
2801 2801 * avoids adding "." into the dnlc (which have been seen
2802 2802 * to occupy >10% of the cache).
2803 2803 */
2804 2804 if ((nm[0] == '.') && (nm[1] == 0)) {
2805 2805 /*
2806 2806 * Don't return without checking accessibility
2807 2807 * of the directory. We only need the lock if
2808 2808 * we are going to return it.
2809 2809 */
2810 2810 if ((error = ufs_iaccess(ip, IEXEC, cr, 1)) == 0) {
2811 2811 VN_HOLD(dvp);
2812 2812 *vpp = dvp;
2813 2813 }
2814 2814 goto out;
2815 2815 }
2816 2816
2817 2817 /*
2818 2818 * Fast path: Check the directory name lookup cache.
2819 2819 */
2820 2820 if (vp = dnlc_lookup(dvp, nm)) {
2821 2821 /*
2822 2822 * Check accessibility of directory.
2823 2823 */
2824 2824 if ((error = ufs_iaccess(ip, IEXEC, cr, 1)) != 0) {
2825 2825 VN_RELE(vp);
2826 2826 goto out;
2827 2827 }
2828 2828 if (vp == DNLC_NO_VNODE) {
2829 2829 VN_RELE(vp);
2830 2830 error = ENOENT;
2831 2831 goto out;
2832 2832 }
2833 2833 xip = VTOI(vp);
2834 2834 ulp = NULL;
2835 2835 goto fastpath;
2836 2836 }
2837 2837
2838 2838 /*
2839 2839 * Keep the idle queue from getting too long by
2840 2840 * idling two inodes before attempting to allocate another.
2841 2841 * This operation must be performed before entering
2842 2842 * lockfs or a transaction.
2843 2843 */
2844 2844 if (ufs_idle_q.uq_ne > ufs_idle_q.uq_hiwat)
2845 2845 if ((curthread->t_flag & T_DONTBLOCK) == 0) {
2846 2846 ins.in_lidles.value.ul += ufs_lookup_idle_count;
2847 2847 ufs_idle_some(ufs_lookup_idle_count);
2848 2848 }
2849 2849
2850 2850 retry_lookup:
2851 2851 /*
2852 2852 * Check accessibility of directory.
2853 2853 */
2854 2854 if (error = ufs_diraccess(ip, IEXEC, cr))
2855 2855 goto out;
2856 2856
2857 2857 ufsvfsp = ip->i_ufsvfs;
2858 2858 error = ufs_lockfs_begin(ufsvfsp, &ulp, ULOCKFS_LOOKUP_MASK);
2859 2859 if (error)
2860 2860 goto out;
2861 2861
2862 2862 error = ufs_dirlook(ip, nm, &xip, cr, 1, 0);
2863 2863
2864 2864 fastpath:
2865 2865 if (error == 0) {
2866 2866 ip = xip;
2867 2867 *vpp = ITOV(ip);
2868 2868
2869 2869 /*
2870 2870 * If vnode is a device return special vnode instead.
2871 2871 */
2872 2872 if (IS_DEVVP(*vpp)) {
2873 2873 struct vnode *newvp;
2874 2874
2875 2875 newvp = specvp(*vpp, (*vpp)->v_rdev, (*vpp)->v_type,
2876 2876 cr);
2877 2877 VN_RELE(*vpp);
2878 2878 if (newvp == NULL)
2879 2879 error = ENOSYS;
2880 2880 else
2881 2881 *vpp = newvp;
2882 2882 } else if (ip->i_cflags & ICOMPRESS) {
2883 2883 struct vnode *newvp;
2884 2884
2885 2885 /*
2886 2886 * Compressed file, substitute dcfs vnode
2887 2887 */
2888 2888 newvp = decompvp(*vpp, cr, ct);
2889 2889 VN_RELE(*vpp);
2890 2890 if (newvp == NULL)
2891 2891 error = ENOSYS;
2892 2892 else
2893 2893 *vpp = newvp;
2894 2894 }
2895 2895 }
2896 2896 if (ulp) {
2897 2897 ufs_lockfs_end(ulp);
2898 2898 }
2899 2899
2900 2900 if (error == EAGAIN)
2901 2901 goto retry_lookup;
2902 2902
2903 2903 out:
2904 2904 return (error);
2905 2905 }
2906 2906
2907 2907 /*ARGSUSED*/
2908 2908 static int
2909 2909 ufs_create(struct vnode *dvp, char *name, struct vattr *vap, enum vcexcl excl,
2910 2910 int mode, struct vnode **vpp, struct cred *cr, int flag,
2911 2911 caller_context_t *ct, vsecattr_t *vsecp)
2912 2912 {
2913 2913 struct inode *ip;
2914 2914 struct inode *xip;
2915 2915 struct inode *dip;
2916 2916 struct vnode *xvp;
2917 2917 struct ufsvfs *ufsvfsp;
2918 2918 struct ulockfs *ulp;
2919 2919 int error;
2920 2920 int issync;
2921 2921 int truncflag;
2922 2922 int trans_size;
2923 2923 int noentry;
2924 2924 int defer_dip_seq_update = 0; /* need to defer update of dip->i_seq */
2925 2925 int retry = 1;
2926 2926 int indeadlock;
2927 2927
2928 2928 again:
2929 2929 ip = VTOI(dvp);
2930 2930 ufsvfsp = ip->i_ufsvfs;
2931 2931 truncflag = 0;
2932 2932
2933 2933 error = ufs_lockfs_begin(ufsvfsp, &ulp, ULOCKFS_CREATE_MASK);
2934 2934 if (error)
2935 2935 goto out;
2936 2936
2937 2937 if (ulp) {
2938 2938 trans_size = (int)TOP_CREATE_SIZE(ip);
2939 2939 TRANS_BEGIN_CSYNC(ufsvfsp, issync, TOP_CREATE, trans_size);
2940 2940 }
2941 2941
2942 2942 if ((vap->va_mode & VSVTX) && secpolicy_vnode_stky_modify(cr) != 0)
2943 2943 vap->va_mode &= ~VSVTX;
2944 2944
2945 2945 if (*name == '\0') {
2946 2946 /*
2947 2947 * Null component name refers to the directory itself.
2948 2948 */
2949 2949 VN_HOLD(dvp);
2950 2950 /*
2951 2951 * Even though this is an error case, we need to grab the
2952 2952 * quota lock since the error handling code below is common.
2953 2953 */
2954 2954 rw_enter(&ufsvfsp->vfs_dqrwlock, RW_READER);
2955 2955 rw_enter(&ip->i_contents, RW_WRITER);
2956 2956 error = EEXIST;
2957 2957 } else {
2958 2958 xip = NULL;
2959 2959 noentry = 0;
2960 2960 /*
2961 2961 * ufs_tryirwlock_trans uses rw_tryenter and checks for SLOCK
2962 2962 * to avoid i_rwlock, ufs_lockfs_begin deadlock. If deadlock
2963 2963 * possible, retries the operation.
2964 2964 */
2965 2965 ufs_tryirwlock_trans(&ip->i_rwlock, RW_WRITER, TOP_CREATE,
2966 2966 retry_dir);
2967 2967 if (indeadlock)
2968 2968 goto again;
2969 2969
2970 2970 xvp = dnlc_lookup(dvp, name);
2971 2971 if (xvp == DNLC_NO_VNODE) {
2972 2972 noentry = 1;
2973 2973 VN_RELE(xvp);
2974 2974 xvp = NULL;
2975 2975 }
2976 2976 if (xvp) {
2977 2977 rw_exit(&ip->i_rwlock);
2978 2978 if (error = ufs_iaccess(ip, IEXEC, cr, 1)) {
2979 2979 VN_RELE(xvp);
2980 2980 } else {
2981 2981 error = EEXIST;
2982 2982 xip = VTOI(xvp);
2983 2983 }
2984 2984 } else {
2985 2985 /*
2986 2986 * Suppress file system full message if we will retry
2987 2987 */
2988 2988 error = ufs_direnter_cm(ip, name, DE_CREATE,
2989 2989 vap, &xip, cr, (noentry | (retry ? IQUIET : 0)));
2990 2990 if (error == EAGAIN) {
2991 2991 if (ulp) {
2992 2992 TRANS_END_CSYNC(ufsvfsp, error, issync,
2993 2993 TOP_CREATE, trans_size);
2994 2994 ufs_lockfs_end(ulp);
2995 2995 }
2996 2996 goto again;
2997 2997 }
2998 2998 rw_exit(&ip->i_rwlock);
2999 2999 }
3000 3000 ip = xip;
3001 3001 if (ip != NULL) {
3002 3002 rw_enter(&ufsvfsp->vfs_dqrwlock, RW_READER);
3003 3003 rw_enter(&ip->i_contents, RW_WRITER);
3004 3004 }
3005 3005 }
3006 3006
3007 3007 /*
3008 3008 * If the file already exists and this is a non-exclusive create,
3009 3009 * check permissions and allow access for non-directories.
3010 3010 * Read-only create of an existing directory is also allowed.
3011 3011 * We fail an exclusive create of anything which already exists.
3012 3012 */
3013 3013 if (error == EEXIST) {
3014 3014 dip = VTOI(dvp);
3015 3015 if (excl == NONEXCL) {
3016 3016 if ((((ip->i_mode & IFMT) == IFDIR) ||
3017 3017 ((ip->i_mode & IFMT) == IFATTRDIR)) &&
3018 3018 (mode & IWRITE))
3019 3019 error = EISDIR;
3020 3020 else if (mode)
3021 3021 error = ufs_iaccess(ip, mode, cr, 0);
3022 3022 else
3023 3023 error = 0;
3024 3024 }
3025 3025 if (error) {
3026 3026 rw_exit(&ip->i_contents);
3027 3027 rw_exit(&ufsvfsp->vfs_dqrwlock);
3028 3028 VN_RELE(ITOV(ip));
3029 3029 goto unlock;
3030 3030 }
3031 3031 /*
3032 3032 * If the error EEXIST was set, then i_seq can not
3033 3033 * have been updated. The sequence number interface
3034 3034 * is defined such that a non-error VOP_CREATE must
3035 3035 * increase the dir va_seq it by at least one. If we
3036 3036 * have cleared the error, increase i_seq. Note that
3037 3037 * we are increasing the dir i_seq and in rare cases
3038 3038 * ip may actually be from the dvp, so we already have
3039 3039 * the locks and it will not be subject to truncation.
3040 3040 * In case we have to update i_seq of the parent
3041 3041 * directory dip, we have to defer it till we have
3042 3042 * released our locks on ip due to lock ordering requirements.
3043 3043 */
3044 3044 if (ip != dip)
3045 3045 defer_dip_seq_update = 1;
3046 3046 else
3047 3047 ip->i_seq++;
3048 3048
3049 3049 if (((ip->i_mode & IFMT) == IFREG) &&
3050 3050 (vap->va_mask & AT_SIZE) && vap->va_size == 0) {
3051 3051 /*
3052 3052 * Truncate regular files, if requested by caller.
3053 3053 * Grab i_rwlock to make sure no one else is
3054 3054 * currently writing to the file (we promised
3055 3055 * bmap we would do this).
3056 3056 * Must get the locks in the correct order.
3057 3057 */
3058 3058 if (ip->i_size == 0) {
3059 3059 ip->i_flag |= ICHG | IUPD;
3060 3060 ip->i_seq++;
3061 3061 TRANS_INODE(ufsvfsp, ip);
3062 3062 } else {
3063 3063 /*
3064 3064 * Large Files: Why this check here?
3065 3065 * Though we do it in vn_create() we really
3066 3066 * want to guarantee that we do not destroy
3067 3067 * Large file data by atomically checking
3068 3068 * the size while holding the contents
3069 3069 * lock.
3070 3070 */
3071 3071 if (flag && !(flag & FOFFMAX) &&
3072 3072 ((ip->i_mode & IFMT) == IFREG) &&
3073 3073 (ip->i_size > (offset_t)MAXOFF32_T)) {
3074 3074 rw_exit(&ip->i_contents);
3075 3075 rw_exit(&ufsvfsp->vfs_dqrwlock);
3076 3076 error = EOVERFLOW;
3077 3077 goto unlock;
3078 3078 }
3079 3079 if (TRANS_ISTRANS(ufsvfsp))
3080 3080 truncflag++;
3081 3081 else {
3082 3082 rw_exit(&ip->i_contents);
3083 3083 rw_exit(&ufsvfsp->vfs_dqrwlock);
3084 3084 ufs_tryirwlock_trans(&ip->i_rwlock,
3085 3085 RW_WRITER, TOP_CREATE,
3086 3086 retry_file);
3087 3087 if (indeadlock) {
3088 3088 VN_RELE(ITOV(ip));
3089 3089 goto again;
3090 3090 }
3091 3091 rw_enter(&ufsvfsp->vfs_dqrwlock,
3092 3092 RW_READER);
3093 3093 rw_enter(&ip->i_contents, RW_WRITER);
3094 3094 (void) ufs_itrunc(ip, (u_offset_t)0, 0,
3095 3095 cr);
3096 3096 rw_exit(&ip->i_rwlock);
3097 3097 }
3098 3098
3099 3099 }
3100 3100 if (error == 0) {
3101 3101 vnevent_create(ITOV(ip), ct);
3102 3102 }
3103 3103 }
3104 3104 }
3105 3105
3106 3106 if (error) {
3107 3107 if (ip != NULL) {
3108 3108 rw_exit(&ufsvfsp->vfs_dqrwlock);
3109 3109 rw_exit(&ip->i_contents);
3110 3110 }
3111 3111 goto unlock;
3112 3112 }
3113 3113
3114 3114 *vpp = ITOV(ip);
3115 3115 ITIMES(ip);
3116 3116 rw_exit(&ip->i_contents);
3117 3117 rw_exit(&ufsvfsp->vfs_dqrwlock);
3118 3118
3119 3119 /*
3120 3120 * If vnode is a device return special vnode instead.
3121 3121 */
3122 3122 if (!error && IS_DEVVP(*vpp)) {
3123 3123 struct vnode *newvp;
3124 3124
3125 3125 newvp = specvp(*vpp, (*vpp)->v_rdev, (*vpp)->v_type, cr);
3126 3126 VN_RELE(*vpp);
3127 3127 if (newvp == NULL) {
3128 3128 error = ENOSYS;
3129 3129 goto unlock;
3130 3130 }
3131 3131 truncflag = 0;
3132 3132 *vpp = newvp;
3133 3133 }
3134 3134 unlock:
3135 3135
3136 3136 /*
3137 3137 * Do the deferred update of the parent directory's sequence
3138 3138 * number now.
3139 3139 */
3140 3140 if (defer_dip_seq_update == 1) {
3141 3141 rw_enter(&dip->i_contents, RW_READER);
3142 3142 mutex_enter(&dip->i_tlock);
3143 3143 dip->i_seq++;
3144 3144 mutex_exit(&dip->i_tlock);
3145 3145 rw_exit(&dip->i_contents);
3146 3146 }
3147 3147
3148 3148 if (ulp) {
3149 3149 int terr = 0;
3150 3150
3151 3151 TRANS_END_CSYNC(ufsvfsp, terr, issync, TOP_CREATE,
3152 3152 trans_size);
3153 3153
3154 3154 /*
3155 3155 * If we haven't had a more interesting failure
3156 3156 * already, then anything that might've happened
3157 3157 * here should be reported.
3158 3158 */
3159 3159 if (error == 0)
3160 3160 error = terr;
3161 3161 }
3162 3162
3163 3163 if (!error && truncflag) {
3164 3164 ufs_tryirwlock(&ip->i_rwlock, RW_WRITER, retry_trunc);
3165 3165 if (indeadlock) {
3166 3166 if (ulp)
3167 3167 ufs_lockfs_end(ulp);
3168 3168 VN_RELE(ITOV(ip));
3169 3169 goto again;
3170 3170 }
3171 3171 (void) TRANS_ITRUNC(ip, (u_offset_t)0, 0, cr);
3172 3172 rw_exit(&ip->i_rwlock);
3173 3173 }
3174 3174
3175 3175 if (ulp)
3176 3176 ufs_lockfs_end(ulp);
3177 3177
3178 3178 /*
3179 3179 * If no inodes available, try to free one up out of the
3180 3180 * pending delete queue.
3181 3181 */
3182 3182 if ((error == ENOSPC) && retry && TRANS_ISTRANS(ufsvfsp)) {
3183 3183 ufs_delete_drain_wait(ufsvfsp, 1);
3184 3184 retry = 0;
3185 3185 goto again;
3186 3186 }
3187 3187
3188 3188 out:
3189 3189 return (error);
3190 3190 }
3191 3191
3192 3192 extern int ufs_idle_max;
3193 3193 /*ARGSUSED*/
3194 3194 static int
3195 3195 ufs_remove(struct vnode *vp, char *nm, struct cred *cr,
3196 3196 caller_context_t *ct, int flags)
3197 3197 {
3198 3198 struct inode *ip = VTOI(vp);
3199 3199 struct ufsvfs *ufsvfsp = ip->i_ufsvfs;
3200 3200 struct ulockfs *ulp;
3201 3201 vnode_t *rmvp = NULL; /* Vnode corresponding to name being removed */
3202 3202 int indeadlock;
3203 3203 int error;
3204 3204 int issync;
3205 3205 int trans_size;
3206 3206
3207 3207 /*
3208 3208 * don't let the delete queue get too long
3209 3209 */
3210 3210 if (ufsvfsp == NULL) {
3211 3211 error = EIO;
3212 3212 goto out;
3213 3213 }
3214 3214 if (ufsvfsp->vfs_delete.uq_ne > ufs_idle_max)
3215 3215 ufs_delete_drain(vp->v_vfsp, 1, 1);
3216 3216
3217 3217 error = ufs_eventlookup(vp, nm, cr, &rmvp);
3218 3218 if (rmvp != NULL) {
3219 3219 /* Only send the event if there were no errors */
3220 3220 if (error == 0)
3221 3221 vnevent_remove(rmvp, vp, nm, ct);
3222 3222 VN_RELE(rmvp);
3223 3223 }
3224 3224
3225 3225 retry_remove:
3226 3226 error = ufs_lockfs_begin(ufsvfsp, &ulp, ULOCKFS_REMOVE_MASK);
3227 3227 if (error)
3228 3228 goto out;
3229 3229
3230 3230 if (ulp)
3231 3231 TRANS_BEGIN_CSYNC(ufsvfsp, issync, TOP_REMOVE,
3232 3232 trans_size = (int)TOP_REMOVE_SIZE(VTOI(vp)));
3233 3233
3234 3234 /*
3235 3235 * ufs_tryirwlock_trans uses rw_tryenter and checks for SLOCK
3236 3236 * to avoid i_rwlock, ufs_lockfs_begin deadlock. If deadlock
3237 3237 * possible, retries the operation.
3238 3238 */
3239 3239 ufs_tryirwlock_trans(&ip->i_rwlock, RW_WRITER, TOP_REMOVE, retry);
3240 3240 if (indeadlock)
3241 3241 goto retry_remove;
3242 3242 error = ufs_dirremove(ip, nm, (struct inode *)0, (struct vnode *)0,
3243 3243 DR_REMOVE, cr);
3244 3244 rw_exit(&ip->i_rwlock);
3245 3245
3246 3246 if (ulp) {
3247 3247 TRANS_END_CSYNC(ufsvfsp, error, issync, TOP_REMOVE, trans_size);
3248 3248 ufs_lockfs_end(ulp);
3249 3249 }
3250 3250
3251 3251 out:
3252 3252 return (error);
3253 3253 }
3254 3254
3255 3255 /*
3256 3256 * Link a file or a directory. Only privileged processes are allowed to
3257 3257 * make links to directories.
3258 3258 */
3259 3259 /*ARGSUSED*/
3260 3260 static int
3261 3261 ufs_link(struct vnode *tdvp, struct vnode *svp, char *tnm, struct cred *cr,
3262 3262 caller_context_t *ct, int flags)
3263 3263 {
3264 3264 struct inode *sip;
3265 3265 struct inode *tdp = VTOI(tdvp);
3266 3266 struct ufsvfs *ufsvfsp = tdp->i_ufsvfs;
3267 3267 struct ulockfs *ulp;
3268 3268 struct vnode *realvp;
3269 3269 int error;
3270 3270 int issync;
3271 3271 int trans_size;
3272 3272 int isdev;
3273 3273 int indeadlock;
3274 3274
3275 3275 retry_link:
3276 3276 error = ufs_lockfs_begin(ufsvfsp, &ulp, ULOCKFS_LINK_MASK);
3277 3277 if (error)
3278 3278 goto out;
3279 3279
3280 3280 if (ulp)
3281 3281 TRANS_BEGIN_CSYNC(ufsvfsp, issync, TOP_LINK,
3282 3282 trans_size = (int)TOP_LINK_SIZE(VTOI(tdvp)));
3283 3283
3284 3284 if (VOP_REALVP(svp, &realvp, ct) == 0)
3285 3285 svp = realvp;
3286 3286
3287 3287 /*
3288 3288 * Make sure link for extended attributes is valid
3289 3289 * We only support hard linking of attr in ATTRDIR to ATTRDIR
3290 3290 *
3291 3291 * Make certain we don't attempt to look at a device node as
3292 3292 * a ufs inode.
3293 3293 */
3294 3294
3295 3295 isdev = IS_DEVVP(svp);
3296 3296 if (((isdev == 0) && ((VTOI(svp)->i_cflags & IXATTR) == 0) &&
3297 3297 ((tdp->i_mode & IFMT) == IFATTRDIR)) ||
3298 3298 ((isdev == 0) && (VTOI(svp)->i_cflags & IXATTR) &&
3299 3299 ((tdp->i_mode & IFMT) == IFDIR))) {
3300 3300 error = EINVAL;
3301 3301 goto unlock;
3302 3302 }
3303 3303
3304 3304 sip = VTOI(svp);
3305 3305 if ((svp->v_type == VDIR &&
3306 3306 secpolicy_fs_linkdir(cr, ufsvfsp->vfs_vfs) != 0) ||
3307 3307 (sip->i_uid != crgetuid(cr) && secpolicy_basic_link(cr) != 0)) {
3308 3308 error = EPERM;
3309 3309 goto unlock;
3310 3310 }
3311 3311
3312 3312 /*
3313 3313 * ufs_tryirwlock_trans uses rw_tryenter and checks for SLOCK
3314 3314 * to avoid i_rwlock, ufs_lockfs_begin deadlock. If deadlock
3315 3315 * possible, retries the operation.
3316 3316 */
3317 3317 ufs_tryirwlock_trans(&tdp->i_rwlock, RW_WRITER, TOP_LINK, retry);
3318 3318 if (indeadlock)
3319 3319 goto retry_link;
3320 3320 error = ufs_direnter_lr(tdp, tnm, DE_LINK, (struct inode *)0,
3321 3321 sip, cr);
3322 3322 rw_exit(&tdp->i_rwlock);
3323 3323
3324 3324 unlock:
3325 3325 if (ulp) {
3326 3326 TRANS_END_CSYNC(ufsvfsp, error, issync, TOP_LINK, trans_size);
3327 3327 ufs_lockfs_end(ulp);
3328 3328 }
3329 3329
3330 3330 if (!error) {
3331 3331 vnevent_link(svp, ct);
3332 3332 }
3333 3333 out:
3334 3334 return (error);
3335 3335 }
3336 3336
3337 3337 uint64_t ufs_rename_retry_cnt;
3338 3338 uint64_t ufs_rename_upgrade_retry_cnt;
3339 3339 uint64_t ufs_rename_dircheck_retry_cnt;
3340 3340 clock_t ufs_rename_backoff_delay = 1;
3341 3341
3342 3342 /*
3343 3343 * Rename a file or directory.
3344 3344 * We are given the vnode and entry string of the source and the
3345 3345 * vnode and entry string of the place we want to move the source
3346 3346 * to (the target). The essential operation is:
3347 3347 * unlink(target);
3348 3348 * link(source, target);
3349 3349 * unlink(source);
3350 3350 * but "atomically". Can't do full commit without saving state in
3351 3351 * the inode on disk, which isn't feasible at this time. Best we
3352 3352 * can do is always guarantee that the TARGET exists.
3353 3353 */
3354 3354
3355 3355 /*ARGSUSED*/
3356 3356 static int
3357 3357 ufs_rename(
3358 3358 struct vnode *sdvp, /* old (source) parent vnode */
3359 3359 char *snm, /* old (source) entry name */
3360 3360 struct vnode *tdvp, /* new (target) parent vnode */
3361 3361 char *tnm, /* new (target) entry name */
3362 3362 struct cred *cr,
3363 3363 caller_context_t *ct,
3364 3364 int flags)
3365 3365 {
3366 3366 struct inode *sip = NULL; /* source inode */
3367 3367 struct inode *ip = NULL; /* check inode */
3368 3368 struct inode *sdp; /* old (source) parent inode */
3369 3369 struct inode *tdp; /* new (target) parent inode */
3370 3370 struct vnode *svp = NULL; /* source vnode */
3371 3371 struct vnode *tvp = NULL; /* target vnode, if it exists */
3372 3372 struct vnode *realvp;
3373 3373 struct ufsvfs *ufsvfsp;
3374 3374 struct ulockfs *ulp;
3375 3375 struct ufs_slot slot;
3376 3376 timestruc_t now;
3377 3377 int error;
3378 3378 int issync;
3379 3379 int trans_size;
3380 3380 krwlock_t *first_lock;
3381 3381 krwlock_t *second_lock;
3382 3382 krwlock_t *reverse_lock;
3383 3383 int serr, terr;
3384 3384
3385 3385 sdp = VTOI(sdvp);
3386 3386 slot.fbp = NULL;
3387 3387 ufsvfsp = sdp->i_ufsvfs;
3388 3388
3389 3389 if (VOP_REALVP(tdvp, &realvp, ct) == 0)
3390 3390 tdvp = realvp;
3391 3391
3392 3392 terr = ufs_eventlookup(tdvp, tnm, cr, &tvp);
3393 3393 serr = ufs_eventlookup(sdvp, snm, cr, &svp);
3394 3394
3395 3395 if ((serr == 0) && ((terr == 0) || (terr == ENOENT))) {
3396 3396 if (tvp != NULL)
3397 3397 vnevent_rename_dest(tvp, tdvp, tnm, ct);
3398 3398
3399 3399 /*
3400 3400 * Notify the target directory of the rename event
3401 3401 * if source and target directories are not the same.
3402 3402 */
3403 3403 if (sdvp != tdvp)
3404 3404 vnevent_rename_dest_dir(tdvp, ct);
3405 3405
3406 3406 if (svp != NULL)
3407 3407 vnevent_rename_src(svp, sdvp, snm, ct);
3408 3408 }
3409 3409
3410 3410 if (tvp != NULL)
3411 3411 VN_RELE(tvp);
3412 3412
3413 3413 if (svp != NULL)
3414 3414 VN_RELE(svp);
3415 3415
3416 3416 retry_rename:
3417 3417 error = ufs_lockfs_begin(ufsvfsp, &ulp, ULOCKFS_RENAME_MASK);
3418 3418 if (error)
3419 3419 goto out;
3420 3420
3421 3421 if (ulp)
3422 3422 TRANS_BEGIN_CSYNC(ufsvfsp, issync, TOP_RENAME,
3423 3423 trans_size = (int)TOP_RENAME_SIZE(sdp));
3424 3424
3425 3425 if (VOP_REALVP(tdvp, &realvp, ct) == 0)
3426 3426 tdvp = realvp;
3427 3427
3428 3428 tdp = VTOI(tdvp);
3429 3429
3430 3430 /*
3431 3431 * We only allow renaming of attributes from ATTRDIR to ATTRDIR.
3432 3432 */
3433 3433 if ((tdp->i_mode & IFMT) != (sdp->i_mode & IFMT)) {
3434 3434 error = EINVAL;
3435 3435 goto unlock;
3436 3436 }
3437 3437
3438 3438 /*
3439 3439 * Check accessibility of directory.
3440 3440 */
3441 3441 if (error = ufs_diraccess(sdp, IEXEC, cr))
3442 3442 goto unlock;
3443 3443
3444 3444 /*
3445 3445 * Look up inode of file we're supposed to rename.
3446 3446 */
3447 3447 gethrestime(&now);
3448 3448 if (error = ufs_dirlook(sdp, snm, &sip, cr, 0, 0)) {
3449 3449 if (error == EAGAIN) {
3450 3450 if (ulp) {
3451 3451 TRANS_END_CSYNC(ufsvfsp, error, issync,
3452 3452 TOP_RENAME, trans_size);
3453 3453 ufs_lockfs_end(ulp);
3454 3454 }
3455 3455 goto retry_rename;
3456 3456 }
3457 3457
3458 3458 goto unlock;
3459 3459 }
3460 3460
3461 3461 /*
3462 3462 * Lock both the source and target directories (they may be
3463 3463 * the same) to provide the atomicity semantics that was
3464 3464 * previously provided by the per file system vfs_rename_lock
3465 3465 *
3466 3466 * with vfs_rename_lock removed to allow simultaneous renames
3467 3467 * within a file system, ufs_dircheckpath can deadlock while
3468 3468 * traversing back to ensure that source is not a parent directory
3469 3469 * of target parent directory. This is because we get into
3470 3470 * ufs_dircheckpath with the sdp and tdp locks held as RW_WRITER.
3471 3471 * If the tdp and sdp of the simultaneous renames happen to be
3472 3472 * in the path of each other, it can lead to a deadlock. This
3473 3473 * can be avoided by getting the locks as RW_READER here and then
3474 3474 * upgrading to RW_WRITER after completing the ufs_dircheckpath.
3475 3475 *
3476 3476 * We hold the target directory's i_rwlock after calling
3477 3477 * ufs_lockfs_begin but in many other operations (like ufs_readdir)
3478 3478 * VOP_RWLOCK is explicitly called by the filesystem independent code
3479 3479 * before calling the file system operation. In these cases the order
3480 3480 * is reversed (i.e i_rwlock is taken first and then ufs_lockfs_begin
3481 3481 * is called). This is fine as long as ufs_lockfs_begin acts as a VOP
3482 3482 * counter but with ufs_quiesce setting the SLOCK bit this becomes a
3483 3483 * synchronizing object which might lead to a deadlock. So we use
3484 3484 * rw_tryenter instead of rw_enter. If we fail to get this lock and
3485 3485 * find that SLOCK bit is set, we call ufs_lockfs_end and restart the
3486 3486 * operation.
3487 3487 */
3488 3488 retry:
3489 3489 first_lock = &tdp->i_rwlock;
3490 3490 second_lock = &sdp->i_rwlock;
3491 3491 retry_firstlock:
3492 3492 if (!rw_tryenter(first_lock, RW_READER)) {
3493 3493 /*
3494 3494 * We didn't get the lock. Check if the SLOCK is set in the
3495 3495 * ufsvfs. If yes, we might be in a deadlock. Safer to give up
3496 3496 * and wait for SLOCK to be cleared.
3497 3497 */
3498 3498
3499 3499 if (ulp && ULOCKFS_IS_SLOCK(ulp)) {
3500 3500 TRANS_END_CSYNC(ufsvfsp, error, issync, TOP_RENAME,
3501 3501 trans_size);
3502 3502 ufs_lockfs_end(ulp);
3503 3503 goto retry_rename;
3504 3504
3505 3505 } else {
3506 3506 /*
3507 3507 * SLOCK isn't set so this is a genuine synchronization
3508 3508 * case. Let's try again after giving them a breather.
3509 3509 */
3510 3510 delay(RETRY_LOCK_DELAY);
3511 3511 goto retry_firstlock;
3512 3512 }
3513 3513 }
3514 3514 /*
3515 3515 * Need to check if the tdp and sdp are same !!!
3516 3516 */
3517 3517 if ((tdp != sdp) && (!rw_tryenter(second_lock, RW_READER))) {
3518 3518 /*
3519 3519 * We didn't get the lock. Check if the SLOCK is set in the
3520 3520 * ufsvfs. If yes, we might be in a deadlock. Safer to give up
3521 3521 * and wait for SLOCK to be cleared.
3522 3522 */
3523 3523
3524 3524 rw_exit(first_lock);
3525 3525 if (ulp && ULOCKFS_IS_SLOCK(ulp)) {
3526 3526 TRANS_END_CSYNC(ufsvfsp, error, issync, TOP_RENAME,
3527 3527 trans_size);
3528 3528 ufs_lockfs_end(ulp);
3529 3529 goto retry_rename;
3530 3530
3531 3531 } else {
3532 3532 /*
3533 3533 * So we couldn't get the second level peer lock *and*
3534 3534 * the SLOCK bit isn't set. Too bad we can be
3535 3535 * contentding with someone wanting these locks otherway
3536 3536 * round. Reverse the locks in case there is a heavy
3537 3537 * contention for the second level lock.
3538 3538 */
3539 3539 reverse_lock = first_lock;
3540 3540 first_lock = second_lock;
3541 3541 second_lock = reverse_lock;
3542 3542 ufs_rename_retry_cnt++;
3543 3543 goto retry_firstlock;
3544 3544 }
3545 3545 }
3546 3546
3547 3547 if (sip == tdp) {
3548 3548 error = EINVAL;
3549 3549 goto errout;
3550 3550 }
3551 3551 /*
3552 3552 * Make sure we can delete the source entry. This requires
3553 3553 * write permission on the containing directory.
3554 3554 * Check for sticky directories.
3555 3555 */
3556 3556 rw_enter(&sdp->i_contents, RW_READER);
3557 3557 rw_enter(&sip->i_contents, RW_READER);
3558 3558 if ((error = ufs_iaccess(sdp, IWRITE, cr, 0)) != 0 ||
3559 3559 (error = ufs_sticky_remove_access(sdp, sip, cr)) != 0) {
3560 3560 rw_exit(&sip->i_contents);
3561 3561 rw_exit(&sdp->i_contents);
3562 3562 goto errout;
3563 3563 }
3564 3564
3565 3565 /*
3566 3566 * If this is a rename of a directory and the parent is
3567 3567 * different (".." must be changed), then the source
3568 3568 * directory must not be in the directory hierarchy
3569 3569 * above the target, as this would orphan everything
3570 3570 * below the source directory. Also the user must have
3571 3571 * write permission in the source so as to be able to
3572 3572 * change "..".
3573 3573 */
3574 3574 if ((((sip->i_mode & IFMT) == IFDIR) ||
3575 3575 ((sip->i_mode & IFMT) == IFATTRDIR)) && sdp != tdp) {
3576 3576 ino_t inum;
3577 3577
3578 3578 if (error = ufs_iaccess(sip, IWRITE, cr, 0)) {
3579 3579 rw_exit(&sip->i_contents);
3580 3580 rw_exit(&sdp->i_contents);
3581 3581 goto errout;
3582 3582 }
3583 3583 inum = sip->i_number;
3584 3584 rw_exit(&sip->i_contents);
3585 3585 rw_exit(&sdp->i_contents);
3586 3586 if ((error = ufs_dircheckpath(inum, tdp, sdp, cr))) {
3587 3587 /*
3588 3588 * If we got EAGAIN ufs_dircheckpath detected a
3589 3589 * potential deadlock and backed out. We need
3590 3590 * to retry the operation since sdp and tdp have
3591 3591 * to be released to avoid the deadlock.
3592 3592 */
3593 3593 if (error == EAGAIN) {
3594 3594 rw_exit(&tdp->i_rwlock);
3595 3595 if (tdp != sdp)
3596 3596 rw_exit(&sdp->i_rwlock);
3597 3597 delay(ufs_rename_backoff_delay);
3598 3598 ufs_rename_dircheck_retry_cnt++;
3599 3599 goto retry;
3600 3600 }
3601 3601 goto errout;
3602 3602 }
3603 3603 } else {
3604 3604 rw_exit(&sip->i_contents);
3605 3605 rw_exit(&sdp->i_contents);
3606 3606 }
3607 3607
3608 3608
3609 3609 /*
3610 3610 * Check for renaming '.' or '..' or alias of '.'
3611 3611 */
3612 3612 if (strcmp(snm, ".") == 0 || strcmp(snm, "..") == 0 || sdp == sip) {
3613 3613 error = EINVAL;
3614 3614 goto errout;
3615 3615 }
3616 3616
3617 3617 /*
3618 3618 * Simultaneous renames can deadlock in ufs_dircheckpath since it
3619 3619 * tries to traverse back the file tree with both tdp and sdp held
3620 3620 * as RW_WRITER. To avoid that we have to hold the tdp and sdp locks
3621 3621 * as RW_READERS till ufs_dircheckpath is done.
3622 3622 * Now that ufs_dircheckpath is done with, we can upgrade the locks
3623 3623 * to RW_WRITER.
3624 3624 */
3625 3625 if (!rw_tryupgrade(&tdp->i_rwlock)) {
3626 3626 /*
3627 3627 * The upgrade failed. We got to give away the lock
3628 3628 * as to avoid deadlocking with someone else who is
3629 3629 * waiting for writer lock. With the lock gone, we
3630 3630 * cannot be sure the checks done above will hold
3631 3631 * good when we eventually get them back as writer.
3632 3632 * So if we can't upgrade we drop the locks and retry
3633 3633 * everything again.
3634 3634 */
3635 3635 rw_exit(&tdp->i_rwlock);
3636 3636 if (tdp != sdp)
3637 3637 rw_exit(&sdp->i_rwlock);
3638 3638 delay(ufs_rename_backoff_delay);
3639 3639 ufs_rename_upgrade_retry_cnt++;
3640 3640 goto retry;
3641 3641 }
3642 3642 if (tdp != sdp) {
3643 3643 if (!rw_tryupgrade(&sdp->i_rwlock)) {
3644 3644 /*
3645 3645 * The upgrade failed. We got to give away the lock
3646 3646 * as to avoid deadlocking with someone else who is
3647 3647 * waiting for writer lock. With the lock gone, we
3648 3648 * cannot be sure the checks done above will hold
3649 3649 * good when we eventually get them back as writer.
3650 3650 * So if we can't upgrade we drop the locks and retry
3651 3651 * everything again.
3652 3652 */
3653 3653 rw_exit(&tdp->i_rwlock);
3654 3654 rw_exit(&sdp->i_rwlock);
3655 3655 delay(ufs_rename_backoff_delay);
3656 3656 ufs_rename_upgrade_retry_cnt++;
3657 3657 goto retry;
3658 3658 }
3659 3659 }
3660 3660
3661 3661 /*
3662 3662 * Now that all the locks are held check to make sure another thread
3663 3663 * didn't slip in and take out the sip.
3664 3664 */
3665 3665 slot.status = NONE;
3666 3666 if ((sip->i_ctime.tv_usec * 1000) > now.tv_nsec ||
3667 3667 sip->i_ctime.tv_sec > now.tv_sec) {
3668 3668 rw_enter(&sdp->i_ufsvfs->vfs_dqrwlock, RW_READER);
3669 3669 rw_enter(&sdp->i_contents, RW_WRITER);
3670 3670 error = ufs_dircheckforname(sdp, snm, strlen(snm), &slot,
3671 3671 &ip, cr, 0);
3672 3672 rw_exit(&sdp->i_contents);
3673 3673 rw_exit(&sdp->i_ufsvfs->vfs_dqrwlock);
3674 3674 if (error) {
3675 3675 goto errout;
3676 3676 }
3677 3677 if (ip == NULL) {
3678 3678 error = ENOENT;
3679 3679 goto errout;
3680 3680 } else {
3681 3681 /*
3682 3682 * If the inode was found need to drop the v_count
3683 3683 * so as not to keep the filesystem from being
3684 3684 * unmounted at a later time.
3685 3685 */
3686 3686 VN_RELE(ITOV(ip));
3687 3687 }
3688 3688
3689 3689 /*
3690 3690 * Release the slot.fbp that has the page mapped and
3691 3691 * locked SE_SHARED, and could be used in in
3692 3692 * ufs_direnter_lr() which needs to get the SE_EXCL lock
3693 3693 * on said page.
3694 3694 */
3695 3695 if (slot.fbp) {
3696 3696 fbrelse(slot.fbp, S_OTHER);
3697 3697 slot.fbp = NULL;
3698 3698 }
3699 3699 }
3700 3700
3701 3701 /*
3702 3702 * Link source to the target.
3703 3703 */
3704 3704 if (error = ufs_direnter_lr(tdp, tnm, DE_RENAME, sdp, sip, cr)) {
3705 3705 /*
3706 3706 * ESAME isn't really an error; it indicates that the
3707 3707 * operation should not be done because the source and target
3708 3708 * are the same file, but that no error should be reported.
3709 3709 */
3710 3710 if (error == ESAME)
3711 3711 error = 0;
3712 3712 goto errout;
3713 3713 }
3714 3714
3715 3715 /*
3716 3716 * Unlink the source.
3717 3717 * Remove the source entry. ufs_dirremove() checks that the entry
3718 3718 * still reflects sip, and returns an error if it doesn't.
3719 3719 * If the entry has changed just forget about it. Release
3720 3720 * the source inode.
3721 3721 */
3722 3722 if ((error = ufs_dirremove(sdp, snm, sip, (struct vnode *)0,
3723 3723 DR_RENAME, cr)) == ENOENT)
3724 3724 error = 0;
3725 3725
3726 3726 errout:
3727 3727 if (slot.fbp)
3728 3728 fbrelse(slot.fbp, S_OTHER);
3729 3729
3730 3730 rw_exit(&tdp->i_rwlock);
3731 3731 if (sdp != tdp) {
3732 3732 rw_exit(&sdp->i_rwlock);
3733 3733 }
3734 3734
3735 3735 VN_RELE(ITOV(sip));
3736 3736
3737 3737 unlock:
3738 3738 if (ulp) {
3739 3739 TRANS_END_CSYNC(ufsvfsp, error, issync, TOP_RENAME, trans_size);
3740 3740 ufs_lockfs_end(ulp);
3741 3741 }
3742 3742
3743 3743 out:
3744 3744 return (error);
3745 3745 }
3746 3746
3747 3747 /*ARGSUSED*/
3748 3748 static int
3749 3749 ufs_mkdir(struct vnode *dvp, char *dirname, struct vattr *vap,
3750 3750 struct vnode **vpp, struct cred *cr, caller_context_t *ct, int flags,
3751 3751 vsecattr_t *vsecp)
3752 3752 {
3753 3753 struct inode *ip;
3754 3754 struct inode *xip;
3755 3755 struct ufsvfs *ufsvfsp;
3756 3756 struct ulockfs *ulp;
3757 3757 int error;
3758 3758 int issync;
3759 3759 int trans_size;
3760 3760 int indeadlock;
3761 3761 int retry = 1;
3762 3762
3763 3763 ASSERT((vap->va_mask & (AT_TYPE|AT_MODE)) == (AT_TYPE|AT_MODE));
3764 3764
3765 3765 /*
3766 3766 * Can't make directory in attr hidden dir
3767 3767 */
3768 3768 if ((VTOI(dvp)->i_mode & IFMT) == IFATTRDIR)
3769 3769 return (EINVAL);
3770 3770
3771 3771 again:
3772 3772 ip = VTOI(dvp);
3773 3773 ufsvfsp = ip->i_ufsvfs;
3774 3774 error = ufs_lockfs_begin(ufsvfsp, &ulp, ULOCKFS_MKDIR_MASK);
3775 3775 if (error)
3776 3776 goto out;
3777 3777 if (ulp)
3778 3778 TRANS_BEGIN_CSYNC(ufsvfsp, issync, TOP_MKDIR,
3779 3779 trans_size = (int)TOP_MKDIR_SIZE(ip));
3780 3780
3781 3781 /*
3782 3782 * ufs_tryirwlock_trans uses rw_tryenter and checks for SLOCK
3783 3783 * to avoid i_rwlock, ufs_lockfs_begin deadlock. If deadlock
3784 3784 * possible, retries the operation.
3785 3785 */
3786 3786 ufs_tryirwlock_trans(&ip->i_rwlock, RW_WRITER, TOP_MKDIR, retry);
3787 3787 if (indeadlock)
3788 3788 goto again;
3789 3789
3790 3790 error = ufs_direnter_cm(ip, dirname, DE_MKDIR, vap, &xip, cr,
3791 3791 (retry ? IQUIET : 0));
3792 3792 if (error == EAGAIN) {
3793 3793 if (ulp) {
3794 3794 TRANS_END_CSYNC(ufsvfsp, error, issync, TOP_MKDIR,
3795 3795 trans_size);
3796 3796 ufs_lockfs_end(ulp);
3797 3797 }
3798 3798 goto again;
3799 3799 }
3800 3800
3801 3801 rw_exit(&ip->i_rwlock);
3802 3802 if (error == 0) {
3803 3803 ip = xip;
3804 3804 *vpp = ITOV(ip);
3805 3805 } else if (error == EEXIST)
3806 3806 VN_RELE(ITOV(xip));
3807 3807
3808 3808 if (ulp) {
3809 3809 int terr = 0;
3810 3810 TRANS_END_CSYNC(ufsvfsp, terr, issync, TOP_MKDIR, trans_size);
3811 3811 ufs_lockfs_end(ulp);
3812 3812 if (error == 0)
3813 3813 error = terr;
3814 3814 }
3815 3815 out:
3816 3816 if ((error == ENOSPC) && retry && TRANS_ISTRANS(ufsvfsp)) {
3817 3817 ufs_delete_drain_wait(ufsvfsp, 1);
3818 3818 retry = 0;
3819 3819 goto again;
3820 3820 }
3821 3821
3822 3822 return (error);
3823 3823 }
3824 3824
3825 3825 /*ARGSUSED*/
3826 3826 static int
3827 3827 ufs_rmdir(struct vnode *vp, char *nm, struct vnode *cdir, struct cred *cr,
3828 3828 caller_context_t *ct, int flags)
3829 3829 {
3830 3830 struct inode *ip = VTOI(vp);
3831 3831 struct ufsvfs *ufsvfsp = ip->i_ufsvfs;
3832 3832 struct ulockfs *ulp;
3833 3833 vnode_t *rmvp = NULL; /* Vnode of removed directory */
3834 3834 int error;
3835 3835 int issync;
3836 3836 int trans_size;
3837 3837 int indeadlock;
3838 3838
3839 3839 /*
3840 3840 * don't let the delete queue get too long
3841 3841 */
3842 3842 if (ufsvfsp == NULL) {
3843 3843 error = EIO;
3844 3844 goto out;
3845 3845 }
3846 3846 if (ufsvfsp->vfs_delete.uq_ne > ufs_idle_max)
3847 3847 ufs_delete_drain(vp->v_vfsp, 1, 1);
3848 3848
3849 3849 error = ufs_eventlookup(vp, nm, cr, &rmvp);
3850 3850 if (rmvp != NULL) {
3851 3851 /* Only send the event if there were no errors */
3852 3852 if (error == 0)
3853 3853 vnevent_rmdir(rmvp, vp, nm, ct);
3854 3854 VN_RELE(rmvp);
3855 3855 }
3856 3856
3857 3857 retry_rmdir:
3858 3858 error = ufs_lockfs_begin(ufsvfsp, &ulp, ULOCKFS_RMDIR_MASK);
3859 3859 if (error)
3860 3860 goto out;
3861 3861
3862 3862 if (ulp)
3863 3863 TRANS_BEGIN_CSYNC(ufsvfsp, issync, TOP_RMDIR,
3864 3864 trans_size = TOP_RMDIR_SIZE);
3865 3865
3866 3866 /*
3867 3867 * ufs_tryirwlock_trans uses rw_tryenter and checks for SLOCK
3868 3868 * to avoid i_rwlock, ufs_lockfs_begin deadlock. If deadlock
3869 3869 * possible, retries the operation.
3870 3870 */
3871 3871 ufs_tryirwlock_trans(&ip->i_rwlock, RW_WRITER, TOP_RMDIR, retry);
3872 3872 if (indeadlock)
3873 3873 goto retry_rmdir;
3874 3874 error = ufs_dirremove(ip, nm, (struct inode *)0, cdir, DR_RMDIR, cr);
3875 3875
3876 3876 rw_exit(&ip->i_rwlock);
3877 3877
3878 3878 if (ulp) {
3879 3879 TRANS_END_CSYNC(ufsvfsp, error, issync, TOP_RMDIR,
3880 3880 trans_size);
3881 3881 ufs_lockfs_end(ulp);
3882 3882 }
3883 3883
3884 3884 out:
3885 3885 return (error);
3886 3886 }
3887 3887
3888 3888 /* ARGSUSED */
3889 3889 static int
3890 3890 ufs_readdir(
3891 3891 struct vnode *vp,
3892 3892 struct uio *uiop,
3893 3893 struct cred *cr,
3894 3894 int *eofp,
3895 3895 caller_context_t *ct,
3896 3896 int flags)
3897 3897 {
3898 3898 struct iovec *iovp;
3899 3899 struct inode *ip;
3900 3900 struct direct *idp;
3901 3901 struct dirent64 *odp;
3902 3902 struct fbuf *fbp;
3903 3903 struct ufsvfs *ufsvfsp;
3904 3904 struct ulockfs *ulp;
3905 3905 caddr_t outbuf;
3906 3906 size_t bufsize;
3907 3907 uint_t offset;
3908 3908 uint_t bytes_wanted, total_bytes_wanted;
3909 3909 int incount = 0;
3910 3910 int outcount = 0;
3911 3911 int error;
3912 3912
3913 3913 ip = VTOI(vp);
3914 3914 ASSERT(RW_READ_HELD(&ip->i_rwlock));
3915 3915
3916 3916 if (uiop->uio_loffset >= MAXOFF32_T) {
3917 3917 if (eofp)
3918 3918 *eofp = 1;
3919 3919 return (0);
3920 3920 }
3921 3921
3922 3922 /*
3923 3923 * Check if we have been called with a valid iov_len
3924 3924 * and bail out if not, otherwise we may potentially loop
3925 3925 * forever further down.
3926 3926 */
3927 3927 if (uiop->uio_iov->iov_len <= 0) {
3928 3928 error = EINVAL;
3929 3929 goto out;
3930 3930 }
3931 3931
3932 3932 /*
3933 3933 * Large Files: When we come here we are guaranteed that
3934 3934 * uio_offset can be used safely. The high word is zero.
3935 3935 */
3936 3936
3937 3937 ufsvfsp = ip->i_ufsvfs;
3938 3938 error = ufs_lockfs_begin(ufsvfsp, &ulp, ULOCKFS_READDIR_MASK);
3939 3939 if (error)
3940 3940 goto out;
3941 3941
3942 3942 iovp = uiop->uio_iov;
3943 3943 total_bytes_wanted = iovp->iov_len;
3944 3944
3945 3945 /* Large Files: directory files should not be "large" */
3946 3946
3947 3947 ASSERT(ip->i_size <= MAXOFF32_T);
3948 3948
3949 3949 /* Force offset to be valid (to guard against bogus lseek() values) */
3950 3950 offset = (uint_t)uiop->uio_offset & ~(DIRBLKSIZ - 1);
3951 3951
3952 3952 /* Quit if at end of file or link count of zero (posix) */
3953 3953 if (offset >= (uint_t)ip->i_size || ip->i_nlink <= 0) {
3954 3954 if (eofp)
3955 3955 *eofp = 1;
3956 3956 error = 0;
3957 3957 goto unlock;
3958 3958 }
3959 3959
3960 3960 /*
3961 3961 * Get space to change directory entries into fs independent format.
3962 3962 * Do fast alloc for the most commonly used-request size (filesystem
3963 3963 * block size).
3964 3964 */
3965 3965 if (uiop->uio_segflg != UIO_SYSSPACE || uiop->uio_iovcnt != 1) {
3966 3966 bufsize = total_bytes_wanted;
3967 3967 outbuf = kmem_alloc(bufsize, KM_SLEEP);
3968 3968 odp = (struct dirent64 *)outbuf;
3969 3969 } else {
3970 3970 bufsize = total_bytes_wanted;
3971 3971 odp = (struct dirent64 *)iovp->iov_base;
3972 3972 }
3973 3973
3974 3974 nextblk:
3975 3975 bytes_wanted = total_bytes_wanted;
3976 3976
3977 3977 /* Truncate request to file size */
3978 3978 if (offset + bytes_wanted > (int)ip->i_size)
3979 3979 bytes_wanted = (int)(ip->i_size - offset);
3980 3980
3981 3981 /* Comply with MAXBSIZE boundary restrictions of fbread() */
3982 3982 if ((offset & MAXBOFFSET) + bytes_wanted > MAXBSIZE)
3983 3983 bytes_wanted = MAXBSIZE - (offset & MAXBOFFSET);
3984 3984
3985 3985 /*
3986 3986 * Read in the next chunk.
3987 3987 * We are still holding the i_rwlock.
3988 3988 */
3989 3989 error = fbread(vp, (offset_t)offset, bytes_wanted, S_OTHER, &fbp);
3990 3990
3991 3991 if (error)
3992 3992 goto update_inode;
3993 3993 if (!ULOCKFS_IS_NOIACC(ITOUL(ip)) && (ip->i_fs->fs_ronly == 0) &&
3994 3994 (!ufsvfsp->vfs_noatime)) {
3995 3995 ip->i_flag |= IACC;
3996 3996 }
3997 3997 incount = 0;
3998 3998 idp = (struct direct *)fbp->fb_addr;
3999 3999 if (idp->d_ino == 0 && idp->d_reclen == 0 && idp->d_namlen == 0) {
4000 4000 cmn_err(CE_WARN, "ufs_readdir: bad dir, inumber = %llu, "
4001 4001 "fs = %s\n",
4002 4002 (u_longlong_t)ip->i_number, ufsvfsp->vfs_fs->fs_fsmnt);
4003 4003 fbrelse(fbp, S_OTHER);
4004 4004 error = ENXIO;
4005 4005 goto update_inode;
4006 4006 }
4007 4007 /* Transform to file-system independent format */
4008 4008 while (incount < bytes_wanted) {
4009 4009 /*
4010 4010 * If the current directory entry is mangled, then skip
4011 4011 * to the next block. It would be nice to set the FSBAD
4012 4012 * flag in the super-block so that a fsck is forced on
4013 4013 * next reboot, but locking is a problem.
4014 4014 */
4015 4015 if (idp->d_reclen & 0x3) {
4016 4016 offset = (offset + DIRBLKSIZ) & ~(DIRBLKSIZ-1);
4017 4017 break;
4018 4018 }
4019 4019
4020 4020 /* Skip to requested offset and skip empty entries */
4021 4021 if (idp->d_ino != 0 && offset >= (uint_t)uiop->uio_offset) {
4022 4022 ushort_t this_reclen =
4023 4023 DIRENT64_RECLEN(idp->d_namlen);
4024 4024 /* Buffer too small for any entries */
4025 4025 if (!outcount && this_reclen > bufsize) {
4026 4026 fbrelse(fbp, S_OTHER);
4027 4027 error = EINVAL;
4028 4028 goto update_inode;
4029 4029 }
4030 4030 /* If would overrun the buffer, quit */
4031 4031 if (outcount + this_reclen > bufsize) {
4032 4032 break;
4033 4033 }
4034 4034 /* Take this entry */
4035 4035 odp->d_ino = (ino64_t)idp->d_ino;
4036 4036 odp->d_reclen = (ushort_t)this_reclen;
4037 4037 odp->d_off = (offset_t)(offset + idp->d_reclen);
4038 4038
4039 4039 /* use strncpy(9f) to zero out uninitialized bytes */
4040 4040
4041 4041 ASSERT(strlen(idp->d_name) + 1 <=
4042 4042 DIRENT64_NAMELEN(this_reclen));
4043 4043 (void) strncpy(odp->d_name, idp->d_name,
4044 4044 DIRENT64_NAMELEN(this_reclen));
4045 4045 outcount += odp->d_reclen;
4046 4046 odp = (struct dirent64 *)
4047 4047 ((intptr_t)odp + odp->d_reclen);
4048 4048 ASSERT(outcount <= bufsize);
4049 4049 }
4050 4050 if (idp->d_reclen) {
4051 4051 incount += idp->d_reclen;
4052 4052 offset += idp->d_reclen;
4053 4053 idp = (struct direct *)((intptr_t)idp + idp->d_reclen);
4054 4054 } else {
4055 4055 offset = (offset + DIRBLKSIZ) & ~(DIRBLKSIZ-1);
4056 4056 break;
4057 4057 }
4058 4058 }
4059 4059 /* Release the chunk */
4060 4060 fbrelse(fbp, S_OTHER);
4061 4061
4062 4062 /* Read whole block, but got no entries, read another if not eof */
4063 4063
4064 4064 /*
4065 4065 * Large Files: casting i_size to int here is not a problem
4066 4066 * because directory sizes are always less than MAXOFF32_T.
4067 4067 * See assertion above.
4068 4068 */
4069 4069
4070 4070 if (offset < (int)ip->i_size && !outcount)
4071 4071 goto nextblk;
4072 4072
4073 4073 /* Copy out the entry data */
4074 4074 if (uiop->uio_segflg == UIO_SYSSPACE && uiop->uio_iovcnt == 1) {
4075 4075 iovp->iov_base += outcount;
4076 4076 iovp->iov_len -= outcount;
4077 4077 uiop->uio_resid -= outcount;
4078 4078 uiop->uio_offset = offset;
4079 4079 } else if ((error = uiomove(outbuf, (long)outcount, UIO_READ,
4080 4080 uiop)) == 0)
4081 4081 uiop->uio_offset = offset;
4082 4082 update_inode:
4083 4083 ITIMES(ip);
4084 4084 if (uiop->uio_segflg != UIO_SYSSPACE || uiop->uio_iovcnt != 1)
4085 4085 kmem_free(outbuf, bufsize);
4086 4086
4087 4087 if (eofp && error == 0)
4088 4088 *eofp = (uiop->uio_offset >= (int)ip->i_size);
4089 4089 unlock:
4090 4090 if (ulp) {
4091 4091 ufs_lockfs_end(ulp);
4092 4092 }
4093 4093 out:
4094 4094 return (error);
4095 4095 }
4096 4096
4097 4097 /*ARGSUSED*/
4098 4098 static int
4099 4099 ufs_symlink(
4100 4100 struct vnode *dvp, /* ptr to parent dir vnode */
4101 4101 char *linkname, /* name of symbolic link */
4102 4102 struct vattr *vap, /* attributes */
4103 4103 char *target, /* target path */
4104 4104 struct cred *cr, /* user credentials */
4105 4105 caller_context_t *ct,
4106 4106 int flags)
4107 4107 {
4108 4108 struct inode *ip, *dip = VTOI(dvp);
4109 4109 struct ufsvfs *ufsvfsp = dip->i_ufsvfs;
4110 4110 struct ulockfs *ulp;
4111 4111 int error;
4112 4112 int issync;
4113 4113 int trans_size;
4114 4114 int residual;
4115 4115 int ioflag;
4116 4116 int retry = 1;
4117 4117
4118 4118 /*
4119 4119 * No symlinks in attrdirs at this time
4120 4120 */
4121 4121 if ((VTOI(dvp)->i_mode & IFMT) == IFATTRDIR)
4122 4122 return (EINVAL);
4123 4123
4124 4124 again:
4125 4125 ip = (struct inode *)NULL;
4126 4126 vap->va_type = VLNK;
4127 4127 vap->va_rdev = 0;
4128 4128
4129 4129 error = ufs_lockfs_begin(ufsvfsp, &ulp, ULOCKFS_SYMLINK_MASK);
4130 4130 if (error)
4131 4131 goto out;
4132 4132
4133 4133 if (ulp)
4134 4134 TRANS_BEGIN_CSYNC(ufsvfsp, issync, TOP_SYMLINK,
4135 4135 trans_size = (int)TOP_SYMLINK_SIZE(dip));
4136 4136
4137 4137 /*
4138 4138 * We must create the inode before the directory entry, to avoid
4139 4139 * racing with readlink(). ufs_dirmakeinode requires that we
4140 4140 * hold the quota lock as reader, and directory locks as writer.
4141 4141 */
4142 4142
4143 4143 rw_enter(&dip->i_rwlock, RW_WRITER);
4144 4144 rw_enter(&ufsvfsp->vfs_dqrwlock, RW_READER);
4145 4145 rw_enter(&dip->i_contents, RW_WRITER);
4146 4146
4147 4147 /*
4148 4148 * Suppress any out of inodes messages if we will retry on
4149 4149 * ENOSP
4150 4150 */
4151 4151 if (retry)
4152 4152 dip->i_flag |= IQUIET;
4153 4153
4154 4154 error = ufs_dirmakeinode(dip, &ip, vap, DE_SYMLINK, cr);
4155 4155
4156 4156 dip->i_flag &= ~IQUIET;
4157 4157
4158 4158 rw_exit(&dip->i_contents);
4159 4159 rw_exit(&ufsvfsp->vfs_dqrwlock);
4160 4160 rw_exit(&dip->i_rwlock);
4161 4161
4162 4162 if (error)
4163 4163 goto unlock;
4164 4164
4165 4165 /*
4166 4166 * OK. The inode has been created. Write out the data of the
4167 4167 * symbolic link. Since symbolic links are metadata, and should
4168 4168 * remain consistent across a system crash, we need to force the
4169 4169 * data out synchronously.
4170 4170 *
4171 4171 * (This is a change from the semantics in earlier releases, which
4172 4172 * only created symbolic links synchronously if the semi-documented
4173 4173 * 'syncdir' option was set, or if we were being invoked by the NFS
4174 4174 * server, which requires symbolic links to be created synchronously.)
4175 4175 *
4176 4176 * We need to pass in a pointer for the residual length; otherwise
4177 4177 * ufs_rdwri() will always return EIO if it can't write the data,
4178 4178 * even if the error was really ENOSPC or EDQUOT.
4179 4179 */
4180 4180
4181 4181 ioflag = FWRITE | FDSYNC;
4182 4182 residual = 0;
4183 4183
4184 4184 rw_enter(&ufsvfsp->vfs_dqrwlock, RW_READER);
4185 4185 rw_enter(&ip->i_contents, RW_WRITER);
4186 4186
4187 4187 /*
4188 4188 * Suppress file system full messages if we will retry
4189 4189 */
4190 4190 if (retry)
4191 4191 ip->i_flag |= IQUIET;
4192 4192
4193 4193 error = ufs_rdwri(UIO_WRITE, ioflag, ip, target, strlen(target),
4194 4194 (offset_t)0, UIO_SYSSPACE, &residual, cr);
4195 4195
4196 4196 ip->i_flag &= ~IQUIET;
4197 4197
4198 4198 if (error) {
4199 4199 rw_exit(&ip->i_contents);
4200 4200 rw_exit(&ufsvfsp->vfs_dqrwlock);
4201 4201 goto remove;
4202 4202 }
4203 4203
4204 4204 /*
4205 4205 * If the link's data is small enough, we can cache it in the inode.
4206 4206 * This is a "fast symbolic link". We don't use the first direct
4207 4207 * block because that's actually used to point at the symbolic link's
4208 4208 * contents on disk; but we know that none of the other direct or
4209 4209 * indirect blocks can be used because symbolic links are restricted
4210 4210 * to be smaller than a file system block.
4211 4211 */
4212 4212
4213 4213 ASSERT(MAXPATHLEN <= VBSIZE(ITOV(ip)));
4214 4214
4215 4215 if (ip->i_size > 0 && ip->i_size <= FSL_SIZE) {
4216 4216 if (kcopy(target, &ip->i_db[1], ip->i_size) == 0) {
4217 4217 ip->i_flag |= IFASTSYMLNK;
4218 4218 } else {
4219 4219 int i;
4220 4220 /* error, clear garbage left behind */
4221 4221 for (i = 1; i < NDADDR; i++)
4222 4222 ip->i_db[i] = 0;
4223 4223 for (i = 0; i < NIADDR; i++)
4224 4224 ip->i_ib[i] = 0;
4225 4225 }
4226 4226 }
4227 4227
4228 4228 rw_exit(&ip->i_contents);
4229 4229 rw_exit(&ufsvfsp->vfs_dqrwlock);
4230 4230
4231 4231 /*
4232 4232 * OK. We've successfully created the symbolic link. All that
4233 4233 * remains is to insert it into the appropriate directory.
4234 4234 */
4235 4235
4236 4236 rw_enter(&dip->i_rwlock, RW_WRITER);
4237 4237 error = ufs_direnter_lr(dip, linkname, DE_SYMLINK, NULL, ip, cr);
4238 4238 rw_exit(&dip->i_rwlock);
4239 4239
4240 4240 /*
4241 4241 * Fall through into remove-on-error code. We're either done, or we
4242 4242 * need to remove the inode (if we couldn't insert it).
4243 4243 */
4244 4244
4245 4245 remove:
4246 4246 if (error && (ip != NULL)) {
4247 4247 rw_enter(&ip->i_contents, RW_WRITER);
4248 4248 ip->i_nlink--;
4249 4249 ip->i_flag |= ICHG;
4250 4250 ip->i_seq++;
4251 4251 ufs_setreclaim(ip);
4252 4252 rw_exit(&ip->i_contents);
4253 4253 }
4254 4254
4255 4255 unlock:
4256 4256 if (ip != NULL)
4257 4257 VN_RELE(ITOV(ip));
4258 4258
4259 4259 if (ulp) {
4260 4260 int terr = 0;
4261 4261
4262 4262 TRANS_END_CSYNC(ufsvfsp, terr, issync, TOP_SYMLINK,
4263 4263 trans_size);
4264 4264 ufs_lockfs_end(ulp);
4265 4265 if (error == 0)
4266 4266 error = terr;
4267 4267 }
4268 4268
4269 4269 /*
4270 4270 * We may have failed due to lack of an inode or of a block to
4271 4271 * store the target in. Try flushing the delete queue to free
4272 4272 * logically-available things up and try again.
4273 4273 */
4274 4274 if ((error == ENOSPC) && retry && TRANS_ISTRANS(ufsvfsp)) {
4275 4275 ufs_delete_drain_wait(ufsvfsp, 1);
4276 4276 retry = 0;
4277 4277 goto again;
4278 4278 }
4279 4279
4280 4280 out:
4281 4281 return (error);
4282 4282 }
4283 4283
4284 4284 /*
4285 4285 * Ufs specific routine used to do ufs io.
4286 4286 */
4287 4287 int
4288 4288 ufs_rdwri(enum uio_rw rw, int ioflag, struct inode *ip, caddr_t base,
4289 4289 ssize_t len, offset_t offset, enum uio_seg seg, int *aresid,
4290 4290 struct cred *cr)
4291 4291 {
4292 4292 struct uio auio;
4293 4293 struct iovec aiov;
4294 4294 int error;
4295 4295
4296 4296 ASSERT(RW_LOCK_HELD(&ip->i_contents));
4297 4297
4298 4298 bzero((caddr_t)&auio, sizeof (uio_t));
4299 4299 bzero((caddr_t)&aiov, sizeof (iovec_t));
4300 4300
4301 4301 aiov.iov_base = base;
4302 4302 aiov.iov_len = len;
4303 4303 auio.uio_iov = &aiov;
4304 4304 auio.uio_iovcnt = 1;
4305 4305 auio.uio_loffset = offset;
4306 4306 auio.uio_segflg = (short)seg;
4307 4307 auio.uio_resid = len;
4308 4308
4309 4309 if (rw == UIO_WRITE) {
4310 4310 auio.uio_fmode = FWRITE;
4311 4311 auio.uio_extflg = UIO_COPY_DEFAULT;
4312 4312 auio.uio_llimit = curproc->p_fsz_ctl;
4313 4313 error = wrip(ip, &auio, ioflag, cr);
4314 4314 } else {
4315 4315 auio.uio_fmode = FREAD;
4316 4316 auio.uio_extflg = UIO_COPY_CACHED;
4317 4317 auio.uio_llimit = MAXOFFSET_T;
4318 4318 error = rdip(ip, &auio, ioflag, cr);
4319 4319 }
4320 4320
4321 4321 if (aresid) {
4322 4322 *aresid = auio.uio_resid;
4323 4323 } else if (auio.uio_resid) {
4324 4324 error = EIO;
4325 4325 }
4326 4326 return (error);
4327 4327 }
4328 4328
4329 4329 /*ARGSUSED*/
4330 4330 static int
4331 4331 ufs_fid(struct vnode *vp, struct fid *fidp, caller_context_t *ct)
4332 4332 {
4333 4333 struct ufid *ufid;
4334 4334 struct inode *ip = VTOI(vp);
4335 4335
4336 4336 if (ip->i_ufsvfs == NULL)
4337 4337 return (EIO);
4338 4338
4339 4339 if (fidp->fid_len < (sizeof (struct ufid) - sizeof (ushort_t))) {
4340 4340 fidp->fid_len = sizeof (struct ufid) - sizeof (ushort_t);
4341 4341 return (ENOSPC);
4342 4342 }
4343 4343
4344 4344 ufid = (struct ufid *)fidp;
4345 4345 bzero((char *)ufid, sizeof (struct ufid));
4346 4346 ufid->ufid_len = sizeof (struct ufid) - sizeof (ushort_t);
4347 4347 ufid->ufid_ino = ip->i_number;
4348 4348 ufid->ufid_gen = ip->i_gen;
4349 4349
4350 4350 return (0);
4351 4351 }
4352 4352
4353 4353 /* ARGSUSED2 */
4354 4354 static int
4355 4355 ufs_rwlock(struct vnode *vp, int write_lock, caller_context_t *ctp)
4356 4356 {
4357 4357 struct inode *ip = VTOI(vp);
4358 4358 struct ufsvfs *ufsvfsp;
4359 4359 int forcedirectio;
4360 4360
4361 4361 /*
4362 4362 * Read case is easy.
4363 4363 */
4364 4364 if (!write_lock) {
4365 4365 rw_enter(&ip->i_rwlock, RW_READER);
4366 4366 return (V_WRITELOCK_FALSE);
4367 4367 }
4368 4368
4369 4369 /*
4370 4370 * Caller has requested a writer lock, but that inhibits any
4371 4371 * concurrency in the VOPs that follow. Acquire the lock shared
4372 4372 * and defer exclusive access until it is known to be needed in
4373 4373 * other VOP handlers. Some cases can be determined here.
4374 4374 */
4375 4375
4376 4376 /*
4377 4377 * If directio is not set, there is no chance of concurrency,
4378 4378 * so just acquire the lock exclusive. Beware of a forced
4379 4379 * unmount before looking at the mount option.
4380 4380 */
4381 4381 ufsvfsp = ip->i_ufsvfs;
4382 4382 forcedirectio = ufsvfsp ? ufsvfsp->vfs_forcedirectio : 0;
4383 4383 if (!(ip->i_flag & IDIRECTIO || forcedirectio) ||
4384 4384 !ufs_allow_shared_writes) {
4385 4385 rw_enter(&ip->i_rwlock, RW_WRITER);
4386 4386 return (V_WRITELOCK_TRUE);
4387 4387 }
4388 4388
4389 4389 /*
4390 4390 * Mandatory locking forces acquiring i_rwlock exclusive.
4391 4391 */
4392 4392 if (MANDLOCK(vp, ip->i_mode)) {
4393 4393 rw_enter(&ip->i_rwlock, RW_WRITER);
4394 4394 return (V_WRITELOCK_TRUE);
4395 4395 }
4396 4396
4397 4397 /*
4398 4398 * Acquire the lock shared in case a concurrent write follows.
4399 4399 * Mandatory locking could have become enabled before the lock
4400 4400 * was acquired. Re-check and upgrade if needed.
4401 4401 */
4402 4402 rw_enter(&ip->i_rwlock, RW_READER);
4403 4403 if (MANDLOCK(vp, ip->i_mode)) {
4404 4404 rw_exit(&ip->i_rwlock);
4405 4405 rw_enter(&ip->i_rwlock, RW_WRITER);
4406 4406 return (V_WRITELOCK_TRUE);
4407 4407 }
4408 4408 return (V_WRITELOCK_FALSE);
4409 4409 }
4410 4410
4411 4411 /*ARGSUSED*/
4412 4412 static void
4413 4413 ufs_rwunlock(struct vnode *vp, int write_lock, caller_context_t *ctp)
4414 4414 {
4415 4415 struct inode *ip = VTOI(vp);
4416 4416
4417 4417 rw_exit(&ip->i_rwlock);
4418 4418 }
4419 4419
4420 4420 /* ARGSUSED */
4421 4421 static int
4422 4422 ufs_seek(struct vnode *vp, offset_t ooff, offset_t *noffp,
4423 4423 caller_context_t *ct)
4424 4424 {
4425 4425 return ((*noffp < 0 || *noffp > MAXOFFSET_T) ? EINVAL : 0);
4426 4426 }
4427 4427
4428 4428 /* ARGSUSED */
4429 4429 static int
4430 4430 ufs_frlock(struct vnode *vp, int cmd, struct flock64 *bfp, int flag,
4431 4431 offset_t offset, struct flk_callback *flk_cbp, struct cred *cr,
4432 4432 caller_context_t *ct)
4433 4433 {
4434 4434 struct inode *ip = VTOI(vp);
4435 4435
4436 4436 if (ip->i_ufsvfs == NULL)
4437 4437 return (EIO);
4438 4438
4439 4439 /*
4440 4440 * If file is being mapped, disallow frlock.
4441 4441 * XXX I am not holding tlock while checking i_mapcnt because the
4442 4442 * current locking strategy drops all locks before calling fs_frlock.
4443 4443 * So, mapcnt could change before we enter fs_frlock making is
4444 4444 * meaningless to have held tlock in the first place.
4445 4445 */
4446 4446 if (ip->i_mapcnt > 0 && MANDLOCK(vp, ip->i_mode))
4447 4447 return (EAGAIN);
4448 4448 return (fs_frlock(vp, cmd, bfp, flag, offset, flk_cbp, cr, ct));
4449 4449 }
4450 4450
4451 4451 /* ARGSUSED */
4452 4452 static int
4453 4453 ufs_space(struct vnode *vp, int cmd, struct flock64 *bfp, int flag,
4454 4454 offset_t offset, cred_t *cr, caller_context_t *ct)
4455 4455 {
4456 4456 struct ufsvfs *ufsvfsp = VTOI(vp)->i_ufsvfs;
4457 4457 struct ulockfs *ulp;
4458 4458 int error;
4459 4459
4460 4460 if ((error = convoff(vp, bfp, 0, offset)) == 0) {
4461 4461 if (cmd == F_FREESP) {
4462 4462 error = ufs_lockfs_begin(ufsvfsp, &ulp,
4463 4463 ULOCKFS_SPACE_MASK);
4464 4464 if (error)
4465 4465 return (error);
4466 4466 error = ufs_freesp(vp, bfp, flag, cr);
4467 4467
4468 4468 if (error == 0 && bfp->l_start == 0)
4469 4469 vnevent_truncate(vp, ct);
4470 4470 } else if (cmd == F_ALLOCSP) {
4471 4471 error = ufs_lockfs_begin(ufsvfsp, &ulp,
4472 4472 ULOCKFS_FALLOCATE_MASK);
4473 4473 if (error)
4474 4474 return (error);
4475 4475 error = ufs_allocsp(vp, bfp, cr);
4476 4476 } else
4477 4477 return (EINVAL); /* Command not handled here */
4478 4478
4479 4479 if (ulp)
4480 4480 ufs_lockfs_end(ulp);
4481 4481
4482 4482 }
4483 4483 return (error);
4484 4484 }
4485 4485
4486 4486 /*
4487 4487 * Used to determine if read ahead should be done. Also used to
4488 4488 * to determine when write back occurs.
4489 4489 */
4490 4490 #define CLUSTSZ(ip) ((ip)->i_ufsvfs->vfs_ioclustsz)
4491 4491
4492 4492 /*
4493 4493 * A faster version of ufs_getpage.
4494 4494 *
4495 4495 * We optimize by inlining the pvn_getpages iterator, eliminating
4496 4496 * calls to bmap_read if file doesn't have UFS holes, and avoiding
4497 4497 * the overhead of page_exists().
4498 4498 *
4499 4499 * When files has UFS_HOLES and ufs_getpage is called with S_READ,
4500 4500 * we set *protp to PROT_READ to avoid calling bmap_read. This approach
4501 4501 * victimizes performance when a file with UFS holes is faulted
4502 4502 * first in the S_READ mode, and then in the S_WRITE mode. We will get
4503 4503 * two MMU faults in this case.
4504 4504 *
4505 4505 * XXX - the inode fields which control the sequential mode are not
4506 4506 * protected by any mutex. The read ahead will act wild if
4507 4507 * multiple processes will access the file concurrently and
4508 4508 * some of them in sequential mode. One particulary bad case
4509 4509 * is if another thread will change the value of i_nextrio between
4510 4510 * the time this thread tests the i_nextrio value and then reads it
4511 4511 * again to use it as the offset for the read ahead.
4512 4512 */
4513 4513 /*ARGSUSED*/
4514 4514 static int
4515 4515 ufs_getpage(struct vnode *vp, offset_t off, size_t len, uint_t *protp,
4516 4516 page_t *plarr[], size_t plsz, struct seg *seg, caddr_t addr,
4517 4517 enum seg_rw rw, struct cred *cr, caller_context_t *ct)
4518 4518 {
4519 4519 u_offset_t uoff = (u_offset_t)off; /* type conversion */
4520 4520 u_offset_t pgoff;
4521 4521 u_offset_t eoff;
4522 4522 struct inode *ip = VTOI(vp);
4523 4523 struct ufsvfs *ufsvfsp = ip->i_ufsvfs;
4524 4524 struct fs *fs;
4525 4525 struct ulockfs *ulp;
4526 4526 page_t **pl;
4527 4527 caddr_t pgaddr;
4528 4528 krw_t rwtype;
4529 4529 int err;
4530 4530 int has_holes;
4531 4531 int beyond_eof;
4532 4532 int seqmode;
4533 4533 int pgsize = PAGESIZE;
4534 4534 int dolock;
4535 4535 int do_qlock;
4536 4536 int trans_size;
4537 4537
4538 4538 ASSERT((uoff & PAGEOFFSET) == 0);
4539 4539
4540 4540 if (protp)
4541 4541 *protp = PROT_ALL;
4542 4542
4543 4543 /*
4544 4544 * Obey the lockfs protocol
4545 4545 */
4546 4546 err = ufs_lockfs_begin_getpage(ufsvfsp, &ulp, seg,
4547 4547 rw == S_READ || rw == S_EXEC, protp);
4548 4548 if (err)
4549 4549 goto out;
4550 4550
4551 4551 fs = ufsvfsp->vfs_fs;
4552 4552
4553 4553 if (ulp && (rw == S_CREATE || rw == S_WRITE) &&
4554 4554 !(vp->v_flag & VISSWAP)) {
4555 4555 /*
4556 4556 * Try to start a transaction, will return if blocking is
4557 4557 * expected to occur and the address space is not the
4558 4558 * kernel address space.
4559 4559 */
4560 4560 trans_size = TOP_GETPAGE_SIZE(ip);
4561 4561 if (seg->s_as != &kas) {
4562 4562 TRANS_TRY_BEGIN_ASYNC(ufsvfsp, TOP_GETPAGE,
4563 4563 trans_size, err)
4564 4564 if (err == EWOULDBLOCK) {
4565 4565 /*
4566 4566 * Use EDEADLK here because the VM code
4567 4567 * can normally never see this error.
4568 4568 */
4569 4569 err = EDEADLK;
4570 4570 ufs_lockfs_end(ulp);
4571 4571 goto out;
4572 4572 }
4573 4573 } else {
4574 4574 TRANS_BEGIN_ASYNC(ufsvfsp, TOP_GETPAGE, trans_size);
4575 4575 }
4576 4576 }
4577 4577
4578 4578 if (vp->v_flag & VNOMAP) {
4579 4579 err = ENOSYS;
4580 4580 goto unlock;
4581 4581 }
4582 4582
4583 4583 seqmode = ip->i_nextr == uoff && rw != S_CREATE;
4584 4584
4585 4585 rwtype = RW_READER; /* start as a reader */
4586 4586 dolock = (rw_owner(&ip->i_contents) != curthread);
4587 4587 /*
4588 4588 * If this thread owns the lock, i.e., this thread grabbed it
4589 4589 * as writer somewhere above, then we don't need to grab the
4590 4590 * lock as reader in this routine.
4591 4591 */
4592 4592 do_qlock = (rw_owner(&ufsvfsp->vfs_dqrwlock) != curthread);
4593 4593
4594 4594 retrylock:
4595 4595 if (dolock) {
4596 4596 /*
4597 4597 * Grab the quota lock if we need to call
4598 4598 * bmap_write() below (with i_contents as writer).
4599 4599 */
4600 4600 if (do_qlock && rwtype == RW_WRITER)
4601 4601 rw_enter(&ufsvfsp->vfs_dqrwlock, RW_READER);
4602 4602 rw_enter(&ip->i_contents, rwtype);
4603 4603 }
4604 4604
4605 4605 /*
4606 4606 * We may be getting called as a side effect of a bmap using
4607 4607 * fbread() when the blocks might be being allocated and the
4608 4608 * size has not yet been up'ed. In this case we want to be
4609 4609 * able to return zero pages if we get back UFS_HOLE from
4610 4610 * calling bmap for a non write case here. We also might have
4611 4611 * to read some frags from the disk into a page if we are
4612 4612 * extending the number of frags for a given lbn in bmap().
4613 4613 * Large Files: The read of i_size here is atomic because
4614 4614 * i_contents is held here. If dolock is zero, the lock
4615 4615 * is held in bmap routines.
4616 4616 */
4617 4617 beyond_eof = uoff + len >
4618 4618 P2ROUNDUP_TYPED(ip->i_size, PAGESIZE, u_offset_t);
4619 4619 if (beyond_eof && seg != segkmap) {
4620 4620 if (dolock) {
4621 4621 rw_exit(&ip->i_contents);
4622 4622 if (do_qlock && rwtype == RW_WRITER)
4623 4623 rw_exit(&ufsvfsp->vfs_dqrwlock);
4624 4624 }
4625 4625 err = EFAULT;
4626 4626 goto unlock;
4627 4627 }
4628 4628
4629 4629 /*
4630 4630 * Must hold i_contents lock throughout the call to pvn_getpages
4631 4631 * since locked pages are returned from each call to ufs_getapage.
4632 4632 * Must *not* return locked pages and then try for contents lock
4633 4633 * due to lock ordering requirements (inode > page)
4634 4634 */
4635 4635
4636 4636 has_holes = bmap_has_holes(ip);
4637 4637
4638 4638 if ((rw == S_WRITE || rw == S_CREATE) && has_holes && !beyond_eof) {
4639 4639 int blk_size;
4640 4640 u_offset_t offset;
4641 4641
4642 4642 /*
4643 4643 * We must acquire the RW_WRITER lock in order to
4644 4644 * call bmap_write().
4645 4645 */
4646 4646 if (dolock && rwtype == RW_READER) {
4647 4647 rwtype = RW_WRITER;
4648 4648
4649 4649 /*
4650 4650 * Grab the quota lock before
4651 4651 * upgrading i_contents, but if we can't grab it
4652 4652 * don't wait here due to lock order:
4653 4653 * vfs_dqrwlock > i_contents.
4654 4654 */
4655 4655 if (do_qlock &&
4656 4656 rw_tryenter(&ufsvfsp->vfs_dqrwlock, RW_READER)
4657 4657 == 0) {
4658 4658 rw_exit(&ip->i_contents);
4659 4659 goto retrylock;
4660 4660 }
4661 4661 if (!rw_tryupgrade(&ip->i_contents)) {
4662 4662 rw_exit(&ip->i_contents);
4663 4663 if (do_qlock)
4664 4664 rw_exit(&ufsvfsp->vfs_dqrwlock);
4665 4665 goto retrylock;
4666 4666 }
4667 4667 }
4668 4668
4669 4669 /*
4670 4670 * May be allocating disk blocks for holes here as
4671 4671 * a result of mmap faults. write(2) does the bmap_write
4672 4672 * in rdip/wrip, not here. We are not dealing with frags
4673 4673 * in this case.
4674 4674 */
4675 4675 /*
4676 4676 * Large Files: We cast fs_bmask field to offset_t
4677 4677 * just as we do for MAXBMASK because uoff is a 64-bit
4678 4678 * data type. fs_bmask will still be a 32-bit type
4679 4679 * as we cannot change any ondisk data structures.
4680 4680 */
4681 4681
4682 4682 offset = uoff & (offset_t)fs->fs_bmask;
4683 4683 while (offset < uoff + len) {
4684 4684 blk_size = (int)blksize(fs, ip, lblkno(fs, offset));
4685 4685 err = bmap_write(ip, offset, blk_size,
4686 4686 BI_NORMAL, NULL, cr);
4687 4687 if (ip->i_flag & (ICHG|IUPD))
4688 4688 ip->i_seq++;
4689 4689 if (err)
4690 4690 goto update_inode;
4691 4691 offset += blk_size; /* XXX - make this contig */
4692 4692 }
4693 4693 }
4694 4694
4695 4695 /*
4696 4696 * Can be a reader from now on.
4697 4697 */
4698 4698 if (dolock && rwtype == RW_WRITER) {
4699 4699 rw_downgrade(&ip->i_contents);
4700 4700 /*
4701 4701 * We can release vfs_dqrwlock early so do it, but make
4702 4702 * sure we don't try to release it again at the bottom.
4703 4703 */
4704 4704 if (do_qlock) {
4705 4705 rw_exit(&ufsvfsp->vfs_dqrwlock);
4706 4706 do_qlock = 0;
4707 4707 }
4708 4708 }
4709 4709
4710 4710 /*
4711 4711 * We remove PROT_WRITE in cases when the file has UFS holes
4712 4712 * because we don't want to call bmap_read() to check each
4713 4713 * page if it is backed with a disk block.
4714 4714 */
4715 4715 if (protp && has_holes && rw != S_WRITE && rw != S_CREATE)
4716 4716 *protp &= ~PROT_WRITE;
4717 4717
4718 4718 err = 0;
4719 4719
4720 4720 /*
4721 4721 * The loop looks up pages in the range [off, off + len).
4722 4722 * For each page, we first check if we should initiate an asynchronous
4723 4723 * read ahead before we call page_lookup (we may sleep in page_lookup
4724 4724 * for a previously initiated disk read).
4725 4725 */
4726 4726 eoff = (uoff + len);
4727 4727 for (pgoff = uoff, pgaddr = addr, pl = plarr;
4728 4728 pgoff < eoff; /* empty */) {
4729 4729 page_t *pp;
4730 4730 u_offset_t nextrio;
4731 4731 se_t se;
4732 4732 int retval;
4733 4733
4734 4734 se = ((rw == S_CREATE || rw == S_OTHER) ? SE_EXCL : SE_SHARED);
4735 4735
4736 4736 /* Handle async getpage (faultahead) */
4737 4737 if (plarr == NULL) {
4738 4738 ip->i_nextrio = pgoff;
4739 4739 (void) ufs_getpage_ra(vp, pgoff, seg, pgaddr);
4740 4740 pgoff += pgsize;
4741 4741 pgaddr += pgsize;
4742 4742 continue;
4743 4743 }
4744 4744 /*
4745 4745 * Check if we should initiate read ahead of next cluster.
4746 4746 * We call page_exists only when we need to confirm that
4747 4747 * we have the current page before we initiate the read ahead.
4748 4748 */
4749 4749 nextrio = ip->i_nextrio;
4750 4750 if (seqmode &&
4751 4751 pgoff + CLUSTSZ(ip) >= nextrio && pgoff <= nextrio &&
4752 4752 nextrio < ip->i_size && page_exists(vp, pgoff)) {
4753 4753 retval = ufs_getpage_ra(vp, pgoff, seg, pgaddr);
4754 4754 /*
4755 4755 * We always read ahead the next cluster of data
4756 4756 * starting from i_nextrio. If the page (vp,nextrio)
4757 4757 * is actually in core at this point, the routine
4758 4758 * ufs_getpage_ra() will stop pre-fetching data
4759 4759 * until we read that page in a synchronized manner
4760 4760 * through ufs_getpage_miss(). So, we should increase
4761 4761 * i_nextrio if the page (vp, nextrio) exists.
4762 4762 */
4763 4763 if ((retval == 0) && page_exists(vp, nextrio)) {
4764 4764 ip->i_nextrio = nextrio + pgsize;
4765 4765 }
4766 4766 }
4767 4767
4768 4768 if ((pp = page_lookup(vp, pgoff, se)) != NULL) {
4769 4769 /*
4770 4770 * We found the page in the page cache.
4771 4771 */
4772 4772 *pl++ = pp;
4773 4773 pgoff += pgsize;
4774 4774 pgaddr += pgsize;
4775 4775 len -= pgsize;
4776 4776 plsz -= pgsize;
4777 4777 } else {
4778 4778 /*
4779 4779 * We have to create the page, or read it from disk.
4780 4780 */
4781 4781 if (err = ufs_getpage_miss(vp, pgoff, len, seg, pgaddr,
4782 4782 pl, plsz, rw, seqmode))
4783 4783 goto error;
4784 4784
4785 4785 while (*pl != NULL) {
4786 4786 pl++;
4787 4787 pgoff += pgsize;
4788 4788 pgaddr += pgsize;
4789 4789 len -= pgsize;
4790 4790 plsz -= pgsize;
4791 4791 }
4792 4792 }
4793 4793 }
4794 4794
4795 4795 /*
4796 4796 * Return pages up to plsz if they are in the page cache.
4797 4797 * We cannot return pages if there is a chance that they are
4798 4798 * backed with a UFS hole and rw is S_WRITE or S_CREATE.
4799 4799 */
4800 4800 if (plarr && !(has_holes && (rw == S_WRITE || rw == S_CREATE))) {
4801 4801
4802 4802 ASSERT((protp == NULL) ||
4803 4803 !(has_holes && (*protp & PROT_WRITE)));
4804 4804
4805 4805 eoff = pgoff + plsz;
4806 4806 while (pgoff < eoff) {
4807 4807 page_t *pp;
4808 4808
4809 4809 if ((pp = page_lookup_nowait(vp, pgoff,
4810 4810 SE_SHARED)) == NULL)
4811 4811 break;
4812 4812
4813 4813 *pl++ = pp;
4814 4814 pgoff += pgsize;
4815 4815 plsz -= pgsize;
4816 4816 }
4817 4817 }
4818 4818
4819 4819 if (plarr)
4820 4820 *pl = NULL; /* Terminate page list */
4821 4821 ip->i_nextr = pgoff;
4822 4822
4823 4823 error:
4824 4824 if (err && plarr) {
4825 4825 /*
4826 4826 * Release any pages we have locked.
4827 4827 */
4828 4828 while (pl > &plarr[0])
4829 4829 page_unlock(*--pl);
4830 4830
4831 4831 plarr[0] = NULL;
4832 4832 }
4833 4833
4834 4834 update_inode:
4835 4835 /*
4836 4836 * If the inode is not already marked for IACC (in rdip() for read)
4837 4837 * and the inode is not marked for no access time update (in wrip()
4838 4838 * for write) then update the inode access time and mod time now.
4839 4839 */
4840 4840 if ((ip->i_flag & (IACC | INOACC)) == 0) {
4841 4841 if ((rw != S_OTHER) && (ip->i_mode & IFMT) != IFDIR) {
4842 4842 if (!ULOCKFS_IS_NOIACC(ITOUL(ip)) &&
4843 4843 (fs->fs_ronly == 0) &&
4844 4844 (!ufsvfsp->vfs_noatime)) {
4845 4845 mutex_enter(&ip->i_tlock);
4846 4846 ip->i_flag |= IACC;
4847 4847 ITIMES_NOLOCK(ip);
4848 4848 mutex_exit(&ip->i_tlock);
4849 4849 }
4850 4850 }
4851 4851 }
4852 4852
4853 4853 if (dolock) {
4854 4854 rw_exit(&ip->i_contents);
4855 4855 if (do_qlock && rwtype == RW_WRITER)
4856 4856 rw_exit(&ufsvfsp->vfs_dqrwlock);
4857 4857 }
4858 4858
4859 4859 unlock:
4860 4860 if (ulp) {
4861 4861 if ((rw == S_CREATE || rw == S_WRITE) &&
4862 4862 !(vp->v_flag & VISSWAP)) {
4863 4863 TRANS_END_ASYNC(ufsvfsp, TOP_GETPAGE, trans_size);
4864 4864 }
4865 4865 ufs_lockfs_end(ulp);
4866 4866 }
4867 4867 out:
4868 4868 return (err);
4869 4869 }
4870 4870
4871 4871 /*
4872 4872 * ufs_getpage_miss is called when ufs_getpage missed the page in the page
4873 4873 * cache. The page is either read from the disk, or it's created.
4874 4874 * A page is created (without disk read) if rw == S_CREATE, or if
4875 4875 * the page is not backed with a real disk block (UFS hole).
4876 4876 */
4877 4877 /* ARGSUSED */
4878 4878 static int
4879 4879 ufs_getpage_miss(struct vnode *vp, u_offset_t off, size_t len, struct seg *seg,
4880 4880 caddr_t addr, page_t *pl[], size_t plsz, enum seg_rw rw, int seq)
4881 4881 {
4882 4882 struct inode *ip = VTOI(vp);
4883 4883 page_t *pp;
4884 4884 daddr_t bn;
4885 4885 size_t io_len;
4886 4886 int crpage = 0;
4887 4887 int err;
4888 4888 int contig;
4889 4889 int bsize = ip->i_fs->fs_bsize;
4890 4890
4891 4891 /*
4892 4892 * Figure out whether the page can be created, or must be
4893 4893 * must be read from the disk.
4894 4894 */
4895 4895 if (rw == S_CREATE)
4896 4896 crpage = 1;
4897 4897 else {
4898 4898 contig = 0;
4899 4899 if (err = bmap_read(ip, off, &bn, &contig))
4900 4900 return (err);
4901 4901
4902 4902 crpage = (bn == UFS_HOLE);
4903 4903
4904 4904 /*
4905 4905 * If its also a fallocated block that hasn't been written to
4906 4906 * yet, we will treat it just like a UFS_HOLE and create
4907 4907 * a zero page for it
4908 4908 */
4909 4909 if (ISFALLOCBLK(ip, bn))
4910 4910 crpage = 1;
4911 4911 }
4912 4912
4913 4913 if (crpage) {
4914 4914 if ((pp = page_create_va(vp, off, PAGESIZE, PG_WAIT, seg,
4915 4915 addr)) == NULL) {
4916 4916 return (ufs_fault(vp,
4917 4917 "ufs_getpage_miss: page_create == NULL"));
4918 4918 }
4919 4919
4920 4920 if (rw != S_CREATE)
4921 4921 pagezero(pp, 0, PAGESIZE);
4922 4922
4923 4923 io_len = PAGESIZE;
4924 4924 } else {
4925 4925 u_offset_t io_off;
4926 4926 uint_t xlen;
4927 4927 struct buf *bp;
4928 4928 ufsvfs_t *ufsvfsp = ip->i_ufsvfs;
4929 4929
4930 4930 /*
4931 4931 * If access is not in sequential order, we read from disk
4932 4932 * in bsize units.
4933 4933 *
4934 4934 * We limit the size of the transfer to bsize if we are reading
4935 4935 * from the beginning of the file. Note in this situation we
4936 4936 * will hedge our bets and initiate an async read ahead of
4937 4937 * the second block.
4938 4938 */
4939 4939 if (!seq || off == 0)
4940 4940 contig = MIN(contig, bsize);
4941 4941
4942 4942 pp = pvn_read_kluster(vp, off, seg, addr, &io_off,
4943 4943 &io_len, off, contig, 0);
4944 4944
4945 4945 /*
4946 4946 * Some other thread has entered the page.
4947 4947 * ufs_getpage will retry page_lookup.
4948 4948 */
4949 4949 if (pp == NULL) {
4950 4950 pl[0] = NULL;
4951 4951 return (0);
4952 4952 }
4953 4953
4954 4954 /*
4955 4955 * Zero part of the page which we are not
4956 4956 * going to read from the disk.
4957 4957 */
4958 4958 xlen = io_len & PAGEOFFSET;
4959 4959 if (xlen != 0)
4960 4960 pagezero(pp->p_prev, xlen, PAGESIZE - xlen);
4961 4961
4962 4962 bp = pageio_setup(pp, io_len, ip->i_devvp, B_READ);
4963 4963 bp->b_edev = ip->i_dev;
4964 4964 bp->b_dev = cmpdev(ip->i_dev);
4965 4965 bp->b_blkno = bn;
4966 4966 bp->b_un.b_addr = (caddr_t)0;
4967 4967 bp->b_file = ip->i_vnode;
4968 4968 bp->b_offset = off;
4969 4969
4970 4970 if (ufsvfsp->vfs_log) {
4971 4971 lufs_read_strategy(ufsvfsp->vfs_log, bp);
4972 4972 } else if (ufsvfsp->vfs_snapshot) {
4973 4973 fssnap_strategy(&ufsvfsp->vfs_snapshot, bp);
4974 4974 } else {
4975 4975 ufsvfsp->vfs_iotstamp = ddi_get_lbolt();
4976 4976 ub.ub_getpages.value.ul++;
4977 4977 (void) bdev_strategy(bp);
4978 4978 lwp_stat_update(LWP_STAT_INBLK, 1);
4979 4979 }
4980 4980
4981 4981 ip->i_nextrio = off + ((io_len + PAGESIZE - 1) & PAGEMASK);
4982 4982
4983 4983 /*
4984 4984 * If the file access is sequential, initiate read ahead
4985 4985 * of the next cluster.
4986 4986 */
4987 4987 if (seq && ip->i_nextrio < ip->i_size)
4988 4988 (void) ufs_getpage_ra(vp, off, seg, addr);
4989 4989 err = biowait(bp);
4990 4990 pageio_done(bp);
4991 4991
4992 4992 if (err) {
4993 4993 pvn_read_done(pp, B_ERROR);
4994 4994 return (err);
4995 4995 }
4996 4996 }
4997 4997
4998 4998 pvn_plist_init(pp, pl, plsz, off, io_len, rw);
4999 4999 return (0);
5000 5000 }
5001 5001
5002 5002 /*
5003 5003 * Read ahead a cluster from the disk. Returns the length in bytes.
5004 5004 */
5005 5005 static int
5006 5006 ufs_getpage_ra(struct vnode *vp, u_offset_t off, struct seg *seg, caddr_t addr)
5007 5007 {
5008 5008 struct inode *ip = VTOI(vp);
5009 5009 page_t *pp;
5010 5010 u_offset_t io_off = ip->i_nextrio;
5011 5011 ufsvfs_t *ufsvfsp;
5012 5012 caddr_t addr2 = addr + (io_off - off);
5013 5013 struct buf *bp;
5014 5014 daddr_t bn;
5015 5015 size_t io_len;
5016 5016 int err;
5017 5017 int contig;
5018 5018 int xlen;
5019 5019 int bsize = ip->i_fs->fs_bsize;
5020 5020
5021 5021 /*
5022 5022 * If the directio advisory is in effect on this file,
5023 5023 * then do not do buffered read ahead. Read ahead makes
5024 5024 * it more difficult on threads using directio as they
5025 5025 * will be forced to flush the pages from this vnode.
5026 5026 */
5027 5027 if ((ufsvfsp = ip->i_ufsvfs) == NULL)
5028 5028 return (0);
5029 5029 if (ip->i_flag & IDIRECTIO || ufsvfsp->vfs_forcedirectio)
5030 5030 return (0);
5031 5031
5032 5032 /*
5033 5033 * Is this test needed?
5034 5034 */
5035 5035 if (addr2 >= seg->s_base + seg->s_size)
5036 5036 return (0);
5037 5037
5038 5038 contig = 0;
5039 5039 err = bmap_read(ip, io_off, &bn, &contig);
5040 5040 /*
5041 5041 * If its a UFS_HOLE or a fallocated block, do not perform
5042 5042 * any read ahead's since there probably is nothing to read ahead
5043 5043 */
5044 5044 if (err || bn == UFS_HOLE || ISFALLOCBLK(ip, bn))
5045 5045 return (0);
5046 5046
5047 5047 /*
5048 5048 * Limit the transfer size to bsize if this is the 2nd block.
5049 5049 */
5050 5050 if (io_off == (u_offset_t)bsize)
5051 5051 contig = MIN(contig, bsize);
5052 5052
5053 5053 if ((pp = pvn_read_kluster(vp, io_off, seg, addr2, &io_off,
5054 5054 &io_len, io_off, contig, 1)) == NULL)
5055 5055 return (0);
5056 5056
5057 5057 /*
5058 5058 * Zero part of page which we are not going to read from disk
5059 5059 */
5060 5060 if ((xlen = (io_len & PAGEOFFSET)) > 0)
5061 5061 pagezero(pp->p_prev, xlen, PAGESIZE - xlen);
5062 5062
5063 5063 ip->i_nextrio = (io_off + io_len + PAGESIZE - 1) & PAGEMASK;
5064 5064
5065 5065 bp = pageio_setup(pp, io_len, ip->i_devvp, B_READ | B_ASYNC);
5066 5066 bp->b_edev = ip->i_dev;
5067 5067 bp->b_dev = cmpdev(ip->i_dev);
5068 5068 bp->b_blkno = bn;
5069 5069 bp->b_un.b_addr = (caddr_t)0;
5070 5070 bp->b_file = ip->i_vnode;
5071 5071 bp->b_offset = off;
5072 5072
5073 5073 if (ufsvfsp->vfs_log) {
5074 5074 lufs_read_strategy(ufsvfsp->vfs_log, bp);
5075 5075 } else if (ufsvfsp->vfs_snapshot) {
5076 5076 fssnap_strategy(&ufsvfsp->vfs_snapshot, bp);
5077 5077 } else {
5078 5078 ufsvfsp->vfs_iotstamp = ddi_get_lbolt();
5079 5079 ub.ub_getras.value.ul++;
5080 5080 (void) bdev_strategy(bp);
5081 5081 lwp_stat_update(LWP_STAT_INBLK, 1);
5082 5082 }
5083 5083
5084 5084 return (io_len);
5085 5085 }
5086 5086
5087 5087 int ufs_delay = 1;
5088 5088 /*
5089 5089 * Flags are composed of {B_INVAL, B_FREE, B_DONTNEED, B_FORCE, B_ASYNC}
5090 5090 *
5091 5091 * LMXXX - the inode really ought to contain a pointer to one of these
5092 5092 * async args. Stuff gunk in there and just hand the whole mess off.
5093 5093 * This would replace i_delaylen, i_delayoff.
5094 5094 */
5095 5095 /*ARGSUSED*/
5096 5096 static int
5097 5097 ufs_putpage(struct vnode *vp, offset_t off, size_t len, int flags,
5098 5098 struct cred *cr, caller_context_t *ct)
5099 5099 {
5100 5100 struct inode *ip = VTOI(vp);
5101 5101 int err = 0;
5102 5102
5103 5103 if (vp->v_count == 0) {
5104 5104 return (ufs_fault(vp, "ufs_putpage: bad v_count == 0"));
5105 5105 }
5106 5106
5107 5107 /*
5108 5108 * XXX - Why should this check be made here?
5109 5109 */
5110 5110 if (vp->v_flag & VNOMAP) {
5111 5111 err = ENOSYS;
5112 5112 goto errout;
5113 5113 }
5114 5114
5115 5115 if (ip->i_ufsvfs == NULL) {
5116 5116 err = EIO;
5117 5117 goto errout;
5118 5118 }
5119 5119
5120 5120 if (flags & B_ASYNC) {
5121 5121 if (ufs_delay && len &&
5122 5122 (flags & ~(B_ASYNC|B_DONTNEED|B_FREE)) == 0) {
5123 5123 mutex_enter(&ip->i_tlock);
5124 5124 /*
5125 5125 * If nobody stalled, start a new cluster.
5126 5126 */
5127 5127 if (ip->i_delaylen == 0) {
5128 5128 ip->i_delayoff = off;
5129 5129 ip->i_delaylen = len;
5130 5130 mutex_exit(&ip->i_tlock);
5131 5131 goto errout;
5132 5132 }
5133 5133 /*
5134 5134 * If we have a full cluster or they are not contig,
5135 5135 * then push last cluster and start over.
5136 5136 */
5137 5137 if (ip->i_delaylen >= CLUSTSZ(ip) ||
5138 5138 ip->i_delayoff + ip->i_delaylen != off) {
5139 5139 u_offset_t doff;
5140 5140 size_t dlen;
5141 5141
5142 5142 doff = ip->i_delayoff;
5143 5143 dlen = ip->i_delaylen;
5144 5144 ip->i_delayoff = off;
5145 5145 ip->i_delaylen = len;
5146 5146 mutex_exit(&ip->i_tlock);
5147 5147 err = ufs_putpages(vp, doff, dlen,
5148 5148 flags, cr);
5149 5149 /* LMXXX - flags are new val, not old */
5150 5150 goto errout;
5151 5151 }
5152 5152 /*
5153 5153 * There is something there, it's not full, and
5154 5154 * it is contig.
5155 5155 */
5156 5156 ip->i_delaylen += len;
5157 5157 mutex_exit(&ip->i_tlock);
5158 5158 goto errout;
5159 5159 }
5160 5160 /*
5161 5161 * Must have weird flags or we are not clustering.
5162 5162 */
5163 5163 }
5164 5164
5165 5165 err = ufs_putpages(vp, off, len, flags, cr);
5166 5166
5167 5167 errout:
5168 5168 return (err);
5169 5169 }
5170 5170
5171 5171 /*
5172 5172 * If len == 0, do from off to EOF.
5173 5173 *
5174 5174 * The normal cases should be len == 0 & off == 0 (entire vp list),
5175 5175 * len == MAXBSIZE (from segmap_release actions), and len == PAGESIZE
5176 5176 * (from pageout).
5177 5177 */
5178 5178 /*ARGSUSED*/
5179 5179 static int
5180 5180 ufs_putpages(
5181 5181 struct vnode *vp,
5182 5182 offset_t off,
5183 5183 size_t len,
5184 5184 int flags,
5185 5185 struct cred *cr)
5186 5186 {
5187 5187 u_offset_t io_off;
5188 5188 u_offset_t eoff;
5189 5189 struct inode *ip = VTOI(vp);
5190 5190 page_t *pp;
5191 5191 size_t io_len;
5192 5192 int err = 0;
5193 5193 int dolock;
5194 5194
5195 5195 if (vp->v_count == 0)
5196 5196 return (ufs_fault(vp, "ufs_putpages: v_count == 0"));
5197 5197 /*
5198 5198 * Acquire the readers/write inode lock before locking
5199 5199 * any pages in this inode.
5200 5200 * The inode lock is held during i/o.
5201 5201 */
5202 5202 if (len == 0) {
5203 5203 mutex_enter(&ip->i_tlock);
5204 5204 ip->i_delayoff = ip->i_delaylen = 0;
5205 5205 mutex_exit(&ip->i_tlock);
5206 5206 }
5207 5207 dolock = (rw_owner(&ip->i_contents) != curthread);
5208 5208 if (dolock) {
5209 5209 /*
5210 5210 * Must synchronize this thread and any possible thread
5211 5211 * operating in the window of vulnerability in wrip().
5212 5212 * It is dangerous to allow both a thread doing a putpage
5213 5213 * and a thread writing, so serialize them. The exception
5214 5214 * is when the thread in wrip() does something which causes
5215 5215 * a putpage operation. Then, the thread must be allowed
5216 5216 * to continue. It may encounter a bmap_read problem in
5217 5217 * ufs_putapage, but that is handled in ufs_putapage.
5218 5218 * Allow async writers to proceed, we don't want to block
5219 5219 * the pageout daemon.
5220 5220 */
5221 5221 if (ip->i_writer == curthread)
5222 5222 rw_enter(&ip->i_contents, RW_READER);
5223 5223 else {
5224 5224 for (;;) {
5225 5225 rw_enter(&ip->i_contents, RW_READER);
5226 5226 mutex_enter(&ip->i_tlock);
5227 5227 /*
5228 5228 * If there is no thread in the critical
5229 5229 * section of wrip(), then proceed.
5230 5230 * Otherwise, wait until there isn't one.
5231 5231 */
5232 5232 if (ip->i_writer == NULL) {
5233 5233 mutex_exit(&ip->i_tlock);
5234 5234 break;
5235 5235 }
5236 5236 rw_exit(&ip->i_contents);
5237 5237 /*
5238 5238 * Bounce async writers when we have a writer
5239 5239 * working on this file so we don't deadlock
5240 5240 * the pageout daemon.
5241 5241 */
5242 5242 if (flags & B_ASYNC) {
5243 5243 mutex_exit(&ip->i_tlock);
5244 5244 return (0);
5245 5245 }
5246 5246 cv_wait(&ip->i_wrcv, &ip->i_tlock);
5247 5247 mutex_exit(&ip->i_tlock);
5248 5248 }
5249 5249 }
5250 5250 }
5251 5251
5252 5252 if (!vn_has_cached_data(vp)) {
5253 5253 if (dolock)
5254 5254 rw_exit(&ip->i_contents);
5255 5255 return (0);
5256 5256 }
5257 5257
5258 5258 if (len == 0) {
5259 5259 /*
5260 5260 * Search the entire vp list for pages >= off.
5261 5261 */
5262 5262 err = pvn_vplist_dirty(vp, (u_offset_t)off, ufs_putapage,
5263 5263 flags, cr);
5264 5264 } else {
5265 5265 /*
5266 5266 * Loop over all offsets in the range looking for
5267 5267 * pages to deal with.
5268 5268 */
5269 5269 if ((eoff = blkroundup(ip->i_fs, ip->i_size)) != 0)
5270 5270 eoff = MIN(off + len, eoff);
5271 5271 else
5272 5272 eoff = off + len;
5273 5273
5274 5274 for (io_off = off; io_off < eoff; io_off += io_len) {
5275 5275 /*
5276 5276 * If we are not invalidating, synchronously
5277 5277 * freeing or writing pages, use the routine
5278 5278 * page_lookup_nowait() to prevent reclaiming
5279 5279 * them from the free list.
5280 5280 */
5281 5281 if ((flags & B_INVAL) || ((flags & B_ASYNC) == 0)) {
5282 5282 pp = page_lookup(vp, io_off,
5283 5283 (flags & (B_INVAL | B_FREE)) ?
5284 5284 SE_EXCL : SE_SHARED);
5285 5285 } else {
5286 5286 pp = page_lookup_nowait(vp, io_off,
5287 5287 (flags & B_FREE) ? SE_EXCL : SE_SHARED);
5288 5288 }
5289 5289
5290 5290 if (pp == NULL || pvn_getdirty(pp, flags) == 0)
5291 5291 io_len = PAGESIZE;
5292 5292 else {
5293 5293 u_offset_t *io_offp = &io_off;
5294 5294
5295 5295 err = ufs_putapage(vp, pp, io_offp, &io_len,
5296 5296 flags, cr);
5297 5297 if (err != 0)
5298 5298 break;
5299 5299 /*
5300 5300 * "io_off" and "io_len" are returned as
5301 5301 * the range of pages we actually wrote.
5302 5302 * This allows us to skip ahead more quickly
5303 5303 * since several pages may've been dealt
5304 5304 * with by this iteration of the loop.
5305 5305 */
5306 5306 }
5307 5307 }
5308 5308 }
5309 5309 if (err == 0 && off == 0 && (len == 0 || len >= ip->i_size)) {
5310 5310 /*
5311 5311 * We have just sync'ed back all the pages on
5312 5312 * the inode, turn off the IMODTIME flag.
5313 5313 */
5314 5314 mutex_enter(&ip->i_tlock);
5315 5315 ip->i_flag &= ~IMODTIME;
5316 5316 mutex_exit(&ip->i_tlock);
5317 5317 }
5318 5318 if (dolock)
5319 5319 rw_exit(&ip->i_contents);
5320 5320 return (err);
5321 5321 }
5322 5322
5323 5323 static void
5324 5324 ufs_iodone(buf_t *bp)
5325 5325 {
5326 5326 struct inode *ip;
5327 5327
5328 5328 ASSERT((bp->b_pages->p_vnode != NULL) && !(bp->b_flags & B_READ));
5329 5329
5330 5330 bp->b_iodone = NULL;
5331 5331
5332 5332 ip = VTOI(bp->b_pages->p_vnode);
5333 5333
5334 5334 mutex_enter(&ip->i_tlock);
5335 5335 if (ip->i_writes >= ufs_LW) {
5336 5336 if ((ip->i_writes -= bp->b_bcount) <= ufs_LW)
5337 5337 if (ufs_WRITES)
5338 5338 cv_broadcast(&ip->i_wrcv); /* wake all up */
5339 5339 } else {
5340 5340 ip->i_writes -= bp->b_bcount;
5341 5341 }
5342 5342
5343 5343 mutex_exit(&ip->i_tlock);
5344 5344 iodone(bp);
5345 5345 }
5346 5346
5347 5347 /*
5348 5348 * Write out a single page, possibly klustering adjacent
5349 5349 * dirty pages. The inode lock must be held.
5350 5350 *
5351 5351 * LMXXX - bsize < pagesize not done.
5352 5352 */
5353 5353 /*ARGSUSED*/
5354 5354 int
5355 5355 ufs_putapage(
5356 5356 struct vnode *vp,
5357 5357 page_t *pp,
5358 5358 u_offset_t *offp,
5359 5359 size_t *lenp, /* return values */
5360 5360 int flags,
5361 5361 struct cred *cr)
5362 5362 {
5363 5363 u_offset_t io_off;
5364 5364 u_offset_t off;
5365 5365 struct inode *ip = VTOI(vp);
5366 5366 struct ufsvfs *ufsvfsp = ip->i_ufsvfs;
5367 5367 struct fs *fs;
5368 5368 struct buf *bp;
5369 5369 size_t io_len;
5370 5370 daddr_t bn;
5371 5371 int err;
5372 5372 int contig;
5373 5373 int dotrans;
5374 5374
5375 5375 ASSERT(RW_LOCK_HELD(&ip->i_contents));
5376 5376
5377 5377 if (ufsvfsp == NULL) {
5378 5378 err = EIO;
5379 5379 goto out_trace;
5380 5380 }
5381 5381
5382 5382 fs = ip->i_fs;
5383 5383 ASSERT(fs->fs_ronly == 0);
5384 5384
5385 5385 /*
5386 5386 * If the modified time on the inode has not already been
5387 5387 * set elsewhere (e.g. for write/setattr) we set the time now.
5388 5388 * This gives us approximate modified times for mmap'ed files
5389 5389 * which are modified via stores in the user address space.
5390 5390 */
5391 5391 if ((ip->i_flag & IMODTIME) == 0) {
5392 5392 mutex_enter(&ip->i_tlock);
5393 5393 ip->i_flag |= IUPD;
5394 5394 ip->i_seq++;
5395 5395 ITIMES_NOLOCK(ip);
5396 5396 mutex_exit(&ip->i_tlock);
5397 5397 }
5398 5398
5399 5399 /*
5400 5400 * Align the request to a block boundry (for old file systems),
5401 5401 * and go ask bmap() how contiguous things are for this file.
5402 5402 */
5403 5403 off = pp->p_offset & (offset_t)fs->fs_bmask; /* block align it */
5404 5404 contig = 0;
5405 5405 err = bmap_read(ip, off, &bn, &contig);
5406 5406 if (err)
5407 5407 goto out;
5408 5408 if (bn == UFS_HOLE) { /* putpage never allocates */
5409 5409 /*
5410 5410 * logging device is in error mode; simply return EIO
5411 5411 */
5412 5412 if (TRANS_ISERROR(ufsvfsp)) {
5413 5413 err = EIO;
5414 5414 goto out;
5415 5415 }
5416 5416 /*
5417 5417 * Oops, the thread in the window in wrip() did some
5418 5418 * sort of operation which caused a putpage in the bad
5419 5419 * range. In this case, just return an error which will
5420 5420 * cause the software modified bit on the page to set
5421 5421 * and the page will get written out again later.
5422 5422 */
5423 5423 if (ip->i_writer == curthread) {
5424 5424 err = EIO;
5425 5425 goto out;
5426 5426 }
5427 5427 /*
5428 5428 * If the pager is trying to push a page in the bad range
5429 5429 * just tell him to try again later when things are better.
5430 5430 */
5431 5431 if (flags & B_ASYNC) {
5432 5432 err = EAGAIN;
5433 5433 goto out;
5434 5434 }
5435 5435 err = ufs_fault(ITOV(ip), "ufs_putapage: bn == UFS_HOLE");
5436 5436 goto out;
5437 5437 }
5438 5438
5439 5439 /*
5440 5440 * If it is an fallocate'd block, reverse the negativity since
5441 5441 * we are now writing to it
5442 5442 */
5443 5443 if (ISFALLOCBLK(ip, bn)) {
5444 5444 err = bmap_set_bn(vp, off, dbtofsb(fs, -bn));
5445 5445 if (err)
5446 5446 goto out;
5447 5447
5448 5448 bn = -bn;
5449 5449 }
5450 5450
5451 5451 /*
5452 5452 * Take the length (of contiguous bytes) passed back from bmap()
5453 5453 * and _try_ and get a set of pages covering that extent.
5454 5454 */
5455 5455 pp = pvn_write_kluster(vp, pp, &io_off, &io_len, off, contig, flags);
5456 5456
5457 5457 /*
5458 5458 * May have run out of memory and not clustered backwards.
5459 5459 * off p_offset
5460 5460 * [ pp - 1 ][ pp ]
5461 5461 * [ block ]
5462 5462 * We told bmap off, so we have to adjust the bn accordingly.
5463 5463 */
5464 5464 if (io_off > off) {
5465 5465 bn += btod(io_off - off);
5466 5466 contig -= (io_off - off);
5467 5467 }
5468 5468
5469 5469 /*
5470 5470 * bmap was carefull to tell us the right size so use that.
5471 5471 * There might be unallocated frags at the end.
5472 5472 * LMXXX - bzero the end of the page? We must be writing after EOF.
5473 5473 */
5474 5474 if (io_len > contig) {
5475 5475 ASSERT(io_len - contig < fs->fs_bsize);
5476 5476 io_len -= (io_len - contig);
5477 5477 }
5478 5478
5479 5479 /*
5480 5480 * Handle the case where we are writing the last page after EOF.
5481 5481 *
5482 5482 * XXX - just a patch for i-mt3.
5483 5483 */
5484 5484 if (io_len == 0) {
5485 5485 ASSERT(pp->p_offset >=
5486 5486 (u_offset_t)(roundup(ip->i_size, PAGESIZE)));
5487 5487 io_len = PAGESIZE;
5488 5488 }
5489 5489
5490 5490 bp = pageio_setup(pp, io_len, ip->i_devvp, B_WRITE | flags);
5491 5491
5492 5492 ULOCKFS_SET_MOD(ITOUL(ip));
5493 5493
5494 5494 bp->b_edev = ip->i_dev;
5495 5495 bp->b_dev = cmpdev(ip->i_dev);
5496 5496 bp->b_blkno = bn;
5497 5497 bp->b_un.b_addr = (caddr_t)0;
5498 5498 bp->b_file = ip->i_vnode;
5499 5499
5500 5500 /*
5501 5501 * File contents of shadow or quota inodes are metadata, and updates
5502 5502 * to these need to be put into a logging transaction. All direct
5503 5503 * callers in UFS do that, but fsflush can come here _before_ the
5504 5504 * normal codepath. An example would be updating ACL information, for
5505 5505 * which the normal codepath would be:
5506 5506 * ufs_si_store()
5507 5507 * ufs_rdwri()
5508 5508 * wrip()
5509 5509 * segmap_release()
5510 5510 * VOP_PUTPAGE()
5511 5511 * Here, fsflush can pick up the dirty page before segmap_release()
5512 5512 * forces it out. If that happens, there's no transaction.
5513 5513 * We therefore need to test whether a transaction exists, and if not
5514 5514 * create one - for fsflush.
5515 5515 */
5516 5516 dotrans =
5517 5517 (((ip->i_mode & IFMT) == IFSHAD || ufsvfsp->vfs_qinod == ip) &&
5518 5518 ((curthread->t_flag & T_DONTBLOCK) == 0) &&
5519 5519 (TRANS_ISTRANS(ufsvfsp)));
5520 5520
5521 5521 if (dotrans) {
5522 5522 curthread->t_flag |= T_DONTBLOCK;
5523 5523 TRANS_BEGIN_ASYNC(ufsvfsp, TOP_PUTPAGE, TOP_PUTPAGE_SIZE(ip));
5524 5524 }
5525 5525 if (TRANS_ISTRANS(ufsvfsp)) {
5526 5526 if ((ip->i_mode & IFMT) == IFSHAD) {
5527 5527 TRANS_BUF(ufsvfsp, 0, io_len, bp, DT_SHAD);
5528 5528 } else if (ufsvfsp->vfs_qinod == ip) {
5529 5529 TRANS_DELTA(ufsvfsp, ldbtob(bn), bp->b_bcount, DT_QR,
5530 5530 0, 0);
5531 5531 }
5532 5532 }
5533 5533 if (dotrans) {
5534 5534 TRANS_END_ASYNC(ufsvfsp, TOP_PUTPAGE, TOP_PUTPAGE_SIZE(ip));
5535 5535 curthread->t_flag &= ~T_DONTBLOCK;
5536 5536 }
5537 5537
5538 5538 /* write throttle */
5539 5539
5540 5540 ASSERT(bp->b_iodone == NULL);
5541 5541 bp->b_iodone = (int (*)())ufs_iodone;
5542 5542 mutex_enter(&ip->i_tlock);
5543 5543 ip->i_writes += bp->b_bcount;
5544 5544 mutex_exit(&ip->i_tlock);
5545 5545
5546 5546 if (bp->b_flags & B_ASYNC) {
5547 5547 if (ufsvfsp->vfs_log) {
5548 5548 lufs_write_strategy(ufsvfsp->vfs_log, bp);
5549 5549 } else if (ufsvfsp->vfs_snapshot) {
5550 5550 fssnap_strategy(&ufsvfsp->vfs_snapshot, bp);
5551 5551 } else {
5552 5552 ufsvfsp->vfs_iotstamp = ddi_get_lbolt();
5553 5553 ub.ub_putasyncs.value.ul++;
5554 5554 (void) bdev_strategy(bp);
5555 5555 lwp_stat_update(LWP_STAT_OUBLK, 1);
5556 5556 }
5557 5557 } else {
5558 5558 if (ufsvfsp->vfs_log) {
5559 5559 lufs_write_strategy(ufsvfsp->vfs_log, bp);
5560 5560 } else if (ufsvfsp->vfs_snapshot) {
5561 5561 fssnap_strategy(&ufsvfsp->vfs_snapshot, bp);
5562 5562 } else {
5563 5563 ufsvfsp->vfs_iotstamp = ddi_get_lbolt();
5564 5564 ub.ub_putsyncs.value.ul++;
5565 5565 (void) bdev_strategy(bp);
5566 5566 lwp_stat_update(LWP_STAT_OUBLK, 1);
5567 5567 }
5568 5568 err = biowait(bp);
5569 5569 pageio_done(bp);
5570 5570 pvn_write_done(pp, ((err) ? B_ERROR : 0) | B_WRITE | flags);
5571 5571 }
5572 5572
5573 5573 pp = NULL;
5574 5574
5575 5575 out:
5576 5576 if (err != 0 && pp != NULL)
5577 5577 pvn_write_done(pp, B_ERROR | B_WRITE | flags);
5578 5578
5579 5579 if (offp)
5580 5580 *offp = io_off;
5581 5581 if (lenp)
5582 5582 *lenp = io_len;
5583 5583 out_trace:
5584 5584 return (err);
5585 5585 }
5586 5586
5587 5587 uint64_t ufs_map_alock_retry_cnt;
5588 5588 uint64_t ufs_map_lockfs_retry_cnt;
5589 5589
5590 5590 /* ARGSUSED */
5591 5591 static int
5592 5592 ufs_map(struct vnode *vp,
5593 5593 offset_t off,
5594 5594 struct as *as,
5595 5595 caddr_t *addrp,
5596 5596 size_t len,
5597 5597 uchar_t prot,
5598 5598 uchar_t maxprot,
5599 5599 uint_t flags,
5600 5600 struct cred *cr,
5601 5601 caller_context_t *ct)
5602 5602 {
5603 5603 struct segvn_crargs vn_a;
5604 5604 struct ufsvfs *ufsvfsp = VTOI(vp)->i_ufsvfs;
5605 5605 struct ulockfs *ulp;
5606 5606 int error, sig;
5607 5607 k_sigset_t smask;
5608 5608 caddr_t hint = *addrp;
5609 5609
5610 5610 if (vp->v_flag & VNOMAP) {
5611 5611 error = ENOSYS;
5612 5612 goto out;
5613 5613 }
5614 5614
5615 5615 if (off < (offset_t)0 || (offset_t)(off + len) < (offset_t)0) {
5616 5616 error = ENXIO;
5617 5617 goto out;
5618 5618 }
5619 5619
5620 5620 if (vp->v_type != VREG) {
5621 5621 error = ENODEV;
5622 5622 goto out;
5623 5623 }
5624 5624
5625 5625 retry_map:
5626 5626 *addrp = hint;
5627 5627 /*
5628 5628 * If file is being locked, disallow mapping.
5629 5629 */
5630 5630 if (vn_has_mandatory_locks(vp, VTOI(vp)->i_mode)) {
5631 5631 error = EAGAIN;
5632 5632 goto out;
5633 5633 }
5634 5634
5635 5635 as_rangelock(as);
5636 5636 /*
5637 5637 * Note that if we are retrying (because ufs_lockfs_trybegin failed in
5638 5638 * the previous attempt), some other thread could have grabbed
5639 5639 * the same VA range if MAP_FIXED is set. In that case, choose_addr
5640 5640 * would unmap the valid VA range, that is ok.
5641 5641 */
5642 5642 error = choose_addr(as, addrp, len, off, ADDR_VACALIGN, flags);
5643 5643 if (error != 0) {
5644 5644 as_rangeunlock(as);
5645 5645 goto out;
↓ open down ↓ |
5645 lines elided |
↑ open up ↑ |
5646 5646 }
5647 5647
5648 5648 /*
5649 5649 * a_lock has to be acquired before entering the lockfs protocol
5650 5650 * because that is the order in which pagefault works. Also we cannot
5651 5651 * block on a_lock here because this waiting writer will prevent
5652 5652 * further readers like ufs_read from progressing and could cause
5653 5653 * deadlock between ufs_read/ufs_map/pagefault when a quiesce is
5654 5654 * pending.
5655 5655 */
5656 - while (!AS_LOCK_TRYENTER(as, &as->a_lock, RW_WRITER)) {
5656 + while (!AS_LOCK_TRYENTER(as, RW_WRITER)) {
5657 5657 ufs_map_alock_retry_cnt++;
5658 5658 delay(RETRY_LOCK_DELAY);
5659 5659 }
5660 5660
5661 5661 /*
5662 5662 * We can't hold as->a_lock and wait for lockfs to succeed because
5663 5663 * the proc tools might hang on a_lock, so call ufs_lockfs_trybegin()
5664 5664 * instead.
5665 5665 */
5666 5666 if (error = ufs_lockfs_trybegin(ufsvfsp, &ulp, ULOCKFS_MAP_MASK)) {
5667 5667 /*
5668 5668 * ufs_lockfs_trybegin() did not succeed. It is safer to give up
5669 5669 * as->a_lock and wait for ulp->ul_fs_lock status to change.
5670 5670 */
5671 5671 ufs_map_lockfs_retry_cnt++;
5672 - AS_LOCK_EXIT(as, &as->a_lock);
5672 + AS_LOCK_EXIT(as);
5673 5673 as_rangeunlock(as);
5674 5674 if (error == EIO)
5675 5675 goto out;
5676 5676
5677 5677 mutex_enter(&ulp->ul_lock);
5678 5678 while (ulp->ul_fs_lock & ULOCKFS_MAP_MASK) {
5679 5679 if (ULOCKFS_IS_SLOCK(ulp) || ufsvfsp->vfs_nointr) {
5680 5680 cv_wait(&ulp->ul_cv, &ulp->ul_lock);
5681 5681 } else {
5682 5682 sigintr(&smask, 1);
5683 5683 sig = cv_wait_sig(&ulp->ul_cv, &ulp->ul_lock);
5684 5684 sigunintr(&smask);
5685 5685 if (((ulp->ul_fs_lock & ULOCKFS_MAP_MASK) &&
5686 5686 !sig) || ufsvfsp->vfs_dontblock) {
5687 5687 mutex_exit(&ulp->ul_lock);
5688 5688 return (EINTR);
5689 5689 }
5690 5690 }
5691 5691 }
5692 5692 mutex_exit(&ulp->ul_lock);
5693 5693 goto retry_map;
5694 5694 }
5695 5695
5696 5696 vn_a.vp = vp;
5697 5697 vn_a.offset = (u_offset_t)off;
5698 5698 vn_a.type = flags & MAP_TYPE;
5699 5699 vn_a.prot = prot;
5700 5700 vn_a.maxprot = maxprot;
5701 5701 vn_a.cred = cr;
5702 5702 vn_a.amp = NULL;
5703 5703 vn_a.flags = flags & ~MAP_TYPE;
5704 5704 vn_a.szc = 0;
5705 5705 vn_a.lgrp_mem_policy_flags = 0;
5706 5706
5707 5707 error = as_map_locked(as, *addrp, len, segvn_create, &vn_a);
5708 5708 if (ulp)
5709 5709 ufs_lockfs_end(ulp);
5710 5710 as_rangeunlock(as);
5711 5711 out:
5712 5712 return (error);
5713 5713 }
5714 5714
5715 5715 /* ARGSUSED */
5716 5716 static int
5717 5717 ufs_addmap(struct vnode *vp,
5718 5718 offset_t off,
5719 5719 struct as *as,
5720 5720 caddr_t addr,
5721 5721 size_t len,
5722 5722 uchar_t prot,
5723 5723 uchar_t maxprot,
5724 5724 uint_t flags,
5725 5725 struct cred *cr,
5726 5726 caller_context_t *ct)
5727 5727 {
5728 5728 struct inode *ip = VTOI(vp);
5729 5729
5730 5730 if (vp->v_flag & VNOMAP) {
5731 5731 return (ENOSYS);
5732 5732 }
5733 5733
5734 5734 mutex_enter(&ip->i_tlock);
5735 5735 ip->i_mapcnt += btopr(len);
5736 5736 mutex_exit(&ip->i_tlock);
5737 5737 return (0);
5738 5738 }
5739 5739
5740 5740 /*ARGSUSED*/
5741 5741 static int
5742 5742 ufs_delmap(struct vnode *vp, offset_t off, struct as *as, caddr_t addr,
5743 5743 size_t len, uint_t prot, uint_t maxprot, uint_t flags,
5744 5744 struct cred *cr, caller_context_t *ct)
5745 5745 {
5746 5746 struct inode *ip = VTOI(vp);
5747 5747
5748 5748 if (vp->v_flag & VNOMAP) {
5749 5749 return (ENOSYS);
5750 5750 }
5751 5751
5752 5752 mutex_enter(&ip->i_tlock);
5753 5753 ip->i_mapcnt -= btopr(len); /* Count released mappings */
5754 5754 ASSERT(ip->i_mapcnt >= 0);
5755 5755 mutex_exit(&ip->i_tlock);
5756 5756 return (0);
5757 5757 }
5758 5758 /*
5759 5759 * Return the answer requested to poll() for non-device files
5760 5760 */
5761 5761 struct pollhead ufs_pollhd;
5762 5762
5763 5763 /* ARGSUSED */
5764 5764 int
5765 5765 ufs_poll(vnode_t *vp, short ev, int any, short *revp, struct pollhead **phpp,
5766 5766 caller_context_t *ct)
5767 5767 {
5768 5768 struct ufsvfs *ufsvfsp;
5769 5769
5770 5770 *revp = 0;
5771 5771 ufsvfsp = VTOI(vp)->i_ufsvfs;
5772 5772
5773 5773 if (!ufsvfsp) {
5774 5774 *revp = POLLHUP;
5775 5775 goto out;
5776 5776 }
5777 5777
5778 5778 if (ULOCKFS_IS_HLOCK(&ufsvfsp->vfs_ulockfs) ||
5779 5779 ULOCKFS_IS_ELOCK(&ufsvfsp->vfs_ulockfs)) {
5780 5780 *revp |= POLLERR;
5781 5781
5782 5782 } else {
5783 5783 if ((ev & POLLOUT) && !ufsvfsp->vfs_fs->fs_ronly &&
5784 5784 !ULOCKFS_IS_WLOCK(&ufsvfsp->vfs_ulockfs))
5785 5785 *revp |= POLLOUT;
5786 5786
5787 5787 if ((ev & POLLWRBAND) && !ufsvfsp->vfs_fs->fs_ronly &&
5788 5788 !ULOCKFS_IS_WLOCK(&ufsvfsp->vfs_ulockfs))
5789 5789 *revp |= POLLWRBAND;
5790 5790
5791 5791 if (ev & POLLIN)
5792 5792 *revp |= POLLIN;
5793 5793
5794 5794 if (ev & POLLRDNORM)
5795 5795 *revp |= POLLRDNORM;
5796 5796
5797 5797 if (ev & POLLRDBAND)
5798 5798 *revp |= POLLRDBAND;
5799 5799 }
5800 5800
5801 5801 if ((ev & POLLPRI) && (*revp & (POLLERR|POLLHUP)))
5802 5802 *revp |= POLLPRI;
5803 5803 out:
5804 5804 *phpp = !any && !*revp ? &ufs_pollhd : (struct pollhead *)NULL;
5805 5805
5806 5806 return (0);
5807 5807 }
5808 5808
5809 5809 /* ARGSUSED */
5810 5810 static int
5811 5811 ufs_l_pathconf(struct vnode *vp, int cmd, ulong_t *valp, struct cred *cr,
5812 5812 caller_context_t *ct)
5813 5813 {
5814 5814 struct ufsvfs *ufsvfsp = VTOI(vp)->i_ufsvfs;
5815 5815 struct ulockfs *ulp = NULL;
5816 5816 struct inode *sip = NULL;
5817 5817 int error;
5818 5818 struct inode *ip = VTOI(vp);
5819 5819 int issync;
5820 5820
5821 5821 error = ufs_lockfs_begin(ufsvfsp, &ulp, ULOCKFS_PATHCONF_MASK);
5822 5822 if (error)
5823 5823 return (error);
5824 5824
5825 5825 switch (cmd) {
5826 5826 /*
5827 5827 * Have to handle _PC_NAME_MAX here, because the normal way
5828 5828 * [fs_pathconf() -> VOP_STATVFS() -> ufs_statvfs()]
5829 5829 * results in a lock ordering reversal between
5830 5830 * ufs_lockfs_{begin,end}() and
5831 5831 * ufs_thread_{suspend,continue}().
5832 5832 *
5833 5833 * Keep in sync with ufs_statvfs().
5834 5834 */
5835 5835 case _PC_NAME_MAX:
5836 5836 *valp = MAXNAMLEN;
5837 5837 break;
5838 5838
5839 5839 case _PC_FILESIZEBITS:
5840 5840 if (ufsvfsp->vfs_lfflags & UFS_LARGEFILES)
5841 5841 *valp = UFS_FILESIZE_BITS;
5842 5842 else
5843 5843 *valp = 32;
5844 5844 break;
5845 5845
5846 5846 case _PC_XATTR_EXISTS:
5847 5847 if (vp->v_vfsp->vfs_flag & VFS_XATTR) {
5848 5848
5849 5849 error =
5850 5850 ufs_xattr_getattrdir(vp, &sip, LOOKUP_XATTR, cr);
5851 5851 if (error == 0 && sip != NULL) {
5852 5852 /* Start transaction */
5853 5853 if (ulp) {
5854 5854 TRANS_BEGIN_CSYNC(ufsvfsp, issync,
5855 5855 TOP_RMDIR, TOP_RMDIR_SIZE);
5856 5856 }
5857 5857 /*
5858 5858 * Is directory empty
5859 5859 */
5860 5860 rw_enter(&sip->i_rwlock, RW_WRITER);
5861 5861 rw_enter(&sip->i_contents, RW_WRITER);
5862 5862 if (ufs_xattrdirempty(sip,
5863 5863 sip->i_number, CRED())) {
5864 5864 rw_enter(&ip->i_contents, RW_WRITER);
5865 5865 ufs_unhook_shadow(ip, sip);
5866 5866 rw_exit(&ip->i_contents);
5867 5867
5868 5868 *valp = 0;
5869 5869
5870 5870 } else
5871 5871 *valp = 1;
5872 5872 rw_exit(&sip->i_contents);
5873 5873 rw_exit(&sip->i_rwlock);
5874 5874 if (ulp) {
5875 5875 TRANS_END_CSYNC(ufsvfsp, error, issync,
5876 5876 TOP_RMDIR, TOP_RMDIR_SIZE);
5877 5877 }
5878 5878 VN_RELE(ITOV(sip));
5879 5879 } else if (error == ENOENT) {
5880 5880 *valp = 0;
5881 5881 error = 0;
5882 5882 }
5883 5883 } else {
5884 5884 error = fs_pathconf(vp, cmd, valp, cr, ct);
5885 5885 }
5886 5886 break;
5887 5887
5888 5888 case _PC_ACL_ENABLED:
5889 5889 *valp = _ACL_ACLENT_ENABLED;
5890 5890 break;
5891 5891
5892 5892 case _PC_MIN_HOLE_SIZE:
5893 5893 *valp = (ulong_t)ip->i_fs->fs_bsize;
5894 5894 break;
5895 5895
5896 5896 case _PC_SATTR_ENABLED:
5897 5897 case _PC_SATTR_EXISTS:
5898 5898 *valp = vfs_has_feature(vp->v_vfsp, VFSFT_SYSATTR_VIEWS) &&
5899 5899 (vp->v_type == VREG || vp->v_type == VDIR);
5900 5900 break;
5901 5901
5902 5902 case _PC_TIMESTAMP_RESOLUTION:
5903 5903 /*
5904 5904 * UFS keeps only microsecond timestamp resolution.
5905 5905 * This is historical and will probably never change.
5906 5906 */
5907 5907 *valp = 1000L;
5908 5908 break;
5909 5909
5910 5910 default:
5911 5911 error = fs_pathconf(vp, cmd, valp, cr, ct);
5912 5912 break;
5913 5913 }
5914 5914
5915 5915 if (ulp != NULL) {
5916 5916 ufs_lockfs_end(ulp);
5917 5917 }
5918 5918 return (error);
5919 5919 }
5920 5920
5921 5921 int ufs_pageio_writes, ufs_pageio_reads;
5922 5922
5923 5923 /*ARGSUSED*/
5924 5924 static int
5925 5925 ufs_pageio(struct vnode *vp, page_t *pp, u_offset_t io_off, size_t io_len,
5926 5926 int flags, struct cred *cr, caller_context_t *ct)
5927 5927 {
5928 5928 struct inode *ip = VTOI(vp);
5929 5929 struct ufsvfs *ufsvfsp;
5930 5930 page_t *npp = NULL, *opp = NULL, *cpp = pp;
5931 5931 struct buf *bp;
5932 5932 daddr_t bn;
5933 5933 size_t done_len = 0, cur_len = 0;
5934 5934 int err = 0;
5935 5935 int contig = 0;
5936 5936 int dolock;
5937 5937 int vmpss = 0;
5938 5938 struct ulockfs *ulp;
5939 5939
5940 5940 if ((flags & B_READ) && pp != NULL && pp->p_vnode == vp &&
5941 5941 vp->v_mpssdata != NULL) {
5942 5942 vmpss = 1;
5943 5943 }
5944 5944
5945 5945 dolock = (rw_owner(&ip->i_contents) != curthread);
5946 5946 /*
5947 5947 * We need a better check. Ideally, we would use another
5948 5948 * vnodeops so that hlocked and forcibly unmounted file
5949 5949 * systems would return EIO where appropriate and w/o the
5950 5950 * need for these checks.
5951 5951 */
5952 5952 if ((ufsvfsp = ip->i_ufsvfs) == NULL)
5953 5953 return (EIO);
5954 5954
5955 5955 /*
5956 5956 * For vmpss (pp can be NULL) case respect the quiesce protocol.
5957 5957 * ul_lock must be taken before locking pages so we can't use it here
5958 5958 * if pp is non NULL because segvn already locked pages
5959 5959 * SE_EXCL. Instead we rely on the fact that a forced umount or
5960 5960 * applying a filesystem lock via ufs_fiolfs() will block in the
5961 5961 * implicit call to ufs_flush() until we unlock the pages after the
5962 5962 * return to segvn. Other ufs_quiesce() callers keep ufs_quiesce_pend
5963 5963 * above 0 until they are done. We have to be careful not to increment
5964 5964 * ul_vnops_cnt here after forceful unmount hlocks the file system.
5965 5965 *
5966 5966 * If pp is NULL use ul_lock to make sure we don't increment
5967 5967 * ul_vnops_cnt after forceful unmount hlocks the file system.
5968 5968 */
5969 5969 if (vmpss || pp == NULL) {
5970 5970 ulp = &ufsvfsp->vfs_ulockfs;
5971 5971 if (pp == NULL)
5972 5972 mutex_enter(&ulp->ul_lock);
5973 5973 if (ulp->ul_fs_lock & ULOCKFS_GETREAD_MASK) {
5974 5974 if (pp == NULL) {
5975 5975 mutex_exit(&ulp->ul_lock);
5976 5976 }
5977 5977 return (vmpss ? EIO : EINVAL);
5978 5978 }
5979 5979 atomic_inc_ulong(&ulp->ul_vnops_cnt);
5980 5980 if (pp == NULL)
5981 5981 mutex_exit(&ulp->ul_lock);
5982 5982 if (ufs_quiesce_pend) {
5983 5983 if (!atomic_dec_ulong_nv(&ulp->ul_vnops_cnt))
5984 5984 cv_broadcast(&ulp->ul_cv);
5985 5985 return (vmpss ? EIO : EINVAL);
5986 5986 }
5987 5987 }
5988 5988
5989 5989 if (dolock) {
5990 5990 /*
5991 5991 * segvn may call VOP_PAGEIO() instead of VOP_GETPAGE() to
5992 5992 * handle a fault against a segment that maps vnode pages with
5993 5993 * large mappings. Segvn creates pages and holds them locked
5994 5994 * SE_EXCL during VOP_PAGEIO() call. In this case we have to
5995 5995 * use rw_tryenter() to avoid a potential deadlock since in
5996 5996 * lock order i_contents needs to be taken first.
5997 5997 * Segvn will retry via VOP_GETPAGE() if VOP_PAGEIO() fails.
5998 5998 */
5999 5999 if (!vmpss) {
6000 6000 rw_enter(&ip->i_contents, RW_READER);
6001 6001 } else if (!rw_tryenter(&ip->i_contents, RW_READER)) {
6002 6002 if (!atomic_dec_ulong_nv(&ulp->ul_vnops_cnt))
6003 6003 cv_broadcast(&ulp->ul_cv);
6004 6004 return (EDEADLK);
6005 6005 }
6006 6006 }
6007 6007
6008 6008 /*
6009 6009 * Return an error to segvn because the pagefault request is beyond
6010 6010 * PAGESIZE rounded EOF.
6011 6011 */
6012 6012 if (vmpss && btopr(io_off + io_len) > btopr(ip->i_size)) {
6013 6013 if (dolock)
6014 6014 rw_exit(&ip->i_contents);
6015 6015 if (!atomic_dec_ulong_nv(&ulp->ul_vnops_cnt))
6016 6016 cv_broadcast(&ulp->ul_cv);
6017 6017 return (EFAULT);
6018 6018 }
6019 6019
6020 6020 if (pp == NULL) {
6021 6021 if (bmap_has_holes(ip)) {
6022 6022 err = ENOSYS;
6023 6023 } else {
6024 6024 err = EINVAL;
6025 6025 }
6026 6026 if (dolock)
6027 6027 rw_exit(&ip->i_contents);
6028 6028 if (!atomic_dec_ulong_nv(&ulp->ul_vnops_cnt))
6029 6029 cv_broadcast(&ulp->ul_cv);
6030 6030 return (err);
6031 6031 }
6032 6032
6033 6033 /*
6034 6034 * Break the io request into chunks, one for each contiguous
6035 6035 * stretch of disk blocks in the target file.
6036 6036 */
6037 6037 while (done_len < io_len) {
6038 6038 ASSERT(cpp);
6039 6039 contig = 0;
6040 6040 if (err = bmap_read(ip, (u_offset_t)(io_off + done_len),
6041 6041 &bn, &contig))
6042 6042 break;
6043 6043
6044 6044 if (bn == UFS_HOLE) { /* No holey swapfiles */
6045 6045 if (vmpss) {
6046 6046 err = EFAULT;
6047 6047 break;
6048 6048 }
6049 6049 err = ufs_fault(ITOV(ip), "ufs_pageio: bn == UFS_HOLE");
6050 6050 break;
6051 6051 }
6052 6052
6053 6053 cur_len = MIN(io_len - done_len, contig);
6054 6054 /*
6055 6055 * Zero out a page beyond EOF, when the last block of
6056 6056 * a file is a UFS fragment so that ufs_pageio() can be used
6057 6057 * instead of ufs_getpage() to handle faults against
6058 6058 * segvn segments that use large pages.
6059 6059 */
6060 6060 page_list_break(&cpp, &npp, btopr(cur_len));
6061 6061 if ((flags & B_READ) && (cur_len & PAGEOFFSET)) {
6062 6062 size_t xlen = cur_len & PAGEOFFSET;
6063 6063 pagezero(cpp->p_prev, xlen, PAGESIZE - xlen);
6064 6064 }
6065 6065
6066 6066 bp = pageio_setup(cpp, cur_len, ip->i_devvp, flags);
6067 6067 ASSERT(bp != NULL);
6068 6068
6069 6069 bp->b_edev = ip->i_dev;
6070 6070 bp->b_dev = cmpdev(ip->i_dev);
6071 6071 bp->b_blkno = bn;
6072 6072 bp->b_un.b_addr = (caddr_t)0;
6073 6073 bp->b_file = ip->i_vnode;
6074 6074
6075 6075 ufsvfsp->vfs_iotstamp = ddi_get_lbolt();
6076 6076 ub.ub_pageios.value.ul++;
6077 6077 if (ufsvfsp->vfs_snapshot)
6078 6078 fssnap_strategy(&(ufsvfsp->vfs_snapshot), bp);
6079 6079 else
6080 6080 (void) bdev_strategy(bp);
6081 6081
6082 6082 if (flags & B_READ)
6083 6083 ufs_pageio_reads++;
6084 6084 else
6085 6085 ufs_pageio_writes++;
6086 6086 if (flags & B_READ)
6087 6087 lwp_stat_update(LWP_STAT_INBLK, 1);
6088 6088 else
6089 6089 lwp_stat_update(LWP_STAT_OUBLK, 1);
6090 6090 /*
6091 6091 * If the request is not B_ASYNC, wait for i/o to complete
6092 6092 * and re-assemble the page list to return to the caller.
6093 6093 * If it is B_ASYNC we leave the page list in pieces and
6094 6094 * cleanup() will dispose of them.
6095 6095 */
6096 6096 if ((flags & B_ASYNC) == 0) {
6097 6097 err = biowait(bp);
6098 6098 pageio_done(bp);
6099 6099 if (err)
6100 6100 break;
6101 6101 page_list_concat(&opp, &cpp);
6102 6102 }
6103 6103 cpp = npp;
6104 6104 npp = NULL;
6105 6105 if (flags & B_READ)
6106 6106 cur_len = P2ROUNDUP_TYPED(cur_len, PAGESIZE, size_t);
6107 6107 done_len += cur_len;
6108 6108 }
6109 6109 ASSERT(err || (cpp == NULL && npp == NULL && done_len == io_len));
6110 6110 if (err) {
6111 6111 if (flags & B_ASYNC) {
6112 6112 /* Cleanup unprocessed parts of list */
6113 6113 page_list_concat(&cpp, &npp);
6114 6114 if (flags & B_READ)
6115 6115 pvn_read_done(cpp, B_ERROR);
6116 6116 else
6117 6117 pvn_write_done(cpp, B_ERROR);
6118 6118 } else {
6119 6119 /* Re-assemble list and let caller clean up */
6120 6120 page_list_concat(&opp, &cpp);
6121 6121 page_list_concat(&opp, &npp);
6122 6122 }
6123 6123 }
6124 6124
6125 6125 if (vmpss && !(ip->i_flag & IACC) && !ULOCKFS_IS_NOIACC(ulp) &&
6126 6126 ufsvfsp->vfs_fs->fs_ronly == 0 && !ufsvfsp->vfs_noatime) {
6127 6127 mutex_enter(&ip->i_tlock);
6128 6128 ip->i_flag |= IACC;
6129 6129 ITIMES_NOLOCK(ip);
6130 6130 mutex_exit(&ip->i_tlock);
6131 6131 }
6132 6132
6133 6133 if (dolock)
6134 6134 rw_exit(&ip->i_contents);
6135 6135 if (vmpss && !atomic_dec_ulong_nv(&ulp->ul_vnops_cnt))
6136 6136 cv_broadcast(&ulp->ul_cv);
6137 6137 return (err);
6138 6138 }
6139 6139
6140 6140 /*
6141 6141 * Called when the kernel is in a frozen state to dump data
6142 6142 * directly to the device. It uses a private dump data structure,
6143 6143 * set up by dump_ctl, to locate the correct disk block to which to dump.
6144 6144 */
6145 6145 /*ARGSUSED*/
6146 6146 static int
6147 6147 ufs_dump(vnode_t *vp, caddr_t addr, offset_t ldbn, offset_t dblks,
6148 6148 caller_context_t *ct)
6149 6149 {
6150 6150 u_offset_t file_size;
6151 6151 struct inode *ip = VTOI(vp);
6152 6152 struct fs *fs = ip->i_fs;
6153 6153 daddr_t dbn, lfsbn;
6154 6154 int disk_blks = fs->fs_bsize >> DEV_BSHIFT;
6155 6155 int error = 0;
6156 6156 int ndbs, nfsbs;
6157 6157
6158 6158 /*
6159 6159 * forced unmount case
6160 6160 */
6161 6161 if (ip->i_ufsvfs == NULL)
6162 6162 return (EIO);
6163 6163 /*
6164 6164 * Validate the inode that it has not been modified since
6165 6165 * the dump structure is allocated.
6166 6166 */
6167 6167 mutex_enter(&ip->i_tlock);
6168 6168 if ((dump_info == NULL) ||
6169 6169 (dump_info->ip != ip) ||
6170 6170 (dump_info->time.tv_sec != ip->i_mtime.tv_sec) ||
6171 6171 (dump_info->time.tv_usec != ip->i_mtime.tv_usec)) {
6172 6172 mutex_exit(&ip->i_tlock);
6173 6173 return (-1);
6174 6174 }
6175 6175 mutex_exit(&ip->i_tlock);
6176 6176
6177 6177 /*
6178 6178 * See that the file has room for this write
6179 6179 */
6180 6180 UFS_GET_ISIZE(&file_size, ip);
6181 6181
6182 6182 if (ldbtob(ldbn + dblks) > file_size)
6183 6183 return (ENOSPC);
6184 6184
6185 6185 /*
6186 6186 * Find the physical disk block numbers from the dump
6187 6187 * private data structure directly and write out the data
6188 6188 * in contiguous block lumps
6189 6189 */
6190 6190 while (dblks > 0 && !error) {
6191 6191 lfsbn = (daddr_t)lblkno(fs, ldbtob(ldbn));
6192 6192 dbn = fsbtodb(fs, dump_info->dblk[lfsbn]) + ldbn % disk_blks;
6193 6193 nfsbs = 1;
6194 6194 ndbs = disk_blks - ldbn % disk_blks;
6195 6195 while (ndbs < dblks && fsbtodb(fs, dump_info->dblk[lfsbn +
6196 6196 nfsbs]) == dbn + ndbs) {
6197 6197 nfsbs++;
6198 6198 ndbs += disk_blks;
6199 6199 }
6200 6200 if (ndbs > dblks)
6201 6201 ndbs = dblks;
6202 6202 error = bdev_dump(ip->i_dev, addr, dbn, ndbs);
6203 6203 addr += ldbtob((offset_t)ndbs);
6204 6204 dblks -= ndbs;
6205 6205 ldbn += ndbs;
6206 6206 }
6207 6207 return (error);
6208 6208
6209 6209 }
6210 6210
6211 6211 /*
6212 6212 * Prepare the file system before and after the dump operation.
6213 6213 *
6214 6214 * action = DUMP_ALLOC:
6215 6215 * Preparation before dump, allocate dump private data structure
6216 6216 * to hold all the direct and indirect block info for dump.
6217 6217 *
6218 6218 * action = DUMP_FREE:
6219 6219 * Clean up after dump, deallocate the dump private data structure.
6220 6220 *
6221 6221 * action = DUMP_SCAN:
6222 6222 * Scan dump_info for *blkp DEV_BSIZE blocks of contig fs space;
6223 6223 * if found, the starting file-relative DEV_BSIZE lbn is written
6224 6224 * to *bklp; that lbn is intended for use with VOP_DUMP()
6225 6225 */
6226 6226 /*ARGSUSED*/
6227 6227 static int
6228 6228 ufs_dumpctl(vnode_t *vp, int action, offset_t *blkp, caller_context_t *ct)
6229 6229 {
6230 6230 struct inode *ip = VTOI(vp);
6231 6231 ufsvfs_t *ufsvfsp = ip->i_ufsvfs;
6232 6232 struct fs *fs;
6233 6233 daddr32_t *dblk, *storeblk;
6234 6234 daddr32_t *nextblk, *endblk;
6235 6235 struct buf *bp;
6236 6236 int i, entry, entries;
6237 6237 int n, ncontig;
6238 6238
6239 6239 /*
6240 6240 * check for forced unmount
6241 6241 */
6242 6242 if (ufsvfsp == NULL)
6243 6243 return (EIO);
6244 6244
6245 6245 if (action == DUMP_ALLOC) {
6246 6246 /*
6247 6247 * alloc and record dump_info
6248 6248 */
6249 6249 if (dump_info != NULL)
6250 6250 return (EINVAL);
6251 6251
6252 6252 ASSERT(vp->v_type == VREG);
6253 6253 fs = ufsvfsp->vfs_fs;
6254 6254
6255 6255 rw_enter(&ip->i_contents, RW_READER);
6256 6256
6257 6257 if (bmap_has_holes(ip)) {
6258 6258 rw_exit(&ip->i_contents);
6259 6259 return (EFAULT);
6260 6260 }
6261 6261
6262 6262 /*
6263 6263 * calculate and allocate space needed according to i_size
6264 6264 */
6265 6265 entries = (int)lblkno(fs, blkroundup(fs, ip->i_size));
6266 6266 dump_info = kmem_alloc(sizeof (struct dump) +
6267 6267 (entries - 1) * sizeof (daddr32_t), KM_NOSLEEP);
6268 6268 if (dump_info == NULL) {
6269 6269 rw_exit(&ip->i_contents);
6270 6270 return (ENOMEM);
6271 6271 }
6272 6272
6273 6273 /* Start saving the info */
6274 6274 dump_info->fsbs = entries;
6275 6275 dump_info->ip = ip;
6276 6276 storeblk = &dump_info->dblk[0];
6277 6277
6278 6278 /* Direct Blocks */
6279 6279 for (entry = 0; entry < NDADDR && entry < entries; entry++)
6280 6280 *storeblk++ = ip->i_db[entry];
6281 6281
6282 6282 /* Indirect Blocks */
6283 6283 for (i = 0; i < NIADDR; i++) {
6284 6284 int error = 0;
6285 6285
6286 6286 bp = UFS_BREAD(ufsvfsp,
6287 6287 ip->i_dev, fsbtodb(fs, ip->i_ib[i]), fs->fs_bsize);
6288 6288 if (bp->b_flags & B_ERROR)
6289 6289 error = EIO;
6290 6290 else {
6291 6291 dblk = bp->b_un.b_daddr;
6292 6292 if ((storeblk = save_dblks(ip, ufsvfsp,
6293 6293 storeblk, dblk, i, entries)) == NULL)
6294 6294 error = EIO;
6295 6295 }
6296 6296
6297 6297 brelse(bp);
6298 6298
6299 6299 if (error != 0) {
6300 6300 kmem_free(dump_info, sizeof (struct dump) +
6301 6301 (entries - 1) * sizeof (daddr32_t));
6302 6302 rw_exit(&ip->i_contents);
6303 6303 dump_info = NULL;
6304 6304 return (error);
6305 6305 }
6306 6306 }
6307 6307 /* and time stamp the information */
6308 6308 mutex_enter(&ip->i_tlock);
6309 6309 dump_info->time = ip->i_mtime;
6310 6310 mutex_exit(&ip->i_tlock);
6311 6311
6312 6312 rw_exit(&ip->i_contents);
6313 6313 } else if (action == DUMP_FREE) {
6314 6314 /*
6315 6315 * free dump_info
6316 6316 */
6317 6317 if (dump_info == NULL)
6318 6318 return (EINVAL);
6319 6319 entries = dump_info->fsbs - 1;
6320 6320 kmem_free(dump_info, sizeof (struct dump) +
6321 6321 entries * sizeof (daddr32_t));
6322 6322 dump_info = NULL;
6323 6323 } else if (action == DUMP_SCAN) {
6324 6324 /*
6325 6325 * scan dump_info
6326 6326 */
6327 6327 if (dump_info == NULL)
6328 6328 return (EINVAL);
6329 6329
6330 6330 dblk = dump_info->dblk;
6331 6331 nextblk = dblk + 1;
6332 6332 endblk = dblk + dump_info->fsbs - 1;
6333 6333 fs = ufsvfsp->vfs_fs;
6334 6334 ncontig = *blkp >> (fs->fs_bshift - DEV_BSHIFT);
6335 6335
6336 6336 /*
6337 6337 * scan dblk[] entries; contig fs space is found when:
6338 6338 * ((current blkno + frags per block) == next blkno)
6339 6339 */
6340 6340 n = 0;
6341 6341 while (n < ncontig && dblk < endblk) {
6342 6342 if ((*dblk + fs->fs_frag) == *nextblk)
6343 6343 n++;
6344 6344 else
6345 6345 n = 0;
6346 6346 dblk++;
6347 6347 nextblk++;
6348 6348 }
6349 6349
6350 6350 /*
6351 6351 * index is where size bytes of contig space begins;
6352 6352 * conversion from index to the file's DEV_BSIZE lbn
6353 6353 * is equivalent to: (index * fs_bsize) / DEV_BSIZE
6354 6354 */
6355 6355 if (n == ncontig) {
6356 6356 i = (dblk - dump_info->dblk) - ncontig;
6357 6357 *blkp = i << (fs->fs_bshift - DEV_BSHIFT);
6358 6358 } else
6359 6359 return (EFAULT);
6360 6360 }
6361 6361 return (0);
6362 6362 }
6363 6363
6364 6364 /*
6365 6365 * Recursive helper function for ufs_dumpctl(). It follows the indirect file
6366 6366 * system blocks until it reaches the the disk block addresses, which are
6367 6367 * then stored into the given buffer, storeblk.
6368 6368 */
6369 6369 static daddr32_t *
6370 6370 save_dblks(struct inode *ip, struct ufsvfs *ufsvfsp, daddr32_t *storeblk,
6371 6371 daddr32_t *dblk, int level, int entries)
6372 6372 {
6373 6373 struct fs *fs = ufsvfsp->vfs_fs;
6374 6374 struct buf *bp;
6375 6375 int i;
6376 6376
6377 6377 if (level == 0) {
6378 6378 for (i = 0; i < NINDIR(fs); i++) {
6379 6379 if (storeblk - dump_info->dblk >= entries)
6380 6380 break;
6381 6381 *storeblk++ = dblk[i];
6382 6382 }
6383 6383 return (storeblk);
6384 6384 }
6385 6385 for (i = 0; i < NINDIR(fs); i++) {
6386 6386 if (storeblk - dump_info->dblk >= entries)
6387 6387 break;
6388 6388 bp = UFS_BREAD(ufsvfsp,
6389 6389 ip->i_dev, fsbtodb(fs, dblk[i]), fs->fs_bsize);
6390 6390 if (bp->b_flags & B_ERROR) {
6391 6391 brelse(bp);
6392 6392 return (NULL);
6393 6393 }
6394 6394 storeblk = save_dblks(ip, ufsvfsp, storeblk, bp->b_un.b_daddr,
6395 6395 level - 1, entries);
6396 6396 brelse(bp);
6397 6397
6398 6398 if (storeblk == NULL)
6399 6399 return (NULL);
6400 6400 }
6401 6401 return (storeblk);
6402 6402 }
6403 6403
6404 6404 /* ARGSUSED */
6405 6405 static int
6406 6406 ufs_getsecattr(struct vnode *vp, vsecattr_t *vsap, int flag,
6407 6407 struct cred *cr, caller_context_t *ct)
6408 6408 {
6409 6409 struct inode *ip = VTOI(vp);
6410 6410 struct ulockfs *ulp;
6411 6411 struct ufsvfs *ufsvfsp = ip->i_ufsvfs;
6412 6412 ulong_t vsa_mask = vsap->vsa_mask;
6413 6413 int err = EINVAL;
6414 6414
6415 6415 vsa_mask &= (VSA_ACL | VSA_ACLCNT | VSA_DFACL | VSA_DFACLCNT);
6416 6416
6417 6417 /*
6418 6418 * Only grab locks if needed - they're not needed to check vsa_mask
6419 6419 * or if the mask contains no acl flags.
6420 6420 */
6421 6421 if (vsa_mask != 0) {
6422 6422 if (err = ufs_lockfs_begin(ufsvfsp, &ulp,
6423 6423 ULOCKFS_GETATTR_MASK))
6424 6424 return (err);
6425 6425
6426 6426 rw_enter(&ip->i_contents, RW_READER);
6427 6427 err = ufs_acl_get(ip, vsap, flag, cr);
6428 6428 rw_exit(&ip->i_contents);
6429 6429
6430 6430 if (ulp)
6431 6431 ufs_lockfs_end(ulp);
6432 6432 }
6433 6433 return (err);
6434 6434 }
6435 6435
6436 6436 /* ARGSUSED */
6437 6437 static int
6438 6438 ufs_setsecattr(struct vnode *vp, vsecattr_t *vsap, int flag, struct cred *cr,
6439 6439 caller_context_t *ct)
6440 6440 {
6441 6441 struct inode *ip = VTOI(vp);
6442 6442 struct ulockfs *ulp = NULL;
6443 6443 struct ufsvfs *ufsvfsp = VTOI(vp)->i_ufsvfs;
6444 6444 ulong_t vsa_mask = vsap->vsa_mask;
6445 6445 int err;
6446 6446 int haverwlock = 1;
6447 6447 int trans_size;
6448 6448 int donetrans = 0;
6449 6449 int retry = 1;
6450 6450
6451 6451 ASSERT(RW_LOCK_HELD(&ip->i_rwlock));
6452 6452
6453 6453 /* Abort now if the request is either empty or invalid. */
6454 6454 vsa_mask &= (VSA_ACL | VSA_ACLCNT | VSA_DFACL | VSA_DFACLCNT);
6455 6455 if ((vsa_mask == 0) ||
6456 6456 ((vsap->vsa_aclentp == NULL) &&
6457 6457 (vsap->vsa_dfaclentp == NULL))) {
6458 6458 err = EINVAL;
6459 6459 goto out;
6460 6460 }
6461 6461
6462 6462 /*
6463 6463 * Following convention, if this is a directory then we acquire the
6464 6464 * inode's i_rwlock after starting a UFS logging transaction;
6465 6465 * otherwise, we acquire it beforehand. Since we were called (and
6466 6466 * must therefore return) with the lock held, we will have to drop it,
6467 6467 * and later reacquire it, if operating on a directory.
6468 6468 */
6469 6469 if (vp->v_type == VDIR) {
6470 6470 rw_exit(&ip->i_rwlock);
6471 6471 haverwlock = 0;
6472 6472 } else {
6473 6473 /* Upgrade the lock if required. */
6474 6474 if (!rw_write_held(&ip->i_rwlock)) {
6475 6475 rw_exit(&ip->i_rwlock);
6476 6476 rw_enter(&ip->i_rwlock, RW_WRITER);
6477 6477 }
6478 6478 }
6479 6479
6480 6480 again:
6481 6481 ASSERT(!(vp->v_type == VDIR && haverwlock));
6482 6482 if (err = ufs_lockfs_begin(ufsvfsp, &ulp, ULOCKFS_SETATTR_MASK)) {
6483 6483 ulp = NULL;
6484 6484 retry = 0;
6485 6485 goto out;
6486 6486 }
6487 6487
6488 6488 /*
6489 6489 * Check that the file system supports this operation. Note that
6490 6490 * ufs_lockfs_begin() will have checked that the file system had
6491 6491 * not been forcibly unmounted.
6492 6492 */
6493 6493 if (ufsvfsp->vfs_fs->fs_ronly) {
6494 6494 err = EROFS;
6495 6495 goto out;
6496 6496 }
6497 6497 if (ufsvfsp->vfs_nosetsec) {
6498 6498 err = ENOSYS;
6499 6499 goto out;
6500 6500 }
6501 6501
6502 6502 if (ulp) {
6503 6503 TRANS_BEGIN_ASYNC(ufsvfsp, TOP_SETSECATTR,
6504 6504 trans_size = TOP_SETSECATTR_SIZE(VTOI(vp)));
6505 6505 donetrans = 1;
6506 6506 }
6507 6507
6508 6508 if (vp->v_type == VDIR) {
6509 6509 rw_enter(&ip->i_rwlock, RW_WRITER);
6510 6510 haverwlock = 1;
6511 6511 }
6512 6512
6513 6513 ASSERT(haverwlock);
6514 6514
6515 6515 /* Do the actual work. */
6516 6516 rw_enter(&ip->i_contents, RW_WRITER);
6517 6517 /*
6518 6518 * Suppress out of inodes messages if we will retry.
6519 6519 */
6520 6520 if (retry)
6521 6521 ip->i_flag |= IQUIET;
6522 6522 err = ufs_acl_set(ip, vsap, flag, cr);
6523 6523 ip->i_flag &= ~IQUIET;
6524 6524 rw_exit(&ip->i_contents);
6525 6525
6526 6526 out:
6527 6527 if (ulp) {
6528 6528 if (donetrans) {
6529 6529 /*
6530 6530 * top_end_async() can eventually call
6531 6531 * top_end_sync(), which can block. We must
6532 6532 * therefore observe the lock-ordering protocol
6533 6533 * here as well.
6534 6534 */
6535 6535 if (vp->v_type == VDIR) {
6536 6536 rw_exit(&ip->i_rwlock);
6537 6537 haverwlock = 0;
6538 6538 }
6539 6539 TRANS_END_ASYNC(ufsvfsp, TOP_SETSECATTR, trans_size);
6540 6540 }
6541 6541 ufs_lockfs_end(ulp);
6542 6542 }
6543 6543 /*
6544 6544 * If no inodes available, try scaring a logically-
6545 6545 * free one out of the delete queue to someplace
6546 6546 * that we can find it.
6547 6547 */
6548 6548 if ((err == ENOSPC) && retry && TRANS_ISTRANS(ufsvfsp)) {
6549 6549 ufs_delete_drain_wait(ufsvfsp, 1);
6550 6550 retry = 0;
6551 6551 if (vp->v_type == VDIR && haverwlock) {
6552 6552 rw_exit(&ip->i_rwlock);
6553 6553 haverwlock = 0;
6554 6554 }
6555 6555 goto again;
6556 6556 }
6557 6557 /*
6558 6558 * If we need to reacquire the lock then it is safe to do so
6559 6559 * as a reader. This is because ufs_rwunlock(), which will be
6560 6560 * called by our caller after we return, does not differentiate
6561 6561 * between shared and exclusive locks.
6562 6562 */
6563 6563 if (!haverwlock) {
6564 6564 ASSERT(vp->v_type == VDIR);
6565 6565 rw_enter(&ip->i_rwlock, RW_READER);
6566 6566 }
6567 6567
6568 6568 return (err);
6569 6569 }
6570 6570
6571 6571 /*
6572 6572 * Locate the vnode to be used for an event notification. As this will
6573 6573 * be called prior to the name space change perform basic verification
6574 6574 * that the change will be allowed.
6575 6575 */
6576 6576
6577 6577 static int
6578 6578 ufs_eventlookup(struct vnode *dvp, char *nm, struct cred *cr,
6579 6579 struct vnode **vpp)
6580 6580 {
6581 6581 int namlen;
6582 6582 int error;
6583 6583 struct vnode *vp;
6584 6584 struct inode *ip;
6585 6585 struct inode *xip;
6586 6586 struct ufsvfs *ufsvfsp;
6587 6587 struct ulockfs *ulp;
6588 6588
6589 6589 ip = VTOI(dvp);
6590 6590 *vpp = NULL;
6591 6591
6592 6592 if ((namlen = strlen(nm)) == 0)
6593 6593 return (EINVAL);
6594 6594
6595 6595 if (nm[0] == '.') {
6596 6596 if (namlen == 1)
6597 6597 return (EINVAL);
6598 6598 else if ((namlen == 2) && nm[1] == '.') {
6599 6599 return (EEXIST);
6600 6600 }
6601 6601 }
6602 6602
6603 6603 /*
6604 6604 * Check accessibility and write access of parent directory as we
6605 6605 * only want to post the event if we're able to make a change.
6606 6606 */
6607 6607 if (error = ufs_diraccess(ip, IEXEC|IWRITE, cr))
6608 6608 return (error);
6609 6609
6610 6610 if (vp = dnlc_lookup(dvp, nm)) {
6611 6611 if (vp == DNLC_NO_VNODE) {
6612 6612 VN_RELE(vp);
6613 6613 return (ENOENT);
6614 6614 }
6615 6615
6616 6616 *vpp = vp;
6617 6617 return (0);
6618 6618 }
6619 6619
6620 6620 /*
6621 6621 * Keep the idle queue from getting too long by idling two
6622 6622 * inodes before attempting to allocate another.
6623 6623 * This operation must be performed before entering lockfs
6624 6624 * or a transaction.
6625 6625 */
6626 6626 if (ufs_idle_q.uq_ne > ufs_idle_q.uq_hiwat)
6627 6627 if ((curthread->t_flag & T_DONTBLOCK) == 0) {
6628 6628 ins.in_lidles.value.ul += ufs_lookup_idle_count;
6629 6629 ufs_idle_some(ufs_lookup_idle_count);
6630 6630 }
6631 6631
6632 6632 ufsvfsp = ip->i_ufsvfs;
6633 6633
6634 6634 retry_lookup:
6635 6635 if (error = ufs_lockfs_begin(ufsvfsp, &ulp, ULOCKFS_LOOKUP_MASK))
6636 6636 return (error);
6637 6637
6638 6638 if ((error = ufs_dirlook(ip, nm, &xip, cr, 1, 1)) == 0) {
6639 6639 vp = ITOV(xip);
6640 6640 *vpp = vp;
6641 6641 }
6642 6642
6643 6643 if (ulp) {
6644 6644 ufs_lockfs_end(ulp);
6645 6645 }
6646 6646
6647 6647 if (error == EAGAIN)
6648 6648 goto retry_lookup;
6649 6649
6650 6650 return (error);
6651 6651 }
↓ open down ↓ |
969 lines elided |
↑ open up ↑ |
XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX