1 /* $NetBSD: udf_subr.c,v 1.103 2010/02/24 19:20:13 reinoud Exp $ */ 2 3 /* 4 * Copyright (c) 2006, 2008 Reinoud Zandijk 5 * All rights reserved. 6 * 7 * Redistribution and use in source and binary forms, with or without 8 * modification, are permitted provided that the following conditions 9 * are met: 10 * 1. Redistributions of source code must retain the above copyright 11 * notice, this list of conditions and the following disclaimer. 12 * 2. Redistributions in binary form must reproduce the above copyright 13 * notice, this list of conditions and the following disclaimer in the 14 * documentation and/or other materials provided with the distribution. 15 * 16 * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR 17 * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES 18 * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. 19 * IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT, 20 * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT 21 * NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, 22 * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY 23 * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT 24 * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF 25 * THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. 26 * 27 */ 28 29 30 #include <sys/cdefs.h> 31 #ifndef lint 32 __KERNEL_RCSID(0, "$NetBSD: udf_subr.c,v 1.103 2010/02/24 19:20:13 reinoud Exp $"); 33 #endif /* not lint */ 34 35 36 #if defined(_KERNEL_OPT) 37 #include "opt_compat_netbsd.h" 38 #endif 39 40 #include <sys/param.h> 41 #include <sys/systm.h> 42 #include <sys/sysctl.h> 43 #include <sys/namei.h> 44 #include <sys/proc.h> 45 #include <sys/kernel.h> 46 #include <sys/vnode.h> 47 #include <miscfs/genfs/genfs_node.h> 48 #include <sys/mount.h> 49 #include <sys/buf.h> 50 #include <sys/file.h> 51 #include <sys/device.h> 52 #include <sys/disklabel.h> 53 #include <sys/ioctl.h> 54 #include <sys/malloc.h> 55 #include <sys/dirent.h> 56 #include <sys/stat.h> 57 #include <sys/conf.h> 58 #include <sys/kauth.h> 59 #include <fs/unicode.h> 60 #include <dev/clock_subr.h> 61 62 #include <fs/udf/ecma167-udf.h> 63 #include <fs/udf/udf_mount.h> 64 #include <sys/dirhash.h> 65 66 #include "udf.h" 67 #include "udf_subr.h" 68 #include "udf_bswap.h" 69 70 71 #define VTOI(vnode) ((struct udf_node *) (vnode)->v_data) 72 73 #define UDF_SET_SYSTEMFILE(vp) \ 74 /* XXXAD Is the vnode locked? */ \ 75 (vp)->v_vflag |= VV_SYSTEM; \ 76 vref(vp); \ 77 vput(vp); \ 78 79 extern int syncer_maxdelay; /* maximum delay time */ 80 extern int (**udf_vnodeop_p)(void *); 81 82 /* --------------------------------------------------------------------- */ 83 84 //#ifdef DEBUG 85 #if 1 86 87 #if 0 88 static void 89 udf_dumpblob(boid *blob, uint32_t dlen) 90 { 91 int i, j; 92 93 printf("blob = %p\n", blob); 94 printf("dump of %d bytes\n", dlen); 95 96 for (i = 0; i < dlen; i+ = 16) { 97 printf("%04x ", i); 98 for (j = 0; j < 16; j++) { 99 if (i+j < dlen) { 100 printf("%02x ", blob[i+j]); 101 } else { 102 printf(" "); 103 } 104 } 105 for (j = 0; j < 16; j++) { 106 if (i+j < dlen) { 107 if (blob[i+j]>32 && blob[i+j]! = 127) { 108 printf("%c", blob[i+j]); 109 } else { 110 printf("."); 111 } 112 } 113 } 114 printf("\n"); 115 } 116 printf("\n"); 117 Debugger(); 118 } 119 #endif 120 121 static void 122 udf_dump_discinfo(struct udf_mount *ump) 123 { 124 char bits[128]; 125 struct mmc_discinfo *di = &ump->discinfo; 126 127 if ((udf_verbose & UDF_DEBUG_VOLUMES) == 0) 128 return; 129 130 printf("Device/media info :\n"); 131 printf("\tMMC profile 0x%02x\n", di->mmc_profile); 132 printf("\tderived class %d\n", di->mmc_class); 133 printf("\tsector size %d\n", di->sector_size); 134 printf("\tdisc state %d\n", di->disc_state); 135 printf("\tlast ses state %d\n", di->last_session_state); 136 printf("\tbg format state %d\n", di->bg_format_state); 137 printf("\tfrst track %d\n", di->first_track); 138 printf("\tfst on last ses %d\n", di->first_track_last_session); 139 printf("\tlst on last ses %d\n", di->last_track_last_session); 140 printf("\tlink block penalty %d\n", di->link_block_penalty); 141 snprintb(bits, sizeof(bits), MMC_DFLAGS_FLAGBITS, di->disc_flags); 142 printf("\tdisc flags %s\n", bits); 143 printf("\tdisc id %x\n", di->disc_id); 144 printf("\tdisc barcode %"PRIx64"\n", di->disc_barcode); 145 146 printf("\tnum sessions %d\n", di->num_sessions); 147 printf("\tnum tracks %d\n", di->num_tracks); 148 149 snprintb(bits, sizeof(bits), MMC_CAP_FLAGBITS, di->mmc_cur); 150 printf("\tcapabilities cur %s\n", bits); 151 snprintb(bits, sizeof(bits), MMC_CAP_FLAGBITS, di->mmc_cap); 152 printf("\tcapabilities cap %s\n", bits); 153 } 154 155 static void 156 udf_dump_trackinfo(struct mmc_trackinfo *trackinfo) 157 { 158 char bits[128]; 159 160 if ((udf_verbose & UDF_DEBUG_VOLUMES) == 0) 161 return; 162 163 printf("Trackinfo for track %d:\n", trackinfo->tracknr); 164 printf("\tsessionnr %d\n", trackinfo->sessionnr); 165 printf("\ttrack mode %d\n", trackinfo->track_mode); 166 printf("\tdata mode %d\n", trackinfo->data_mode); 167 snprintb(bits, sizeof(bits), MMC_TRACKINFO_FLAGBITS, trackinfo->flags); 168 printf("\tflags %s\n", bits); 169 170 printf("\ttrack start %d\n", trackinfo->track_start); 171 printf("\tnext_writable %d\n", trackinfo->next_writable); 172 printf("\tfree_blocks %d\n", trackinfo->free_blocks); 173 printf("\tpacket_size %d\n", trackinfo->packet_size); 174 printf("\ttrack size %d\n", trackinfo->track_size); 175 printf("\tlast recorded block %d\n", trackinfo->last_recorded); 176 } 177 178 #else 179 #define udf_dump_discinfo(a); 180 #define udf_dump_trackinfo(a); 181 #endif 182 183 184 /* --------------------------------------------------------------------- */ 185 186 /* not called often */ 187 int 188 udf_update_discinfo(struct udf_mount *ump) 189 { 190 struct vnode *devvp = ump->devvp; 191 struct partinfo dpart; 192 struct mmc_discinfo *di; 193 int error; 194 195 DPRINTF(VOLUMES, ("read/update disc info\n")); 196 di = &ump->discinfo; 197 memset(di, 0, sizeof(struct mmc_discinfo)); 198 199 /* check if we're on a MMC capable device, i.e. CD/DVD */ 200 error = VOP_IOCTL(devvp, MMCGETDISCINFO, di, FKIOCTL, NOCRED); 201 if (error == 0) { 202 udf_dump_discinfo(ump); 203 return 0; 204 } 205 206 /* disc partition support */ 207 error = VOP_IOCTL(devvp, DIOCGPART, &dpart, FREAD, NOCRED); 208 if (error) 209 return ENODEV; 210 211 /* set up a disc info profile for partitions */ 212 di->mmc_profile = 0x01; /* disc type */ 213 di->mmc_class = MMC_CLASS_DISC; 214 di->disc_state = MMC_STATE_CLOSED; 215 di->last_session_state = MMC_STATE_CLOSED; 216 di->bg_format_state = MMC_BGFSTATE_COMPLETED; 217 di->link_block_penalty = 0; 218 219 di->mmc_cur = MMC_CAP_RECORDABLE | MMC_CAP_REWRITABLE | 220 MMC_CAP_ZEROLINKBLK | MMC_CAP_HW_DEFECTFREE; 221 di->mmc_cap = di->mmc_cur; 222 di->disc_flags = MMC_DFLAGS_UNRESTRICTED; 223 224 /* TODO problem with last_possible_lba on resizable VND; request */ 225 di->last_possible_lba = dpart.part->p_size; 226 di->sector_size = dpart.disklab->d_secsize; 227 228 di->num_sessions = 1; 229 di->num_tracks = 1; 230 231 di->first_track = 1; 232 di->first_track_last_session = di->last_track_last_session = 1; 233 234 udf_dump_discinfo(ump); 235 return 0; 236 } 237 238 239 int 240 udf_update_trackinfo(struct udf_mount *ump, struct mmc_trackinfo *ti) 241 { 242 struct vnode *devvp = ump->devvp; 243 struct mmc_discinfo *di = &ump->discinfo; 244 int error, class; 245 246 DPRINTF(VOLUMES, ("read track info\n")); 247 248 class = di->mmc_class; 249 if (class != MMC_CLASS_DISC) { 250 /* tracknr specified in struct ti */ 251 error = VOP_IOCTL(devvp, MMCGETTRACKINFO, ti, FKIOCTL, NOCRED); 252 return error; 253 } 254 255 /* disc partition support */ 256 if (ti->tracknr != 1) 257 return EIO; 258 259 /* create fake ti (TODO check for resized vnds) */ 260 ti->sessionnr = 1; 261 262 ti->track_mode = 0; /* XXX */ 263 ti->data_mode = 0; /* XXX */ 264 ti->flags = MMC_TRACKINFO_LRA_VALID | MMC_TRACKINFO_NWA_VALID; 265 266 ti->track_start = 0; 267 ti->packet_size = 1; 268 269 /* TODO support for resizable vnd */ 270 ti->track_size = di->last_possible_lba; 271 ti->next_writable = di->last_possible_lba; 272 ti->last_recorded = ti->next_writable; 273 ti->free_blocks = 0; 274 275 return 0; 276 } 277 278 279 int 280 udf_setup_writeparams(struct udf_mount *ump) 281 { 282 struct mmc_writeparams mmc_writeparams; 283 int error; 284 285 if (ump->discinfo.mmc_class == MMC_CLASS_DISC) 286 return 0; 287 288 /* 289 * only CD burning normally needs setting up, but other disc types 290 * might need other settings to be made. The MMC framework will set up 291 * the nessisary recording parameters according to the disc 292 * characteristics read in. Modifications can be made in the discinfo 293 * structure passed to change the nature of the disc. 294 */ 295 296 memset(&mmc_writeparams, 0, sizeof(struct mmc_writeparams)); 297 mmc_writeparams.mmc_class = ump->discinfo.mmc_class; 298 mmc_writeparams.mmc_cur = ump->discinfo.mmc_cur; 299 300 /* 301 * UDF dictates first track to determine track mode for the whole 302 * disc. [UDF 1.50/6.10.1.1, UDF 1.50/6.10.2.1] 303 * To prevent problems with a `reserved' track in front we start with 304 * the 2nd track and if that is not valid, go for the 1st. 305 */ 306 mmc_writeparams.tracknr = 2; 307 mmc_writeparams.data_mode = MMC_DATAMODE_DEFAULT; /* XA disc */ 308 mmc_writeparams.track_mode = MMC_TRACKMODE_DEFAULT; /* data */ 309 310 error = VOP_IOCTL(ump->devvp, MMCSETUPWRITEPARAMS, &mmc_writeparams, 311 FKIOCTL, NOCRED); 312 if (error) { 313 mmc_writeparams.tracknr = 1; 314 error = VOP_IOCTL(ump->devvp, MMCSETUPWRITEPARAMS, 315 &mmc_writeparams, FKIOCTL, NOCRED); 316 } 317 return error; 318 } 319 320 321 int 322 udf_synchronise_caches(struct udf_mount *ump) 323 { 324 struct mmc_op mmc_op; 325 326 DPRINTF(CALL, ("udf_synchronise_caches()\n")); 327 328 if (ump->vfs_mountp->mnt_flag & MNT_RDONLY) 329 return 0; 330 331 /* discs are done now */ 332 if (ump->discinfo.mmc_class == MMC_CLASS_DISC) 333 return 0; 334 335 memset(&mmc_op, 0, sizeof(struct mmc_op)); 336 mmc_op.operation = MMC_OP_SYNCHRONISECACHE; 337 338 /* ignore return code */ 339 (void) VOP_IOCTL(ump->devvp, MMCOP, &mmc_op, FKIOCTL, NOCRED); 340 341 return 0; 342 } 343 344 /* --------------------------------------------------------------------- */ 345 346 /* track/session searching for mounting */ 347 int 348 udf_search_tracks(struct udf_mount *ump, struct udf_args *args, 349 int *first_tracknr, int *last_tracknr) 350 { 351 struct mmc_trackinfo trackinfo; 352 uint32_t tracknr, start_track, num_tracks; 353 int error; 354 355 /* if negative, sessionnr is relative to last session */ 356 if (args->sessionnr < 0) { 357 args->sessionnr += ump->discinfo.num_sessions; 358 } 359 360 /* sanity */ 361 if (args->sessionnr < 0) 362 args->sessionnr = 0; 363 if (args->sessionnr > ump->discinfo.num_sessions) 364 args->sessionnr = ump->discinfo.num_sessions; 365 366 /* search the tracks for this session, zero session nr indicates last */ 367 if (args->sessionnr == 0) 368 args->sessionnr = ump->discinfo.num_sessions; 369 if (ump->discinfo.last_session_state == MMC_STATE_EMPTY) 370 args->sessionnr--; 371 372 /* sanity again */ 373 if (args->sessionnr < 0) 374 args->sessionnr = 0; 375 376 /* search the first and last track of the specified session */ 377 num_tracks = ump->discinfo.num_tracks; 378 start_track = ump->discinfo.first_track; 379 380 /* search for first track of this session */ 381 for (tracknr = start_track; tracknr <= num_tracks; tracknr++) { 382 /* get track info */ 383 trackinfo.tracknr = tracknr; 384 error = udf_update_trackinfo(ump, &trackinfo); 385 if (error) 386 return error; 387 388 if (trackinfo.sessionnr == args->sessionnr) 389 break; 390 } 391 *first_tracknr = tracknr; 392 393 /* search for last track of this session */ 394 for (;tracknr <= num_tracks; tracknr++) { 395 /* get track info */ 396 trackinfo.tracknr = tracknr; 397 error = udf_update_trackinfo(ump, &trackinfo); 398 if (error || (trackinfo.sessionnr != args->sessionnr)) { 399 tracknr--; 400 break; 401 } 402 } 403 if (tracknr > num_tracks) 404 tracknr--; 405 406 *last_tracknr = tracknr; 407 408 if (*last_tracknr < *first_tracknr) { 409 printf( "udf_search_tracks: sanity check on drive+disc failed, " 410 "drive returned garbage\n"); 411 return EINVAL; 412 } 413 414 assert(*last_tracknr >= *first_tracknr); 415 return 0; 416 } 417 418 419 /* 420 * NOTE: this is the only routine in this file that directly peeks into the 421 * metadata file but since its at a larval state of the mount it can't hurt. 422 * 423 * XXX candidate for udf_allocation.c 424 * XXX clean me up!, change to new node reading code. 425 */ 426 427 static void 428 udf_check_track_metadata_overlap(struct udf_mount *ump, 429 struct mmc_trackinfo *trackinfo) 430 { 431 struct part_desc *part; 432 struct file_entry *fe; 433 struct extfile_entry *efe; 434 struct short_ad *s_ad; 435 struct long_ad *l_ad; 436 uint32_t track_start, track_end; 437 uint32_t phys_part_start, phys_part_end, part_start, part_end; 438 uint32_t sector_size, len, alloclen, plb_num; 439 uint8_t *pos; 440 int addr_type, icblen, icbflags, flags; 441 442 /* get our track extents */ 443 track_start = trackinfo->track_start; 444 track_end = track_start + trackinfo->track_size; 445 446 /* get our base partition extent */ 447 KASSERT(ump->node_part == ump->fids_part); 448 part = ump->partitions[ump->node_part]; 449 phys_part_start = udf_rw32(part->start_loc); 450 phys_part_end = phys_part_start + udf_rw32(part->part_len); 451 452 /* no use if its outside the physical partition */ 453 if ((phys_part_start >= track_end) || (phys_part_end < track_start)) 454 return; 455 456 /* 457 * now follow all extents in the fe/efe to see if they refer to this 458 * track 459 */ 460 461 sector_size = ump->discinfo.sector_size; 462 463 /* XXX should we claim exclusive access to the metafile ? */ 464 /* TODO: move to new node read code */ 465 fe = ump->metadata_node->fe; 466 efe = ump->metadata_node->efe; 467 if (fe) { 468 alloclen = udf_rw32(fe->l_ad); 469 pos = &fe->data[0] + udf_rw32(fe->l_ea); 470 icbflags = udf_rw16(fe->icbtag.flags); 471 } else { 472 assert(efe); 473 alloclen = udf_rw32(efe->l_ad); 474 pos = &efe->data[0] + udf_rw32(efe->l_ea); 475 icbflags = udf_rw16(efe->icbtag.flags); 476 } 477 addr_type = icbflags & UDF_ICB_TAG_FLAGS_ALLOC_MASK; 478 479 while (alloclen) { 480 if (addr_type == UDF_ICB_SHORT_ALLOC) { 481 icblen = sizeof(struct short_ad); 482 s_ad = (struct short_ad *) pos; 483 len = udf_rw32(s_ad->len); 484 plb_num = udf_rw32(s_ad->lb_num); 485 } else { 486 /* should not be present, but why not */ 487 icblen = sizeof(struct long_ad); 488 l_ad = (struct long_ad *) pos; 489 len = udf_rw32(l_ad->len); 490 plb_num = udf_rw32(l_ad->loc.lb_num); 491 /* pvpart_num = udf_rw16(l_ad->loc.part_num); */ 492 } 493 /* process extent */ 494 flags = UDF_EXT_FLAGS(len); 495 len = UDF_EXT_LEN(len); 496 497 part_start = phys_part_start + plb_num; 498 part_end = part_start + (len / sector_size); 499 500 if ((part_start >= track_start) && (part_end <= track_end)) { 501 /* extent is enclosed within this track */ 502 ump->metadata_track = *trackinfo; 503 return; 504 } 505 506 pos += icblen; 507 alloclen -= icblen; 508 } 509 } 510 511 512 int 513 udf_search_writing_tracks(struct udf_mount *ump) 514 { 515 struct vnode *devvp = ump->devvp; 516 struct mmc_trackinfo trackinfo; 517 struct mmc_op mmc_op; 518 struct part_desc *part; 519 uint32_t tracknr, start_track, num_tracks; 520 uint32_t track_start, track_end, part_start, part_end; 521 int node_alloc, error; 522 523 /* 524 * in the CD/(HD)DVD/BD recordable device model a few tracks within 525 * the last session might be open but in the UDF device model at most 526 * three tracks can be open: a reserved track for delayed ISO VRS 527 * writing, a data track and a metadata track. We search here for the 528 * data track and the metadata track. Note that the reserved track is 529 * troublesome but can be detected by its small size of < 512 sectors. 530 */ 531 532 /* update discinfo since it might have changed */ 533 error = udf_update_discinfo(ump); 534 if (error) 535 return error; 536 537 num_tracks = ump->discinfo.num_tracks; 538 start_track = ump->discinfo.first_track; 539 540 /* fetch info on first and possibly only track */ 541 trackinfo.tracknr = start_track; 542 error = udf_update_trackinfo(ump, &trackinfo); 543 if (error) 544 return error; 545 546 /* copy results to our mount point */ 547 ump->data_track = trackinfo; 548 ump->metadata_track = trackinfo; 549 550 /* if not sequential, we're done */ 551 if (num_tracks == 1) 552 return 0; 553 554 for (tracknr = start_track;tracknr <= num_tracks; tracknr++) { 555 /* get track info */ 556 trackinfo.tracknr = tracknr; 557 error = udf_update_trackinfo(ump, &trackinfo); 558 if (error) 559 return error; 560 561 /* 562 * If this track is marked damaged, ask for repair. This is an 563 * optional command, so ignore its error but report warning. 564 */ 565 if (trackinfo.flags & MMC_TRACKINFO_DAMAGED) { 566 memset(&mmc_op, 0, sizeof(mmc_op)); 567 mmc_op.operation = MMC_OP_REPAIRTRACK; 568 mmc_op.mmc_profile = ump->discinfo.mmc_profile; 569 mmc_op.tracknr = tracknr; 570 error = VOP_IOCTL(devvp, MMCOP, &mmc_op, FKIOCTL, NOCRED); 571 if (error) 572 (void)printf("Drive can't explicitly repair " 573 "damaged track %d, but it might " 574 "autorepair\n", tracknr); 575 576 /* reget track info */ 577 error = udf_update_trackinfo(ump, &trackinfo); 578 if (error) 579 return error; 580 } 581 if ((trackinfo.flags & MMC_TRACKINFO_NWA_VALID) == 0) 582 continue; 583 584 track_start = trackinfo.track_start; 585 track_end = track_start + trackinfo.track_size; 586 587 /* check for overlap on data partition */ 588 part = ump->partitions[ump->data_part]; 589 part_start = udf_rw32(part->start_loc); 590 part_end = part_start + udf_rw32(part->part_len); 591 if ((part_start < track_end) && (part_end > track_start)) { 592 ump->data_track = trackinfo; 593 /* TODO check if UDF partition data_part is writable */ 594 } 595 596 /* check for overlap on metadata partition */ 597 node_alloc = ump->vtop_alloc[ump->node_part]; 598 if ((node_alloc == UDF_ALLOC_METASEQUENTIAL) || 599 (node_alloc == UDF_ALLOC_METABITMAP)) { 600 udf_check_track_metadata_overlap(ump, &trackinfo); 601 } else { 602 ump->metadata_track = trackinfo; 603 } 604 } 605 606 if ((ump->data_track.flags & MMC_TRACKINFO_NWA_VALID) == 0) 607 return EROFS; 608 609 if ((ump->metadata_track.flags & MMC_TRACKINFO_NWA_VALID) == 0) 610 return EROFS; 611 612 return 0; 613 } 614 615 /* --------------------------------------------------------------------- */ 616 617 /* 618 * Check if the blob starts with a good UDF tag. Tags are protected by a 619 * checksum over the reader except one byte at position 4 that is the checksum 620 * itself. 621 */ 622 623 int 624 udf_check_tag(void *blob) 625 { 626 struct desc_tag *tag = blob; 627 uint8_t *pos, sum, cnt; 628 629 /* check TAG header checksum */ 630 pos = (uint8_t *) tag; 631 sum = 0; 632 633 for(cnt = 0; cnt < 16; cnt++) { 634 if (cnt != 4) 635 sum += *pos; 636 pos++; 637 } 638 if (sum != tag->cksum) { 639 /* bad tag header checksum; this is not a valid tag */ 640 return EINVAL; 641 } 642 643 return 0; 644 } 645 646 647 /* 648 * check tag payload will check descriptor CRC as specified. 649 * If the descriptor is too long, it will return EIO otherwise EINVAL. 650 */ 651 652 int 653 udf_check_tag_payload(void *blob, uint32_t max_length) 654 { 655 struct desc_tag *tag = blob; 656 uint16_t crc, crc_len; 657 658 crc_len = udf_rw16(tag->desc_crc_len); 659 660 /* check payload CRC if applicable */ 661 if (crc_len == 0) 662 return 0; 663 664 if (crc_len > max_length) 665 return EIO; 666 667 crc = udf_cksum(((uint8_t *) tag) + UDF_DESC_TAG_LENGTH, crc_len); 668 if (crc != udf_rw16(tag->desc_crc)) { 669 /* bad payload CRC; this is a broken tag */ 670 return EINVAL; 671 } 672 673 return 0; 674 } 675 676 677 void 678 udf_validate_tag_sum(void *blob) 679 { 680 struct desc_tag *tag = blob; 681 uint8_t *pos, sum, cnt; 682 683 /* calculate TAG header checksum */ 684 pos = (uint8_t *) tag; 685 sum = 0; 686 687 for(cnt = 0; cnt < 16; cnt++) { 688 if (cnt != 4) sum += *pos; 689 pos++; 690 } 691 tag->cksum = sum; /* 8 bit */ 692 } 693 694 695 /* assumes sector number of descriptor to be saved already present */ 696 void 697 udf_validate_tag_and_crc_sums(void *blob) 698 { 699 struct desc_tag *tag = blob; 700 uint8_t *btag = (uint8_t *) tag; 701 uint16_t crc, crc_len; 702 703 crc_len = udf_rw16(tag->desc_crc_len); 704 705 /* check payload CRC if applicable */ 706 if (crc_len > 0) { 707 crc = udf_cksum(btag + UDF_DESC_TAG_LENGTH, crc_len); 708 tag->desc_crc = udf_rw16(crc); 709 } 710 711 /* calculate TAG header checksum */ 712 udf_validate_tag_sum(blob); 713 } 714 715 /* --------------------------------------------------------------------- */ 716 717 /* 718 * XXX note the different semantics from udfclient: for FIDs it still rounds 719 * up to sectors. Use udf_fidsize() for a correct length. 720 */ 721 722 int 723 udf_tagsize(union dscrptr *dscr, uint32_t lb_size) 724 { 725 uint32_t size, tag_id, num_lb, elmsz; 726 727 tag_id = udf_rw16(dscr->tag.id); 728 729 switch (tag_id) { 730 case TAGID_LOGVOL : 731 size = sizeof(struct logvol_desc) - 1; 732 size += udf_rw32(dscr->lvd.mt_l); 733 break; 734 case TAGID_UNALLOC_SPACE : 735 elmsz = sizeof(struct extent_ad); 736 size = sizeof(struct unalloc_sp_desc) - elmsz; 737 size += udf_rw32(dscr->usd.alloc_desc_num) * elmsz; 738 break; 739 case TAGID_FID : 740 size = UDF_FID_SIZE + dscr->fid.l_fi + udf_rw16(dscr->fid.l_iu); 741 size = (size + 3) & ~3; 742 break; 743 case TAGID_LOGVOL_INTEGRITY : 744 size = sizeof(struct logvol_int_desc) - sizeof(uint32_t); 745 size += udf_rw32(dscr->lvid.l_iu); 746 size += (2 * udf_rw32(dscr->lvid.num_part) * sizeof(uint32_t)); 747 break; 748 case TAGID_SPACE_BITMAP : 749 size = sizeof(struct space_bitmap_desc) - 1; 750 size += udf_rw32(dscr->sbd.num_bytes); 751 break; 752 case TAGID_SPARING_TABLE : 753 elmsz = sizeof(struct spare_map_entry); 754 size = sizeof(struct udf_sparing_table) - elmsz; 755 size += udf_rw16(dscr->spt.rt_l) * elmsz; 756 break; 757 case TAGID_FENTRY : 758 size = sizeof(struct file_entry); 759 size += udf_rw32(dscr->fe.l_ea) + udf_rw32(dscr->fe.l_ad)-1; 760 break; 761 case TAGID_EXTFENTRY : 762 size = sizeof(struct extfile_entry); 763 size += udf_rw32(dscr->efe.l_ea) + udf_rw32(dscr->efe.l_ad)-1; 764 break; 765 case TAGID_FSD : 766 size = sizeof(struct fileset_desc); 767 break; 768 default : 769 size = sizeof(union dscrptr); 770 break; 771 } 772 773 if ((size == 0) || (lb_size == 0)) 774 return 0; 775 776 if (lb_size == 1) 777 return size; 778 779 /* round up in sectors */ 780 num_lb = (size + lb_size -1) / lb_size; 781 return num_lb * lb_size; 782 } 783 784 785 int 786 udf_fidsize(struct fileid_desc *fid) 787 { 788 uint32_t size; 789 790 if (udf_rw16(fid->tag.id) != TAGID_FID) 791 panic("got udf_fidsize on non FID\n"); 792 793 size = UDF_FID_SIZE + fid->l_fi + udf_rw16(fid->l_iu); 794 size = (size + 3) & ~3; 795 796 return size; 797 } 798 799 /* --------------------------------------------------------------------- */ 800 801 void 802 udf_lock_node(struct udf_node *udf_node, int flag, char const *fname, const int lineno) 803 { 804 int ret; 805 806 mutex_enter(&udf_node->node_mutex); 807 /* wait until free */ 808 while (udf_node->i_flags & IN_LOCKED) { 809 ret = cv_timedwait(&udf_node->node_lock, &udf_node->node_mutex, hz/8); 810 /* TODO check if we should return error; abort */ 811 if (ret == EWOULDBLOCK) { 812 DPRINTF(LOCKING, ( "udf_lock_node: udf_node %p would block " 813 "wanted at %s:%d, previously locked at %s:%d\n", 814 udf_node, fname, lineno, 815 udf_node->lock_fname, udf_node->lock_lineno)); 816 } 817 } 818 /* grab */ 819 udf_node->i_flags |= IN_LOCKED | flag; 820 /* debug */ 821 udf_node->lock_fname = fname; 822 udf_node->lock_lineno = lineno; 823 824 mutex_exit(&udf_node->node_mutex); 825 } 826 827 828 void 829 udf_unlock_node(struct udf_node *udf_node, int flag) 830 { 831 mutex_enter(&udf_node->node_mutex); 832 udf_node->i_flags &= ~(IN_LOCKED | flag); 833 cv_broadcast(&udf_node->node_lock); 834 mutex_exit(&udf_node->node_mutex); 835 } 836 837 838 /* --------------------------------------------------------------------- */ 839 840 static int 841 udf_read_anchor(struct udf_mount *ump, uint32_t sector, struct anchor_vdp **dst) 842 { 843 int error; 844 845 error = udf_read_phys_dscr(ump, sector, M_UDFVOLD, 846 (union dscrptr **) dst); 847 if (!error) { 848 /* blank terminator blocks are not allowed here */ 849 if (*dst == NULL) 850 return ENOENT; 851 if (udf_rw16((*dst)->tag.id) != TAGID_ANCHOR) { 852 error = ENOENT; 853 free(*dst, M_UDFVOLD); 854 *dst = NULL; 855 DPRINTF(VOLUMES, ("Not an anchor\n")); 856 } 857 } 858 859 return error; 860 } 861 862 863 int 864 udf_read_anchors(struct udf_mount *ump) 865 { 866 struct udf_args *args = &ump->mount_args; 867 struct mmc_trackinfo first_track; 868 struct mmc_trackinfo second_track; 869 struct mmc_trackinfo last_track; 870 struct anchor_vdp **anchorsp; 871 uint32_t track_start; 872 uint32_t track_end; 873 uint32_t positions[4]; 874 int first_tracknr, last_tracknr; 875 int error, anch, ok, first_anchor; 876 877 /* search the first and last track of the specified session */ 878 error = udf_search_tracks(ump, args, &first_tracknr, &last_tracknr); 879 if (!error) { 880 first_track.tracknr = first_tracknr; 881 error = udf_update_trackinfo(ump, &first_track); 882 } 883 if (!error) { 884 last_track.tracknr = last_tracknr; 885 error = udf_update_trackinfo(ump, &last_track); 886 } 887 if ((!error) && (first_tracknr != last_tracknr)) { 888 second_track.tracknr = first_tracknr+1; 889 error = udf_update_trackinfo(ump, &second_track); 890 } 891 if (error) { 892 printf("UDF mount: reading disc geometry failed\n"); 893 return 0; 894 } 895 896 track_start = first_track.track_start; 897 898 /* `end' is not as straitforward as start. */ 899 track_end = last_track.track_start 900 + last_track.track_size - last_track.free_blocks - 1; 901 902 if (ump->discinfo.mmc_cur & MMC_CAP_SEQUENTIAL) { 903 /* end of track is not straitforward here */ 904 if (last_track.flags & MMC_TRACKINFO_LRA_VALID) 905 track_end = last_track.last_recorded; 906 else if (last_track.flags & MMC_TRACKINFO_NWA_VALID) 907 track_end = last_track.next_writable 908 - ump->discinfo.link_block_penalty; 909 } 910 911 /* its no use reading a blank track */ 912 first_anchor = 0; 913 if (first_track.flags & MMC_TRACKINFO_BLANK) 914 first_anchor = 1; 915 916 /* get our packet size */ 917 ump->packet_size = first_track.packet_size; 918 if (first_track.flags & MMC_TRACKINFO_BLANK) 919 ump->packet_size = second_track.packet_size; 920 921 if (ump->packet_size <= 1) { 922 /* take max, but not bigger than 64 */ 923 ump->packet_size = MAXPHYS / ump->discinfo.sector_size; 924 ump->packet_size = MIN(ump->packet_size, 64); 925 } 926 KASSERT(ump->packet_size >= 1); 927 928 /* read anchors start+256, start+512, end-256, end */ 929 positions[0] = track_start+256; 930 positions[1] = track_end-256; 931 positions[2] = track_end; 932 positions[3] = track_start+512; /* [UDF 2.60/6.11.2] */ 933 /* XXX shouldn't +512 be prefered above +256 for compat with Roxio CD */ 934 935 ok = 0; 936 anchorsp = ump->anchors; 937 for (anch = first_anchor; anch < 4; anch++) { 938 DPRINTF(VOLUMES, ("Read anchor %d at sector %d\n", anch, 939 positions[anch])); 940 error = udf_read_anchor(ump, positions[anch], anchorsp); 941 if (!error) { 942 anchorsp++; 943 ok++; 944 } 945 } 946 947 /* VATs are only recorded on sequential media, but initialise */ 948 ump->first_possible_vat_location = track_start + 2; 949 ump->last_possible_vat_location = track_end + last_track.packet_size; 950 951 return ok; 952 } 953 954 /* --------------------------------------------------------------------- */ 955 956 int 957 udf_get_c_type(struct udf_node *udf_node) 958 { 959 int isdir, what; 960 961 isdir = (udf_node->vnode->v_type == VDIR); 962 what = isdir ? UDF_C_FIDS : UDF_C_USERDATA; 963 964 if (udf_node->ump) 965 if (udf_node == udf_node->ump->metadatabitmap_node) 966 what = UDF_C_METADATA_SBM; 967 968 return what; 969 } 970 971 972 int 973 udf_get_record_vpart(struct udf_mount *ump, int udf_c_type) 974 { 975 int vpart_num; 976 977 vpart_num = ump->data_part; 978 if (udf_c_type == UDF_C_NODE) 979 vpart_num = ump->node_part; 980 if (udf_c_type == UDF_C_FIDS) 981 vpart_num = ump->fids_part; 982 983 return vpart_num; 984 } 985 986 /* --------------------------------------------------------------------- */ 987 988 /* we dont try to be smart; we just record the parts */ 989 #define UDF_UPDATE_DSCR(name, dscr) \ 990 if (name) \ 991 free(name, M_UDFVOLD); \ 992 name = dscr; 993 994 static int 995 udf_process_vds_descriptor(struct udf_mount *ump, union dscrptr *dscr) 996 { 997 struct part_desc *part; 998 uint16_t phys_part, raw_phys_part; 999 1000 DPRINTF(VOLUMES, ("\tprocessing VDS descr %d\n", 1001 udf_rw16(dscr->tag.id))); 1002 switch (udf_rw16(dscr->tag.id)) { 1003 case TAGID_PRI_VOL : /* primary partition */ 1004 UDF_UPDATE_DSCR(ump->primary_vol, &dscr->pvd); 1005 break; 1006 case TAGID_LOGVOL : /* logical volume */ 1007 UDF_UPDATE_DSCR(ump->logical_vol, &dscr->lvd); 1008 break; 1009 case TAGID_UNALLOC_SPACE : /* unallocated space */ 1010 UDF_UPDATE_DSCR(ump->unallocated, &dscr->usd); 1011 break; 1012 case TAGID_IMP_VOL : /* implementation */ 1013 /* XXX do we care about multiple impl. descr ? */ 1014 UDF_UPDATE_DSCR(ump->implementation, &dscr->ivd); 1015 break; 1016 case TAGID_PARTITION : /* physical partition */ 1017 /* not much use if its not allocated */ 1018 if ((udf_rw16(dscr->pd.flags) & UDF_PART_FLAG_ALLOCATED) == 0) { 1019 free(dscr, M_UDFVOLD); 1020 break; 1021 } 1022 1023 /* 1024 * BUGALERT: some rogue implementations use random physical 1025 * partition numbers to break other implementations so lookup 1026 * the number. 1027 */ 1028 raw_phys_part = udf_rw16(dscr->pd.part_num); 1029 for (phys_part = 0; phys_part < UDF_PARTITIONS; phys_part++) { 1030 part = ump->partitions[phys_part]; 1031 if (part == NULL) 1032 break; 1033 if (udf_rw16(part->part_num) == raw_phys_part) 1034 break; 1035 } 1036 if (phys_part == UDF_PARTITIONS) { 1037 free(dscr, M_UDFVOLD); 1038 return EINVAL; 1039 } 1040 1041 UDF_UPDATE_DSCR(ump->partitions[phys_part], &dscr->pd); 1042 break; 1043 case TAGID_VOL : /* volume space extender; rare */ 1044 DPRINTF(VOLUMES, ("VDS extender ignored\n")); 1045 free(dscr, M_UDFVOLD); 1046 break; 1047 default : 1048 DPRINTF(VOLUMES, ("Unhandled VDS type %d\n", 1049 udf_rw16(dscr->tag.id))); 1050 free(dscr, M_UDFVOLD); 1051 } 1052 1053 return 0; 1054 } 1055 #undef UDF_UPDATE_DSCR 1056 1057 /* --------------------------------------------------------------------- */ 1058 1059 static int 1060 udf_read_vds_extent(struct udf_mount *ump, uint32_t loc, uint32_t len) 1061 { 1062 union dscrptr *dscr; 1063 uint32_t sector_size, dscr_size; 1064 int error; 1065 1066 sector_size = ump->discinfo.sector_size; 1067 1068 /* loc is sectornr, len is in bytes */ 1069 error = EIO; 1070 while (len) { 1071 error = udf_read_phys_dscr(ump, loc, M_UDFVOLD, &dscr); 1072 if (error) 1073 return error; 1074 1075 /* blank block is a terminator */ 1076 if (dscr == NULL) 1077 return 0; 1078 1079 /* TERM descriptor is a terminator */ 1080 if (udf_rw16(dscr->tag.id) == TAGID_TERM) { 1081 free(dscr, M_UDFVOLD); 1082 return 0; 1083 } 1084 1085 /* process all others */ 1086 dscr_size = udf_tagsize(dscr, sector_size); 1087 error = udf_process_vds_descriptor(ump, dscr); 1088 if (error) { 1089 free(dscr, M_UDFVOLD); 1090 break; 1091 } 1092 assert((dscr_size % sector_size) == 0); 1093 1094 len -= dscr_size; 1095 loc += dscr_size / sector_size; 1096 } 1097 1098 return error; 1099 } 1100 1101 1102 int 1103 udf_read_vds_space(struct udf_mount *ump) 1104 { 1105 /* struct udf_args *args = &ump->mount_args; */ 1106 struct anchor_vdp *anchor, *anchor2; 1107 size_t size; 1108 uint32_t main_loc, main_len; 1109 uint32_t reserve_loc, reserve_len; 1110 int error; 1111 1112 /* 1113 * read in VDS space provided by the anchors; if one descriptor read 1114 * fails, try the mirror sector. 1115 * 1116 * check if 2nd anchor is different from 1st; if so, go for 2nd. This 1117 * avoids the `compatibility features' of DirectCD that may confuse 1118 * stuff completely. 1119 */ 1120 1121 anchor = ump->anchors[0]; 1122 anchor2 = ump->anchors[1]; 1123 assert(anchor); 1124 1125 if (anchor2) { 1126 size = sizeof(struct extent_ad); 1127 if (memcmp(&anchor->main_vds_ex, &anchor2->main_vds_ex, size)) 1128 anchor = anchor2; 1129 /* reserve is specified to be a literal copy of main */ 1130 } 1131 1132 main_loc = udf_rw32(anchor->main_vds_ex.loc); 1133 main_len = udf_rw32(anchor->main_vds_ex.len); 1134 1135 reserve_loc = udf_rw32(anchor->reserve_vds_ex.loc); 1136 reserve_len = udf_rw32(anchor->reserve_vds_ex.len); 1137 1138 error = udf_read_vds_extent(ump, main_loc, main_len); 1139 if (error) { 1140 printf("UDF mount: reading in reserve VDS extent\n"); 1141 error = udf_read_vds_extent(ump, reserve_loc, reserve_len); 1142 } 1143 1144 return error; 1145 } 1146 1147 /* --------------------------------------------------------------------- */ 1148 1149 /* 1150 * Read in the logical volume integrity sequence pointed to by our logical 1151 * volume descriptor. Its a sequence that can be extended using fields in the 1152 * integrity descriptor itself. On sequential media only one is found, on 1153 * rewritable media a sequence of descriptors can be found as a form of 1154 * history keeping and on non sequential write-once media the chain is vital 1155 * to allow more and more descriptors to be written. The last descriptor 1156 * written in an extent needs to claim space for a new extent. 1157 */ 1158 1159 static int 1160 udf_retrieve_lvint(struct udf_mount *ump) 1161 { 1162 union dscrptr *dscr; 1163 struct logvol_int_desc *lvint; 1164 struct udf_lvintq *trace; 1165 uint32_t lb_size, lbnum, len; 1166 int dscr_type, error, trace_len; 1167 1168 lb_size = udf_rw32(ump->logical_vol->lb_size); 1169 len = udf_rw32(ump->logical_vol->integrity_seq_loc.len); 1170 lbnum = udf_rw32(ump->logical_vol->integrity_seq_loc.loc); 1171 1172 /* clean trace */ 1173 memset(ump->lvint_trace, 0, 1174 UDF_LVDINT_SEGMENTS * sizeof(struct udf_lvintq)); 1175 1176 trace_len = 0; 1177 trace = ump->lvint_trace; 1178 trace->start = lbnum; 1179 trace->end = lbnum + len/lb_size; 1180 trace->pos = 0; 1181 trace->wpos = 0; 1182 1183 lvint = NULL; 1184 dscr = NULL; 1185 error = 0; 1186 while (len) { 1187 trace->pos = lbnum - trace->start; 1188 trace->wpos = trace->pos + 1; 1189 1190 /* read in our integrity descriptor */ 1191 error = udf_read_phys_dscr(ump, lbnum, M_UDFVOLD, &dscr); 1192 if (!error) { 1193 if (dscr == NULL) { 1194 trace->wpos = trace->pos; 1195 break; /* empty terminates */ 1196 } 1197 dscr_type = udf_rw16(dscr->tag.id); 1198 if (dscr_type == TAGID_TERM) { 1199 trace->wpos = trace->pos; 1200 break; /* clean terminator */ 1201 } 1202 if (dscr_type != TAGID_LOGVOL_INTEGRITY) { 1203 /* fatal... corrupt disc */ 1204 error = ENOENT; 1205 break; 1206 } 1207 if (lvint) 1208 free(lvint, M_UDFVOLD); 1209 lvint = &dscr->lvid; 1210 dscr = NULL; 1211 } /* else hope for the best... maybe the next is ok */ 1212 1213 DPRINTFIF(VOLUMES, lvint, ("logvol integrity read, state %s\n", 1214 udf_rw32(lvint->integrity_type) ? "CLOSED" : "OPEN")); 1215 1216 /* proceed sequential */ 1217 lbnum += 1; 1218 len -= lb_size; 1219 1220 /* are we linking to a new piece? */ 1221 if (dscr && lvint->next_extent.len) { 1222 len = udf_rw32(lvint->next_extent.len); 1223 lbnum = udf_rw32(lvint->next_extent.loc); 1224 1225 if (trace_len >= UDF_LVDINT_SEGMENTS-1) { 1226 /* IEK! segment link full... */ 1227 DPRINTF(VOLUMES, ("lvdint segments full\n")); 1228 error = EINVAL; 1229 } else { 1230 trace++; 1231 trace_len++; 1232 1233 trace->start = lbnum; 1234 trace->end = lbnum + len/lb_size; 1235 trace->pos = 0; 1236 trace->wpos = 0; 1237 } 1238 } 1239 } 1240 1241 /* clean up the mess, esp. when there is an error */ 1242 if (dscr) 1243 free(dscr, M_UDFVOLD); 1244 1245 if (error && lvint) { 1246 free(lvint, M_UDFVOLD); 1247 lvint = NULL; 1248 } 1249 1250 if (!lvint) 1251 error = ENOENT; 1252 1253 ump->logvol_integrity = lvint; 1254 return error; 1255 } 1256 1257 1258 static int 1259 udf_loose_lvint_history(struct udf_mount *ump) 1260 { 1261 union dscrptr **bufs, *dscr, *last_dscr; 1262 struct udf_lvintq *trace, *in_trace, *out_trace; 1263 struct logvol_int_desc *lvint; 1264 uint32_t in_ext, in_pos, in_len; 1265 uint32_t out_ext, out_wpos, out_len; 1266 uint32_t lb_size, packet_size, lb_num; 1267 uint32_t len, start; 1268 int ext, minext, extlen, cnt, cpy_len, dscr_type; 1269 int losing; 1270 int error; 1271 1272 DPRINTF(VOLUMES, ("need to lose some lvint history\n")); 1273 1274 lb_size = udf_rw32(ump->logical_vol->lb_size); 1275 packet_size = ump->data_track.packet_size; /* XXX data track */ 1276 1277 /* search smallest extent */ 1278 trace = &ump->lvint_trace[0]; 1279 minext = trace->end - trace->start; 1280 for (ext = 1; ext < UDF_LVDINT_SEGMENTS; ext++) { 1281 trace = &ump->lvint_trace[ext]; 1282 extlen = trace->end - trace->start; 1283 if (extlen == 0) 1284 break; 1285 minext = MIN(minext, extlen); 1286 } 1287 losing = MIN(minext, UDF_LVINT_LOSSAGE); 1288 /* no sense wiping all */ 1289 if (losing == minext) 1290 losing--; 1291 1292 DPRINTF(VOLUMES, ("\tlosing %d entries\n", losing)); 1293 1294 /* get buffer for pieces */ 1295 bufs = malloc(UDF_LVDINT_SEGMENTS * sizeof(void *), M_TEMP, M_WAITOK); 1296 1297 in_ext = 0; 1298 in_pos = losing; 1299 in_trace = &ump->lvint_trace[in_ext]; 1300 in_len = in_trace->end - in_trace->start; 1301 out_ext = 0; 1302 out_wpos = 0; 1303 out_trace = &ump->lvint_trace[out_ext]; 1304 out_len = out_trace->end - out_trace->start; 1305 1306 last_dscr = NULL; 1307 for(;;) { 1308 out_trace->pos = out_wpos; 1309 out_trace->wpos = out_trace->pos; 1310 if (in_pos >= in_len) { 1311 in_ext++; 1312 in_pos = 0; 1313 in_trace = &ump->lvint_trace[in_ext]; 1314 in_len = in_trace->end - in_trace->start; 1315 } 1316 if (out_wpos >= out_len) { 1317 out_ext++; 1318 out_wpos = 0; 1319 out_trace = &ump->lvint_trace[out_ext]; 1320 out_len = out_trace->end - out_trace->start; 1321 } 1322 /* copy overlap contents */ 1323 cpy_len = MIN(in_len - in_pos, out_len - out_wpos); 1324 cpy_len = MIN(cpy_len, in_len - in_trace->pos); 1325 if (cpy_len == 0) 1326 break; 1327 1328 /* copy */ 1329 DPRINTF(VOLUMES, ("\treading %d lvid descriptors\n", cpy_len)); 1330 for (cnt = 0; cnt < cpy_len; cnt++) { 1331 /* read in our integrity descriptor */ 1332 lb_num = in_trace->start + in_pos + cnt; 1333 error = udf_read_phys_dscr(ump, lb_num, M_UDFVOLD, 1334 &dscr); 1335 if (error) { 1336 /* copy last one */ 1337 dscr = last_dscr; 1338 } 1339 bufs[cnt] = dscr; 1340 if (!error) { 1341 if (dscr == NULL) { 1342 out_trace->pos = out_wpos + cnt; 1343 out_trace->wpos = out_trace->pos; 1344 break; /* empty terminates */ 1345 } 1346 dscr_type = udf_rw16(dscr->tag.id); 1347 if (dscr_type == TAGID_TERM) { 1348 out_trace->pos = out_wpos + cnt; 1349 out_trace->wpos = out_trace->pos; 1350 break; /* clean terminator */ 1351 } 1352 if (dscr_type != TAGID_LOGVOL_INTEGRITY) { 1353 panic( "UDF integrity sequence " 1354 "corrupted while mounted!\n"); 1355 } 1356 last_dscr = dscr; 1357 } 1358 } 1359 1360 /* patch up if first entry was on error */ 1361 if (bufs[0] == NULL) { 1362 for (cnt = 0; cnt < cpy_len; cnt++) 1363 if (bufs[cnt] != NULL) 1364 break; 1365 last_dscr = bufs[cnt]; 1366 for (; cnt > 0; cnt--) { 1367 bufs[cnt] = last_dscr; 1368 } 1369 } 1370 1371 /* glue + write out */ 1372 DPRINTF(VOLUMES, ("\twriting %d lvid descriptors\n", cpy_len)); 1373 for (cnt = 0; cnt < cpy_len; cnt++) { 1374 lb_num = out_trace->start + out_wpos + cnt; 1375 lvint = &bufs[cnt]->lvid; 1376 1377 /* set continuation */ 1378 len = 0; 1379 start = 0; 1380 if (out_wpos + cnt == out_len) { 1381 /* get continuation */ 1382 trace = &ump->lvint_trace[out_ext+1]; 1383 len = trace->end - trace->start; 1384 start = trace->start; 1385 } 1386 lvint->next_extent.len = udf_rw32(len); 1387 lvint->next_extent.loc = udf_rw32(start); 1388 1389 lb_num = trace->start + trace->wpos; 1390 error = udf_write_phys_dscr_sync(ump, NULL, UDF_C_DSCR, 1391 bufs[cnt], lb_num, lb_num); 1392 DPRINTFIF(VOLUMES, error, 1393 ("error writing lvint lb_num\n")); 1394 } 1395 1396 /* free non repeating descriptors */ 1397 last_dscr = NULL; 1398 for (cnt = 0; cnt < cpy_len; cnt++) { 1399 if (bufs[cnt] != last_dscr) 1400 free(bufs[cnt], M_UDFVOLD); 1401 last_dscr = bufs[cnt]; 1402 } 1403 1404 /* advance */ 1405 in_pos += cpy_len; 1406 out_wpos += cpy_len; 1407 } 1408 1409 free(bufs, M_TEMP); 1410 1411 return 0; 1412 } 1413 1414 1415 static int 1416 udf_writeout_lvint(struct udf_mount *ump, int lvflag) 1417 { 1418 struct udf_lvintq *trace; 1419 struct timeval now_v; 1420 struct timespec now_s; 1421 uint32_t sector; 1422 int logvol_integrity; 1423 int space, error; 1424 1425 DPRINTF(VOLUMES, ("writing out logvol integrity descriptor\n")); 1426 1427 again: 1428 /* get free space in last chunk */ 1429 trace = ump->lvint_trace; 1430 while (trace->wpos > (trace->end - trace->start)) { 1431 DPRINTF(VOLUMES, ("skip : start = %d, end = %d, pos = %d, " 1432 "wpos = %d\n", trace->start, trace->end, 1433 trace->pos, trace->wpos)); 1434 trace++; 1435 } 1436 1437 /* check if there is space to append */ 1438 space = (trace->end - trace->start) - trace->wpos; 1439 DPRINTF(VOLUMES, ("write start = %d, end = %d, pos = %d, wpos = %d, " 1440 "space = %d\n", trace->start, trace->end, trace->pos, 1441 trace->wpos, space)); 1442 1443 /* get state */ 1444 logvol_integrity = udf_rw32(ump->logvol_integrity->integrity_type); 1445 if (logvol_integrity == UDF_INTEGRITY_CLOSED) { 1446 if ((space < 3) && (lvflag & UDF_APPENDONLY_LVINT)) { 1447 /* don't allow this logvol to be opened */ 1448 /* TODO extent LVINT space if possible */ 1449 return EROFS; 1450 } 1451 } 1452 1453 if (space < 1) { 1454 if (lvflag & UDF_APPENDONLY_LVINT) 1455 return EROFS; 1456 /* loose history by re-writing extents */ 1457 error = udf_loose_lvint_history(ump); 1458 if (error) 1459 return error; 1460 goto again; 1461 } 1462 1463 /* update our integrity descriptor to identify us and timestamp it */ 1464 DPRINTF(VOLUMES, ("updating integrity descriptor\n")); 1465 microtime(&now_v); 1466 TIMEVAL_TO_TIMESPEC(&now_v, &now_s); 1467 udf_timespec_to_timestamp(&now_s, &ump->logvol_integrity->time); 1468 udf_set_regid(&ump->logvol_info->impl_id, IMPL_NAME); 1469 udf_add_impl_regid(ump, &ump->logvol_info->impl_id); 1470 1471 /* writeout integrity descriptor */ 1472 sector = trace->start + trace->wpos; 1473 error = udf_write_phys_dscr_sync(ump, NULL, UDF_C_DSCR, 1474 (union dscrptr *) ump->logvol_integrity, 1475 sector, sector); 1476 DPRINTF(VOLUMES, ("writeout lvint : error = %d\n", error)); 1477 if (error) 1478 return error; 1479 1480 /* advance write position */ 1481 trace->wpos++; space--; 1482 if (space >= 1) { 1483 /* append terminator */ 1484 sector = trace->start + trace->wpos; 1485 error = udf_write_terminator(ump, sector); 1486 1487 DPRINTF(VOLUMES, ("write terminator : error = %d\n", error)); 1488 } 1489 1490 space = (trace->end - trace->start) - trace->wpos; 1491 DPRINTF(VOLUMES, ("write start = %d, end = %d, pos = %d, wpos = %d, " 1492 "space = %d\n", trace->start, trace->end, trace->pos, 1493 trace->wpos, space)); 1494 DPRINTF(VOLUMES, ("finished writing out logvol integrity descriptor " 1495 "successfull\n")); 1496 1497 return error; 1498 } 1499 1500 /* --------------------------------------------------------------------- */ 1501 1502 static int 1503 udf_read_physical_partition_spacetables(struct udf_mount *ump) 1504 { 1505 union dscrptr *dscr; 1506 /* struct udf_args *args = &ump->mount_args; */ 1507 struct part_desc *partd; 1508 struct part_hdr_desc *parthdr; 1509 struct udf_bitmap *bitmap; 1510 uint32_t phys_part; 1511 uint32_t lb_num, len; 1512 int error, dscr_type; 1513 1514 /* unallocated space map */ 1515 for (phys_part = 0; phys_part < UDF_PARTITIONS; phys_part++) { 1516 partd = ump->partitions[phys_part]; 1517 if (partd == NULL) 1518 continue; 1519 parthdr = &partd->_impl_use.part_hdr; 1520 1521 lb_num = udf_rw32(partd->start_loc); 1522 lb_num += udf_rw32(parthdr->unalloc_space_bitmap.lb_num); 1523 len = udf_rw32(parthdr->unalloc_space_bitmap.len); 1524 if (len == 0) 1525 continue; 1526 1527 DPRINTF(VOLUMES, ("Read unalloc. space bitmap %d\n", lb_num)); 1528 error = udf_read_phys_dscr(ump, lb_num, M_UDFVOLD, &dscr); 1529 if (!error && dscr) { 1530 /* analyse */ 1531 dscr_type = udf_rw16(dscr->tag.id); 1532 if (dscr_type == TAGID_SPACE_BITMAP) { 1533 DPRINTF(VOLUMES, ("Accepting space bitmap\n")); 1534 ump->part_unalloc_dscr[phys_part] = &dscr->sbd; 1535 1536 /* fill in ump->part_unalloc_bits */ 1537 bitmap = &ump->part_unalloc_bits[phys_part]; 1538 bitmap->blob = (uint8_t *) dscr; 1539 bitmap->bits = dscr->sbd.data; 1540 bitmap->max_offset = udf_rw32(dscr->sbd.num_bits); 1541 bitmap->pages = NULL; /* TODO */ 1542 bitmap->data_pos = 0; 1543 bitmap->metadata_pos = 0; 1544 } else { 1545 free(dscr, M_UDFVOLD); 1546 1547 printf( "UDF mount: error reading unallocated " 1548 "space bitmap\n"); 1549 return EROFS; 1550 } 1551 } else { 1552 /* blank not allowed */ 1553 printf("UDF mount: blank unallocated space bitmap\n"); 1554 return EROFS; 1555 } 1556 } 1557 1558 /* unallocated space table (not supported) */ 1559 for (phys_part = 0; phys_part < UDF_PARTITIONS; phys_part++) { 1560 partd = ump->partitions[phys_part]; 1561 if (partd == NULL) 1562 continue; 1563 parthdr = &partd->_impl_use.part_hdr; 1564 1565 len = udf_rw32(parthdr->unalloc_space_table.len); 1566 if (len) { 1567 printf("UDF mount: space tables not supported\n"); 1568 return EROFS; 1569 } 1570 } 1571 1572 /* freed space map */ 1573 for (phys_part = 0; phys_part < UDF_PARTITIONS; phys_part++) { 1574 partd = ump->partitions[phys_part]; 1575 if (partd == NULL) 1576 continue; 1577 parthdr = &partd->_impl_use.part_hdr; 1578 1579 /* freed space map */ 1580 lb_num = udf_rw32(partd->start_loc); 1581 lb_num += udf_rw32(parthdr->freed_space_bitmap.lb_num); 1582 len = udf_rw32(parthdr->freed_space_bitmap.len); 1583 if (len == 0) 1584 continue; 1585 1586 DPRINTF(VOLUMES, ("Read unalloc. space bitmap %d\n", lb_num)); 1587 error = udf_read_phys_dscr(ump, lb_num, M_UDFVOLD, &dscr); 1588 if (!error && dscr) { 1589 /* analyse */ 1590 dscr_type = udf_rw16(dscr->tag.id); 1591 if (dscr_type == TAGID_SPACE_BITMAP) { 1592 DPRINTF(VOLUMES, ("Accepting space bitmap\n")); 1593 ump->part_freed_dscr[phys_part] = &dscr->sbd; 1594 1595 /* fill in ump->part_freed_bits */ 1596 bitmap = &ump->part_unalloc_bits[phys_part]; 1597 bitmap->blob = (uint8_t *) dscr; 1598 bitmap->bits = dscr->sbd.data; 1599 bitmap->max_offset = udf_rw32(dscr->sbd.num_bits); 1600 bitmap->pages = NULL; /* TODO */ 1601 bitmap->data_pos = 0; 1602 bitmap->metadata_pos = 0; 1603 } else { 1604 free(dscr, M_UDFVOLD); 1605 1606 printf( "UDF mount: error reading freed " 1607 "space bitmap\n"); 1608 return EROFS; 1609 } 1610 } else { 1611 /* blank not allowed */ 1612 printf("UDF mount: blank freed space bitmap\n"); 1613 return EROFS; 1614 } 1615 } 1616 1617 /* freed space table (not supported) */ 1618 for (phys_part = 0; phys_part < UDF_PARTITIONS; phys_part++) { 1619 partd = ump->partitions[phys_part]; 1620 if (partd == NULL) 1621 continue; 1622 parthdr = &partd->_impl_use.part_hdr; 1623 1624 len = udf_rw32(parthdr->freed_space_table.len); 1625 if (len) { 1626 printf("UDF mount: space tables not supported\n"); 1627 return EROFS; 1628 } 1629 } 1630 1631 return 0; 1632 } 1633 1634 1635 /* TODO implement async writeout */ 1636 int 1637 udf_write_physical_partition_spacetables(struct udf_mount *ump, int waitfor) 1638 { 1639 union dscrptr *dscr; 1640 /* struct udf_args *args = &ump->mount_args; */ 1641 struct part_desc *partd; 1642 struct part_hdr_desc *parthdr; 1643 uint32_t phys_part; 1644 uint32_t lb_num, len, ptov; 1645 int error_all, error; 1646 1647 error_all = 0; 1648 /* unallocated space map */ 1649 for (phys_part = 0; phys_part < UDF_PARTITIONS; phys_part++) { 1650 partd = ump->partitions[phys_part]; 1651 if (partd == NULL) 1652 continue; 1653 parthdr = &partd->_impl_use.part_hdr; 1654 1655 ptov = udf_rw32(partd->start_loc); 1656 lb_num = udf_rw32(parthdr->unalloc_space_bitmap.lb_num); 1657 len = udf_rw32(parthdr->unalloc_space_bitmap.len); 1658 if (len == 0) 1659 continue; 1660 1661 DPRINTF(VOLUMES, ("Write unalloc. space bitmap %d\n", 1662 lb_num + ptov)); 1663 dscr = (union dscrptr *) ump->part_unalloc_dscr[phys_part]; 1664 error = udf_write_phys_dscr_sync(ump, NULL, UDF_C_DSCR, 1665 (union dscrptr *) dscr, 1666 ptov + lb_num, lb_num); 1667 if (error) { 1668 DPRINTF(VOLUMES, ("\tfailed!! (error %d)\n", error)); 1669 error_all = error; 1670 } 1671 } 1672 1673 /* freed space map */ 1674 for (phys_part = 0; phys_part < UDF_PARTITIONS; phys_part++) { 1675 partd = ump->partitions[phys_part]; 1676 if (partd == NULL) 1677 continue; 1678 parthdr = &partd->_impl_use.part_hdr; 1679 1680 /* freed space map */ 1681 ptov = udf_rw32(partd->start_loc); 1682 lb_num = udf_rw32(parthdr->freed_space_bitmap.lb_num); 1683 len = udf_rw32(parthdr->freed_space_bitmap.len); 1684 if (len == 0) 1685 continue; 1686 1687 DPRINTF(VOLUMES, ("Write freed space bitmap %d\n", 1688 lb_num + ptov)); 1689 dscr = (union dscrptr *) ump->part_freed_dscr[phys_part]; 1690 error = udf_write_phys_dscr_sync(ump, NULL, UDF_C_DSCR, 1691 (union dscrptr *) dscr, 1692 ptov + lb_num, lb_num); 1693 if (error) { 1694 DPRINTF(VOLUMES, ("\tfailed!! (error %d)\n", error)); 1695 error_all = error; 1696 } 1697 } 1698 1699 return error_all; 1700 } 1701 1702 1703 static int 1704 udf_read_metadata_partition_spacetable(struct udf_mount *ump) 1705 { 1706 struct udf_node *bitmap_node; 1707 union dscrptr *dscr; 1708 struct udf_bitmap *bitmap; 1709 uint64_t inflen; 1710 int error, dscr_type; 1711 1712 bitmap_node = ump->metadatabitmap_node; 1713 1714 /* only read in when metadata bitmap node is read in */ 1715 if (bitmap_node == NULL) 1716 return 0; 1717 1718 if (bitmap_node->fe) { 1719 inflen = udf_rw64(bitmap_node->fe->inf_len); 1720 } else { 1721 KASSERT(bitmap_node->efe); 1722 inflen = udf_rw64(bitmap_node->efe->inf_len); 1723 } 1724 1725 DPRINTF(VOLUMES, ("Reading metadata space bitmap for " 1726 "%"PRIu64" bytes\n", inflen)); 1727 1728 /* allocate space for bitmap */ 1729 dscr = malloc(inflen, M_UDFVOLD, M_CANFAIL | M_WAITOK); 1730 if (!dscr) 1731 return ENOMEM; 1732 1733 /* set vnode type to regular file or we can't read from it! */ 1734 bitmap_node->vnode->v_type = VREG; 1735 1736 /* read in complete metadata bitmap file */ 1737 error = vn_rdwr(UIO_READ, bitmap_node->vnode, 1738 dscr, 1739 inflen, 0, 1740 UIO_SYSSPACE, 1741 IO_SYNC | IO_NODELOCKED | IO_ALTSEMANTICS, FSCRED, 1742 NULL, NULL); 1743 if (error) { 1744 DPRINTF(VOLUMES, ("Error reading metadata space bitmap\n")); 1745 goto errorout; 1746 } 1747 1748 /* analyse */ 1749 dscr_type = udf_rw16(dscr->tag.id); 1750 if (dscr_type == TAGID_SPACE_BITMAP) { 1751 DPRINTF(VOLUMES, ("Accepting metadata space bitmap\n")); 1752 ump->metadata_unalloc_dscr = &dscr->sbd; 1753 1754 /* fill in bitmap bits */ 1755 bitmap = &ump->metadata_unalloc_bits; 1756 bitmap->blob = (uint8_t *) dscr; 1757 bitmap->bits = dscr->sbd.data; 1758 bitmap->max_offset = udf_rw32(dscr->sbd.num_bits); 1759 bitmap->pages = NULL; /* TODO */ 1760 bitmap->data_pos = 0; 1761 bitmap->metadata_pos = 0; 1762 } else { 1763 DPRINTF(VOLUMES, ("No valid bitmap found!\n")); 1764 goto errorout; 1765 } 1766 1767 return 0; 1768 1769 errorout: 1770 free(dscr, M_UDFVOLD); 1771 printf( "UDF mount: error reading unallocated " 1772 "space bitmap for metadata partition\n"); 1773 return EROFS; 1774 } 1775 1776 1777 int 1778 udf_write_metadata_partition_spacetable(struct udf_mount *ump, int waitfor) 1779 { 1780 struct udf_node *bitmap_node; 1781 union dscrptr *dscr; 1782 uint64_t inflen, new_inflen; 1783 int dummy, error; 1784 1785 bitmap_node = ump->metadatabitmap_node; 1786 1787 /* only write out when metadata bitmap node is known */ 1788 if (bitmap_node == NULL) 1789 return 0; 1790 1791 if (bitmap_node->fe) { 1792 inflen = udf_rw64(bitmap_node->fe->inf_len); 1793 } else { 1794 KASSERT(bitmap_node->efe); 1795 inflen = udf_rw64(bitmap_node->efe->inf_len); 1796 } 1797 1798 /* reduce length to zero */ 1799 dscr = (union dscrptr *) ump->metadata_unalloc_dscr; 1800 new_inflen = udf_tagsize(dscr, 1); 1801 1802 DPRINTF(VOLUMES, ("Resize and write out metadata space bitmap from " 1803 "%"PRIu64" to %"PRIu64" bytes\n", inflen, new_inflen)); 1804 1805 error = udf_resize_node(bitmap_node, new_inflen, &dummy); 1806 if (error) 1807 printf("Error resizing metadata space bitmap\n"); 1808 1809 error = vn_rdwr(UIO_WRITE, bitmap_node->vnode, 1810 dscr, 1811 new_inflen, 0, 1812 UIO_SYSSPACE, 1813 IO_NODELOCKED | IO_ALTSEMANTICS, FSCRED, 1814 NULL, NULL); 1815 1816 bitmap_node->i_flags |= IN_MODIFIED; 1817 vflushbuf(bitmap_node->vnode, 1 /* sync */); 1818 1819 error = VOP_FSYNC(bitmap_node->vnode, 1820 FSCRED, FSYNC_WAIT, 0, 0); 1821 1822 if (error) 1823 printf( "Error writing out metadata partition unalloced " 1824 "space bitmap!\n"); 1825 1826 return error; 1827 } 1828 1829 1830 /* --------------------------------------------------------------------- */ 1831 1832 /* 1833 * Checks if ump's vds information is correct and complete 1834 */ 1835 1836 int 1837 udf_process_vds(struct udf_mount *ump) { 1838 union udf_pmap *mapping; 1839 /* struct udf_args *args = &ump->mount_args; */ 1840 struct logvol_int_desc *lvint; 1841 struct udf_logvol_info *lvinfo; 1842 struct part_desc *part; 1843 uint32_t n_pm, mt_l; 1844 uint8_t *pmap_pos; 1845 char *domain_name, *map_name; 1846 const char *check_name; 1847 char bits[128]; 1848 int pmap_stype, pmap_size; 1849 int pmap_type, log_part, phys_part, raw_phys_part, maps_on; 1850 int n_phys, n_virt, n_spar, n_meta; 1851 int len, error; 1852 1853 if (ump == NULL) 1854 return ENOENT; 1855 1856 /* we need at least an anchor (trivial, but for safety) */ 1857 if (ump->anchors[0] == NULL) 1858 return EINVAL; 1859 1860 /* we need at least one primary and one logical volume descriptor */ 1861 if ((ump->primary_vol == NULL) || (ump->logical_vol) == NULL) 1862 return EINVAL; 1863 1864 /* we need at least one partition descriptor */ 1865 if (ump->partitions[0] == NULL) 1866 return EINVAL; 1867 1868 /* check logical volume sector size verses device sector size */ 1869 if (udf_rw32(ump->logical_vol->lb_size) != ump->discinfo.sector_size) { 1870 printf("UDF mount: format violation, lb_size != sector size\n"); 1871 return EINVAL; 1872 } 1873 1874 /* check domain name */ 1875 domain_name = ump->logical_vol->domain_id.id; 1876 if (strncmp(domain_name, "*OSTA UDF Compliant", 20)) { 1877 printf("mount_udf: disc not OSTA UDF Compliant, aborting\n"); 1878 return EINVAL; 1879 } 1880 1881 /* retrieve logical volume integrity sequence */ 1882 error = udf_retrieve_lvint(ump); 1883 1884 /* 1885 * We need at least one logvol integrity descriptor recorded. Note 1886 * that its OK to have an open logical volume integrity here. The VAT 1887 * will close/update the integrity. 1888 */ 1889 if (ump->logvol_integrity == NULL) 1890 return EINVAL; 1891 1892 /* process derived structures */ 1893 n_pm = udf_rw32(ump->logical_vol->n_pm); /* num partmaps */ 1894 lvint = ump->logvol_integrity; 1895 lvinfo = (struct udf_logvol_info *) (&lvint->tables[2 * n_pm]); 1896 ump->logvol_info = lvinfo; 1897 1898 /* TODO check udf versions? */ 1899 1900 /* 1901 * check logvol mappings: effective virt->log partmap translation 1902 * check and recording of the mapping results. Saves expensive 1903 * strncmp() in tight places. 1904 */ 1905 DPRINTF(VOLUMES, ("checking logvol mappings\n")); 1906 n_pm = udf_rw32(ump->logical_vol->n_pm); /* num partmaps */ 1907 mt_l = udf_rw32(ump->logical_vol->mt_l); /* partmaps data length */ 1908 pmap_pos = ump->logical_vol->maps; 1909 1910 if (n_pm > UDF_PMAPS) { 1911 printf("UDF mount: too many mappings\n"); 1912 return EINVAL; 1913 } 1914 1915 /* count types and set partition numbers */ 1916 ump->data_part = ump->node_part = ump->fids_part = 0; 1917 n_phys = n_virt = n_spar = n_meta = 0; 1918 for (log_part = 0; log_part < n_pm; log_part++) { 1919 mapping = (union udf_pmap *) pmap_pos; 1920 pmap_stype = pmap_pos[0]; 1921 pmap_size = pmap_pos[1]; 1922 switch (pmap_stype) { 1923 case 1: /* physical mapping */ 1924 /* volseq = udf_rw16(mapping->pm1.vol_seq_num); */ 1925 raw_phys_part = udf_rw16(mapping->pm1.part_num); 1926 pmap_type = UDF_VTOP_TYPE_PHYS; 1927 n_phys++; 1928 ump->data_part = log_part; 1929 ump->node_part = log_part; 1930 ump->fids_part = log_part; 1931 break; 1932 case 2: /* virtual/sparable/meta mapping */ 1933 map_name = mapping->pm2.part_id.id; 1934 /* volseq = udf_rw16(mapping->pm2.vol_seq_num); */ 1935 raw_phys_part = udf_rw16(mapping->pm2.part_num); 1936 pmap_type = UDF_VTOP_TYPE_UNKNOWN; 1937 len = UDF_REGID_ID_SIZE; 1938 1939 check_name = "*UDF Virtual Partition"; 1940 if (strncmp(map_name, check_name, len) == 0) { 1941 pmap_type = UDF_VTOP_TYPE_VIRT; 1942 n_virt++; 1943 ump->node_part = log_part; 1944 break; 1945 } 1946 check_name = "*UDF Sparable Partition"; 1947 if (strncmp(map_name, check_name, len) == 0) { 1948 pmap_type = UDF_VTOP_TYPE_SPARABLE; 1949 n_spar++; 1950 ump->data_part = log_part; 1951 ump->node_part = log_part; 1952 ump->fids_part = log_part; 1953 break; 1954 } 1955 check_name = "*UDF Metadata Partition"; 1956 if (strncmp(map_name, check_name, len) == 0) { 1957 pmap_type = UDF_VTOP_TYPE_META; 1958 n_meta++; 1959 ump->node_part = log_part; 1960 ump->fids_part = log_part; 1961 break; 1962 } 1963 break; 1964 default: 1965 return EINVAL; 1966 } 1967 1968 /* 1969 * BUGALERT: some rogue implementations use random physical 1970 * partition numbers to break other implementations so lookup 1971 * the number. 1972 */ 1973 for (phys_part = 0; phys_part < UDF_PARTITIONS; phys_part++) { 1974 part = ump->partitions[phys_part]; 1975 if (part == NULL) 1976 continue; 1977 if (udf_rw16(part->part_num) == raw_phys_part) 1978 break; 1979 } 1980 1981 DPRINTF(VOLUMES, ("\t%d -> %d(%d) type %d\n", log_part, 1982 raw_phys_part, phys_part, pmap_type)); 1983 1984 if (phys_part == UDF_PARTITIONS) 1985 return EINVAL; 1986 if (pmap_type == UDF_VTOP_TYPE_UNKNOWN) 1987 return EINVAL; 1988 1989 ump->vtop [log_part] = phys_part; 1990 ump->vtop_tp[log_part] = pmap_type; 1991 1992 pmap_pos += pmap_size; 1993 } 1994 /* not winning the beauty contest */ 1995 ump->vtop_tp[UDF_VTOP_RAWPART] = UDF_VTOP_TYPE_RAW; 1996 1997 /* test some basic UDF assertions/requirements */ 1998 if ((n_virt > 1) || (n_spar > 1) || (n_meta > 1)) 1999 return EINVAL; 2000 2001 if (n_virt) { 2002 if ((n_phys == 0) || n_spar || n_meta) 2003 return EINVAL; 2004 } 2005 if (n_spar + n_phys == 0) 2006 return EINVAL; 2007 2008 /* select allocation type for each logical partition */ 2009 for (log_part = 0; log_part < n_pm; log_part++) { 2010 maps_on = ump->vtop[log_part]; 2011 switch (ump->vtop_tp[log_part]) { 2012 case UDF_VTOP_TYPE_PHYS : 2013 assert(maps_on == log_part); 2014 ump->vtop_alloc[log_part] = UDF_ALLOC_SPACEMAP; 2015 break; 2016 case UDF_VTOP_TYPE_VIRT : 2017 ump->vtop_alloc[log_part] = UDF_ALLOC_VAT; 2018 ump->vtop_alloc[maps_on] = UDF_ALLOC_SEQUENTIAL; 2019 break; 2020 case UDF_VTOP_TYPE_SPARABLE : 2021 assert(maps_on == log_part); 2022 ump->vtop_alloc[log_part] = UDF_ALLOC_SPACEMAP; 2023 break; 2024 case UDF_VTOP_TYPE_META : 2025 ump->vtop_alloc[log_part] = UDF_ALLOC_METABITMAP; 2026 if (ump->discinfo.mmc_cur & MMC_CAP_PSEUDOOVERWRITE) { 2027 /* special case for UDF 2.60 */ 2028 ump->vtop_alloc[log_part] = UDF_ALLOC_METASEQUENTIAL; 2029 ump->vtop_alloc[maps_on] = UDF_ALLOC_SEQUENTIAL; 2030 } 2031 break; 2032 default: 2033 panic("bad alloction type in udf's ump->vtop\n"); 2034 } 2035 } 2036 2037 /* determine logical volume open/closure actions */ 2038 if (n_virt) { 2039 ump->lvopen = 0; 2040 if (ump->discinfo.last_session_state == MMC_STATE_EMPTY) 2041 ump->lvopen |= UDF_OPEN_SESSION ; 2042 ump->lvclose = UDF_WRITE_VAT; 2043 if (ump->mount_args.udfmflags & UDFMNT_CLOSESESSION) 2044 ump->lvclose |= UDF_CLOSE_SESSION; 2045 } else { 2046 /* `normal' rewritable or non sequential media */ 2047 ump->lvopen = UDF_WRITE_LVINT; 2048 ump->lvclose = UDF_WRITE_LVINT; 2049 if ((ump->discinfo.mmc_cur & MMC_CAP_REWRITABLE) == 0) 2050 ump->lvopen |= UDF_APPENDONLY_LVINT; 2051 } 2052 2053 /* 2054 * Determine sheduler error behaviour. For virtual partitions, update 2055 * the trackinfo; for sparable partitions replace a whole block on the 2056 * sparable table. Allways requeue. 2057 */ 2058 ump->lvreadwrite = 0; 2059 if (n_virt) 2060 ump->lvreadwrite = UDF_UPDATE_TRACKINFO; 2061 if (n_spar) 2062 ump->lvreadwrite = UDF_REMAP_BLOCK; 2063 2064 /* 2065 * Select our sheduler 2066 */ 2067 ump->strategy = &udf_strat_rmw; 2068 if (n_virt || (ump->discinfo.mmc_cur & MMC_CAP_PSEUDOOVERWRITE)) 2069 ump->strategy = &udf_strat_sequential; 2070 if ((ump->discinfo.mmc_class == MMC_CLASS_DISC) || 2071 (ump->discinfo.mmc_class == MMC_CLASS_UNKN)) 2072 ump->strategy = &udf_strat_direct; 2073 if (n_spar) 2074 ump->strategy = &udf_strat_rmw; 2075 2076 #if 0 2077 /* read-only access won't benefit from the other shedulers */ 2078 if (ump->vfs_mountp->mnt_flag & MNT_RDONLY) 2079 ump->strategy = &udf_strat_direct; 2080 #endif 2081 2082 /* print results */ 2083 DPRINTF(VOLUMES, ("\tdata partition %d\n", ump->data_part)); 2084 DPRINTF(VOLUMES, ("\t\talloc scheme %d\n", ump->vtop_alloc[ump->data_part])); 2085 DPRINTF(VOLUMES, ("\tnode partition %d\n", ump->node_part)); 2086 DPRINTF(VOLUMES, ("\t\talloc scheme %d\n", ump->vtop_alloc[ump->node_part])); 2087 DPRINTF(VOLUMES, ("\tfids partition %d\n", ump->fids_part)); 2088 DPRINTF(VOLUMES, ("\t\talloc scheme %d\n", ump->vtop_alloc[ump->fids_part])); 2089 2090 snprintb(bits, sizeof(bits), UDFLOGVOL_BITS, ump->lvopen); 2091 DPRINTF(VOLUMES, ("\tactions on logvol open %s\n", bits)); 2092 snprintb(bits, sizeof(bits), UDFLOGVOL_BITS, ump->lvclose); 2093 DPRINTF(VOLUMES, ("\tactions on logvol close %s\n", bits)); 2094 snprintb(bits, sizeof(bits), UDFONERROR_BITS, ump->lvreadwrite); 2095 DPRINTF(VOLUMES, ("\tactions on logvol errors %s\n", bits)); 2096 2097 DPRINTF(VOLUMES, ("\tselected sheduler `%s`\n", 2098 (ump->strategy == &udf_strat_direct) ? "Direct" : 2099 (ump->strategy == &udf_strat_sequential) ? "Sequential" : 2100 (ump->strategy == &udf_strat_rmw) ? "RMW" : "UNKNOWN!")); 2101 2102 /* signal its OK for now */ 2103 return 0; 2104 } 2105 2106 /* --------------------------------------------------------------------- */ 2107 2108 /* 2109 * Update logical volume name in all structures that keep a record of it. We 2110 * use memmove since each of them might be specified as a source. 2111 * 2112 * Note that it doesn't update the VAT structure! 2113 */ 2114 2115 static void 2116 udf_update_logvolname(struct udf_mount *ump, char *logvol_id) 2117 { 2118 struct logvol_desc *lvd = NULL; 2119 struct fileset_desc *fsd = NULL; 2120 struct udf_lv_info *lvi = NULL; 2121 2122 DPRINTF(VOLUMES, ("Updating logical volume name\n")); 2123 lvd = ump->logical_vol; 2124 fsd = ump->fileset_desc; 2125 if (ump->implementation) 2126 lvi = &ump->implementation->_impl_use.lv_info; 2127 2128 /* logvol's id might be specified as origional so use memmove here */ 2129 memmove(lvd->logvol_id, logvol_id, 128); 2130 if (fsd) 2131 memmove(fsd->logvol_id, logvol_id, 128); 2132 if (lvi) 2133 memmove(lvi->logvol_id, logvol_id, 128); 2134 } 2135 2136 /* --------------------------------------------------------------------- */ 2137 2138 void 2139 udf_inittag(struct udf_mount *ump, struct desc_tag *tag, int tagid, 2140 uint32_t sector) 2141 { 2142 assert(ump->logical_vol); 2143 2144 tag->id = udf_rw16(tagid); 2145 tag->descriptor_ver = ump->logical_vol->tag.descriptor_ver; 2146 tag->cksum = 0; 2147 tag->reserved = 0; 2148 tag->serial_num = ump->logical_vol->tag.serial_num; 2149 tag->tag_loc = udf_rw32(sector); 2150 } 2151 2152 2153 uint64_t 2154 udf_advance_uniqueid(struct udf_mount *ump) 2155 { 2156 uint64_t unique_id; 2157 2158 mutex_enter(&ump->logvol_mutex); 2159 unique_id = udf_rw64(ump->logvol_integrity->lvint_next_unique_id); 2160 if (unique_id < 0x10) 2161 unique_id = 0x10; 2162 ump->logvol_integrity->lvint_next_unique_id = udf_rw64(unique_id + 1); 2163 mutex_exit(&ump->logvol_mutex); 2164 2165 return unique_id; 2166 } 2167 2168 2169 static void 2170 udf_adjust_filecount(struct udf_node *udf_node, int sign) 2171 { 2172 struct udf_mount *ump = udf_node->ump; 2173 uint32_t num_dirs, num_files; 2174 int udf_file_type; 2175 2176 /* get file type */ 2177 if (udf_node->fe) { 2178 udf_file_type = udf_node->fe->icbtag.file_type; 2179 } else { 2180 udf_file_type = udf_node->efe->icbtag.file_type; 2181 } 2182 2183 /* adjust file count */ 2184 mutex_enter(&ump->allocate_mutex); 2185 if (udf_file_type == UDF_ICB_FILETYPE_DIRECTORY) { 2186 num_dirs = udf_rw32(ump->logvol_info->num_directories); 2187 ump->logvol_info->num_directories = 2188 udf_rw32((num_dirs + sign)); 2189 } else { 2190 num_files = udf_rw32(ump->logvol_info->num_files); 2191 ump->logvol_info->num_files = 2192 udf_rw32((num_files + sign)); 2193 } 2194 mutex_exit(&ump->allocate_mutex); 2195 } 2196 2197 2198 void 2199 udf_osta_charset(struct charspec *charspec) 2200 { 2201 memset(charspec, 0, sizeof(struct charspec)); 2202 charspec->type = 0; 2203 strcpy((char *) charspec->inf, "OSTA Compressed Unicode"); 2204 } 2205 2206 2207 /* first call udf_set_regid and then the suffix */ 2208 void 2209 udf_set_regid(struct regid *regid, char const *name) 2210 { 2211 memset(regid, 0, sizeof(struct regid)); 2212 regid->flags = 0; /* not dirty and not protected */ 2213 strcpy((char *) regid->id, name); 2214 } 2215 2216 2217 void 2218 udf_add_domain_regid(struct udf_mount *ump, struct regid *regid) 2219 { 2220 uint16_t *ver; 2221 2222 ver = (uint16_t *) regid->id_suffix; 2223 *ver = ump->logvol_info->min_udf_readver; 2224 } 2225 2226 2227 void 2228 udf_add_udf_regid(struct udf_mount *ump, struct regid *regid) 2229 { 2230 uint16_t *ver; 2231 2232 ver = (uint16_t *) regid->id_suffix; 2233 *ver = ump->logvol_info->min_udf_readver; 2234 2235 regid->id_suffix[2] = 4; /* unix */ 2236 regid->id_suffix[3] = 8; /* NetBSD */ 2237 } 2238 2239 2240 void 2241 udf_add_impl_regid(struct udf_mount *ump, struct regid *regid) 2242 { 2243 regid->id_suffix[0] = 4; /* unix */ 2244 regid->id_suffix[1] = 8; /* NetBSD */ 2245 } 2246 2247 2248 void 2249 udf_add_app_regid(struct udf_mount *ump, struct regid *regid) 2250 { 2251 regid->id_suffix[0] = APP_VERSION_MAIN; 2252 regid->id_suffix[1] = APP_VERSION_SUB; 2253 } 2254 2255 static int 2256 udf_create_parentfid(struct udf_mount *ump, struct fileid_desc *fid, 2257 struct long_ad *parent, uint64_t unique_id) 2258 { 2259 /* the size of an empty FID is 38 but needs to be a multiple of 4 */ 2260 int fidsize = 40; 2261 2262 udf_inittag(ump, &fid->tag, TAGID_FID, udf_rw32(parent->loc.lb_num)); 2263 fid->file_version_num = udf_rw16(1); /* UDF 2.3.4.1 */ 2264 fid->file_char = UDF_FILE_CHAR_DIR | UDF_FILE_CHAR_PAR; 2265 fid->icb = *parent; 2266 fid->icb.longad_uniqueid = udf_rw32((uint32_t) unique_id); 2267 fid->tag.desc_crc_len = udf_rw16(fidsize - UDF_DESC_TAG_LENGTH); 2268 (void) udf_validate_tag_and_crc_sums((union dscrptr *) fid); 2269 2270 return fidsize; 2271 } 2272 2273 /* --------------------------------------------------------------------- */ 2274 2275 /* 2276 * Extended attribute support. UDF knows of 3 places for extended attributes: 2277 * 2278 * (a) inside the file's (e)fe in the length of the extended attribute area 2279 * before the allocation descriptors/filedata 2280 * 2281 * (b) in a file referenced by (e)fe->ext_attr_icb and 2282 * 2283 * (c) in the e(fe)'s associated stream directory that can hold various 2284 * sub-files. In the stream directory a few fixed named subfiles are reserved 2285 * for NT/Unix ACL's and OS/2 attributes. 2286 * 2287 * NOTE: Extended attributes are read randomly but allways written 2288 * *atomicaly*. For ACL's this interface is propably different but not known 2289 * to me yet. 2290 * 2291 * Order of extended attributes in a space : 2292 * ECMA 167 EAs 2293 * Non block aligned Implementation Use EAs 2294 * Block aligned Implementation Use EAs 2295 * Application Use EAs 2296 */ 2297 2298 static int 2299 udf_impl_extattr_check(struct impl_extattr_entry *implext) 2300 { 2301 uint16_t *spos; 2302 2303 if (strncmp(implext->imp_id.id, "*UDF", 4) == 0) { 2304 /* checksum valid? */ 2305 DPRINTF(EXTATTR, ("checking UDF impl. attr checksum\n")); 2306 spos = (uint16_t *) implext->data; 2307 if (udf_rw16(*spos) != udf_ea_cksum((uint8_t *) implext)) 2308 return EINVAL; 2309 } 2310 return 0; 2311 } 2312 2313 static void 2314 udf_calc_impl_extattr_checksum(struct impl_extattr_entry *implext) 2315 { 2316 uint16_t *spos; 2317 2318 if (strncmp(implext->imp_id.id, "*UDF", 4) == 0) { 2319 /* set checksum */ 2320 spos = (uint16_t *) implext->data; 2321 *spos = udf_rw16(udf_ea_cksum((uint8_t *) implext)); 2322 } 2323 } 2324 2325 2326 int 2327 udf_extattr_search_intern(struct udf_node *node, 2328 uint32_t sattr, char const *sattrname, 2329 uint32_t *offsetp, uint32_t *lengthp) 2330 { 2331 struct extattrhdr_desc *eahdr; 2332 struct extattr_entry *attrhdr; 2333 struct impl_extattr_entry *implext; 2334 uint32_t offset, a_l, sector_size; 2335 int32_t l_ea; 2336 uint8_t *pos; 2337 int error; 2338 2339 /* get mountpoint */ 2340 sector_size = node->ump->discinfo.sector_size; 2341 2342 /* get information from fe/efe */ 2343 if (node->fe) { 2344 l_ea = udf_rw32(node->fe->l_ea); 2345 eahdr = (struct extattrhdr_desc *) node->fe->data; 2346 } else { 2347 assert(node->efe); 2348 l_ea = udf_rw32(node->efe->l_ea); 2349 eahdr = (struct extattrhdr_desc *) node->efe->data; 2350 } 2351 2352 /* something recorded here? */ 2353 if (l_ea == 0) 2354 return ENOENT; 2355 2356 /* check extended attribute tag; what to do if it fails? */ 2357 error = udf_check_tag(eahdr); 2358 if (error) 2359 return EINVAL; 2360 if (udf_rw16(eahdr->tag.id) != TAGID_EXTATTR_HDR) 2361 return EINVAL; 2362 error = udf_check_tag_payload(eahdr, sizeof(struct extattrhdr_desc)); 2363 if (error) 2364 return EINVAL; 2365 2366 DPRINTF(EXTATTR, ("Found %d bytes of extended attributes\n", l_ea)); 2367 2368 /* looking for Ecma-167 attributes? */ 2369 offset = sizeof(struct extattrhdr_desc); 2370 2371 /* looking for either implemenation use or application use */ 2372 if (sattr == 2048) { /* [4/48.10.8] */ 2373 offset = udf_rw32(eahdr->impl_attr_loc); 2374 if (offset == UDF_IMPL_ATTR_LOC_NOT_PRESENT) 2375 return ENOENT; 2376 } 2377 if (sattr == 65536) { /* [4/48.10.9] */ 2378 offset = udf_rw32(eahdr->appl_attr_loc); 2379 if (offset == UDF_APPL_ATTR_LOC_NOT_PRESENT) 2380 return ENOENT; 2381 } 2382 2383 /* paranoia check offset and l_ea */ 2384 if (l_ea + offset >= sector_size - sizeof(struct extattr_entry)) 2385 return EINVAL; 2386 2387 DPRINTF(EXTATTR, ("Starting at offset %d\n", offset)); 2388 2389 /* find our extended attribute */ 2390 l_ea -= offset; 2391 pos = (uint8_t *) eahdr + offset; 2392 2393 while (l_ea >= sizeof(struct extattr_entry)) { 2394 DPRINTF(EXTATTR, ("%d extended attr bytes left\n", l_ea)); 2395 attrhdr = (struct extattr_entry *) pos; 2396 implext = (struct impl_extattr_entry *) pos; 2397 2398 /* get complete attribute length and check for roque values */ 2399 a_l = udf_rw32(attrhdr->a_l); 2400 DPRINTF(EXTATTR, ("attribute %d:%d, len %d/%d\n", 2401 udf_rw32(attrhdr->type), 2402 attrhdr->subtype, a_l, l_ea)); 2403 if ((a_l == 0) || (a_l > l_ea)) 2404 return EINVAL; 2405 2406 if (attrhdr->type != sattr) 2407 goto next_attribute; 2408 2409 /* we might have found it! */ 2410 if (attrhdr->type < 2048) { /* Ecma-167 attribute */ 2411 *offsetp = offset; 2412 *lengthp = a_l; 2413 return 0; /* success */ 2414 } 2415 2416 /* 2417 * Implementation use and application use extended attributes 2418 * have a name to identify. They share the same structure only 2419 * UDF implementation use extended attributes have a checksum 2420 * we need to check 2421 */ 2422 2423 DPRINTF(EXTATTR, ("named attribute %s\n", implext->imp_id.id)); 2424 if (strcmp(implext->imp_id.id, sattrname) == 0) { 2425 /* we have found our appl/implementation attribute */ 2426 *offsetp = offset; 2427 *lengthp = a_l; 2428 return 0; /* success */ 2429 } 2430 2431 next_attribute: 2432 /* next attribute */ 2433 pos += a_l; 2434 l_ea -= a_l; 2435 offset += a_l; 2436 } 2437 /* not found */ 2438 return ENOENT; 2439 } 2440 2441 2442 static void 2443 udf_extattr_insert_internal(struct udf_mount *ump, union dscrptr *dscr, 2444 struct extattr_entry *extattr) 2445 { 2446 struct file_entry *fe; 2447 struct extfile_entry *efe; 2448 struct extattrhdr_desc *extattrhdr; 2449 struct impl_extattr_entry *implext; 2450 uint32_t impl_attr_loc, appl_attr_loc, l_ea, a_l, exthdr_len; 2451 uint32_t *l_eap, l_ad; 2452 uint16_t *spos; 2453 uint8_t *bpos, *data; 2454 2455 if (udf_rw16(dscr->tag.id) == TAGID_FENTRY) { 2456 fe = &dscr->fe; 2457 data = fe->data; 2458 l_eap = &fe->l_ea; 2459 l_ad = udf_rw32(fe->l_ad); 2460 } else if (udf_rw16(dscr->tag.id) == TAGID_EXTFENTRY) { 2461 efe = &dscr->efe; 2462 data = efe->data; 2463 l_eap = &efe->l_ea; 2464 l_ad = udf_rw32(efe->l_ad); 2465 } else { 2466 panic("Bad tag passed to udf_extattr_insert_internal"); 2467 } 2468 2469 /* can't append already written to file descriptors yet */ 2470 assert(l_ad == 0); 2471 2472 /* should have a header! */ 2473 extattrhdr = (struct extattrhdr_desc *) data; 2474 l_ea = udf_rw32(*l_eap); 2475 if (l_ea == 0) { 2476 /* create empty extended attribute header */ 2477 exthdr_len = sizeof(struct extattrhdr_desc); 2478 2479 udf_inittag(ump, &extattrhdr->tag, TAGID_EXTATTR_HDR, 2480 /* loc */ 0); 2481 extattrhdr->impl_attr_loc = udf_rw32(exthdr_len); 2482 extattrhdr->appl_attr_loc = udf_rw32(exthdr_len); 2483 extattrhdr->tag.desc_crc_len = udf_rw16(8); 2484 2485 /* record extended attribute header length */ 2486 l_ea = exthdr_len; 2487 *l_eap = udf_rw32(l_ea); 2488 } 2489 2490 /* extract locations */ 2491 impl_attr_loc = udf_rw32(extattrhdr->impl_attr_loc); 2492 appl_attr_loc = udf_rw32(extattrhdr->appl_attr_loc); 2493 if (impl_attr_loc == UDF_IMPL_ATTR_LOC_NOT_PRESENT) 2494 impl_attr_loc = l_ea; 2495 if (appl_attr_loc == UDF_IMPL_ATTR_LOC_NOT_PRESENT) 2496 appl_attr_loc = l_ea; 2497 2498 /* Ecma 167 EAs */ 2499 if (udf_rw32(extattr->type) < 2048) { 2500 assert(impl_attr_loc == l_ea); 2501 assert(appl_attr_loc == l_ea); 2502 } 2503 2504 /* implementation use extended attributes */ 2505 if (udf_rw32(extattr->type) == 2048) { 2506 assert(appl_attr_loc == l_ea); 2507 2508 /* calculate and write extended attribute header checksum */ 2509 implext = (struct impl_extattr_entry *) extattr; 2510 assert(udf_rw32(implext->iu_l) == 4); /* [UDF 3.3.4.5] */ 2511 spos = (uint16_t *) implext->data; 2512 *spos = udf_rw16(udf_ea_cksum((uint8_t *) implext)); 2513 } 2514 2515 /* application use extended attributes */ 2516 assert(udf_rw32(extattr->type) != 65536); 2517 assert(appl_attr_loc == l_ea); 2518 2519 /* append the attribute at the end of the current space */ 2520 bpos = data + udf_rw32(*l_eap); 2521 a_l = udf_rw32(extattr->a_l); 2522 2523 /* update impl. attribute locations */ 2524 if (udf_rw32(extattr->type) < 2048) { 2525 impl_attr_loc = l_ea + a_l; 2526 appl_attr_loc = l_ea + a_l; 2527 } 2528 if (udf_rw32(extattr->type) == 2048) { 2529 appl_attr_loc = l_ea + a_l; 2530 } 2531 2532 /* copy and advance */ 2533 memcpy(bpos, extattr, a_l); 2534 l_ea += a_l; 2535 *l_eap = udf_rw32(l_ea); 2536 2537 /* do the `dance` again backwards */ 2538 if (udf_rw16(ump->logical_vol->tag.descriptor_ver) != 2) { 2539 if (impl_attr_loc == l_ea) 2540 impl_attr_loc = UDF_IMPL_ATTR_LOC_NOT_PRESENT; 2541 if (appl_attr_loc == l_ea) 2542 appl_attr_loc = UDF_APPL_ATTR_LOC_NOT_PRESENT; 2543 } 2544 2545 /* store offsets */ 2546 extattrhdr->impl_attr_loc = udf_rw32(impl_attr_loc); 2547 extattrhdr->appl_attr_loc = udf_rw32(appl_attr_loc); 2548 } 2549 2550 2551 /* --------------------------------------------------------------------- */ 2552 2553 static int 2554 udf_update_lvid_from_vat_extattr(struct udf_node *vat_node) 2555 { 2556 struct udf_mount *ump; 2557 struct udf_logvol_info *lvinfo; 2558 struct impl_extattr_entry *implext; 2559 struct vatlvext_extattr_entry lvext; 2560 const char *extstr = "*UDF VAT LVExtension"; 2561 uint64_t vat_uniqueid; 2562 uint32_t offset, a_l; 2563 uint8_t *ea_start, *lvextpos; 2564 int error; 2565 2566 /* get mountpoint and lvinfo */ 2567 ump = vat_node->ump; 2568 lvinfo = ump->logvol_info; 2569 2570 /* get information from fe/efe */ 2571 if (vat_node->fe) { 2572 vat_uniqueid = udf_rw64(vat_node->fe->unique_id); 2573 ea_start = vat_node->fe->data; 2574 } else { 2575 vat_uniqueid = udf_rw64(vat_node->efe->unique_id); 2576 ea_start = vat_node->efe->data; 2577 } 2578 2579 error = udf_extattr_search_intern(vat_node, 2048, extstr, &offset, &a_l); 2580 if (error) 2581 return error; 2582 2583 implext = (struct impl_extattr_entry *) (ea_start + offset); 2584 error = udf_impl_extattr_check(implext); 2585 if (error) 2586 return error; 2587 2588 /* paranoia */ 2589 if (a_l != sizeof(*implext) -1 + udf_rw32(implext->iu_l) + sizeof(lvext)) { 2590 DPRINTF(VOLUMES, ("VAT LVExtension size doesn't compute\n")); 2591 return EINVAL; 2592 } 2593 2594 /* 2595 * we have found our "VAT LVExtension attribute. BUT due to a 2596 * bug in the specification it might not be word aligned so 2597 * copy first to avoid panics on some machines (!!) 2598 */ 2599 DPRINTF(VOLUMES, ("Found VAT LVExtension attr\n")); 2600 lvextpos = implext->data + udf_rw32(implext->iu_l); 2601 memcpy(&lvext, lvextpos, sizeof(lvext)); 2602 2603 /* check if it was updated the last time */ 2604 if (udf_rw64(lvext.unique_id_chk) == vat_uniqueid) { 2605 lvinfo->num_files = lvext.num_files; 2606 lvinfo->num_directories = lvext.num_directories; 2607 udf_update_logvolname(ump, lvext.logvol_id); 2608 } else { 2609 DPRINTF(VOLUMES, ("VAT LVExtension out of date\n")); 2610 /* replace VAT LVExt by free space EA */ 2611 memset(implext->imp_id.id, 0, UDF_REGID_ID_SIZE); 2612 strcpy(implext->imp_id.id, "*UDF FreeEASpace"); 2613 udf_calc_impl_extattr_checksum(implext); 2614 } 2615 2616 return 0; 2617 } 2618 2619 2620 static int 2621 udf_update_vat_extattr_from_lvid(struct udf_node *vat_node) 2622 { 2623 struct udf_mount *ump; 2624 struct udf_logvol_info *lvinfo; 2625 struct impl_extattr_entry *implext; 2626 struct vatlvext_extattr_entry lvext; 2627 const char *extstr = "*UDF VAT LVExtension"; 2628 uint64_t vat_uniqueid; 2629 uint32_t offset, a_l; 2630 uint8_t *ea_start, *lvextpos; 2631 int error; 2632 2633 /* get mountpoint and lvinfo */ 2634 ump = vat_node->ump; 2635 lvinfo = ump->logvol_info; 2636 2637 /* get information from fe/efe */ 2638 if (vat_node->fe) { 2639 vat_uniqueid = udf_rw64(vat_node->fe->unique_id); 2640 ea_start = vat_node->fe->data; 2641 } else { 2642 vat_uniqueid = udf_rw64(vat_node->efe->unique_id); 2643 ea_start = vat_node->efe->data; 2644 } 2645 2646 error = udf_extattr_search_intern(vat_node, 2048, extstr, &offset, &a_l); 2647 if (error) 2648 return error; 2649 /* found, it existed */ 2650 2651 /* paranoia */ 2652 implext = (struct impl_extattr_entry *) (ea_start + offset); 2653 error = udf_impl_extattr_check(implext); 2654 if (error) { 2655 DPRINTF(VOLUMES, ("VAT LVExtension bad on update\n")); 2656 return error; 2657 } 2658 /* it is correct */ 2659 2660 /* 2661 * we have found our "VAT LVExtension attribute. BUT due to a 2662 * bug in the specification it might not be word aligned so 2663 * copy first to avoid panics on some machines (!!) 2664 */ 2665 DPRINTF(VOLUMES, ("Updating VAT LVExtension attr\n")); 2666 lvextpos = implext->data + udf_rw32(implext->iu_l); 2667 2668 lvext.unique_id_chk = vat_uniqueid; 2669 lvext.num_files = lvinfo->num_files; 2670 lvext.num_directories = lvinfo->num_directories; 2671 memmove(lvext.logvol_id, ump->logical_vol->logvol_id, 128); 2672 2673 memcpy(lvextpos, &lvext, sizeof(lvext)); 2674 2675 return 0; 2676 } 2677 2678 /* --------------------------------------------------------------------- */ 2679 2680 int 2681 udf_vat_read(struct udf_node *vat_node, uint8_t *blob, int size, uint32_t offset) 2682 { 2683 struct udf_mount *ump = vat_node->ump; 2684 2685 if (offset + size > ump->vat_offset + ump->vat_entries * 4) 2686 return EINVAL; 2687 2688 memcpy(blob, ump->vat_table + offset, size); 2689 return 0; 2690 } 2691 2692 int 2693 udf_vat_write(struct udf_node *vat_node, uint8_t *blob, int size, uint32_t offset) 2694 { 2695 struct udf_mount *ump = vat_node->ump; 2696 uint32_t offset_high; 2697 uint8_t *new_vat_table; 2698 2699 /* extent VAT allocation if needed */ 2700 offset_high = offset + size; 2701 if (offset_high >= ump->vat_table_alloc_len) { 2702 /* realloc */ 2703 new_vat_table = realloc(ump->vat_table, 2704 ump->vat_table_alloc_len + UDF_VAT_CHUNKSIZE, 2705 M_UDFVOLD, M_WAITOK | M_CANFAIL); 2706 if (!new_vat_table) { 2707 printf("udf_vat_write: can't extent VAT, out of mem\n"); 2708 return ENOMEM; 2709 } 2710 ump->vat_table = new_vat_table; 2711 ump->vat_table_alloc_len += UDF_VAT_CHUNKSIZE; 2712 } 2713 ump->vat_table_len = MAX(ump->vat_table_len, offset_high); 2714 2715 memcpy(ump->vat_table + offset, blob, size); 2716 return 0; 2717 } 2718 2719 /* --------------------------------------------------------------------- */ 2720 2721 /* TODO support previous VAT location writeout */ 2722 static int 2723 udf_update_vat_descriptor(struct udf_mount *ump) 2724 { 2725 struct udf_node *vat_node = ump->vat_node; 2726 struct udf_logvol_info *lvinfo = ump->logvol_info; 2727 struct icb_tag *icbtag; 2728 struct udf_oldvat_tail *oldvat_tl; 2729 struct udf_vat *vat; 2730 uint64_t unique_id; 2731 uint32_t lb_size; 2732 uint8_t *raw_vat; 2733 int filetype, error; 2734 2735 KASSERT(vat_node); 2736 KASSERT(lvinfo); 2737 lb_size = udf_rw32(ump->logical_vol->lb_size); 2738 2739 /* get our new unique_id */ 2740 unique_id = udf_advance_uniqueid(ump); 2741 2742 /* get information from fe/efe */ 2743 if (vat_node->fe) { 2744 icbtag = &vat_node->fe->icbtag; 2745 vat_node->fe->unique_id = udf_rw64(unique_id); 2746 } else { 2747 icbtag = &vat_node->efe->icbtag; 2748 vat_node->efe->unique_id = udf_rw64(unique_id); 2749 } 2750 2751 /* Check icb filetype! it has to be 0 or UDF_ICB_FILETYPE_VAT */ 2752 filetype = icbtag->file_type; 2753 KASSERT((filetype == 0) || (filetype == UDF_ICB_FILETYPE_VAT)); 2754 2755 /* allocate piece to process head or tail of VAT file */ 2756 raw_vat = malloc(lb_size, M_TEMP, M_WAITOK); 2757 2758 if (filetype == 0) { 2759 /* 2760 * Update "*UDF VAT LVExtension" extended attribute from the 2761 * lvint if present. 2762 */ 2763 udf_update_vat_extattr_from_lvid(vat_node); 2764 2765 /* setup identifying regid */ 2766 oldvat_tl = (struct udf_oldvat_tail *) raw_vat; 2767 memset(oldvat_tl, 0, sizeof(struct udf_oldvat_tail)); 2768 2769 udf_set_regid(&oldvat_tl->id, "*UDF Virtual Alloc Tbl"); 2770 udf_add_udf_regid(ump, &oldvat_tl->id); 2771 oldvat_tl->prev_vat = udf_rw32(0xffffffff); 2772 2773 /* write out new tail of virtual allocation table file */ 2774 error = udf_vat_write(vat_node, raw_vat, 2775 sizeof(struct udf_oldvat_tail), ump->vat_entries * 4); 2776 } else { 2777 /* compose the VAT2 header */ 2778 vat = (struct udf_vat *) raw_vat; 2779 memset(vat, 0, sizeof(struct udf_vat)); 2780 2781 vat->header_len = udf_rw16(152); /* as per spec */ 2782 vat->impl_use_len = udf_rw16(0); 2783 memmove(vat->logvol_id, ump->logical_vol->logvol_id, 128); 2784 vat->prev_vat = udf_rw32(0xffffffff); 2785 vat->num_files = lvinfo->num_files; 2786 vat->num_directories = lvinfo->num_directories; 2787 vat->min_udf_readver = lvinfo->min_udf_readver; 2788 vat->min_udf_writever = lvinfo->min_udf_writever; 2789 vat->max_udf_writever = lvinfo->max_udf_writever; 2790 2791 error = udf_vat_write(vat_node, raw_vat, 2792 sizeof(struct udf_vat), 0); 2793 } 2794 free(raw_vat, M_TEMP); 2795 2796 return error; /* success! */ 2797 } 2798 2799 2800 int 2801 udf_writeout_vat(struct udf_mount *ump) 2802 { 2803 struct udf_node *vat_node = ump->vat_node; 2804 uint32_t vat_length; 2805 int error; 2806 2807 KASSERT(vat_node); 2808 2809 DPRINTF(CALL, ("udf_writeout_vat\n")); 2810 2811 // mutex_enter(&ump->allocate_mutex); 2812 udf_update_vat_descriptor(ump); 2813 2814 /* write out the VAT contents ; TODO intelligent writing */ 2815 vat_length = ump->vat_table_len; 2816 error = vn_rdwr(UIO_WRITE, vat_node->vnode, 2817 ump->vat_table, ump->vat_table_len, 0, 2818 UIO_SYSSPACE, IO_NODELOCKED, FSCRED, NULL, NULL); 2819 if (error) { 2820 printf("udf_writeout_vat: failed to write out VAT contents\n"); 2821 goto out; 2822 } 2823 2824 // mutex_exit(&ump->allocate_mutex); 2825 2826 vflushbuf(ump->vat_node->vnode, 1 /* sync */); 2827 error = VOP_FSYNC(ump->vat_node->vnode, 2828 FSCRED, FSYNC_WAIT, 0, 0); 2829 if (error) 2830 printf("udf_writeout_vat: error writing VAT node!\n"); 2831 out: 2832 2833 return error; 2834 } 2835 2836 /* --------------------------------------------------------------------- */ 2837 2838 /* 2839 * Read in relevant pieces of VAT file and check if its indeed a VAT file 2840 * descriptor. If OK, read in complete VAT file. 2841 */ 2842 2843 static int 2844 udf_check_for_vat(struct udf_node *vat_node) 2845 { 2846 struct udf_mount *ump; 2847 struct icb_tag *icbtag; 2848 struct timestamp *mtime; 2849 struct udf_vat *vat; 2850 struct udf_oldvat_tail *oldvat_tl; 2851 struct udf_logvol_info *lvinfo; 2852 uint64_t unique_id; 2853 uint32_t vat_length; 2854 uint32_t vat_offset, vat_entries, vat_table_alloc_len; 2855 uint32_t sector_size; 2856 uint32_t *raw_vat; 2857 uint8_t *vat_table; 2858 char *regid_name; 2859 int filetype; 2860 int error; 2861 2862 /* vat_length is really 64 bits though impossible */ 2863 2864 DPRINTF(VOLUMES, ("Checking for VAT\n")); 2865 if (!vat_node) 2866 return ENOENT; 2867 2868 /* get mount info */ 2869 ump = vat_node->ump; 2870 sector_size = udf_rw32(ump->logical_vol->lb_size); 2871 2872 /* check assertions */ 2873 assert(vat_node->fe || vat_node->efe); 2874 assert(ump->logvol_integrity); 2875 2876 /* set vnode type to regular file or we can't read from it! */ 2877 vat_node->vnode->v_type = VREG; 2878 2879 /* get information from fe/efe */ 2880 if (vat_node->fe) { 2881 vat_length = udf_rw64(vat_node->fe->inf_len); 2882 icbtag = &vat_node->fe->icbtag; 2883 mtime = &vat_node->fe->mtime; 2884 unique_id = udf_rw64(vat_node->fe->unique_id); 2885 } else { 2886 vat_length = udf_rw64(vat_node->efe->inf_len); 2887 icbtag = &vat_node->efe->icbtag; 2888 mtime = &vat_node->efe->mtime; 2889 unique_id = udf_rw64(vat_node->efe->unique_id); 2890 } 2891 2892 /* Check icb filetype! it has to be 0 or UDF_ICB_FILETYPE_VAT */ 2893 filetype = icbtag->file_type; 2894 if ((filetype != 0) && (filetype != UDF_ICB_FILETYPE_VAT)) 2895 return ENOENT; 2896 2897 DPRINTF(VOLUMES, ("\tPossible VAT length %d\n", vat_length)); 2898 2899 vat_table_alloc_len = 2900 ((vat_length + UDF_VAT_CHUNKSIZE-1) / UDF_VAT_CHUNKSIZE) 2901 * UDF_VAT_CHUNKSIZE; 2902 2903 vat_table = malloc(vat_table_alloc_len, M_UDFVOLD, 2904 M_CANFAIL | M_WAITOK); 2905 if (vat_table == NULL) { 2906 printf("allocation of %d bytes failed for VAT\n", 2907 vat_table_alloc_len); 2908 return ENOMEM; 2909 } 2910 2911 /* allocate piece to read in head or tail of VAT file */ 2912 raw_vat = malloc(sector_size, M_TEMP, M_WAITOK); 2913 2914 /* 2915 * check contents of the file if its the old 1.50 VAT table format. 2916 * Its notoriously broken and allthough some implementations support an 2917 * extention as defined in the UDF 1.50 errata document, its doubtfull 2918 * to be useable since a lot of implementations don't maintain it. 2919 */ 2920 lvinfo = ump->logvol_info; 2921 2922 if (filetype == 0) { 2923 /* definition */ 2924 vat_offset = 0; 2925 vat_entries = (vat_length-36)/4; 2926 2927 /* read in tail of virtual allocation table file */ 2928 error = vn_rdwr(UIO_READ, vat_node->vnode, 2929 (uint8_t *) raw_vat, 2930 sizeof(struct udf_oldvat_tail), 2931 vat_entries * 4, 2932 UIO_SYSSPACE, IO_SYNC | IO_NODELOCKED, FSCRED, 2933 NULL, NULL); 2934 if (error) 2935 goto out; 2936 2937 /* check 1.50 VAT */ 2938 oldvat_tl = (struct udf_oldvat_tail *) raw_vat; 2939 regid_name = (char *) oldvat_tl->id.id; 2940 error = strncmp(regid_name, "*UDF Virtual Alloc Tbl", 22); 2941 if (error) { 2942 DPRINTF(VOLUMES, ("VAT format 1.50 rejected\n")); 2943 error = ENOENT; 2944 goto out; 2945 } 2946 2947 /* 2948 * update LVID from "*UDF VAT LVExtension" extended attribute 2949 * if present. 2950 */ 2951 udf_update_lvid_from_vat_extattr(vat_node); 2952 } else { 2953 /* read in head of virtual allocation table file */ 2954 error = vn_rdwr(UIO_READ, vat_node->vnode, 2955 (uint8_t *) raw_vat, 2956 sizeof(struct udf_vat), 0, 2957 UIO_SYSSPACE, IO_SYNC | IO_NODELOCKED, FSCRED, 2958 NULL, NULL); 2959 if (error) 2960 goto out; 2961 2962 /* definition */ 2963 vat = (struct udf_vat *) raw_vat; 2964 vat_offset = vat->header_len; 2965 vat_entries = (vat_length - vat_offset)/4; 2966 2967 assert(lvinfo); 2968 lvinfo->num_files = vat->num_files; 2969 lvinfo->num_directories = vat->num_directories; 2970 lvinfo->min_udf_readver = vat->min_udf_readver; 2971 lvinfo->min_udf_writever = vat->min_udf_writever; 2972 lvinfo->max_udf_writever = vat->max_udf_writever; 2973 2974 udf_update_logvolname(ump, vat->logvol_id); 2975 } 2976 2977 /* read in complete VAT file */ 2978 error = vn_rdwr(UIO_READ, vat_node->vnode, 2979 vat_table, 2980 vat_length, 0, 2981 UIO_SYSSPACE, IO_SYNC | IO_NODELOCKED, FSCRED, 2982 NULL, NULL); 2983 if (error) 2984 printf("read in of complete VAT file failed (error %d)\n", 2985 error); 2986 if (error) 2987 goto out; 2988 2989 DPRINTF(VOLUMES, ("VAT format accepted, marking it closed\n")); 2990 ump->logvol_integrity->lvint_next_unique_id = udf_rw64(unique_id); 2991 ump->logvol_integrity->integrity_type = udf_rw32(UDF_INTEGRITY_CLOSED); 2992 ump->logvol_integrity->time = *mtime; 2993 2994 ump->vat_table_len = vat_length; 2995 ump->vat_table_alloc_len = vat_table_alloc_len; 2996 ump->vat_table = vat_table; 2997 ump->vat_offset = vat_offset; 2998 ump->vat_entries = vat_entries; 2999 ump->vat_last_free_lb = 0; /* start at beginning */ 3000 3001 out: 3002 if (error) { 3003 if (vat_table) 3004 free(vat_table, M_UDFVOLD); 3005 } 3006 free(raw_vat, M_TEMP); 3007 3008 return error; 3009 } 3010 3011 /* --------------------------------------------------------------------- */ 3012 3013 static int 3014 udf_search_vat(struct udf_mount *ump, union udf_pmap *mapping) 3015 { 3016 struct udf_node *vat_node; 3017 struct long_ad icb_loc; 3018 uint32_t early_vat_loc, late_vat_loc, vat_loc; 3019 int error; 3020 3021 /* mapping info not needed */ 3022 mapping = mapping; 3023 3024 vat_loc = ump->last_possible_vat_location; 3025 early_vat_loc = vat_loc - 256; /* 8 blocks of 32 sectors */ 3026 3027 DPRINTF(VOLUMES, ("1) last possible %d, early_vat_loc %d \n", 3028 vat_loc, early_vat_loc)); 3029 early_vat_loc = MAX(early_vat_loc, ump->first_possible_vat_location); 3030 late_vat_loc = vat_loc + 1024; 3031 3032 DPRINTF(VOLUMES, ("2) last possible %d, early_vat_loc %d \n", 3033 vat_loc, early_vat_loc)); 3034 3035 /* start looking from the end of the range */ 3036 do { 3037 DPRINTF(VOLUMES, ("Checking for VAT at sector %d\n", vat_loc)); 3038 icb_loc.loc.part_num = udf_rw16(UDF_VTOP_RAWPART); 3039 icb_loc.loc.lb_num = udf_rw32(vat_loc); 3040 3041 error = udf_get_node(ump, &icb_loc, &vat_node); 3042 if (!error) { 3043 error = udf_check_for_vat(vat_node); 3044 DPRINTFIF(VOLUMES, !error, 3045 ("VAT accepted at %d\n", vat_loc)); 3046 if (!error) 3047 break; 3048 } 3049 if (vat_node) { 3050 vput(vat_node->vnode); 3051 vat_node = NULL; 3052 } 3053 vat_loc--; /* walk backwards */ 3054 } while (vat_loc >= early_vat_loc); 3055 3056 /* keep our VAT node around */ 3057 if (vat_node) { 3058 UDF_SET_SYSTEMFILE(vat_node->vnode); 3059 ump->vat_node = vat_node; 3060 } 3061 3062 return error; 3063 } 3064 3065 /* --------------------------------------------------------------------- */ 3066 3067 static int 3068 udf_read_sparables(struct udf_mount *ump, union udf_pmap *mapping) 3069 { 3070 union dscrptr *dscr; 3071 struct part_map_spare *pms = &mapping->pms; 3072 uint32_t lb_num; 3073 int spar, error; 3074 3075 /* 3076 * The partition mapping passed on to us specifies the information we 3077 * need to locate and initialise the sparable partition mapping 3078 * information we need. 3079 */ 3080 3081 DPRINTF(VOLUMES, ("Read sparable table\n")); 3082 ump->sparable_packet_size = udf_rw16(pms->packet_len); 3083 KASSERT(ump->sparable_packet_size >= ump->packet_size); /* XXX */ 3084 3085 for (spar = 0; spar < pms->n_st; spar++) { 3086 lb_num = pms->st_loc[spar]; 3087 DPRINTF(VOLUMES, ("Checking for sparing table %d\n", lb_num)); 3088 error = udf_read_phys_dscr(ump, lb_num, M_UDFVOLD, &dscr); 3089 if (!error && dscr) { 3090 if (udf_rw16(dscr->tag.id) == TAGID_SPARING_TABLE) { 3091 if (ump->sparing_table) 3092 free(ump->sparing_table, M_UDFVOLD); 3093 ump->sparing_table = &dscr->spt; 3094 dscr = NULL; 3095 DPRINTF(VOLUMES, 3096 ("Sparing table accepted (%d entries)\n", 3097 udf_rw16(ump->sparing_table->rt_l))); 3098 break; /* we're done */ 3099 } 3100 } 3101 if (dscr) 3102 free(dscr, M_UDFVOLD); 3103 } 3104 3105 if (ump->sparing_table) 3106 return 0; 3107 3108 return ENOENT; 3109 } 3110 3111 /* --------------------------------------------------------------------- */ 3112 3113 static int 3114 udf_read_metadata_nodes(struct udf_mount *ump, union udf_pmap *mapping) 3115 { 3116 struct part_map_meta *pmm = &mapping->pmm; 3117 struct long_ad icb_loc; 3118 struct vnode *vp; 3119 int error; 3120 3121 /* extract our allocation parameters set up on format */ 3122 ump->metadata_alloc_unit_size = udf_rw32(mapping->pmm.alloc_unit_size); 3123 ump->metadata_alignment_unit_size = udf_rw16(mapping->pmm.alignment_unit_size); 3124 ump->metadata_flags = mapping->pmm.flags; 3125 3126 DPRINTF(VOLUMES, ("Reading in Metadata files\n")); 3127 icb_loc.loc.part_num = pmm->part_num; 3128 icb_loc.loc.lb_num = pmm->meta_file_lbn; 3129 DPRINTF(VOLUMES, ("Metadata file\n")); 3130 error = udf_get_node(ump, &icb_loc, &ump->metadata_node); 3131 if (ump->metadata_node) { 3132 vp = ump->metadata_node->vnode; 3133 UDF_SET_SYSTEMFILE(vp); 3134 } 3135 3136 icb_loc.loc.lb_num = pmm->meta_mirror_file_lbn; 3137 if (icb_loc.loc.lb_num != -1) { 3138 DPRINTF(VOLUMES, ("Metadata copy file\n")); 3139 error = udf_get_node(ump, &icb_loc, &ump->metadatamirror_node); 3140 if (ump->metadatamirror_node) { 3141 vp = ump->metadatamirror_node->vnode; 3142 UDF_SET_SYSTEMFILE(vp); 3143 } 3144 } 3145 3146 icb_loc.loc.lb_num = pmm->meta_bitmap_file_lbn; 3147 if (icb_loc.loc.lb_num != -1) { 3148 DPRINTF(VOLUMES, ("Metadata bitmap file\n")); 3149 error = udf_get_node(ump, &icb_loc, &ump->metadatabitmap_node); 3150 if (ump->metadatabitmap_node) { 3151 vp = ump->metadatabitmap_node->vnode; 3152 UDF_SET_SYSTEMFILE(vp); 3153 } 3154 } 3155 3156 /* if we're mounting read-only we relax the requirements */ 3157 if (ump->vfs_mountp->mnt_flag & MNT_RDONLY) { 3158 error = EFAULT; 3159 if (ump->metadata_node) 3160 error = 0; 3161 if ((ump->metadata_node == NULL) && (ump->metadatamirror_node)) { 3162 printf( "udf mount: Metadata file not readable, " 3163 "substituting Metadata copy file\n"); 3164 ump->metadata_node = ump->metadatamirror_node; 3165 ump->metadatamirror_node = NULL; 3166 error = 0; 3167 } 3168 } else { 3169 /* mounting read/write */ 3170 /* XXX DISABLED! metadata writing is not working yet XXX */ 3171 if (error) 3172 error = EROFS; 3173 } 3174 DPRINTFIF(VOLUMES, error, ("udf mount: failed to read " 3175 "metadata files\n")); 3176 return error; 3177 } 3178 3179 /* --------------------------------------------------------------------- */ 3180 3181 int 3182 udf_read_vds_tables(struct udf_mount *ump) 3183 { 3184 union udf_pmap *mapping; 3185 /* struct udf_args *args = &ump->mount_args; */ 3186 uint32_t n_pm, mt_l; 3187 uint32_t log_part; 3188 uint8_t *pmap_pos; 3189 int pmap_size; 3190 int error; 3191 3192 /* Iterate (again) over the part mappings for locations */ 3193 n_pm = udf_rw32(ump->logical_vol->n_pm); /* num partmaps */ 3194 mt_l = udf_rw32(ump->logical_vol->mt_l); /* partmaps data length */ 3195 pmap_pos = ump->logical_vol->maps; 3196 3197 for (log_part = 0; log_part < n_pm; log_part++) { 3198 mapping = (union udf_pmap *) pmap_pos; 3199 switch (ump->vtop_tp[log_part]) { 3200 case UDF_VTOP_TYPE_PHYS : 3201 /* nothing */ 3202 break; 3203 case UDF_VTOP_TYPE_VIRT : 3204 /* search and load VAT */ 3205 error = udf_search_vat(ump, mapping); 3206 if (error) 3207 return ENOENT; 3208 break; 3209 case UDF_VTOP_TYPE_SPARABLE : 3210 /* load one of the sparable tables */ 3211 error = udf_read_sparables(ump, mapping); 3212 if (error) 3213 return ENOENT; 3214 break; 3215 case UDF_VTOP_TYPE_META : 3216 /* load the associated file descriptors */ 3217 error = udf_read_metadata_nodes(ump, mapping); 3218 if (error) 3219 return ENOENT; 3220 break; 3221 default: 3222 break; 3223 } 3224 pmap_size = pmap_pos[1]; 3225 pmap_pos += pmap_size; 3226 } 3227 3228 /* read in and check unallocated and free space info if writing */ 3229 if ((ump->vfs_mountp->mnt_flag & MNT_RDONLY) == 0) { 3230 error = udf_read_physical_partition_spacetables(ump); 3231 if (error) 3232 return error; 3233 3234 /* also read in metadata partition spacebitmap if defined */ 3235 error = udf_read_metadata_partition_spacetable(ump); 3236 return error; 3237 } 3238 3239 return 0; 3240 } 3241 3242 /* --------------------------------------------------------------------- */ 3243 3244 int 3245 udf_read_rootdirs(struct udf_mount *ump) 3246 { 3247 union dscrptr *dscr; 3248 /* struct udf_args *args = &ump->mount_args; */ 3249 struct udf_node *rootdir_node, *streamdir_node; 3250 struct long_ad fsd_loc, *dir_loc; 3251 uint32_t lb_num, dummy; 3252 uint32_t fsd_len; 3253 int dscr_type; 3254 int error; 3255 3256 /* TODO implement FSD reading in separate function like integrity? */ 3257 /* get fileset descriptor sequence */ 3258 fsd_loc = ump->logical_vol->lv_fsd_loc; 3259 fsd_len = udf_rw32(fsd_loc.len); 3260 3261 dscr = NULL; 3262 error = 0; 3263 while (fsd_len || error) { 3264 DPRINTF(VOLUMES, ("fsd_len = %d\n", fsd_len)); 3265 /* translate fsd_loc to lb_num */ 3266 error = udf_translate_vtop(ump, &fsd_loc, &lb_num, &dummy); 3267 if (error) 3268 break; 3269 DPRINTF(VOLUMES, ("Reading FSD at lb %d\n", lb_num)); 3270 error = udf_read_phys_dscr(ump, lb_num, M_UDFVOLD, &dscr); 3271 /* end markers */ 3272 if (error || (dscr == NULL)) 3273 break; 3274 3275 /* analyse */ 3276 dscr_type = udf_rw16(dscr->tag.id); 3277 if (dscr_type == TAGID_TERM) 3278 break; 3279 if (dscr_type != TAGID_FSD) { 3280 free(dscr, M_UDFVOLD); 3281 return ENOENT; 3282 } 3283 3284 /* 3285 * TODO check for multiple fileset descriptors; its only 3286 * picking the last now. Also check for FSD 3287 * correctness/interpretability 3288 */ 3289 3290 /* update */ 3291 if (ump->fileset_desc) { 3292 free(ump->fileset_desc, M_UDFVOLD); 3293 } 3294 ump->fileset_desc = &dscr->fsd; 3295 dscr = NULL; 3296 3297 /* continue to the next fsd */ 3298 fsd_len -= ump->discinfo.sector_size; 3299 fsd_loc.loc.lb_num = udf_rw32(udf_rw32(fsd_loc.loc.lb_num)+1); 3300 3301 /* follow up to fsd->next_ex (long_ad) if its not null */ 3302 if (udf_rw32(ump->fileset_desc->next_ex.len)) { 3303 DPRINTF(VOLUMES, ("follow up FSD extent\n")); 3304 fsd_loc = ump->fileset_desc->next_ex; 3305 fsd_len = udf_rw32(ump->fileset_desc->next_ex.len); 3306 } 3307 } 3308 if (dscr) 3309 free(dscr, M_UDFVOLD); 3310 3311 /* there has to be one */ 3312 if (ump->fileset_desc == NULL) 3313 return ENOENT; 3314 3315 DPRINTF(VOLUMES, ("FSD read in fine\n")); 3316 DPRINTF(VOLUMES, ("Updating fsd logical volume id\n")); 3317 udf_update_logvolname(ump, ump->logical_vol->logvol_id); 3318 3319 /* 3320 * Now the FSD is known, read in the rootdirectory and if one exists, 3321 * the system stream dir. Some files in the system streamdir are not 3322 * wanted in this implementation since they are not maintained. If 3323 * writing is enabled we'll delete these files if they exist. 3324 */ 3325 3326 rootdir_node = streamdir_node = NULL; 3327 dir_loc = NULL; 3328 3329 /* try to read in the rootdir */ 3330 dir_loc = &ump->fileset_desc->rootdir_icb; 3331 error = udf_get_node(ump, dir_loc, &rootdir_node); 3332 if (error) 3333 return ENOENT; 3334 3335 /* aparently it read in fine */ 3336 3337 /* 3338 * Try the system stream directory; not very likely in the ones we 3339 * test, but for completeness. 3340 */ 3341 dir_loc = &ump->fileset_desc->streamdir_icb; 3342 if (udf_rw32(dir_loc->len)) { 3343 printf("udf_read_rootdirs: streamdir defined "); 3344 error = udf_get_node(ump, dir_loc, &streamdir_node); 3345 if (error) { 3346 printf("but error in streamdir reading\n"); 3347 } else { 3348 printf("but ignored\n"); 3349 /* 3350 * TODO process streamdir `baddies' i.e. files we dont 3351 * want if R/W 3352 */ 3353 } 3354 } 3355 3356 DPRINTF(VOLUMES, ("Rootdir(s) read in fine\n")); 3357 3358 /* release the vnodes again; they'll be auto-recycled later */ 3359 if (streamdir_node) { 3360 vput(streamdir_node->vnode); 3361 } 3362 if (rootdir_node) { 3363 vput(rootdir_node->vnode); 3364 } 3365 3366 return 0; 3367 } 3368 3369 /* --------------------------------------------------------------------- */ 3370 3371 /* To make absolutely sure we are NOT returning zero, add one :) */ 3372 3373 long 3374 udf_get_node_id(const struct long_ad *icbptr) 3375 { 3376 /* ought to be enough since each mountpoint has its own chain */ 3377 return udf_rw32(icbptr->loc.lb_num) + 1; 3378 } 3379 3380 3381 int 3382 udf_compare_icb(const struct long_ad *a, const struct long_ad *b) 3383 { 3384 if (udf_rw16(a->loc.part_num) < udf_rw16(b->loc.part_num)) 3385 return -1; 3386 if (udf_rw16(a->loc.part_num) > udf_rw16(b->loc.part_num)) 3387 return 1; 3388 3389 if (udf_rw32(a->loc.lb_num) < udf_rw32(b->loc.lb_num)) 3390 return -1; 3391 if (udf_rw32(a->loc.lb_num) > udf_rw32(b->loc.lb_num)) 3392 return 1; 3393 3394 return 0; 3395 } 3396 3397 3398 static int 3399 udf_compare_rbnodes(const struct rb_node *a, const struct rb_node *b) 3400 { 3401 struct udf_node *a_node = RBTOUDFNODE(a); 3402 struct udf_node *b_node = RBTOUDFNODE(b); 3403 3404 return udf_compare_icb(&a_node->loc, &b_node->loc); 3405 } 3406 3407 3408 static int 3409 udf_compare_rbnode_icb(const struct rb_node *a, const void *key) 3410 { 3411 struct udf_node *a_node = RBTOUDFNODE(a); 3412 const struct long_ad * const icb = key; 3413 3414 return udf_compare_icb(&a_node->loc, icb); 3415 } 3416 3417 3418 static const struct rb_tree_ops udf_node_rbtree_ops = { 3419 .rbto_compare_nodes = udf_compare_rbnodes, 3420 .rbto_compare_key = udf_compare_rbnode_icb, 3421 }; 3422 3423 3424 void 3425 udf_init_nodes_tree(struct udf_mount *ump) 3426 { 3427 rb_tree_init(&ump->udf_node_tree, &udf_node_rbtree_ops); 3428 } 3429 3430 3431 static struct udf_node * 3432 udf_node_lookup(struct udf_mount *ump, struct long_ad *icbptr) 3433 { 3434 struct rb_node *rb_node; 3435 struct udf_node *udf_node; 3436 struct vnode *vp; 3437 3438 loop: 3439 mutex_enter(&ump->ihash_lock); 3440 3441 rb_node = rb_tree_find_node(&ump->udf_node_tree, icbptr); 3442 if (rb_node) { 3443 udf_node = RBTOUDFNODE(rb_node); 3444 vp = udf_node->vnode; 3445 assert(vp); 3446 mutex_enter(&vp->v_interlock); 3447 mutex_exit(&ump->ihash_lock); 3448 if (vget(vp, LK_EXCLUSIVE | LK_INTERLOCK)) 3449 goto loop; 3450 return udf_node; 3451 } 3452 mutex_exit(&ump->ihash_lock); 3453 3454 return NULL; 3455 } 3456 3457 3458 static void 3459 udf_register_node(struct udf_node *udf_node) 3460 { 3461 struct udf_mount *ump = udf_node->ump; 3462 3463 /* add node to the rb tree */ 3464 mutex_enter(&ump->ihash_lock); 3465 rb_tree_insert_node(&ump->udf_node_tree, &udf_node->rbnode); 3466 mutex_exit(&ump->ihash_lock); 3467 } 3468 3469 3470 static void 3471 udf_deregister_node(struct udf_node *udf_node) 3472 { 3473 struct udf_mount *ump = udf_node->ump; 3474 3475 /* remove node from the rb tree */ 3476 mutex_enter(&ump->ihash_lock); 3477 rb_tree_remove_node(&ump->udf_node_tree, &udf_node->rbnode); 3478 mutex_exit(&ump->ihash_lock); 3479 } 3480 3481 /* --------------------------------------------------------------------- */ 3482 3483 static int 3484 udf_validate_session_start(struct udf_mount *ump) 3485 { 3486 struct mmc_trackinfo trackinfo; 3487 struct vrs_desc *vrs; 3488 uint32_t tracknr, sessionnr, sector, sector_size; 3489 uint32_t iso9660_vrs, write_track_start; 3490 uint8_t *buffer, *blank, *pos; 3491 int blks, max_sectors, vrs_len; 3492 int error; 3493 3494 /* disc appendable? */ 3495 if (ump->discinfo.disc_state == MMC_STATE_FULL) 3496 return EROFS; 3497 3498 /* already written here? if so, there should be an ISO VDS */ 3499 if (ump->discinfo.last_session_state == MMC_STATE_INCOMPLETE) 3500 return 0; 3501 3502 /* 3503 * Check if the first track of the session is blank and if so, copy or 3504 * create a dummy ISO descriptor so the disc is valid again. 3505 */ 3506 3507 tracknr = ump->discinfo.first_track_last_session; 3508 memset(&trackinfo, 0, sizeof(struct mmc_trackinfo)); 3509 trackinfo.tracknr = tracknr; 3510 error = udf_update_trackinfo(ump, &trackinfo); 3511 if (error) 3512 return error; 3513 3514 udf_dump_trackinfo(&trackinfo); 3515 KASSERT(trackinfo.flags & (MMC_TRACKINFO_BLANK | MMC_TRACKINFO_RESERVED)); 3516 KASSERT(trackinfo.sessionnr > 1); 3517 3518 KASSERT(trackinfo.flags & MMC_TRACKINFO_NWA_VALID); 3519 write_track_start = trackinfo.next_writable; 3520 3521 /* we have to copy the ISO VRS from a former session */ 3522 DPRINTF(VOLUMES, ("validate_session_start: " 3523 "blank or reserved track, copying VRS\n")); 3524 3525 /* sessionnr should be the session we're mounting */ 3526 sessionnr = ump->mount_args.sessionnr; 3527 3528 /* start at the first track */ 3529 tracknr = ump->discinfo.first_track; 3530 while (tracknr <= ump->discinfo.num_tracks) { 3531 trackinfo.tracknr = tracknr; 3532 error = udf_update_trackinfo(ump, &trackinfo); 3533 if (error) { 3534 DPRINTF(VOLUMES, ("failed to get trackinfo; aborting\n")); 3535 return error; 3536 } 3537 if (trackinfo.sessionnr == sessionnr) 3538 break; 3539 tracknr++; 3540 } 3541 if (trackinfo.sessionnr != sessionnr) { 3542 DPRINTF(VOLUMES, ("failed to get trackinfo; aborting\n")); 3543 return ENOENT; 3544 } 3545 3546 DPRINTF(VOLUMES, ("found possible former ISO VRS at\n")); 3547 udf_dump_trackinfo(&trackinfo); 3548 3549 /* 3550 * location of iso9660 vrs is defined as first sector AFTER 32kb, 3551 * minimum ISO `sector size' 2048 3552 */ 3553 sector_size = ump->discinfo.sector_size; 3554 iso9660_vrs = ((32*1024 + sector_size - 1) / sector_size) 3555 + trackinfo.track_start; 3556 3557 buffer = malloc(UDF_ISO_VRS_SIZE, M_TEMP, M_WAITOK); 3558 max_sectors = UDF_ISO_VRS_SIZE / sector_size; 3559 blks = MAX(1, 2048 / sector_size); 3560 3561 error = 0; 3562 for (sector = 0; sector < max_sectors; sector += blks) { 3563 pos = buffer + sector * sector_size; 3564 error = udf_read_phys_sectors(ump, UDF_C_DSCR, pos, 3565 iso9660_vrs + sector, blks); 3566 if (error) 3567 break; 3568 /* check this ISO descriptor */ 3569 vrs = (struct vrs_desc *) pos; 3570 DPRINTF(VOLUMES, ("got VRS id `%4s`\n", vrs->identifier)); 3571 if (strncmp(vrs->identifier, VRS_CD001, 5) == 0) 3572 continue; 3573 if (strncmp(vrs->identifier, VRS_CDW02, 5) == 0) 3574 continue; 3575 if (strncmp(vrs->identifier, VRS_BEA01, 5) == 0) 3576 continue; 3577 if (strncmp(vrs->identifier, VRS_NSR02, 5) == 0) 3578 continue; 3579 if (strncmp(vrs->identifier, VRS_NSR03, 5) == 0) 3580 continue; 3581 if (strncmp(vrs->identifier, VRS_TEA01, 5) == 0) 3582 break; 3583 /* now what? for now, end of sequence */ 3584 break; 3585 } 3586 vrs_len = sector + blks; 3587 if (error) { 3588 DPRINTF(VOLUMES, ("error reading old ISO VRS\n")); 3589 DPRINTF(VOLUMES, ("creating minimal ISO VRS\n")); 3590 3591 memset(buffer, 0, UDF_ISO_VRS_SIZE); 3592 3593 vrs = (struct vrs_desc *) (buffer); 3594 vrs->struct_type = 0; 3595 vrs->version = 1; 3596 memcpy(vrs->identifier,VRS_BEA01, 5); 3597 3598 vrs = (struct vrs_desc *) (buffer + 2048); 3599 vrs->struct_type = 0; 3600 vrs->version = 1; 3601 if (udf_rw16(ump->logical_vol->tag.descriptor_ver) == 2) { 3602 memcpy(vrs->identifier,VRS_NSR02, 5); 3603 } else { 3604 memcpy(vrs->identifier,VRS_NSR03, 5); 3605 } 3606 3607 vrs = (struct vrs_desc *) (buffer + 4096); 3608 vrs->struct_type = 0; 3609 vrs->version = 1; 3610 memcpy(vrs->identifier, VRS_TEA01, 5); 3611 3612 vrs_len = 3*blks; 3613 } 3614 3615 DPRINTF(VOLUMES, ("Got VRS of %d sectors long\n", vrs_len)); 3616 3617 /* 3618 * location of iso9660 vrs is defined as first sector AFTER 32kb, 3619 * minimum ISO `sector size' 2048 3620 */ 3621 sector_size = ump->discinfo.sector_size; 3622 iso9660_vrs = ((32*1024 + sector_size - 1) / sector_size) 3623 + write_track_start; 3624 3625 /* write out 32 kb */ 3626 blank = malloc(sector_size, M_TEMP, M_WAITOK); 3627 memset(blank, 0, sector_size); 3628 error = 0; 3629 for (sector = write_track_start; sector < iso9660_vrs; sector ++) { 3630 error = udf_write_phys_sectors(ump, UDF_C_ABSOLUTE, 3631 blank, sector, 1); 3632 if (error) 3633 break; 3634 } 3635 if (!error) { 3636 /* write out our ISO VRS */ 3637 KASSERT(sector == iso9660_vrs); 3638 error = udf_write_phys_sectors(ump, UDF_C_ABSOLUTE, buffer, 3639 sector, vrs_len); 3640 sector += vrs_len; 3641 } 3642 if (!error) { 3643 /* fill upto the first anchor at S+256 */ 3644 for (; sector < write_track_start+256; sector++) { 3645 error = udf_write_phys_sectors(ump, UDF_C_ABSOLUTE, 3646 blank, sector, 1); 3647 if (error) 3648 break; 3649 } 3650 } 3651 if (!error) { 3652 /* write out anchor; write at ABSOLUTE place! */ 3653 error = udf_write_phys_dscr_sync(ump, NULL, UDF_C_ABSOLUTE, 3654 (union dscrptr *) ump->anchors[0], sector, sector); 3655 if (error) 3656 printf("writeout of anchor failed!\n"); 3657 } 3658 3659 free(blank, M_TEMP); 3660 free(buffer, M_TEMP); 3661 3662 if (error) 3663 printf("udf_open_session: error writing iso vrs! : " 3664 "leaving disc in compromised state!\n"); 3665 3666 /* synchronise device caches */ 3667 (void) udf_synchronise_caches(ump); 3668 3669 return error; 3670 } 3671 3672 3673 int 3674 udf_open_logvol(struct udf_mount *ump) 3675 { 3676 int logvol_integrity; 3677 int error; 3678 3679 /* already/still open? */ 3680 logvol_integrity = udf_rw32(ump->logvol_integrity->integrity_type); 3681 if (logvol_integrity == UDF_INTEGRITY_OPEN) 3682 return 0; 3683 3684 /* can we open it ? */ 3685 if (ump->vfs_mountp->mnt_flag & MNT_RDONLY) 3686 return EROFS; 3687 3688 /* setup write parameters */ 3689 DPRINTF(VOLUMES, ("Setting up write parameters\n")); 3690 if ((error = udf_setup_writeparams(ump)) != 0) 3691 return error; 3692 3693 /* determine data and metadata tracks (most likely same) */ 3694 error = udf_search_writing_tracks(ump); 3695 if (error) { 3696 /* most likely lack of space */ 3697 printf("udf_open_logvol: error searching writing tracks\n"); 3698 return EROFS; 3699 } 3700 3701 /* writeout/update lvint on disc or only in memory */ 3702 DPRINTF(VOLUMES, ("Opening logical volume\n")); 3703 if (ump->lvopen & UDF_OPEN_SESSION) { 3704 /* TODO optional track reservation opening */ 3705 error = udf_validate_session_start(ump); 3706 if (error) 3707 return error; 3708 3709 /* determine data and metadata tracks again */ 3710 error = udf_search_writing_tracks(ump); 3711 } 3712 3713 /* mark it open */ 3714 ump->logvol_integrity->integrity_type = udf_rw32(UDF_INTEGRITY_OPEN); 3715 3716 /* do we need to write it out? */ 3717 if (ump->lvopen & UDF_WRITE_LVINT) { 3718 error = udf_writeout_lvint(ump, ump->lvopen); 3719 /* if we couldn't write it mark it closed again */ 3720 if (error) { 3721 ump->logvol_integrity->integrity_type = 3722 udf_rw32(UDF_INTEGRITY_CLOSED); 3723 return error; 3724 } 3725 } 3726 3727 return 0; 3728 } 3729 3730 3731 int 3732 udf_close_logvol(struct udf_mount *ump, int mntflags) 3733 { 3734 struct vnode *devvp = ump->devvp; 3735 struct mmc_op mmc_op; 3736 int logvol_integrity; 3737 int error = 0, error1 = 0, error2 = 0; 3738 int tracknr; 3739 int nvats, n, nok; 3740 3741 /* already/still closed? */ 3742 logvol_integrity = udf_rw32(ump->logvol_integrity->integrity_type); 3743 if (logvol_integrity == UDF_INTEGRITY_CLOSED) 3744 return 0; 3745 3746 /* writeout/update lvint or write out VAT */ 3747 DPRINTF(VOLUMES, ("udf_close_logvol: closing logical volume\n")); 3748 #ifdef DIAGNOSTIC 3749 if (ump->lvclose & UDF_CLOSE_SESSION) 3750 KASSERT(ump->lvclose & UDF_WRITE_VAT); 3751 #endif 3752 3753 if (ump->lvclose & UDF_WRITE_VAT) { 3754 DPRINTF(VOLUMES, ("lvclose & UDF_WRITE_VAT\n")); 3755 3756 /* write out the VAT data and all its descriptors */ 3757 DPRINTF(VOLUMES, ("writeout vat_node\n")); 3758 udf_writeout_vat(ump); 3759 vflushbuf(ump->vat_node->vnode, 1 /* sync */); 3760 3761 (void) VOP_FSYNC(ump->vat_node->vnode, 3762 FSCRED, FSYNC_WAIT, 0, 0); 3763 3764 if (ump->lvclose & UDF_CLOSE_SESSION) { 3765 DPRINTF(VOLUMES, ("udf_close_logvol: closing session " 3766 "as requested\n")); 3767 } 3768 3769 /* at least two DVD packets and 3 CD-R packets */ 3770 nvats = 32; 3771 3772 #if notyet 3773 /* 3774 * TODO calculate the available space and if the disc is 3775 * allmost full, write out till end-256-1 with banks, write 3776 * AVDP and fill up with VATs, then close session and close 3777 * disc. 3778 */ 3779 if (ump->lvclose & UDF_FINALISE_DISC) { 3780 error = udf_write_phys_dscr_sync(ump, NULL, 3781 UDF_C_FLOAT_DSCR, 3782 (union dscrptr *) ump->anchors[0], 3783 0, 0); 3784 if (error) 3785 printf("writeout of anchor failed!\n"); 3786 3787 /* pad space with VAT ICBs */ 3788 nvats = 256; 3789 } 3790 #endif 3791 3792 /* write out a number of VAT nodes */ 3793 nok = 0; 3794 for (n = 0; n < nvats; n++) { 3795 /* will now only write last FE/EFE */ 3796 ump->vat_node->i_flags |= IN_MODIFIED; 3797 error = VOP_FSYNC(ump->vat_node->vnode, 3798 FSCRED, FSYNC_WAIT, 0, 0); 3799 if (!error) 3800 nok++; 3801 } 3802 if (nok < 14) { 3803 /* arbitrary; but at least one or two CD frames */ 3804 printf("writeout of at least 14 VATs failed\n"); 3805 return error; 3806 } 3807 } 3808 3809 /* NOTE the disc is in a (minimal) valid state now; no erroring out */ 3810 3811 /* finish closing of session */ 3812 if (ump->lvclose & UDF_CLOSE_SESSION) { 3813 error = udf_validate_session_start(ump); 3814 if (error) 3815 return error; 3816 3817 (void) udf_synchronise_caches(ump); 3818 3819 /* close all associated tracks */ 3820 tracknr = ump->discinfo.first_track_last_session; 3821 error = 0; 3822 while (tracknr <= ump->discinfo.last_track_last_session) { 3823 DPRINTF(VOLUMES, ("\tclosing possible open " 3824 "track %d\n", tracknr)); 3825 memset(&mmc_op, 0, sizeof(mmc_op)); 3826 mmc_op.operation = MMC_OP_CLOSETRACK; 3827 mmc_op.mmc_profile = ump->discinfo.mmc_profile; 3828 mmc_op.tracknr = tracknr; 3829 error = VOP_IOCTL(devvp, MMCOP, &mmc_op, 3830 FKIOCTL, NOCRED); 3831 if (error) 3832 printf("udf_close_logvol: closing of " 3833 "track %d failed\n", tracknr); 3834 tracknr ++; 3835 } 3836 if (!error) { 3837 DPRINTF(VOLUMES, ("closing session\n")); 3838 memset(&mmc_op, 0, sizeof(mmc_op)); 3839 mmc_op.operation = MMC_OP_CLOSESESSION; 3840 mmc_op.mmc_profile = ump->discinfo.mmc_profile; 3841 mmc_op.sessionnr = ump->discinfo.num_sessions; 3842 error = VOP_IOCTL(devvp, MMCOP, &mmc_op, 3843 FKIOCTL, NOCRED); 3844 if (error) 3845 printf("udf_close_logvol: closing of session" 3846 "failed\n"); 3847 } 3848 if (!error) 3849 ump->lvopen |= UDF_OPEN_SESSION; 3850 if (error) { 3851 printf("udf_close_logvol: leaving disc as it is\n"); 3852 ump->lvclose &= ~UDF_FINALISE_DISC; 3853 } 3854 } 3855 3856 if (ump->lvclose & UDF_FINALISE_DISC) { 3857 memset(&mmc_op, 0, sizeof(mmc_op)); 3858 mmc_op.operation = MMC_OP_FINALISEDISC; 3859 mmc_op.mmc_profile = ump->discinfo.mmc_profile; 3860 mmc_op.sessionnr = ump->discinfo.num_sessions; 3861 error = VOP_IOCTL(devvp, MMCOP, &mmc_op, 3862 FKIOCTL, NOCRED); 3863 if (error) 3864 printf("udf_close_logvol: finalising disc" 3865 "failed\n"); 3866 } 3867 3868 /* write out partition bitmaps if requested */ 3869 if (ump->lvclose & UDF_WRITE_PART_BITMAPS) { 3870 /* sync writeout metadata spacetable if existing */ 3871 error1 = udf_write_metadata_partition_spacetable(ump, true); 3872 if (error1) 3873 printf( "udf_close_logvol: writeout of metadata space " 3874 "bitmap failed\n"); 3875 3876 /* sync writeout partition spacetables */ 3877 error2 = udf_write_physical_partition_spacetables(ump, true); 3878 if (error2) 3879 printf( "udf_close_logvol: writeout of space tables " 3880 "failed\n"); 3881 3882 if (error1 || error2) 3883 return (error1 | error2); 3884 3885 ump->lvclose &= ~UDF_WRITE_PART_BITMAPS; 3886 } 3887 3888 /* mark it closed */ 3889 ump->logvol_integrity->integrity_type = udf_rw32(UDF_INTEGRITY_CLOSED); 3890 3891 /* do we need to write out the logical volume integrity? */ 3892 if (ump->lvclose & UDF_WRITE_LVINT) 3893 error = udf_writeout_lvint(ump, ump->lvopen); 3894 if (error) { 3895 /* HELP now what? mark it open again for now */ 3896 ump->logvol_integrity->integrity_type = 3897 udf_rw32(UDF_INTEGRITY_OPEN); 3898 return error; 3899 } 3900 3901 (void) udf_synchronise_caches(ump); 3902 3903 return 0; 3904 } 3905 3906 /* --------------------------------------------------------------------- */ 3907 3908 /* 3909 * Genfs interfacing 3910 * 3911 * static const struct genfs_ops udf_genfsops = { 3912 * .gop_size = genfs_size, 3913 * size of transfers 3914 * .gop_alloc = udf_gop_alloc, 3915 * allocate len bytes at offset 3916 * .gop_write = genfs_gop_write, 3917 * putpages interface code 3918 * .gop_markupdate = udf_gop_markupdate, 3919 * set update/modify flags etc. 3920 * } 3921 */ 3922 3923 /* 3924 * Genfs interface. These four functions are the only ones defined though not 3925 * documented... great.... 3926 */ 3927 3928 /* 3929 * Called for allocating an extent of the file either by VOP_WRITE() or by 3930 * genfs filling up gaps. 3931 */ 3932 static int 3933 udf_gop_alloc(struct vnode *vp, off_t off, 3934 off_t len, int flags, kauth_cred_t cred) 3935 { 3936 struct udf_node *udf_node = VTOI(vp); 3937 struct udf_mount *ump = udf_node->ump; 3938 uint64_t lb_start, lb_end; 3939 uint32_t lb_size, num_lb; 3940 int udf_c_type, vpart_num, can_fail; 3941 int error; 3942 3943 DPRINTF(ALLOC, ("udf_gop_alloc called for offset %"PRIu64" for %"PRIu64" bytes, %s\n", 3944 off, len, flags? "SYNC":"NONE")); 3945 3946 /* 3947 * request the pages of our vnode and see how many pages will need to 3948 * be allocated and reserve that space 3949 */ 3950 lb_size = udf_rw32(udf_node->ump->logical_vol->lb_size); 3951 lb_start = off / lb_size; 3952 lb_end = (off + len + lb_size -1) / lb_size; 3953 num_lb = lb_end - lb_start; 3954 3955 udf_c_type = udf_get_c_type(udf_node); 3956 vpart_num = udf_get_record_vpart(ump, udf_c_type); 3957 3958 /* all requests can fail */ 3959 can_fail = true; 3960 3961 /* fid's (directories) can't fail */ 3962 if (udf_c_type == UDF_C_FIDS) 3963 can_fail = false; 3964 3965 /* system files can't fail */ 3966 if (vp->v_vflag & VV_SYSTEM) 3967 can_fail = false; 3968 3969 error = udf_reserve_space(ump, udf_node, udf_c_type, 3970 vpart_num, num_lb, can_fail); 3971 3972 DPRINTF(ALLOC, ("\tlb_start %"PRIu64", lb_end %"PRIu64", num_lb %d\n", 3973 lb_start, lb_end, num_lb)); 3974 3975 return error; 3976 } 3977 3978 3979 /* 3980 * callback from genfs to update our flags 3981 */ 3982 static void 3983 udf_gop_markupdate(struct vnode *vp, int flags) 3984 { 3985 struct udf_node *udf_node = VTOI(vp); 3986 u_long mask = 0; 3987 3988 if ((flags & GOP_UPDATE_ACCESSED) != 0) { 3989 mask = IN_ACCESS; 3990 } 3991 if ((flags & GOP_UPDATE_MODIFIED) != 0) { 3992 if (vp->v_type == VREG) { 3993 mask |= IN_CHANGE | IN_UPDATE; 3994 } else { 3995 mask |= IN_MODIFY; 3996 } 3997 } 3998 if (mask) { 3999 udf_node->i_flags |= mask; 4000 } 4001 } 4002 4003 4004 static const struct genfs_ops udf_genfsops = { 4005 .gop_size = genfs_size, 4006 .gop_alloc = udf_gop_alloc, 4007 .gop_write = genfs_gop_write_rwmap, 4008 .gop_markupdate = udf_gop_markupdate, 4009 }; 4010 4011 4012 /* --------------------------------------------------------------------- */ 4013 4014 int 4015 udf_write_terminator(struct udf_mount *ump, uint32_t sector) 4016 { 4017 union dscrptr *dscr; 4018 int error; 4019 4020 dscr = malloc(ump->discinfo.sector_size, M_TEMP, M_WAITOK|M_ZERO); 4021 udf_inittag(ump, &dscr->tag, TAGID_TERM, sector); 4022 4023 /* CRC length for an anchor is 512 - tag length; defined in Ecma 167 */ 4024 dscr->tag.desc_crc_len = udf_rw16(512-UDF_DESC_TAG_LENGTH); 4025 (void) udf_validate_tag_and_crc_sums(dscr); 4026 4027 error = udf_write_phys_dscr_sync(ump, NULL, UDF_C_DSCR, 4028 dscr, sector, sector); 4029 4030 free(dscr, M_TEMP); 4031 4032 return error; 4033 } 4034 4035 4036 /* --------------------------------------------------------------------- */ 4037 4038 /* UDF<->unix converters */ 4039 4040 /* --------------------------------------------------------------------- */ 4041 4042 static mode_t 4043 udf_perm_to_unix_mode(uint32_t perm) 4044 { 4045 mode_t mode; 4046 4047 mode = ((perm & UDF_FENTRY_PERM_USER_MASK) ); 4048 mode |= ((perm & UDF_FENTRY_PERM_GRP_MASK ) >> 2); 4049 mode |= ((perm & UDF_FENTRY_PERM_OWNER_MASK) >> 4); 4050 4051 return mode; 4052 } 4053 4054 /* --------------------------------------------------------------------- */ 4055 4056 static uint32_t 4057 unix_mode_to_udf_perm(mode_t mode) 4058 { 4059 uint32_t perm; 4060 4061 perm = ((mode & S_IRWXO) ); 4062 perm |= ((mode & S_IRWXG) << 2); 4063 perm |= ((mode & S_IRWXU) << 4); 4064 perm |= ((mode & S_IWOTH) << 3); 4065 perm |= ((mode & S_IWGRP) << 5); 4066 perm |= ((mode & S_IWUSR) << 7); 4067 4068 return perm; 4069 } 4070 4071 /* --------------------------------------------------------------------- */ 4072 4073 static uint32_t 4074 udf_icb_to_unix_filetype(uint32_t icbftype) 4075 { 4076 switch (icbftype) { 4077 case UDF_ICB_FILETYPE_DIRECTORY : 4078 case UDF_ICB_FILETYPE_STREAMDIR : 4079 return S_IFDIR; 4080 case UDF_ICB_FILETYPE_FIFO : 4081 return S_IFIFO; 4082 case UDF_ICB_FILETYPE_CHARDEVICE : 4083 return S_IFCHR; 4084 case UDF_ICB_FILETYPE_BLOCKDEVICE : 4085 return S_IFBLK; 4086 case UDF_ICB_FILETYPE_RANDOMACCESS : 4087 case UDF_ICB_FILETYPE_REALTIME : 4088 return S_IFREG; 4089 case UDF_ICB_FILETYPE_SYMLINK : 4090 return S_IFLNK; 4091 case UDF_ICB_FILETYPE_SOCKET : 4092 return S_IFSOCK; 4093 } 4094 /* no idea what this is */ 4095 return 0; 4096 } 4097 4098 /* --------------------------------------------------------------------- */ 4099 4100 void 4101 udf_to_unix_name(char *result, int result_len, char *id, int len, 4102 struct charspec *chsp) 4103 { 4104 uint16_t *raw_name, *unix_name; 4105 uint16_t *inchp, ch; 4106 uint8_t *outchp; 4107 const char *osta_id = "OSTA Compressed Unicode"; 4108 int ucode_chars, nice_uchars, is_osta_typ0, nout; 4109 4110 raw_name = malloc(2048 * sizeof(uint16_t), M_UDFTEMP, M_WAITOK); 4111 unix_name = raw_name + 1024; /* split space in half */ 4112 assert(sizeof(char) == sizeof(uint8_t)); 4113 outchp = (uint8_t *) result; 4114 4115 is_osta_typ0 = (chsp->type == 0); 4116 is_osta_typ0 &= (strcmp((char *) chsp->inf, osta_id) == 0); 4117 if (is_osta_typ0) { 4118 /* TODO clean up */ 4119 *raw_name = *unix_name = 0; 4120 ucode_chars = udf_UncompressUnicode(len, (uint8_t *) id, raw_name); 4121 ucode_chars = MIN(ucode_chars, UnicodeLength((unicode_t *) raw_name)); 4122 nice_uchars = UDFTransName(unix_name, raw_name, ucode_chars); 4123 /* output UTF8 */ 4124 for (inchp = unix_name; nice_uchars>0; inchp++, nice_uchars--) { 4125 ch = *inchp; 4126 nout = wput_utf8(outchp, result_len, ch); 4127 outchp += nout; result_len -= nout; 4128 if (!ch) break; 4129 } 4130 *outchp++ = 0; 4131 } else { 4132 /* assume 8bit char length byte latin-1 */ 4133 assert(*id == 8); 4134 assert(strlen((char *) (id+1)) <= MAXNAMLEN); 4135 strncpy((char *) result, (char *) (id+1), strlen((char *) (id+1))); 4136 } 4137 free(raw_name, M_UDFTEMP); 4138 } 4139 4140 /* --------------------------------------------------------------------- */ 4141 4142 void 4143 unix_to_udf_name(char *result, uint8_t *result_len, char const *name, int name_len, 4144 struct charspec *chsp) 4145 { 4146 uint16_t *raw_name; 4147 uint16_t *outchp; 4148 const char *inchp; 4149 const char *osta_id = "OSTA Compressed Unicode"; 4150 int udf_chars, is_osta_typ0, bits; 4151 size_t cnt; 4152 4153 /* allocate temporary unicode-16 buffer */ 4154 raw_name = malloc(1024, M_UDFTEMP, M_WAITOK); 4155 4156 /* convert utf8 to unicode-16 */ 4157 *raw_name = 0; 4158 inchp = name; 4159 outchp = raw_name; 4160 bits = 8; 4161 for (cnt = name_len, udf_chars = 0; cnt;) { 4162 /*###3490 [cc] warning: passing argument 2 of 'wget_utf8' from incompatible pointer type%%%*/ 4163 *outchp = wget_utf8(&inchp, &cnt); 4164 if (*outchp > 0xff) 4165 bits=16; 4166 outchp++; 4167 udf_chars++; 4168 } 4169 /* null terminate just in case */ 4170 *outchp++ = 0; 4171 4172 is_osta_typ0 = (chsp->type == 0); 4173 is_osta_typ0 &= (strcmp((char *) chsp->inf, osta_id) == 0); 4174 if (is_osta_typ0) { 4175 udf_chars = udf_CompressUnicode(udf_chars, bits, 4176 (unicode_t *) raw_name, 4177 (byte *) result); 4178 } else { 4179 printf("unix to udf name: no CHSP0 ?\n"); 4180 /* XXX assume 8bit char length byte latin-1 */ 4181 *result++ = 8; udf_chars = 1; 4182 strncpy(result, name + 1, name_len); 4183 udf_chars += name_len; 4184 } 4185 *result_len = udf_chars; 4186 free(raw_name, M_UDFTEMP); 4187 } 4188 4189 /* --------------------------------------------------------------------- */ 4190 4191 void 4192 udf_timestamp_to_timespec(struct udf_mount *ump, 4193 struct timestamp *timestamp, 4194 struct timespec *timespec) 4195 { 4196 struct clock_ymdhms ymdhms; 4197 uint32_t usecs, secs, nsecs; 4198 uint16_t tz; 4199 4200 /* fill in ymdhms structure from timestamp */ 4201 memset(&ymdhms, 0, sizeof(ymdhms)); 4202 ymdhms.dt_year = udf_rw16(timestamp->year); 4203 ymdhms.dt_mon = timestamp->month; 4204 ymdhms.dt_day = timestamp->day; 4205 ymdhms.dt_wday = 0; /* ? */ 4206 ymdhms.dt_hour = timestamp->hour; 4207 ymdhms.dt_min = timestamp->minute; 4208 ymdhms.dt_sec = timestamp->second; 4209 4210 secs = clock_ymdhms_to_secs(&ymdhms); 4211 usecs = timestamp->usec + 4212 100*timestamp->hund_usec + 10000*timestamp->centisec; 4213 nsecs = usecs * 1000; 4214 4215 /* 4216 * Calculate the time zone. The timezone is 12 bit signed 2's 4217 * compliment, so we gotta do some extra magic to handle it right. 4218 */ 4219 tz = udf_rw16(timestamp->type_tz); 4220 tz &= 0x0fff; /* only lower 12 bits are significant */ 4221 if (tz & 0x0800) /* sign extention */ 4222 tz |= 0xf000; 4223 4224 /* TODO check timezone conversion */ 4225 /* check if we are specified a timezone to convert */ 4226 if (udf_rw16(timestamp->type_tz) & 0x1000) { 4227 if ((int16_t) tz != -2047) 4228 secs -= (int16_t) tz * 60; 4229 } else { 4230 secs -= ump->mount_args.gmtoff; 4231 } 4232 4233 timespec->tv_sec = secs; 4234 timespec->tv_nsec = nsecs; 4235 } 4236 4237 4238 void 4239 udf_timespec_to_timestamp(struct timespec *timespec, struct timestamp *timestamp) 4240 { 4241 struct clock_ymdhms ymdhms; 4242 uint32_t husec, usec, csec; 4243 4244 (void) clock_secs_to_ymdhms(timespec->tv_sec, &ymdhms); 4245 4246 usec = timespec->tv_nsec / 1000; 4247 husec = usec / 100; 4248 usec -= husec * 100; /* only 0-99 in usec */ 4249 csec = husec / 100; /* only 0-99 in csec */ 4250 husec -= csec * 100; /* only 0-99 in husec */ 4251 4252 /* set method 1 for CUT/GMT */ 4253 timestamp->type_tz = udf_rw16((1<<12) + 0); 4254 timestamp->year = udf_rw16(ymdhms.dt_year); 4255 timestamp->month = ymdhms.dt_mon; 4256 timestamp->day = ymdhms.dt_day; 4257 timestamp->hour = ymdhms.dt_hour; 4258 timestamp->minute = ymdhms.dt_min; 4259 timestamp->second = ymdhms.dt_sec; 4260 timestamp->centisec = csec; 4261 timestamp->hund_usec = husec; 4262 timestamp->usec = usec; 4263 } 4264 4265 /* --------------------------------------------------------------------- */ 4266 4267 /* 4268 * Attribute and filetypes converters with get/set pairs 4269 */ 4270 4271 uint32_t 4272 udf_getaccessmode(struct udf_node *udf_node) 4273 { 4274 struct file_entry *fe = udf_node->fe; 4275 struct extfile_entry *efe = udf_node->efe; 4276 uint32_t udf_perm, icbftype; 4277 uint32_t mode, ftype; 4278 uint16_t icbflags; 4279 4280 UDF_LOCK_NODE(udf_node, 0); 4281 if (fe) { 4282 udf_perm = udf_rw32(fe->perm); 4283 icbftype = fe->icbtag.file_type; 4284 icbflags = udf_rw16(fe->icbtag.flags); 4285 } else { 4286 assert(udf_node->efe); 4287 udf_perm = udf_rw32(efe->perm); 4288 icbftype = efe->icbtag.file_type; 4289 icbflags = udf_rw16(efe->icbtag.flags); 4290 } 4291 4292 mode = udf_perm_to_unix_mode(udf_perm); 4293 ftype = udf_icb_to_unix_filetype(icbftype); 4294 4295 /* set suid, sgid, sticky from flags in fe/efe */ 4296 if (icbflags & UDF_ICB_TAG_FLAGS_SETUID) 4297 mode |= S_ISUID; 4298 if (icbflags & UDF_ICB_TAG_FLAGS_SETGID) 4299 mode |= S_ISGID; 4300 if (icbflags & UDF_ICB_TAG_FLAGS_STICKY) 4301 mode |= S_ISVTX; 4302 4303 UDF_UNLOCK_NODE(udf_node, 0); 4304 4305 return mode | ftype; 4306 } 4307 4308 4309 void 4310 udf_setaccessmode(struct udf_node *udf_node, mode_t mode) 4311 { 4312 struct file_entry *fe = udf_node->fe; 4313 struct extfile_entry *efe = udf_node->efe; 4314 uint32_t udf_perm; 4315 uint16_t icbflags; 4316 4317 UDF_LOCK_NODE(udf_node, 0); 4318 udf_perm = unix_mode_to_udf_perm(mode & ALLPERMS); 4319 if (fe) { 4320 icbflags = udf_rw16(fe->icbtag.flags); 4321 } else { 4322 icbflags = udf_rw16(efe->icbtag.flags); 4323 } 4324 4325 icbflags &= ~UDF_ICB_TAG_FLAGS_SETUID; 4326 icbflags &= ~UDF_ICB_TAG_FLAGS_SETGID; 4327 icbflags &= ~UDF_ICB_TAG_FLAGS_STICKY; 4328 if (mode & S_ISUID) 4329 icbflags |= UDF_ICB_TAG_FLAGS_SETUID; 4330 if (mode & S_ISGID) 4331 icbflags |= UDF_ICB_TAG_FLAGS_SETGID; 4332 if (mode & S_ISVTX) 4333 icbflags |= UDF_ICB_TAG_FLAGS_STICKY; 4334 4335 if (fe) { 4336 fe->perm = udf_rw32(udf_perm); 4337 fe->icbtag.flags = udf_rw16(icbflags); 4338 } else { 4339 efe->perm = udf_rw32(udf_perm); 4340 efe->icbtag.flags = udf_rw16(icbflags); 4341 } 4342 4343 UDF_UNLOCK_NODE(udf_node, 0); 4344 } 4345 4346 4347 void 4348 udf_getownership(struct udf_node *udf_node, uid_t *uidp, gid_t *gidp) 4349 { 4350 struct udf_mount *ump = udf_node->ump; 4351 struct file_entry *fe = udf_node->fe; 4352 struct extfile_entry *efe = udf_node->efe; 4353 uid_t uid; 4354 gid_t gid; 4355 4356 UDF_LOCK_NODE(udf_node, 0); 4357 if (fe) { 4358 uid = (uid_t)udf_rw32(fe->uid); 4359 gid = (gid_t)udf_rw32(fe->gid); 4360 } else { 4361 assert(udf_node->efe); 4362 uid = (uid_t)udf_rw32(efe->uid); 4363 gid = (gid_t)udf_rw32(efe->gid); 4364 } 4365 4366 /* do the uid/gid translation game */ 4367 if (uid == (uid_t) -1) 4368 uid = ump->mount_args.anon_uid; 4369 if (gid == (gid_t) -1) 4370 gid = ump->mount_args.anon_gid; 4371 4372 *uidp = uid; 4373 *gidp = gid; 4374 4375 UDF_UNLOCK_NODE(udf_node, 0); 4376 } 4377 4378 4379 void 4380 udf_setownership(struct udf_node *udf_node, uid_t uid, gid_t gid) 4381 { 4382 struct udf_mount *ump = udf_node->ump; 4383 struct file_entry *fe = udf_node->fe; 4384 struct extfile_entry *efe = udf_node->efe; 4385 uid_t nobody_uid; 4386 gid_t nobody_gid; 4387 4388 UDF_LOCK_NODE(udf_node, 0); 4389 4390 /* do the uid/gid translation game */ 4391 nobody_uid = ump->mount_args.nobody_uid; 4392 nobody_gid = ump->mount_args.nobody_gid; 4393 if (uid == nobody_uid) 4394 uid = (uid_t) -1; 4395 if (gid == nobody_gid) 4396 gid = (gid_t) -1; 4397 4398 if (fe) { 4399 fe->uid = udf_rw32((uint32_t) uid); 4400 fe->gid = udf_rw32((uint32_t) gid); 4401 } else { 4402 efe->uid = udf_rw32((uint32_t) uid); 4403 efe->gid = udf_rw32((uint32_t) gid); 4404 } 4405 4406 UDF_UNLOCK_NODE(udf_node, 0); 4407 } 4408 4409 4410 /* --------------------------------------------------------------------- */ 4411 4412 4413 static int 4414 dirhash_fill(struct udf_node *dir_node) 4415 { 4416 struct vnode *dvp = dir_node->vnode; 4417 struct dirhash *dirh; 4418 struct file_entry *fe = dir_node->fe; 4419 struct extfile_entry *efe = dir_node->efe; 4420 struct fileid_desc *fid; 4421 struct dirent *dirent; 4422 uint64_t file_size, pre_diroffset, diroffset; 4423 uint32_t lb_size; 4424 int error; 4425 4426 /* make sure we have a dirhash to work on */ 4427 dirh = dir_node->dir_hash; 4428 KASSERT(dirh); 4429 KASSERT(dirh->refcnt > 0); 4430 4431 if (dirh->flags & DIRH_BROKEN) 4432 return EIO; 4433 if (dirh->flags & DIRH_COMPLETE) 4434 return 0; 4435 4436 /* make sure we have a clean dirhash to add to */ 4437 dirhash_purge_entries(dirh); 4438 4439 /* get directory filesize */ 4440 if (fe) { 4441 file_size = udf_rw64(fe->inf_len); 4442 } else { 4443 assert(efe); 4444 file_size = udf_rw64(efe->inf_len); 4445 } 4446 4447 /* allocate temporary space for fid */ 4448 lb_size = udf_rw32(dir_node->ump->logical_vol->lb_size); 4449 fid = malloc(lb_size, M_UDFTEMP, M_WAITOK); 4450 4451 /* allocate temporary space for dirent */ 4452 dirent = malloc(sizeof(struct dirent), M_UDFTEMP, M_WAITOK); 4453 4454 error = 0; 4455 diroffset = 0; 4456 while (diroffset < file_size) { 4457 /* transfer a new fid/dirent */ 4458 pre_diroffset = diroffset; 4459 error = udf_read_fid_stream(dvp, &diroffset, fid, dirent); 4460 if (error) { 4461 /* TODO what to do? continue but not add? */ 4462 dirh->flags |= DIRH_BROKEN; 4463 dirhash_purge_entries(dirh); 4464 break; 4465 } 4466 4467 if ((fid->file_char & UDF_FILE_CHAR_DEL)) { 4468 /* register deleted extent for reuse */ 4469 dirhash_enter_freed(dirh, pre_diroffset, 4470 udf_fidsize(fid)); 4471 } else { 4472 /* append to the dirhash */ 4473 dirhash_enter(dirh, dirent, pre_diroffset, 4474 udf_fidsize(fid), 0); 4475 } 4476 } 4477 dirh->flags |= DIRH_COMPLETE; 4478 4479 free(fid, M_UDFTEMP); 4480 free(dirent, M_UDFTEMP); 4481 4482 return error; 4483 } 4484 4485 4486 /* --------------------------------------------------------------------- */ 4487 4488 /* 4489 * Directory read and manipulation functions. 4490 * 4491 */ 4492 4493 int 4494 udf_lookup_name_in_dir(struct vnode *vp, const char *name, int namelen, 4495 struct long_ad *icb_loc, int *found) 4496 { 4497 struct udf_node *dir_node = VTOI(vp); 4498 struct dirhash *dirh; 4499 struct dirhash_entry *dirh_ep; 4500 struct fileid_desc *fid; 4501 struct dirent *dirent; 4502 uint64_t diroffset; 4503 uint32_t lb_size; 4504 int hit, error; 4505 4506 /* set default return */ 4507 *found = 0; 4508 4509 /* get our dirhash and make sure its read in */ 4510 dirhash_get(&dir_node->dir_hash); 4511 error = dirhash_fill(dir_node); 4512 if (error) { 4513 dirhash_put(dir_node->dir_hash); 4514 return error; 4515 } 4516 dirh = dir_node->dir_hash; 4517 4518 /* allocate temporary space for fid */ 4519 lb_size = udf_rw32(dir_node->ump->logical_vol->lb_size); 4520 fid = malloc(lb_size, M_UDFTEMP, M_WAITOK); 4521 dirent = malloc(sizeof(struct dirent), M_UDFTEMP, M_WAITOK); 4522 4523 DPRINTF(DIRHASH, ("dirhash_lookup looking for `%*.*s`\n", 4524 namelen, namelen, name)); 4525 4526 /* search our dirhash hits */ 4527 memset(icb_loc, 0, sizeof(*icb_loc)); 4528 dirh_ep = NULL; 4529 for (;;) { 4530 hit = dirhash_lookup(dirh, name, namelen, &dirh_ep); 4531 /* if no hit, abort the search */ 4532 if (!hit) 4533 break; 4534 4535 /* check this hit */ 4536 diroffset = dirh_ep->offset; 4537 4538 /* transfer a new fid/dirent */ 4539 error = udf_read_fid_stream(vp, &diroffset, fid, dirent); 4540 if (error) 4541 break; 4542 4543 DPRINTF(DIRHASH, ("dirhash_lookup\tchecking `%*.*s`\n", 4544 dirent->d_namlen, dirent->d_namlen, dirent->d_name)); 4545 4546 /* see if its our entry */ 4547 KASSERT(dirent->d_namlen == namelen); 4548 if (strncmp(dirent->d_name, name, namelen) == 0) { 4549 *found = 1; 4550 *icb_loc = fid->icb; 4551 break; 4552 } 4553 } 4554 free(fid, M_UDFTEMP); 4555 free(dirent, M_UDFTEMP); 4556 4557 dirhash_put(dir_node->dir_hash); 4558 4559 return error; 4560 } 4561 4562 /* --------------------------------------------------------------------- */ 4563 4564 static int 4565 udf_create_new_fe(struct udf_mount *ump, struct file_entry *fe, int file_type, 4566 struct long_ad *node_icb, struct long_ad *parent_icb, 4567 uint64_t parent_unique_id) 4568 { 4569 struct timespec now; 4570 struct icb_tag *icb; 4571 struct filetimes_extattr_entry *ft_extattr; 4572 uint64_t unique_id; 4573 uint32_t fidsize, lb_num; 4574 uint8_t *bpos; 4575 int crclen, attrlen; 4576 4577 lb_num = udf_rw32(node_icb->loc.lb_num); 4578 udf_inittag(ump, &fe->tag, TAGID_FENTRY, lb_num); 4579 icb = &fe->icbtag; 4580 4581 /* 4582 * Always use strategy type 4 unless on WORM wich we don't support 4583 * (yet). Fill in defaults and set for internal allocation of data. 4584 */ 4585 icb->strat_type = udf_rw16(4); 4586 icb->max_num_entries = udf_rw16(1); 4587 icb->file_type = file_type; /* 8 bit */ 4588 icb->flags = udf_rw16(UDF_ICB_INTERN_ALLOC); 4589 4590 fe->perm = udf_rw32(0x7fff); /* all is allowed */ 4591 fe->link_cnt = udf_rw16(0); /* explicit setting */ 4592 4593 fe->ckpoint = udf_rw32(1); /* user supplied file version */ 4594 4595 vfs_timestamp(&now); 4596 udf_timespec_to_timestamp(&now, &fe->atime); 4597 udf_timespec_to_timestamp(&now, &fe->attrtime); 4598 udf_timespec_to_timestamp(&now, &fe->mtime); 4599 4600 udf_set_regid(&fe->imp_id, IMPL_NAME); 4601 udf_add_impl_regid(ump, &fe->imp_id); 4602 4603 unique_id = udf_advance_uniqueid(ump); 4604 fe->unique_id = udf_rw64(unique_id); 4605 fe->l_ea = udf_rw32(0); 4606 4607 /* create extended attribute to record our creation time */ 4608 attrlen = UDF_FILETIMES_ATTR_SIZE(1); 4609 ft_extattr = malloc(attrlen, M_UDFTEMP, M_WAITOK); 4610 memset(ft_extattr, 0, attrlen); 4611 ft_extattr->hdr.type = udf_rw32(UDF_FILETIMES_ATTR_NO); 4612 ft_extattr->hdr.subtype = 1; /* [4/48.10.5] */ 4613 ft_extattr->hdr.a_l = udf_rw32(UDF_FILETIMES_ATTR_SIZE(1)); 4614 ft_extattr->d_l = udf_rw32(UDF_TIMESTAMP_SIZE); /* one item */ 4615 ft_extattr->existence = UDF_FILETIMES_FILE_CREATION; 4616 udf_timespec_to_timestamp(&now, &ft_extattr->times[0]); 4617 4618 udf_extattr_insert_internal(ump, (union dscrptr *) fe, 4619 (struct extattr_entry *) ft_extattr); 4620 free(ft_extattr, M_UDFTEMP); 4621 4622 /* if its a directory, create '..' */ 4623 bpos = (uint8_t *) fe->data + udf_rw32(fe->l_ea); 4624 fidsize = 0; 4625 if (file_type == UDF_ICB_FILETYPE_DIRECTORY) { 4626 fidsize = udf_create_parentfid(ump, 4627 (struct fileid_desc *) bpos, parent_icb, 4628 parent_unique_id); 4629 } 4630 4631 /* record fidlength information */ 4632 fe->inf_len = udf_rw64(fidsize); 4633 fe->l_ad = udf_rw32(fidsize); 4634 fe->logblks_rec = udf_rw64(0); /* intern */ 4635 4636 crclen = sizeof(struct file_entry) - 1 - UDF_DESC_TAG_LENGTH; 4637 crclen += udf_rw32(fe->l_ea) + fidsize; 4638 fe->tag.desc_crc_len = udf_rw16(crclen); 4639 4640 (void) udf_validate_tag_and_crc_sums((union dscrptr *) fe); 4641 4642 return fidsize; 4643 } 4644 4645 /* --------------------------------------------------------------------- */ 4646 4647 static int 4648 udf_create_new_efe(struct udf_mount *ump, struct extfile_entry *efe, 4649 int file_type, struct long_ad *node_icb, struct long_ad *parent_icb, 4650 uint64_t parent_unique_id) 4651 { 4652 struct timespec now; 4653 struct icb_tag *icb; 4654 uint64_t unique_id; 4655 uint32_t fidsize, lb_num; 4656 uint8_t *bpos; 4657 int crclen; 4658 4659 lb_num = udf_rw32(node_icb->loc.lb_num); 4660 udf_inittag(ump, &efe->tag, TAGID_EXTFENTRY, lb_num); 4661 icb = &efe->icbtag; 4662 4663 /* 4664 * Always use strategy type 4 unless on WORM wich we don't support 4665 * (yet). Fill in defaults and set for internal allocation of data. 4666 */ 4667 icb->strat_type = udf_rw16(4); 4668 icb->max_num_entries = udf_rw16(1); 4669 icb->file_type = file_type; /* 8 bit */ 4670 icb->flags = udf_rw16(UDF_ICB_INTERN_ALLOC); 4671 4672 efe->perm = udf_rw32(0x7fff); /* all is allowed */ 4673 efe->link_cnt = udf_rw16(0); /* explicit setting */ 4674 4675 efe->ckpoint = udf_rw32(1); /* user supplied file version */ 4676 4677 vfs_timestamp(&now); 4678 udf_timespec_to_timestamp(&now, &efe->ctime); 4679 udf_timespec_to_timestamp(&now, &efe->atime); 4680 udf_timespec_to_timestamp(&now, &efe->attrtime); 4681 udf_timespec_to_timestamp(&now, &efe->mtime); 4682 4683 udf_set_regid(&efe->imp_id, IMPL_NAME); 4684 udf_add_impl_regid(ump, &efe->imp_id); 4685 4686 unique_id = udf_advance_uniqueid(ump); 4687 efe->unique_id = udf_rw64(unique_id); 4688 efe->l_ea = udf_rw32(0); 4689 4690 /* if its a directory, create '..' */ 4691 bpos = (uint8_t *) efe->data + udf_rw32(efe->l_ea); 4692 fidsize = 0; 4693 if (file_type == UDF_ICB_FILETYPE_DIRECTORY) { 4694 fidsize = udf_create_parentfid(ump, 4695 (struct fileid_desc *) bpos, parent_icb, 4696 parent_unique_id); 4697 } 4698 4699 /* record fidlength information */ 4700 efe->obj_size = udf_rw64(fidsize); 4701 efe->inf_len = udf_rw64(fidsize); 4702 efe->l_ad = udf_rw32(fidsize); 4703 efe->logblks_rec = udf_rw64(0); /* intern */ 4704 4705 crclen = sizeof(struct extfile_entry) - 1 - UDF_DESC_TAG_LENGTH; 4706 crclen += udf_rw32(efe->l_ea) + fidsize; 4707 efe->tag.desc_crc_len = udf_rw16(crclen); 4708 4709 (void) udf_validate_tag_and_crc_sums((union dscrptr *) efe); 4710 4711 return fidsize; 4712 } 4713 4714 /* --------------------------------------------------------------------- */ 4715 4716 int 4717 udf_dir_detach(struct udf_mount *ump, struct udf_node *dir_node, 4718 struct udf_node *udf_node, struct componentname *cnp) 4719 { 4720 struct vnode *dvp = dir_node->vnode; 4721 struct dirhash *dirh; 4722 struct dirhash_entry *dirh_ep; 4723 struct file_entry *fe = dir_node->fe; 4724 struct extfile_entry *efe = dir_node->efe; 4725 struct fileid_desc *fid; 4726 struct dirent *dirent; 4727 uint64_t file_size, diroffset; 4728 uint32_t lb_size, fidsize; 4729 int found, error; 4730 char const *name = cnp->cn_nameptr; 4731 int namelen = cnp->cn_namelen; 4732 int hit, refcnt; 4733 4734 /* get our dirhash and make sure its read in */ 4735 dirhash_get(&dir_node->dir_hash); 4736 error = dirhash_fill(dir_node); 4737 if (error) { 4738 dirhash_put(dir_node->dir_hash); 4739 return error; 4740 } 4741 dirh = dir_node->dir_hash; 4742 4743 /* get directory filesize */ 4744 if (fe) { 4745 file_size = udf_rw64(fe->inf_len); 4746 } else { 4747 assert(efe); 4748 file_size = udf_rw64(efe->inf_len); 4749 } 4750 4751 /* allocate temporary space for fid */ 4752 lb_size = udf_rw32(dir_node->ump->logical_vol->lb_size); 4753 fid = malloc(lb_size, M_UDFTEMP, M_WAITOK); 4754 dirent = malloc(sizeof(struct dirent), M_UDFTEMP, M_WAITOK); 4755 4756 /* search our dirhash hits */ 4757 found = 0; 4758 dirh_ep = NULL; 4759 for (;;) { 4760 hit = dirhash_lookup(dirh, name, namelen, &dirh_ep); 4761 /* if no hit, abort the search */ 4762 if (!hit) 4763 break; 4764 4765 /* check this hit */ 4766 diroffset = dirh_ep->offset; 4767 4768 /* transfer a new fid/dirent */ 4769 error = udf_read_fid_stream(dvp, &diroffset, fid, dirent); 4770 if (error) 4771 break; 4772 4773 /* see if its our entry */ 4774 KASSERT(dirent->d_namlen == namelen); 4775 if (strncmp(dirent->d_name, name, namelen) == 0) { 4776 found = 1; 4777 break; 4778 } 4779 } 4780 4781 if (!found) 4782 error = ENOENT; 4783 if (error) 4784 goto error_out; 4785 4786 /* mark deleted */ 4787 fid->file_char |= UDF_FILE_CHAR_DEL; 4788 #ifdef UDF_COMPLETE_DELETE 4789 memset(&fid->icb, 0, sizeof(fid->icb)); 4790 #endif 4791 (void) udf_validate_tag_and_crc_sums((union dscrptr *) fid); 4792 4793 /* get size of fid and compensate for the read_fid_stream advance */ 4794 fidsize = udf_fidsize(fid); 4795 diroffset -= fidsize; 4796 4797 /* write out */ 4798 error = vn_rdwr(UIO_WRITE, dir_node->vnode, 4799 fid, fidsize, diroffset, 4800 UIO_SYSSPACE, IO_ALTSEMANTICS | IO_NODELOCKED, 4801 FSCRED, NULL, NULL); 4802 if (error) 4803 goto error_out; 4804 4805 /* get reference count of attached node */ 4806 if (udf_node->fe) { 4807 refcnt = udf_rw16(udf_node->fe->link_cnt); 4808 } else { 4809 KASSERT(udf_node->efe); 4810 refcnt = udf_rw16(udf_node->efe->link_cnt); 4811 } 4812 #ifdef UDF_COMPLETE_DELETE 4813 /* substract reference counter in attached node */ 4814 refcnt -= 1; 4815 if (udf_node->fe) { 4816 udf_node->fe->link_cnt = udf_rw16(refcnt); 4817 } else { 4818 udf_node->efe->link_cnt = udf_rw16(refcnt); 4819 } 4820 4821 /* prevent writeout when refcnt == 0 */ 4822 if (refcnt == 0) 4823 udf_node->i_flags |= IN_DELETED; 4824 4825 if (fid->file_char & UDF_FILE_CHAR_DIR) { 4826 int drefcnt; 4827 4828 /* substract reference counter in directory node */ 4829 /* note subtract 2 (?) for its was also backreferenced */ 4830 if (dir_node->fe) { 4831 drefcnt = udf_rw16(dir_node->fe->link_cnt); 4832 drefcnt -= 1; 4833 dir_node->fe->link_cnt = udf_rw16(drefcnt); 4834 } else { 4835 KASSERT(dir_node->efe); 4836 drefcnt = udf_rw16(dir_node->efe->link_cnt); 4837 drefcnt -= 1; 4838 dir_node->efe->link_cnt = udf_rw16(drefcnt); 4839 } 4840 } 4841 4842 udf_node->i_flags |= IN_MODIFIED; 4843 dir_node->i_flags |= IN_MODIFIED; 4844 #endif 4845 /* if it is/was a hardlink adjust the file count */ 4846 if (refcnt > 0) 4847 udf_adjust_filecount(udf_node, -1); 4848 4849 /* remove from the dirhash */ 4850 dirhash_remove(dirh, dirent, diroffset, 4851 udf_fidsize(fid)); 4852 4853 error_out: 4854 free(fid, M_UDFTEMP); 4855 free(dirent, M_UDFTEMP); 4856 4857 dirhash_put(dir_node->dir_hash); 4858 4859 return error; 4860 } 4861 4862 /* --------------------------------------------------------------------- */ 4863 4864 int 4865 udf_dir_update_rootentry(struct udf_mount *ump, struct udf_node *dir_node, 4866 struct udf_node *new_parent_node) 4867 { 4868 struct vnode *dvp = dir_node->vnode; 4869 struct dirhash *dirh; 4870 struct dirhash_entry *dirh_ep; 4871 struct file_entry *fe; 4872 struct extfile_entry *efe; 4873 struct fileid_desc *fid; 4874 struct dirent *dirent; 4875 uint64_t file_size, diroffset; 4876 uint64_t new_parent_unique_id; 4877 uint32_t lb_size, fidsize; 4878 int found, error; 4879 char const *name = ".."; 4880 int namelen = 2; 4881 int hit; 4882 4883 /* get our dirhash and make sure its read in */ 4884 dirhash_get(&dir_node->dir_hash); 4885 error = dirhash_fill(dir_node); 4886 if (error) { 4887 dirhash_put(dir_node->dir_hash); 4888 return error; 4889 } 4890 dirh = dir_node->dir_hash; 4891 4892 /* get new parent's unique ID */ 4893 fe = new_parent_node->fe; 4894 efe = new_parent_node->efe; 4895 if (fe) { 4896 new_parent_unique_id = udf_rw64(fe->unique_id); 4897 } else { 4898 assert(efe); 4899 new_parent_unique_id = udf_rw64(efe->unique_id); 4900 } 4901 4902 /* get directory filesize */ 4903 fe = dir_node->fe; 4904 efe = dir_node->efe; 4905 if (fe) { 4906 file_size = udf_rw64(fe->inf_len); 4907 } else { 4908 assert(efe); 4909 file_size = udf_rw64(efe->inf_len); 4910 } 4911 4912 /* allocate temporary space for fid */ 4913 lb_size = udf_rw32(dir_node->ump->logical_vol->lb_size); 4914 fid = malloc(lb_size, M_UDFTEMP, M_WAITOK); 4915 dirent = malloc(sizeof(struct dirent), M_UDFTEMP, M_WAITOK); 4916 4917 /* 4918 * NOTE the standard does not dictate the FID entry '..' should be 4919 * first, though in practice it will most likely be. 4920 */ 4921 4922 /* search our dirhash hits */ 4923 found = 0; 4924 dirh_ep = NULL; 4925 for (;;) { 4926 hit = dirhash_lookup(dirh, name, namelen, &dirh_ep); 4927 /* if no hit, abort the search */ 4928 if (!hit) 4929 break; 4930 4931 /* check this hit */ 4932 diroffset = dirh_ep->offset; 4933 4934 /* transfer a new fid/dirent */ 4935 error = udf_read_fid_stream(dvp, &diroffset, fid, dirent); 4936 if (error) 4937 break; 4938 4939 /* see if its our entry */ 4940 KASSERT(dirent->d_namlen == namelen); 4941 if (strncmp(dirent->d_name, name, namelen) == 0) { 4942 found = 1; 4943 break; 4944 } 4945 } 4946 4947 if (!found) 4948 error = ENOENT; 4949 if (error) 4950 goto error_out; 4951 4952 /* update our ICB to the new parent, hit of lower 32 bits of uniqueid */ 4953 fid->icb = new_parent_node->write_loc; 4954 fid->icb.longad_uniqueid = udf_rw32(new_parent_unique_id); 4955 4956 (void) udf_validate_tag_and_crc_sums((union dscrptr *) fid); 4957 4958 /* get size of fid and compensate for the read_fid_stream advance */ 4959 fidsize = udf_fidsize(fid); 4960 diroffset -= fidsize; 4961 4962 /* write out */ 4963 error = vn_rdwr(UIO_WRITE, dir_node->vnode, 4964 fid, fidsize, diroffset, 4965 UIO_SYSSPACE, IO_ALTSEMANTICS | IO_NODELOCKED, 4966 FSCRED, NULL, NULL); 4967 4968 /* nothing to be done in the dirhash */ 4969 4970 error_out: 4971 free(fid, M_UDFTEMP); 4972 free(dirent, M_UDFTEMP); 4973 4974 dirhash_put(dir_node->dir_hash); 4975 4976 return error; 4977 } 4978 4979 /* --------------------------------------------------------------------- */ 4980 4981 /* 4982 * We are not allowed to split the fid tag itself over an logical block so 4983 * check the space remaining in the logical block. 4984 * 4985 * We try to select the smallest candidate for recycling or when none is 4986 * found, append a new one at the end of the directory. 4987 */ 4988 4989 int 4990 udf_dir_attach(struct udf_mount *ump, struct udf_node *dir_node, 4991 struct udf_node *udf_node, struct vattr *vap, struct componentname *cnp) 4992 { 4993 struct vnode *dvp = dir_node->vnode; 4994 struct dirhash *dirh; 4995 struct dirhash_entry *dirh_ep; 4996 struct fileid_desc *fid; 4997 struct icb_tag *icbtag; 4998 struct charspec osta_charspec; 4999 struct dirent dirent; 5000 uint64_t unique_id, dir_size; 5001 uint64_t fid_pos, end_fid_pos, chosen_fid_pos; 5002 uint32_t chosen_size, chosen_size_diff; 5003 int lb_size, lb_rest, fidsize, this_fidsize, size_diff; 5004 int file_char, refcnt, icbflags, addr_type, hit, error; 5005 5006 /* get our dirhash and make sure its read in */ 5007 dirhash_get(&dir_node->dir_hash); 5008 error = dirhash_fill(dir_node); 5009 if (error) { 5010 dirhash_put(dir_node->dir_hash); 5011 return error; 5012 } 5013 dirh = dir_node->dir_hash; 5014 5015 /* get info */ 5016 lb_size = udf_rw32(ump->logical_vol->lb_size); 5017 udf_osta_charset(&osta_charspec); 5018 5019 if (dir_node->fe) { 5020 dir_size = udf_rw64(dir_node->fe->inf_len); 5021 icbtag = &dir_node->fe->icbtag; 5022 } else { 5023 dir_size = udf_rw64(dir_node->efe->inf_len); 5024 icbtag = &dir_node->efe->icbtag; 5025 } 5026 5027 icbflags = udf_rw16(icbtag->flags); 5028 addr_type = icbflags & UDF_ICB_TAG_FLAGS_ALLOC_MASK; 5029 5030 if (udf_node->fe) { 5031 unique_id = udf_rw64(udf_node->fe->unique_id); 5032 refcnt = udf_rw16(udf_node->fe->link_cnt); 5033 } else { 5034 unique_id = udf_rw64(udf_node->efe->unique_id); 5035 refcnt = udf_rw16(udf_node->efe->link_cnt); 5036 } 5037 5038 if (refcnt > 0) { 5039 unique_id = udf_advance_uniqueid(ump); 5040 udf_adjust_filecount(udf_node, 1); 5041 } 5042 5043 /* determine file characteristics */ 5044 file_char = 0; /* visible non deleted file and not stream metadata */ 5045 if (vap->va_type == VDIR) 5046 file_char = UDF_FILE_CHAR_DIR; 5047 5048 /* malloc scrap buffer */ 5049 fid = malloc(lb_size, M_TEMP, M_WAITOK|M_ZERO); 5050 5051 /* calculate _minimum_ fid size */ 5052 unix_to_udf_name((char *) fid->data, &fid->l_fi, 5053 cnp->cn_nameptr, cnp->cn_namelen, &osta_charspec); 5054 fidsize = UDF_FID_SIZE + fid->l_fi; 5055 fidsize = (fidsize + 3) & ~3; /* multiple of 4 */ 5056 5057 /* find position that will fit the FID */ 5058 chosen_fid_pos = dir_size; 5059 chosen_size = 0; 5060 chosen_size_diff = UINT_MAX; 5061 5062 /* shut up gcc */ 5063 dirent.d_namlen = 0; 5064 5065 /* search our dirhash hits */ 5066 error = 0; 5067 dirh_ep = NULL; 5068 for (;;) { 5069 hit = dirhash_lookup_freed(dirh, fidsize, &dirh_ep); 5070 /* if no hit, abort the search */ 5071 if (!hit) 5072 break; 5073 5074 /* check this hit for size */ 5075 this_fidsize = dirh_ep->entry_size; 5076 5077 /* check this hit */ 5078 fid_pos = dirh_ep->offset; 5079 end_fid_pos = fid_pos + this_fidsize; 5080 size_diff = this_fidsize - fidsize; 5081 lb_rest = lb_size - (end_fid_pos % lb_size); 5082 5083 #ifndef UDF_COMPLETE_DELETE 5084 /* transfer a new fid/dirent */ 5085 error = udf_read_fid_stream(vp, &fid_pos, fid, dirent); 5086 if (error) 5087 goto error_out; 5088 5089 /* only reuse entries that are wiped */ 5090 /* check if the len + loc are marked zero */ 5091 if (udf_rw32(fid->icb.len) != 0) 5092 continue; 5093 if (udf_rw32(fid->icb.loc.lb_num) != 0) 5094 continue; 5095 if (udf_rw16(fid->icb.loc.part_num) != 0) 5096 continue; 5097 #endif /* UDF_COMPLETE_DELETE */ 5098 5099 /* select if not splitting the tag and its smaller */ 5100 if ((size_diff >= 0) && 5101 (size_diff < chosen_size_diff) && 5102 (lb_rest >= sizeof(struct desc_tag))) 5103 { 5104 /* UDF 2.3.4.2+3 specifies rules for iu size */ 5105 if ((size_diff == 0) || (size_diff >= 32)) { 5106 chosen_fid_pos = fid_pos; 5107 chosen_size = this_fidsize; 5108 chosen_size_diff = size_diff; 5109 } 5110 } 5111 } 5112 5113 5114 /* extend directory if no other candidate found */ 5115 if (chosen_size == 0) { 5116 chosen_fid_pos = dir_size; 5117 chosen_size = fidsize; 5118 chosen_size_diff = 0; 5119 5120 /* special case UDF 2.00+ 2.3.4.4, no splitting up fid tag */ 5121 if (addr_type == UDF_ICB_INTERN_ALLOC) { 5122 /* pre-grow directory to see if we're to switch */ 5123 udf_grow_node(dir_node, dir_size + chosen_size); 5124 5125 icbflags = udf_rw16(icbtag->flags); 5126 addr_type = icbflags & UDF_ICB_TAG_FLAGS_ALLOC_MASK; 5127 } 5128 5129 /* make sure the next fid desc_tag won't be splitted */ 5130 if (addr_type != UDF_ICB_INTERN_ALLOC) { 5131 end_fid_pos = chosen_fid_pos + chosen_size; 5132 lb_rest = lb_size - (end_fid_pos % lb_size); 5133 5134 /* pad with implementation use regid if needed */ 5135 if (lb_rest < sizeof(struct desc_tag)) 5136 chosen_size += 32; 5137 } 5138 } 5139 chosen_size_diff = chosen_size - fidsize; 5140 5141 /* populate the FID */ 5142 memset(fid, 0, lb_size); 5143 udf_inittag(ump, &fid->tag, TAGID_FID, 0); 5144 fid->file_version_num = udf_rw16(1); /* UDF 2.3.4.1 */ 5145 fid->file_char = file_char; 5146 fid->icb = udf_node->loc; 5147 fid->icb.longad_uniqueid = udf_rw32((uint32_t) unique_id); 5148 fid->l_iu = udf_rw16(0); 5149 5150 if (chosen_size > fidsize) { 5151 /* insert implementation-use regid to space it correctly */ 5152 fid->l_iu = udf_rw16(chosen_size_diff); 5153 5154 /* set implementation use */ 5155 udf_set_regid((struct regid *) fid->data, IMPL_NAME); 5156 udf_add_impl_regid(ump, (struct regid *) fid->data); 5157 } 5158 5159 /* fill in name */ 5160 unix_to_udf_name((char *) fid->data + udf_rw16(fid->l_iu), 5161 &fid->l_fi, cnp->cn_nameptr, cnp->cn_namelen, &osta_charspec); 5162 5163 fid->tag.desc_crc_len = udf_rw16(chosen_size - UDF_DESC_TAG_LENGTH); 5164 (void) udf_validate_tag_and_crc_sums((union dscrptr *) fid); 5165 5166 /* writeout FID/update parent directory */ 5167 error = vn_rdwr(UIO_WRITE, dvp, 5168 fid, chosen_size, chosen_fid_pos, 5169 UIO_SYSSPACE, IO_ALTSEMANTICS | IO_NODELOCKED, 5170 FSCRED, NULL, NULL); 5171 5172 if (error) 5173 goto error_out; 5174 5175 /* add reference counter in attached node */ 5176 if (udf_node->fe) { 5177 refcnt = udf_rw16(udf_node->fe->link_cnt); 5178 udf_node->fe->link_cnt = udf_rw16(refcnt+1); 5179 } else { 5180 KASSERT(udf_node->efe); 5181 refcnt = udf_rw16(udf_node->efe->link_cnt); 5182 udf_node->efe->link_cnt = udf_rw16(refcnt+1); 5183 } 5184 5185 /* mark not deleted if it was... just in case, but do warn */ 5186 if (udf_node->i_flags & IN_DELETED) { 5187 printf("udf: warning, marking a file undeleted\n"); 5188 udf_node->i_flags &= ~IN_DELETED; 5189 } 5190 5191 if (file_char & UDF_FILE_CHAR_DIR) { 5192 /* add reference counter in directory node for '..' */ 5193 if (dir_node->fe) { 5194 refcnt = udf_rw16(dir_node->fe->link_cnt); 5195 refcnt++; 5196 dir_node->fe->link_cnt = udf_rw16(refcnt); 5197 } else { 5198 KASSERT(dir_node->efe); 5199 refcnt = udf_rw16(dir_node->efe->link_cnt); 5200 refcnt++; 5201 dir_node->efe->link_cnt = udf_rw16(refcnt); 5202 } 5203 } 5204 5205 /* append to the dirhash */ 5206 dirent.d_namlen = cnp->cn_namelen; 5207 memcpy(dirent.d_name, cnp->cn_nameptr, cnp->cn_namelen); 5208 dirhash_enter(dirh, &dirent, chosen_fid_pos, 5209 udf_fidsize(fid), 1); 5210 5211 /* note updates */ 5212 udf_node->i_flags |= IN_CHANGE | IN_MODIFY; /* | IN_CREATE? */ 5213 /* VN_KNOTE(udf_node, ...) */ 5214 udf_update(udf_node->vnode, NULL, NULL, NULL, 0); 5215 5216 error_out: 5217 free(fid, M_TEMP); 5218 5219 dirhash_put(dir_node->dir_hash); 5220 5221 return error; 5222 } 5223 5224 /* --------------------------------------------------------------------- */ 5225 5226 /* 5227 * Each node can have an attached streamdir node though not recursively. These 5228 * are otherwise known as named substreams/named extended attributes that have 5229 * no size limitations. 5230 * 5231 * `Normal' extended attributes are indicated with a number and are recorded 5232 * in either the fe/efe descriptor itself for small descriptors or recorded in 5233 * the attached extended attribute file. Since these spaces can get 5234 * fragmented, care ought to be taken. 5235 * 5236 * Since the size of the space reserved for allocation descriptors is limited, 5237 * there is a mechanim provided for extending this space; this is done by a 5238 * special extent to allow schrinking of the allocations without breaking the 5239 * linkage to the allocation extent descriptor. 5240 */ 5241 5242 int 5243 udf_get_node(struct udf_mount *ump, struct long_ad *node_icb_loc, 5244 struct udf_node **udf_noderes) 5245 { 5246 union dscrptr *dscr; 5247 struct udf_node *udf_node; 5248 struct vnode *nvp; 5249 struct long_ad icb_loc, last_fe_icb_loc; 5250 uint64_t file_size; 5251 uint32_t lb_size, sector, dummy; 5252 uint8_t *file_data; 5253 int udf_file_type, dscr_type, strat, strat4096, needs_indirect; 5254 int slot, eof, error; 5255 5256 DPRINTF(NODE, ("udf_get_node called\n")); 5257 *udf_noderes = udf_node = NULL; 5258 5259 /* lock to disallow simultanious creation of same udf_node */ 5260 mutex_enter(&ump->get_node_lock); 5261 5262 DPRINTF(NODE, ("\tlookup in hash table\n")); 5263 /* lookup in hash table */ 5264 assert(ump); 5265 assert(node_icb_loc); 5266 udf_node = udf_node_lookup(ump, node_icb_loc); 5267 if (udf_node) { 5268 DPRINTF(NODE, ("\tgot it from the hash!\n")); 5269 /* vnode is returned locked */ 5270 *udf_noderes = udf_node; 5271 mutex_exit(&ump->get_node_lock); 5272 return 0; 5273 } 5274 5275 /* garbage check: translate udf_node_icb_loc to sectornr */ 5276 error = udf_translate_vtop(ump, node_icb_loc, §or, &dummy); 5277 if (error) { 5278 /* no use, this will fail anyway */ 5279 mutex_exit(&ump->get_node_lock); 5280 return EINVAL; 5281 } 5282 5283 /* build udf_node (do initialise!) */ 5284 udf_node = pool_get(&udf_node_pool, PR_WAITOK); 5285 memset(udf_node, 0, sizeof(struct udf_node)); 5286 5287 DPRINTF(NODE, ("\tget new vnode\n")); 5288 /* give it a vnode */ 5289 error = getnewvnode(VT_UDF, ump->vfs_mountp, udf_vnodeop_p, &nvp); 5290 if (error) { 5291 pool_put(&udf_node_pool, udf_node); 5292 mutex_exit(&ump->get_node_lock); 5293 return error; 5294 } 5295 5296 /* always return locked vnode */ 5297 if ((error = vn_lock(nvp, LK_EXCLUSIVE | LK_RETRY))) { 5298 /* recycle vnode and unlock; simultanious will fail too */ 5299 ungetnewvnode(nvp); 5300 mutex_exit(&ump->get_node_lock); 5301 return error; 5302 } 5303 5304 /* initialise crosslinks, note location of fe/efe for hashing */ 5305 udf_node->ump = ump; 5306 udf_node->vnode = nvp; 5307 nvp->v_data = udf_node; 5308 udf_node->loc = *node_icb_loc; 5309 udf_node->lockf = 0; 5310 mutex_init(&udf_node->node_mutex, MUTEX_DEFAULT, IPL_NONE); 5311 cv_init(&udf_node->node_lock, "udf_nlk"); 5312 genfs_node_init(nvp, &udf_genfsops); /* inititise genfs */ 5313 udf_node->outstanding_bufs = 0; 5314 udf_node->outstanding_nodedscr = 0; 5315 udf_node->uncommitted_lbs = 0; 5316 5317 /* check if we're fetching the root */ 5318 if (ump->fileset_desc) 5319 if (memcmp(&udf_node->loc, &ump->fileset_desc->rootdir_icb, 5320 sizeof(struct long_ad)) == 0) 5321 nvp->v_vflag |= VV_ROOT; 5322 5323 /* insert into the hash lookup */ 5324 udf_register_node(udf_node); 5325 5326 /* safe to unlock, the entry is in the hash table, vnode is locked */ 5327 mutex_exit(&ump->get_node_lock); 5328 5329 icb_loc = *node_icb_loc; 5330 needs_indirect = 0; 5331 strat4096 = 0; 5332 udf_file_type = UDF_ICB_FILETYPE_UNKNOWN; 5333 file_size = 0; 5334 file_data = NULL; 5335 lb_size = udf_rw32(ump->logical_vol->lb_size); 5336 5337 DPRINTF(NODE, ("\tstart reading descriptors\n")); 5338 do { 5339 /* try to read in fe/efe */ 5340 error = udf_read_logvol_dscr(ump, &icb_loc, &dscr); 5341 5342 /* blank sector marks end of sequence, check this */ 5343 if ((dscr == NULL) && (!strat4096)) 5344 error = ENOENT; 5345 5346 /* break if read error or blank sector */ 5347 if (error || (dscr == NULL)) 5348 break; 5349 5350 /* process descriptor based on the descriptor type */ 5351 dscr_type = udf_rw16(dscr->tag.id); 5352 DPRINTF(NODE, ("\tread descriptor %d\n", dscr_type)); 5353 5354 /* if dealing with an indirect entry, follow the link */ 5355 if (dscr_type == TAGID_INDIRECTENTRY) { 5356 needs_indirect = 0; 5357 udf_free_logvol_dscr(ump, &icb_loc, dscr); 5358 icb_loc = dscr->inde.indirect_icb; 5359 continue; 5360 } 5361 5362 /* only file entries and extended file entries allowed here */ 5363 if ((dscr_type != TAGID_FENTRY) && 5364 (dscr_type != TAGID_EXTFENTRY)) { 5365 udf_free_logvol_dscr(ump, &icb_loc, dscr); 5366 error = ENOENT; 5367 break; 5368 } 5369 5370 KASSERT(udf_tagsize(dscr, lb_size) == lb_size); 5371 5372 /* choose this one */ 5373 last_fe_icb_loc = icb_loc; 5374 5375 /* record and process/update (ext)fentry */ 5376 file_data = NULL; 5377 if (dscr_type == TAGID_FENTRY) { 5378 if (udf_node->fe) 5379 udf_free_logvol_dscr(ump, &last_fe_icb_loc, 5380 udf_node->fe); 5381 udf_node->fe = &dscr->fe; 5382 strat = udf_rw16(udf_node->fe->icbtag.strat_type); 5383 udf_file_type = udf_node->fe->icbtag.file_type; 5384 file_size = udf_rw64(udf_node->fe->inf_len); 5385 file_data = udf_node->fe->data; 5386 } else { 5387 if (udf_node->efe) 5388 udf_free_logvol_dscr(ump, &last_fe_icb_loc, 5389 udf_node->efe); 5390 udf_node->efe = &dscr->efe; 5391 strat = udf_rw16(udf_node->efe->icbtag.strat_type); 5392 udf_file_type = udf_node->efe->icbtag.file_type; 5393 file_size = udf_rw64(udf_node->efe->inf_len); 5394 file_data = udf_node->efe->data; 5395 } 5396 5397 /* check recording strategy (structure) */ 5398 5399 /* 5400 * Strategy 4096 is a daisy linked chain terminating with an 5401 * unrecorded sector or a TERM descriptor. The next 5402 * descriptor is to be found in the sector that follows the 5403 * current sector. 5404 */ 5405 if (strat == 4096) { 5406 strat4096 = 1; 5407 needs_indirect = 1; 5408 5409 icb_loc.loc.lb_num = udf_rw32(icb_loc.loc.lb_num) + 1; 5410 } 5411 5412 /* 5413 * Strategy 4 is the normal strategy and terminates, but if 5414 * we're in strategy 4096, we can't have strategy 4 mixed in 5415 */ 5416 5417 if (strat == 4) { 5418 if (strat4096) { 5419 error = EINVAL; 5420 break; 5421 } 5422 break; /* done */ 5423 } 5424 } while (!error); 5425 5426 /* first round of cleanup code */ 5427 if (error) { 5428 DPRINTF(NODE, ("\tnode fe/efe failed!\n")); 5429 /* recycle udf_node */ 5430 udf_dispose_node(udf_node); 5431 5432 vlockmgr(nvp->v_vnlock, LK_RELEASE); 5433 nvp->v_data = NULL; 5434 ungetnewvnode(nvp); 5435 5436 return EINVAL; /* error code ok? */ 5437 } 5438 DPRINTF(NODE, ("\tnode fe/efe read in fine\n")); 5439 5440 /* assert no references to dscr anymore beyong this point */ 5441 assert((udf_node->fe) || (udf_node->efe)); 5442 dscr = NULL; 5443 5444 /* 5445 * Remember where to record an updated version of the descriptor. If 5446 * there is a sequence of indirect entries, icb_loc will have been 5447 * updated. Its the write disipline to allocate new space and to make 5448 * sure the chain is maintained. 5449 * 5450 * `needs_indirect' flags if the next location is to be filled with 5451 * with an indirect entry. 5452 */ 5453 udf_node->write_loc = icb_loc; 5454 udf_node->needs_indirect = needs_indirect; 5455 5456 /* 5457 * Go trough all allocations extents of this descriptor and when 5458 * encountering a redirect read in the allocation extension. These are 5459 * daisy-chained. 5460 */ 5461 UDF_LOCK_NODE(udf_node, 0); 5462 udf_node->num_extensions = 0; 5463 5464 error = 0; 5465 slot = 0; 5466 for (;;) { 5467 udf_get_adslot(udf_node, slot, &icb_loc, &eof); 5468 DPRINTF(ADWLK, ("slot %d, eof = %d, flags = %d, len = %d, " 5469 "lb_num = %d, part = %d\n", slot, eof, 5470 UDF_EXT_FLAGS(udf_rw32(icb_loc.len)), 5471 UDF_EXT_LEN(udf_rw32(icb_loc.len)), 5472 udf_rw32(icb_loc.loc.lb_num), 5473 udf_rw16(icb_loc.loc.part_num))); 5474 if (eof) 5475 break; 5476 slot++; 5477 5478 if (UDF_EXT_FLAGS(udf_rw32(icb_loc.len)) != UDF_EXT_REDIRECT) 5479 continue; 5480 5481 DPRINTF(NODE, ("\tgot redirect extent\n")); 5482 if (udf_node->num_extensions >= UDF_MAX_ALLOC_EXTENTS) { 5483 DPRINTF(ALLOC, ("udf_get_node: implementation limit, " 5484 "too many allocation extensions on " 5485 "udf_node\n")); 5486 error = EINVAL; 5487 break; 5488 } 5489 5490 /* length can only be *one* lb : UDF 2.50/2.3.7.1 */ 5491 if (UDF_EXT_LEN(udf_rw32(icb_loc.len)) != lb_size) { 5492 DPRINTF(ALLOC, ("udf_get_node: bad allocation " 5493 "extension size in udf_node\n")); 5494 error = EINVAL; 5495 break; 5496 } 5497 5498 DPRINTF(NODE, ("read allocation extent at lb_num %d\n", 5499 UDF_EXT_LEN(udf_rw32(icb_loc.loc.lb_num)))); 5500 /* load in allocation extent */ 5501 error = udf_read_logvol_dscr(ump, &icb_loc, &dscr); 5502 if (error || (dscr == NULL)) 5503 break; 5504 5505 /* process read-in descriptor */ 5506 dscr_type = udf_rw16(dscr->tag.id); 5507 5508 if (dscr_type != TAGID_ALLOCEXTENT) { 5509 udf_free_logvol_dscr(ump, &icb_loc, dscr); 5510 error = ENOENT; 5511 break; 5512 } 5513 5514 DPRINTF(NODE, ("\trecording redirect extent\n")); 5515 udf_node->ext[udf_node->num_extensions] = &dscr->aee; 5516 udf_node->ext_loc[udf_node->num_extensions] = icb_loc; 5517 5518 udf_node->num_extensions++; 5519 5520 } /* while */ 5521 UDF_UNLOCK_NODE(udf_node, 0); 5522 5523 /* second round of cleanup code */ 5524 if (error) { 5525 /* recycle udf_node */ 5526 udf_dispose_node(udf_node); 5527 5528 vlockmgr(nvp->v_vnlock, LK_RELEASE); 5529 nvp->v_data = NULL; 5530 ungetnewvnode(nvp); 5531 5532 return EINVAL; /* error code ok? */ 5533 } 5534 5535 DPRINTF(NODE, ("\tnode read in fine\n")); 5536 5537 /* 5538 * Translate UDF filetypes into vnode types. 5539 * 5540 * Systemfiles like the meta main and mirror files are not treated as 5541 * normal files, so we type them as having no type. UDF dictates that 5542 * they are not allowed to be visible. 5543 */ 5544 5545 switch (udf_file_type) { 5546 case UDF_ICB_FILETYPE_DIRECTORY : 5547 case UDF_ICB_FILETYPE_STREAMDIR : 5548 nvp->v_type = VDIR; 5549 break; 5550 case UDF_ICB_FILETYPE_BLOCKDEVICE : 5551 nvp->v_type = VBLK; 5552 break; 5553 case UDF_ICB_FILETYPE_CHARDEVICE : 5554 nvp->v_type = VCHR; 5555 break; 5556 case UDF_ICB_FILETYPE_SOCKET : 5557 nvp->v_type = VSOCK; 5558 break; 5559 case UDF_ICB_FILETYPE_FIFO : 5560 nvp->v_type = VFIFO; 5561 break; 5562 case UDF_ICB_FILETYPE_SYMLINK : 5563 nvp->v_type = VLNK; 5564 break; 5565 case UDF_ICB_FILETYPE_VAT : 5566 case UDF_ICB_FILETYPE_META_MAIN : 5567 case UDF_ICB_FILETYPE_META_MIRROR : 5568 nvp->v_type = VNON; 5569 break; 5570 case UDF_ICB_FILETYPE_RANDOMACCESS : 5571 case UDF_ICB_FILETYPE_REALTIME : 5572 nvp->v_type = VREG; 5573 break; 5574 default: 5575 /* YIKES, something else */ 5576 nvp->v_type = VNON; 5577 } 5578 5579 /* TODO specfs, fifofs etc etc. vnops setting */ 5580 5581 /* don't forget to set vnode's v_size */ 5582 uvm_vnp_setsize(nvp, file_size); 5583 5584 /* TODO ext attr and streamdir udf_nodes */ 5585 5586 *udf_noderes = udf_node; 5587 5588 return 0; 5589 } 5590 5591 /* --------------------------------------------------------------------- */ 5592 5593 int 5594 udf_writeout_node(struct udf_node *udf_node, int waitfor) 5595 { 5596 union dscrptr *dscr; 5597 struct long_ad *loc; 5598 int extnr, error; 5599 5600 DPRINTF(NODE, ("udf_writeout_node called\n")); 5601 5602 KASSERT(udf_node->outstanding_bufs == 0); 5603 KASSERT(udf_node->outstanding_nodedscr == 0); 5604 5605 KASSERT(LIST_EMPTY(&udf_node->vnode->v_dirtyblkhd)); 5606 5607 if (udf_node->i_flags & IN_DELETED) { 5608 DPRINTF(NODE, ("\tnode deleted; not writing out\n")); 5609 udf_cleanup_reservation(udf_node); 5610 return 0; 5611 } 5612 5613 /* lock node; unlocked in callback */ 5614 UDF_LOCK_NODE(udf_node, 0); 5615 5616 /* remove pending reservations, we're written out */ 5617 udf_cleanup_reservation(udf_node); 5618 5619 /* at least one descriptor writeout */ 5620 udf_node->outstanding_nodedscr = 1; 5621 5622 /* we're going to write out the descriptor so clear the flags */ 5623 udf_node->i_flags &= ~(IN_MODIFIED | IN_ACCESSED); 5624 5625 /* if we were rebuild, write out the allocation extents */ 5626 if (udf_node->i_flags & IN_NODE_REBUILD) { 5627 /* mark outstanding node descriptors and issue them */ 5628 udf_node->outstanding_nodedscr += udf_node->num_extensions; 5629 for (extnr = 0; extnr < udf_node->num_extensions; extnr++) { 5630 loc = &udf_node->ext_loc[extnr]; 5631 dscr = (union dscrptr *) udf_node->ext[extnr]; 5632 error = udf_write_logvol_dscr(udf_node, dscr, loc, 0); 5633 if (error) 5634 return error; 5635 } 5636 /* mark allocation extents written out */ 5637 udf_node->i_flags &= ~(IN_NODE_REBUILD); 5638 } 5639 5640 if (udf_node->fe) { 5641 KASSERT(udf_node->efe == NULL); 5642 dscr = (union dscrptr *) udf_node->fe; 5643 } else { 5644 KASSERT(udf_node->efe); 5645 KASSERT(udf_node->fe == NULL); 5646 dscr = (union dscrptr *) udf_node->efe; 5647 } 5648 KASSERT(dscr); 5649 5650 loc = &udf_node->write_loc; 5651 error = udf_write_logvol_dscr(udf_node, dscr, loc, waitfor); 5652 5653 return error; 5654 } 5655 5656 /* --------------------------------------------------------------------- */ 5657 5658 int 5659 udf_dispose_node(struct udf_node *udf_node) 5660 { 5661 struct vnode *vp; 5662 int extnr; 5663 5664 DPRINTF(NODE, ("udf_dispose_node called on node %p\n", udf_node)); 5665 if (!udf_node) { 5666 DPRINTF(NODE, ("UDF: Dispose node on node NULL, ignoring\n")); 5667 return 0; 5668 } 5669 5670 vp = udf_node->vnode; 5671 #ifdef DIAGNOSTIC 5672 if (vp->v_numoutput) 5673 panic("disposing UDF node with pending I/O's, udf_node = %p, " 5674 "v_numoutput = %d", udf_node, vp->v_numoutput); 5675 #endif 5676 5677 udf_cleanup_reservation(udf_node); 5678 5679 /* TODO extended attributes and streamdir */ 5680 5681 /* remove dirhash if present */ 5682 dirhash_purge(&udf_node->dir_hash); 5683 5684 /* remove from our hash lookup table */ 5685 udf_deregister_node(udf_node); 5686 5687 /* destroy our lock */ 5688 mutex_destroy(&udf_node->node_mutex); 5689 cv_destroy(&udf_node->node_lock); 5690 5691 /* dissociate our udf_node from the vnode */ 5692 genfs_node_destroy(udf_node->vnode); 5693 vp->v_data = NULL; 5694 5695 /* free associated memory and the node itself */ 5696 for (extnr = 0; extnr < udf_node->num_extensions; extnr++) { 5697 udf_free_logvol_dscr(udf_node->ump, &udf_node->ext_loc[extnr], 5698 udf_node->ext[extnr]); 5699 udf_node->ext[extnr] = (void *) 0xdeadcccc; 5700 } 5701 5702 if (udf_node->fe) 5703 udf_free_logvol_dscr(udf_node->ump, &udf_node->loc, 5704 udf_node->fe); 5705 if (udf_node->efe) 5706 udf_free_logvol_dscr(udf_node->ump, &udf_node->loc, 5707 udf_node->efe); 5708 5709 udf_node->fe = (void *) 0xdeadaaaa; 5710 udf_node->efe = (void *) 0xdeadbbbb; 5711 udf_node->ump = (void *) 0xdeadbeef; 5712 pool_put(&udf_node_pool, udf_node); 5713 5714 return 0; 5715 } 5716 5717 5718 5719 /* 5720 * create a new node using the specified vnodeops, vap and cnp but with the 5721 * udf_file_type. This allows special files to be created. Use with care. 5722 */ 5723 5724 static int 5725 udf_create_node_raw(struct vnode *dvp, struct vnode **vpp, int udf_file_type, 5726 int (**vnodeops)(void *), struct vattr *vap, struct componentname *cnp) 5727 { 5728 union dscrptr *dscr; 5729 struct udf_node *dir_node = VTOI(dvp); 5730 struct udf_node *udf_node; 5731 struct udf_mount *ump = dir_node->ump; 5732 struct vnode *nvp; 5733 struct long_ad node_icb_loc; 5734 uint64_t parent_unique_id; 5735 uint64_t lmapping; 5736 uint32_t lb_size, lb_num; 5737 uint16_t vpart_num; 5738 uid_t uid; 5739 gid_t gid, parent_gid; 5740 int fid_size, error; 5741 5742 lb_size = udf_rw32(ump->logical_vol->lb_size); 5743 *vpp = NULL; 5744 5745 /* allocate vnode */ 5746 error = getnewvnode(VT_UDF, ump->vfs_mountp, vnodeops, &nvp); 5747 if (error) 5748 return error; 5749 5750 /* lock node */ 5751 error = vn_lock(nvp, LK_EXCLUSIVE | LK_RETRY); 5752 if (error) 5753 goto error_out_unget; 5754 5755 /* reserve space for one logical block */ 5756 vpart_num = ump->node_part; 5757 error = udf_reserve_space(ump, NULL, UDF_C_NODE, 5758 vpart_num, 1, /* can_fail */ true); 5759 if (error) 5760 goto error_out_unlock; 5761 5762 /* allocate node */ 5763 error = udf_allocate_space(ump, NULL, UDF_C_NODE, 5764 vpart_num, 1, &lmapping); 5765 if (error) 5766 goto error_out_unreserve; 5767 lb_num = lmapping; 5768 5769 /* initialise pointer to location */ 5770 memset(&node_icb_loc, 0, sizeof(struct long_ad)); 5771 node_icb_loc.len = udf_rw32(lb_size); 5772 node_icb_loc.loc.lb_num = udf_rw32(lb_num); 5773 node_icb_loc.loc.part_num = udf_rw16(vpart_num); 5774 5775 /* build udf_node (do initialise!) */ 5776 udf_node = pool_get(&udf_node_pool, PR_WAITOK); 5777 memset(udf_node, 0, sizeof(struct udf_node)); 5778 5779 /* initialise crosslinks, note location of fe/efe for hashing */ 5780 /* bugalert: synchronise with udf_get_node() */ 5781 udf_node->ump = ump; 5782 udf_node->vnode = nvp; 5783 nvp->v_data = udf_node; 5784 udf_node->loc = node_icb_loc; 5785 udf_node->write_loc = node_icb_loc; 5786 udf_node->lockf = 0; 5787 mutex_init(&udf_node->node_mutex, MUTEX_DEFAULT, IPL_NONE); 5788 cv_init(&udf_node->node_lock, "udf_nlk"); 5789 udf_node->outstanding_bufs = 0; 5790 udf_node->outstanding_nodedscr = 0; 5791 udf_node->uncommitted_lbs = 0; 5792 5793 /* initialise genfs */ 5794 genfs_node_init(nvp, &udf_genfsops); 5795 5796 /* insert into the hash lookup */ 5797 udf_register_node(udf_node); 5798 5799 /* get parent's unique ID for refering '..' if its a directory */ 5800 if (dir_node->fe) { 5801 parent_unique_id = udf_rw64(dir_node->fe->unique_id); 5802 parent_gid = (gid_t) udf_rw32(dir_node->fe->gid); 5803 } else { 5804 parent_unique_id = udf_rw64(dir_node->efe->unique_id); 5805 parent_gid = (gid_t) udf_rw32(dir_node->efe->gid); 5806 } 5807 5808 /* get descriptor */ 5809 udf_create_logvol_dscr(ump, udf_node, &node_icb_loc, &dscr); 5810 5811 /* choose a fe or an efe for it */ 5812 if (udf_rw16(ump->logical_vol->tag.descriptor_ver) == 2) { 5813 udf_node->fe = &dscr->fe; 5814 fid_size = udf_create_new_fe(ump, udf_node->fe, 5815 udf_file_type, &udf_node->loc, 5816 &dir_node->loc, parent_unique_id); 5817 /* TODO add extended attribute for creation time */ 5818 } else { 5819 udf_node->efe = &dscr->efe; 5820 fid_size = udf_create_new_efe(ump, udf_node->efe, 5821 udf_file_type, &udf_node->loc, 5822 &dir_node->loc, parent_unique_id); 5823 } 5824 KASSERT(dscr->tag.tag_loc == udf_node->loc.loc.lb_num); 5825 5826 /* update vnode's size and type */ 5827 nvp->v_type = vap->va_type; 5828 uvm_vnp_setsize(nvp, fid_size); 5829 5830 /* set access mode */ 5831 udf_setaccessmode(udf_node, vap->va_mode); 5832 5833 /* set ownership */ 5834 uid = kauth_cred_geteuid(cnp->cn_cred); 5835 gid = parent_gid; 5836 udf_setownership(udf_node, uid, gid); 5837 5838 error = udf_dir_attach(ump, dir_node, udf_node, vap, cnp); 5839 if (error) { 5840 /* free disc allocation for node */ 5841 udf_free_allocated_space(ump, lb_num, vpart_num, 1); 5842 5843 /* recycle udf_node */ 5844 udf_dispose_node(udf_node); 5845 vput(nvp); 5846 5847 *vpp = NULL; 5848 return error; 5849 } 5850 5851 /* adjust file count */ 5852 udf_adjust_filecount(udf_node, 1); 5853 5854 /* return result */ 5855 *vpp = nvp; 5856 5857 return 0; 5858 5859 error_out_unreserve: 5860 udf_do_unreserve_space(ump, NULL, vpart_num, 1); 5861 5862 error_out_unlock: 5863 vlockmgr(nvp->v_vnlock, LK_RELEASE); 5864 5865 error_out_unget: 5866 nvp->v_data = NULL; 5867 ungetnewvnode(nvp); 5868 5869 return error; 5870 } 5871 5872 5873 int 5874 udf_create_node(struct vnode *dvp, struct vnode **vpp, struct vattr *vap, 5875 struct componentname *cnp) 5876 { 5877 int (**vnodeops)(void *); 5878 int udf_file_type; 5879 5880 DPRINTF(NODE, ("udf_create_node called\n")); 5881 5882 /* what type are we creating ? */ 5883 vnodeops = udf_vnodeop_p; 5884 /* start with a default */ 5885 udf_file_type = UDF_ICB_FILETYPE_RANDOMACCESS; 5886 5887 *vpp = NULL; 5888 5889 switch (vap->va_type) { 5890 case VREG : 5891 udf_file_type = UDF_ICB_FILETYPE_RANDOMACCESS; 5892 break; 5893 case VDIR : 5894 udf_file_type = UDF_ICB_FILETYPE_DIRECTORY; 5895 break; 5896 case VLNK : 5897 udf_file_type = UDF_ICB_FILETYPE_SYMLINK; 5898 break; 5899 case VBLK : 5900 udf_file_type = UDF_ICB_FILETYPE_BLOCKDEVICE; 5901 /* specfs */ 5902 return ENOTSUP; 5903 break; 5904 case VCHR : 5905 udf_file_type = UDF_ICB_FILETYPE_CHARDEVICE; 5906 /* specfs */ 5907 return ENOTSUP; 5908 break; 5909 case VFIFO : 5910 udf_file_type = UDF_ICB_FILETYPE_FIFO; 5911 /* specfs */ 5912 return ENOTSUP; 5913 break; 5914 case VSOCK : 5915 udf_file_type = UDF_ICB_FILETYPE_SOCKET; 5916 /* specfs */ 5917 return ENOTSUP; 5918 break; 5919 case VNON : 5920 case VBAD : 5921 default : 5922 /* nothing; can we even create these? */ 5923 return EINVAL; 5924 } 5925 5926 return udf_create_node_raw(dvp, vpp, udf_file_type, vnodeops, vap, cnp); 5927 } 5928 5929 /* --------------------------------------------------------------------- */ 5930 5931 static void 5932 udf_free_descriptor_space(struct udf_node *udf_node, struct long_ad *loc, void *mem) 5933 { 5934 struct udf_mount *ump = udf_node->ump; 5935 uint32_t lb_size, lb_num, len, num_lb; 5936 uint16_t vpart_num; 5937 5938 /* is there really one? */ 5939 if (mem == NULL) 5940 return; 5941 5942 /* got a descriptor here */ 5943 len = UDF_EXT_LEN(udf_rw32(loc->len)); 5944 lb_num = udf_rw32(loc->loc.lb_num); 5945 vpart_num = udf_rw16(loc->loc.part_num); 5946 5947 lb_size = udf_rw32(ump->logical_vol->lb_size); 5948 num_lb = (len + lb_size -1) / lb_size; 5949 5950 udf_free_allocated_space(ump, lb_num, vpart_num, num_lb); 5951 } 5952 5953 void 5954 udf_delete_node(struct udf_node *udf_node) 5955 { 5956 void *dscr; 5957 struct udf_mount *ump; 5958 struct long_ad *loc; 5959 int extnr, lvint, dummy; 5960 5961 ump = udf_node->ump; 5962 5963 /* paranoia check on integrity; should be open!; we could panic */ 5964 lvint = udf_rw32(udf_node->ump->logvol_integrity->integrity_type); 5965 if (lvint == UDF_INTEGRITY_CLOSED) 5966 printf("\tIntegrity was CLOSED!\n"); 5967 5968 /* whatever the node type, change its size to zero */ 5969 (void) udf_resize_node(udf_node, 0, &dummy); 5970 5971 /* force it to be `clean'; no use writing it out */ 5972 udf_node->i_flags &= ~(IN_MODIFIED | IN_ACCESSED | IN_ACCESS | 5973 IN_CHANGE | IN_UPDATE | IN_MODIFY); 5974 5975 /* adjust file count */ 5976 udf_adjust_filecount(udf_node, -1); 5977 5978 /* 5979 * Free its allocated descriptors; memory will be released when 5980 * vop_reclaim() is called. 5981 */ 5982 loc = &udf_node->loc; 5983 5984 dscr = udf_node->fe; 5985 udf_free_descriptor_space(udf_node, loc, dscr); 5986 dscr = udf_node->efe; 5987 udf_free_descriptor_space(udf_node, loc, dscr); 5988 5989 for (extnr = 0; extnr < UDF_MAX_ALLOC_EXTENTS; extnr++) { 5990 dscr = udf_node->ext[extnr]; 5991 loc = &udf_node->ext_loc[extnr]; 5992 udf_free_descriptor_space(udf_node, loc, dscr); 5993 } 5994 } 5995 5996 /* --------------------------------------------------------------------- */ 5997 5998 /* set new filesize; node but be LOCKED on entry and is locked on exit */ 5999 int 6000 udf_resize_node(struct udf_node *udf_node, uint64_t new_size, int *extended) 6001 { 6002 struct file_entry *fe = udf_node->fe; 6003 struct extfile_entry *efe = udf_node->efe; 6004 uint64_t file_size; 6005 int error; 6006 6007 if (fe) { 6008 file_size = udf_rw64(fe->inf_len); 6009 } else { 6010 assert(udf_node->efe); 6011 file_size = udf_rw64(efe->inf_len); 6012 } 6013 6014 DPRINTF(ATTR, ("\tchanging file length from %"PRIu64" to %"PRIu64"\n", 6015 file_size, new_size)); 6016 6017 /* if not changing, we're done */ 6018 if (file_size == new_size) 6019 return 0; 6020 6021 *extended = (new_size > file_size); 6022 if (*extended) { 6023 error = udf_grow_node(udf_node, new_size); 6024 } else { 6025 error = udf_shrink_node(udf_node, new_size); 6026 } 6027 6028 return error; 6029 } 6030 6031 6032 /* --------------------------------------------------------------------- */ 6033 6034 void 6035 udf_itimes(struct udf_node *udf_node, struct timespec *acc, 6036 struct timespec *mod, struct timespec *birth) 6037 { 6038 struct timespec now; 6039 struct file_entry *fe; 6040 struct extfile_entry *efe; 6041 struct filetimes_extattr_entry *ft_extattr; 6042 struct timestamp *atime, *mtime, *attrtime, *ctime; 6043 struct timestamp fe_ctime; 6044 struct timespec cur_birth; 6045 uint32_t offset, a_l; 6046 uint8_t *filedata; 6047 int error; 6048 6049 /* protect against rogue values */ 6050 if (!udf_node) 6051 return; 6052 6053 fe = udf_node->fe; 6054 efe = udf_node->efe; 6055 6056 if (!(udf_node->i_flags & (IN_ACCESS|IN_CHANGE|IN_UPDATE|IN_MODIFY))) 6057 return; 6058 6059 /* get descriptor information */ 6060 if (fe) { 6061 atime = &fe->atime; 6062 mtime = &fe->mtime; 6063 attrtime = &fe->attrtime; 6064 filedata = fe->data; 6065 6066 /* initial save dummy setting */ 6067 ctime = &fe_ctime; 6068 6069 /* check our extended attribute if present */ 6070 error = udf_extattr_search_intern(udf_node, 6071 UDF_FILETIMES_ATTR_NO, "", &offset, &a_l); 6072 if (!error) { 6073 ft_extattr = (struct filetimes_extattr_entry *) 6074 (filedata + offset); 6075 if (ft_extattr->existence & UDF_FILETIMES_FILE_CREATION) 6076 ctime = &ft_extattr->times[0]; 6077 } 6078 /* TODO create the extended attribute if not found ? */ 6079 } else { 6080 assert(udf_node->efe); 6081 atime = &efe->atime; 6082 mtime = &efe->mtime; 6083 attrtime = &efe->attrtime; 6084 ctime = &efe->ctime; 6085 } 6086 6087 vfs_timestamp(&now); 6088 6089 /* set access time */ 6090 if (udf_node->i_flags & IN_ACCESS) { 6091 if (acc == NULL) 6092 acc = &now; 6093 udf_timespec_to_timestamp(acc, atime); 6094 } 6095 6096 /* set modification time */ 6097 if (udf_node->i_flags & (IN_UPDATE | IN_MODIFY)) { 6098 if (mod == NULL) 6099 mod = &now; 6100 udf_timespec_to_timestamp(mod, mtime); 6101 6102 /* ensure birthtime is older than set modification! */ 6103 udf_timestamp_to_timespec(udf_node->ump, ctime, &cur_birth); 6104 if ((cur_birth.tv_sec > mod->tv_sec) || 6105 ((cur_birth.tv_sec == mod->tv_sec) && 6106 (cur_birth.tv_nsec > mod->tv_nsec))) { 6107 udf_timespec_to_timestamp(mod, ctime); 6108 } 6109 } 6110 6111 /* update birthtime if specified */ 6112 /* XXX we asume here that given birthtime is older than mod */ 6113 if (birth && (birth->tv_sec != VNOVAL)) { 6114 udf_timespec_to_timestamp(birth, ctime); 6115 } 6116 6117 /* set change time */ 6118 if (udf_node->i_flags & (IN_CHANGE | IN_MODIFY)) 6119 udf_timespec_to_timestamp(&now, attrtime); 6120 6121 /* notify updates to the node itself */ 6122 if (udf_node->i_flags & (IN_ACCESS | IN_MODIFY)) 6123 udf_node->i_flags |= IN_ACCESSED; 6124 if (udf_node->i_flags & (IN_UPDATE | IN_CHANGE)) 6125 udf_node->i_flags |= IN_MODIFIED; 6126 6127 /* clear modification flags */ 6128 udf_node->i_flags &= ~(IN_ACCESS | IN_CHANGE | IN_UPDATE | IN_MODIFY); 6129 } 6130 6131 /* --------------------------------------------------------------------- */ 6132 6133 int 6134 udf_update(struct vnode *vp, struct timespec *acc, 6135 struct timespec *mod, struct timespec *birth, int updflags) 6136 { 6137 union dscrptr *dscrptr; 6138 struct udf_node *udf_node = VTOI(vp); 6139 struct udf_mount *ump = udf_node->ump; 6140 struct regid *impl_id; 6141 int mnt_async = (vp->v_mount->mnt_flag & MNT_ASYNC); 6142 int waitfor, flags; 6143 6144 #ifdef DEBUG 6145 char bits[128]; 6146 DPRINTF(CALL, ("udf_update(node, %p, %p, %p, %d)\n", acc, mod, birth, 6147 updflags)); 6148 snprintb(bits, sizeof(bits), IN_FLAGBITS, udf_node->i_flags); 6149 DPRINTF(CALL, ("\tnode flags %s\n", bits)); 6150 DPRINTF(CALL, ("\t\tmnt_async = %d\n", mnt_async)); 6151 #endif 6152 6153 /* set our times */ 6154 udf_itimes(udf_node, acc, mod, birth); 6155 6156 /* set our implementation id */ 6157 if (udf_node->fe) { 6158 dscrptr = (union dscrptr *) udf_node->fe; 6159 impl_id = &udf_node->fe->imp_id; 6160 } else { 6161 dscrptr = (union dscrptr *) udf_node->efe; 6162 impl_id = &udf_node->efe->imp_id; 6163 } 6164 6165 /* set our ID */ 6166 udf_set_regid(impl_id, IMPL_NAME); 6167 udf_add_impl_regid(ump, impl_id); 6168 6169 /* update our crc! on RMW we are not allowed to change a thing */ 6170 udf_validate_tag_and_crc_sums(dscrptr); 6171 6172 /* if called when mounted readonly, never write back */ 6173 if (vp->v_mount->mnt_flag & MNT_RDONLY) 6174 return 0; 6175 6176 /* check if the node is dirty 'enough'*/ 6177 if (updflags & UPDATE_CLOSE) { 6178 flags = udf_node->i_flags & (IN_MODIFIED | IN_ACCESSED); 6179 } else { 6180 flags = udf_node->i_flags & IN_MODIFIED; 6181 } 6182 if (flags == 0) 6183 return 0; 6184 6185 /* determine if we need to write sync or async */ 6186 waitfor = 0; 6187 if ((flags & IN_MODIFIED) && (mnt_async == 0)) { 6188 /* sync mounted */ 6189 waitfor = updflags & UPDATE_WAIT; 6190 if (updflags & UPDATE_DIROP) 6191 waitfor |= UPDATE_WAIT; 6192 } 6193 if (waitfor) 6194 return VOP_FSYNC(vp, FSCRED, FSYNC_WAIT, 0,0); 6195 6196 return 0; 6197 } 6198 6199 6200 /* --------------------------------------------------------------------- */ 6201 6202 6203 /* 6204 * Read one fid and process it into a dirent and advance to the next (*fid) 6205 * has to be allocated a logical block in size, (*dirent) struct dirent length 6206 */ 6207 6208 int 6209 udf_read_fid_stream(struct vnode *vp, uint64_t *offset, 6210 struct fileid_desc *fid, struct dirent *dirent) 6211 { 6212 struct udf_node *dir_node = VTOI(vp); 6213 struct udf_mount *ump = dir_node->ump; 6214 struct file_entry *fe = dir_node->fe; 6215 struct extfile_entry *efe = dir_node->efe; 6216 uint32_t fid_size, lb_size; 6217 uint64_t file_size; 6218 char *fid_name; 6219 int enough, error; 6220 6221 assert(fid); 6222 assert(dirent); 6223 assert(dir_node); 6224 assert(offset); 6225 assert(*offset != 1); 6226 6227 DPRINTF(FIDS, ("read_fid_stream called at offset %"PRIu64"\n", *offset)); 6228 /* check if we're past the end of the directory */ 6229 if (fe) { 6230 file_size = udf_rw64(fe->inf_len); 6231 } else { 6232 assert(dir_node->efe); 6233 file_size = udf_rw64(efe->inf_len); 6234 } 6235 if (*offset >= file_size) 6236 return EINVAL; 6237 6238 /* get maximum length of FID descriptor */ 6239 lb_size = udf_rw32(ump->logical_vol->lb_size); 6240 6241 /* initialise return values */ 6242 fid_size = 0; 6243 memset(dirent, 0, sizeof(struct dirent)); 6244 memset(fid, 0, lb_size); 6245 6246 enough = (file_size - (*offset) >= UDF_FID_SIZE); 6247 if (!enough) { 6248 /* short dir ... */ 6249 return EIO; 6250 } 6251 6252 error = vn_rdwr(UIO_READ, vp, 6253 fid, MIN(file_size - (*offset), lb_size), *offset, 6254 UIO_SYSSPACE, IO_ALTSEMANTICS | IO_NODELOCKED, FSCRED, 6255 NULL, NULL); 6256 if (error) 6257 return error; 6258 6259 DPRINTF(FIDS, ("\tfid piece read in fine\n")); 6260 /* 6261 * Check if we got a whole descriptor. 6262 * TODO Try to `resync' directory stream when something is very wrong. 6263 */ 6264 6265 /* check if our FID header is OK */ 6266 error = udf_check_tag(fid); 6267 if (error) { 6268 goto brokendir; 6269 } 6270 DPRINTF(FIDS, ("\ttag check ok\n")); 6271 6272 if (udf_rw16(fid->tag.id) != TAGID_FID) { 6273 error = EIO; 6274 goto brokendir; 6275 } 6276 DPRINTF(FIDS, ("\ttag checked ok: got TAGID_FID\n")); 6277 6278 /* check for length */ 6279 fid_size = udf_fidsize(fid); 6280 enough = (file_size - (*offset) >= fid_size); 6281 if (!enough) { 6282 error = EIO; 6283 goto brokendir; 6284 } 6285 DPRINTF(FIDS, ("\tthe complete fid is read in\n")); 6286 6287 /* check FID contents */ 6288 error = udf_check_tag_payload((union dscrptr *) fid, lb_size); 6289 brokendir: 6290 if (error) { 6291 /* note that is sometimes a bit quick to report */ 6292 printf("UDF: BROKEN DIRECTORY ENTRY\n"); 6293 /* RESYNC? */ 6294 /* TODO: use udf_resync_fid_stream */ 6295 return EIO; 6296 } 6297 DPRINTF(FIDS, ("\tpayload checked ok\n")); 6298 6299 /* we got a whole and valid descriptor! */ 6300 DPRINTF(FIDS, ("\tinterpret FID\n")); 6301 6302 /* create resulting dirent structure */ 6303 fid_name = (char *) fid->data + udf_rw16(fid->l_iu); 6304 udf_to_unix_name(dirent->d_name, MAXNAMLEN, 6305 fid_name, fid->l_fi, &ump->logical_vol->desc_charset); 6306 6307 /* '..' has no name, so provide one */ 6308 if (fid->file_char & UDF_FILE_CHAR_PAR) 6309 strcpy(dirent->d_name, ".."); 6310 6311 dirent->d_fileno = udf_get_node_id(&fid->icb); /* inode hash XXX */ 6312 dirent->d_namlen = strlen(dirent->d_name); 6313 dirent->d_reclen = _DIRENT_SIZE(dirent); 6314 6315 /* 6316 * Note that its not worth trying to go for the filetypes now... its 6317 * too expensive too 6318 */ 6319 dirent->d_type = DT_UNKNOWN; 6320 6321 /* initial guess for filetype we can make */ 6322 if (fid->file_char & UDF_FILE_CHAR_DIR) 6323 dirent->d_type = DT_DIR; 6324 6325 /* advance */ 6326 *offset += fid_size; 6327 6328 return error; 6329 } 6330 6331 6332 /* --------------------------------------------------------------------- */ 6333 6334 static void 6335 udf_sync_pass(struct udf_mount *ump, kauth_cred_t cred, int waitfor, 6336 int pass, int *ndirty) 6337 { 6338 struct udf_node *udf_node, *n_udf_node; 6339 struct vnode *vp; 6340 int vdirty, error; 6341 int on_type, on_flags, on_vnode; 6342 6343 derailed: 6344 KASSERT(mutex_owned(&mntvnode_lock)); 6345 6346 DPRINTF(SYNC, ("sync_pass %d\n", pass)); 6347 udf_node = RBTOUDFNODE(RB_TREE_MIN(&ump->udf_node_tree)); 6348 for (;udf_node; udf_node = n_udf_node) { 6349 DPRINTF(SYNC, (".")); 6350 6351 udf_node->i_flags &= ~IN_SYNCED; 6352 vp = udf_node->vnode; 6353 6354 mutex_enter(&vp->v_interlock); 6355 n_udf_node = RBTOUDFNODE(rb_tree_iterate( 6356 &ump->udf_node_tree, &udf_node->rbnode, 6357 RB_DIR_RIGHT)); 6358 6359 if (n_udf_node) 6360 n_udf_node->i_flags |= IN_SYNCED; 6361 6362 /* system nodes are not synced this way */ 6363 if (vp->v_vflag & VV_SYSTEM) { 6364 mutex_exit(&vp->v_interlock); 6365 continue; 6366 } 6367 6368 /* check if its dirty enough to even try */ 6369 on_type = (waitfor == MNT_LAZY || vp->v_type == VNON); 6370 on_flags = ((udf_node->i_flags & 6371 (IN_ACCESSED | IN_UPDATE | IN_MODIFIED)) == 0); 6372 on_vnode = LIST_EMPTY(&vp->v_dirtyblkhd) 6373 && UVM_OBJ_IS_CLEAN(&vp->v_uobj); 6374 if (on_type || (on_flags || on_vnode)) { /* XXX */ 6375 /* not dirty (enough?) */ 6376 mutex_exit(&vp->v_interlock); 6377 continue; 6378 } 6379 6380 mutex_exit(&mntvnode_lock); 6381 error = vget(vp, LK_EXCLUSIVE | LK_NOWAIT | LK_INTERLOCK); 6382 if (error) { 6383 mutex_enter(&mntvnode_lock); 6384 if (error == ENOENT) 6385 goto derailed; 6386 *ndirty += 1; 6387 continue; 6388 } 6389 6390 switch (pass) { 6391 case 1: 6392 VOP_FSYNC(vp, cred, 0 | FSYNC_DATAONLY,0,0); 6393 break; 6394 case 2: 6395 vdirty = vp->v_numoutput; 6396 if (vp->v_tag == VT_UDF) 6397 vdirty += udf_node->outstanding_bufs + 6398 udf_node->outstanding_nodedscr; 6399 if (vdirty == 0) 6400 VOP_FSYNC(vp, cred, 0,0,0); 6401 *ndirty += vdirty; 6402 break; 6403 case 3: 6404 vdirty = vp->v_numoutput; 6405 if (vp->v_tag == VT_UDF) 6406 vdirty += udf_node->outstanding_bufs + 6407 udf_node->outstanding_nodedscr; 6408 *ndirty += vdirty; 6409 break; 6410 } 6411 6412 vput(vp); 6413 mutex_enter(&mntvnode_lock); 6414 } 6415 DPRINTF(SYNC, ("END sync_pass %d\n", pass)); 6416 } 6417 6418 6419 void 6420 udf_do_sync(struct udf_mount *ump, kauth_cred_t cred, int waitfor) 6421 { 6422 int dummy, ndirty; 6423 6424 mutex_enter(&mntvnode_lock); 6425 recount: 6426 dummy = 0; 6427 DPRINTF(CALL, ("issue VOP_FSYNC(DATA only) on all nodes\n")); 6428 DPRINTF(SYNC, ("issue VOP_FSYNC(DATA only) on all nodes\n")); 6429 udf_sync_pass(ump, cred, waitfor, 1, &dummy); 6430 6431 DPRINTF(CALL, ("issue VOP_FSYNC(COMPLETE) on all finished nodes\n")); 6432 DPRINTF(SYNC, ("issue VOP_FSYNC(COMPLETE) on all finished nodes\n")); 6433 udf_sync_pass(ump, cred, waitfor, 2, &dummy); 6434 6435 if (waitfor == MNT_WAIT) { 6436 ndirty = ump->devvp->v_numoutput; 6437 DPRINTF(SYNC, ("counting pending blocks: on devvp %d\n", 6438 ndirty)); 6439 udf_sync_pass(ump, cred, waitfor, 3, &ndirty); 6440 DPRINTF(SYNC, ("counted num dirty pending blocks %d\n", 6441 ndirty)); 6442 6443 if (ndirty) { 6444 /* 1/4 second wait */ 6445 cv_timedwait(&ump->dirtynodes_cv, &mntvnode_lock, 6446 hz/4); 6447 goto recount; 6448 } 6449 } 6450 6451 mutex_exit(&mntvnode_lock); 6452 } 6453 6454 /* --------------------------------------------------------------------- */ 6455 6456 /* 6457 * Read and write file extent in/from the buffer. 6458 * 6459 * The splitup of the extent into seperate request-buffers is to minimise 6460 * copying around as much as possible. 6461 * 6462 * block based file reading and writing 6463 */ 6464 6465 static int 6466 udf_read_internal(struct udf_node *node, uint8_t *blob) 6467 { 6468 struct udf_mount *ump; 6469 struct file_entry *fe = node->fe; 6470 struct extfile_entry *efe = node->efe; 6471 uint64_t inflen; 6472 uint32_t sector_size; 6473 uint8_t *pos; 6474 int icbflags, addr_type; 6475 6476 /* get extent and do some paranoia checks */ 6477 ump = node->ump; 6478 sector_size = ump->discinfo.sector_size; 6479 6480 if (fe) { 6481 inflen = udf_rw64(fe->inf_len); 6482 pos = &fe->data[0] + udf_rw32(fe->l_ea); 6483 icbflags = udf_rw16(fe->icbtag.flags); 6484 } else { 6485 assert(node->efe); 6486 inflen = udf_rw64(efe->inf_len); 6487 pos = &efe->data[0] + udf_rw32(efe->l_ea); 6488 icbflags = udf_rw16(efe->icbtag.flags); 6489 } 6490 addr_type = icbflags & UDF_ICB_TAG_FLAGS_ALLOC_MASK; 6491 6492 assert(addr_type == UDF_ICB_INTERN_ALLOC); 6493 assert(inflen < sector_size); 6494 6495 /* copy out info */ 6496 memset(blob, 0, sector_size); 6497 memcpy(blob, pos, inflen); 6498 6499 return 0; 6500 } 6501 6502 6503 static int 6504 udf_write_internal(struct udf_node *node, uint8_t *blob) 6505 { 6506 struct udf_mount *ump; 6507 struct file_entry *fe = node->fe; 6508 struct extfile_entry *efe = node->efe; 6509 uint64_t inflen; 6510 uint32_t sector_size; 6511 uint8_t *pos; 6512 int icbflags, addr_type; 6513 6514 /* get extent and do some paranoia checks */ 6515 ump = node->ump; 6516 sector_size = ump->discinfo.sector_size; 6517 6518 if (fe) { 6519 inflen = udf_rw64(fe->inf_len); 6520 pos = &fe->data[0] + udf_rw32(fe->l_ea); 6521 icbflags = udf_rw16(fe->icbtag.flags); 6522 } else { 6523 assert(node->efe); 6524 inflen = udf_rw64(efe->inf_len); 6525 pos = &efe->data[0] + udf_rw32(efe->l_ea); 6526 icbflags = udf_rw16(efe->icbtag.flags); 6527 } 6528 addr_type = icbflags & UDF_ICB_TAG_FLAGS_ALLOC_MASK; 6529 6530 assert(addr_type == UDF_ICB_INTERN_ALLOC); 6531 assert(inflen < sector_size); 6532 6533 /* copy in blob */ 6534 /* memset(pos, 0, inflen); */ 6535 memcpy(pos, blob, inflen); 6536 6537 return 0; 6538 } 6539 6540 6541 void 6542 udf_read_filebuf(struct udf_node *udf_node, struct buf *buf) 6543 { 6544 struct buf *nestbuf; 6545 struct udf_mount *ump = udf_node->ump; 6546 uint64_t *mapping; 6547 uint64_t run_start; 6548 uint32_t sector_size; 6549 uint32_t buf_offset, sector, rbuflen, rblk; 6550 uint32_t from, lblkno; 6551 uint32_t sectors; 6552 uint8_t *buf_pos; 6553 int error, run_length, what; 6554 6555 sector_size = udf_node->ump->discinfo.sector_size; 6556 6557 from = buf->b_blkno; 6558 sectors = buf->b_bcount / sector_size; 6559 6560 what = udf_get_c_type(udf_node); 6561 6562 /* assure we have enough translation slots */ 6563 KASSERT(buf->b_bcount / sector_size <= UDF_MAX_MAPPINGS); 6564 KASSERT(MAXPHYS / sector_size <= UDF_MAX_MAPPINGS); 6565 6566 if (sectors > UDF_MAX_MAPPINGS) { 6567 printf("udf_read_filebuf: implementation limit on bufsize\n"); 6568 buf->b_error = EIO; 6569 biodone(buf); 6570 return; 6571 } 6572 6573 mapping = malloc(sizeof(*mapping) * UDF_MAX_MAPPINGS, M_TEMP, M_WAITOK); 6574 6575 error = 0; 6576 DPRINTF(READ, ("\ttranslate %d-%d\n", from, sectors)); 6577 error = udf_translate_file_extent(udf_node, from, sectors, mapping); 6578 if (error) { 6579 buf->b_error = error; 6580 biodone(buf); 6581 goto out; 6582 } 6583 DPRINTF(READ, ("\ttranslate extent went OK\n")); 6584 6585 /* pre-check if its an internal */ 6586 if (*mapping == UDF_TRANS_INTERN) { 6587 error = udf_read_internal(udf_node, (uint8_t *) buf->b_data); 6588 if (error) 6589 buf->b_error = error; 6590 biodone(buf); 6591 goto out; 6592 } 6593 DPRINTF(READ, ("\tnot intern\n")); 6594 6595 #ifdef DEBUG 6596 if (udf_verbose & UDF_DEBUG_TRANSLATE) { 6597 printf("Returned translation table:\n"); 6598 for (sector = 0; sector < sectors; sector++) { 6599 printf("%d : %"PRIu64"\n", sector, mapping[sector]); 6600 } 6601 } 6602 #endif 6603 6604 /* request read-in of data from disc sheduler */ 6605 buf->b_resid = buf->b_bcount; 6606 for (sector = 0; sector < sectors; sector++) { 6607 buf_offset = sector * sector_size; 6608 buf_pos = (uint8_t *) buf->b_data + buf_offset; 6609 DPRINTF(READ, ("\tprocessing rel sector %d\n", sector)); 6610 6611 /* check if its zero or unmapped to stop reading */ 6612 switch (mapping[sector]) { 6613 case UDF_TRANS_UNMAPPED: 6614 case UDF_TRANS_ZERO: 6615 /* copy zero sector TODO runlength like below */ 6616 memset(buf_pos, 0, sector_size); 6617 DPRINTF(READ, ("\treturning zero sector\n")); 6618 nestiobuf_done(buf, sector_size, 0); 6619 break; 6620 default : 6621 DPRINTF(READ, ("\tread sector " 6622 "%"PRIu64"\n", mapping[sector])); 6623 6624 lblkno = from + sector; 6625 run_start = mapping[sector]; 6626 run_length = 1; 6627 while (sector < sectors-1) { 6628 if (mapping[sector+1] != mapping[sector]+1) 6629 break; 6630 run_length++; 6631 sector++; 6632 } 6633 6634 /* 6635 * nest an iobuf and mark it for async reading. Since 6636 * we're using nested buffers, they can't be cached by 6637 * design. 6638 */ 6639 rbuflen = run_length * sector_size; 6640 rblk = run_start * (sector_size/DEV_BSIZE); 6641 6642 nestbuf = getiobuf(NULL, true); 6643 nestiobuf_setup(buf, nestbuf, buf_offset, rbuflen); 6644 /* nestbuf is B_ASYNC */ 6645 6646 /* identify this nestbuf */ 6647 nestbuf->b_lblkno = lblkno; 6648 assert(nestbuf->b_vp == udf_node->vnode); 6649 6650 /* CD shedules on raw blkno */ 6651 nestbuf->b_blkno = rblk; 6652 nestbuf->b_proc = NULL; 6653 nestbuf->b_rawblkno = rblk; 6654 nestbuf->b_udf_c_type = what; 6655 6656 udf_discstrat_queuebuf(ump, nestbuf); 6657 } 6658 } 6659 out: 6660 /* if we're synchronously reading, wait for the completion */ 6661 if ((buf->b_flags & B_ASYNC) == 0) 6662 biowait(buf); 6663 6664 DPRINTF(READ, ("\tend of read_filebuf\n")); 6665 free(mapping, M_TEMP); 6666 return; 6667 } 6668 6669 6670 void 6671 udf_write_filebuf(struct udf_node *udf_node, struct buf *buf) 6672 { 6673 struct buf *nestbuf; 6674 struct udf_mount *ump = udf_node->ump; 6675 uint64_t *mapping; 6676 uint64_t run_start; 6677 uint32_t lb_size; 6678 uint32_t buf_offset, lb_num, rbuflen, rblk; 6679 uint32_t from, lblkno; 6680 uint32_t num_lb; 6681 int error, run_length, what, s; 6682 6683 lb_size = udf_rw32(udf_node->ump->logical_vol->lb_size); 6684 6685 from = buf->b_blkno; 6686 num_lb = buf->b_bcount / lb_size; 6687 6688 what = udf_get_c_type(udf_node); 6689 6690 /* assure we have enough translation slots */ 6691 KASSERT(buf->b_bcount / lb_size <= UDF_MAX_MAPPINGS); 6692 KASSERT(MAXPHYS / lb_size <= UDF_MAX_MAPPINGS); 6693 6694 if (num_lb > UDF_MAX_MAPPINGS) { 6695 printf("udf_write_filebuf: implementation limit on bufsize\n"); 6696 buf->b_error = EIO; 6697 biodone(buf); 6698 return; 6699 } 6700 6701 mapping = malloc(sizeof(*mapping) * UDF_MAX_MAPPINGS, M_TEMP, M_WAITOK); 6702 6703 error = 0; 6704 DPRINTF(WRITE, ("\ttranslate %d-%d\n", from, num_lb)); 6705 error = udf_translate_file_extent(udf_node, from, num_lb, mapping); 6706 if (error) { 6707 buf->b_error = error; 6708 biodone(buf); 6709 goto out; 6710 } 6711 DPRINTF(WRITE, ("\ttranslate extent went OK\n")); 6712 6713 /* if its internally mapped, we can write it in the descriptor itself */ 6714 if (*mapping == UDF_TRANS_INTERN) { 6715 /* TODO paranoia check if we ARE going to have enough space */ 6716 error = udf_write_internal(udf_node, (uint8_t *) buf->b_data); 6717 if (error) 6718 buf->b_error = error; 6719 biodone(buf); 6720 goto out; 6721 } 6722 DPRINTF(WRITE, ("\tnot intern\n")); 6723 6724 /* request write out of data to disc sheduler */ 6725 buf->b_resid = buf->b_bcount; 6726 for (lb_num = 0; lb_num < num_lb; lb_num++) { 6727 buf_offset = lb_num * lb_size; 6728 DPRINTF(WRITE, ("\tprocessing rel lb_num %d\n", lb_num)); 6729 6730 /* 6731 * Mappings are not that important here. Just before we write 6732 * the lb_num we late-allocate them when needed and update the 6733 * mapping in the udf_node. 6734 */ 6735 6736 /* XXX why not ignore the mapping altogether ? */ 6737 DPRINTF(WRITE, ("\twrite lb_num " 6738 "%"PRIu64, mapping[lb_num])); 6739 6740 lblkno = from + lb_num; 6741 run_start = mapping[lb_num]; 6742 run_length = 1; 6743 while (lb_num < num_lb-1) { 6744 if (mapping[lb_num+1] != mapping[lb_num]+1) 6745 if (mapping[lb_num+1] != mapping[lb_num]) 6746 break; 6747 run_length++; 6748 lb_num++; 6749 } 6750 DPRINTF(WRITE, ("+ %d\n", run_length)); 6751 6752 /* nest an iobuf on the master buffer for the extent */ 6753 rbuflen = run_length * lb_size; 6754 rblk = run_start * (lb_size/DEV_BSIZE); 6755 6756 nestbuf = getiobuf(NULL, true); 6757 nestiobuf_setup(buf, nestbuf, buf_offset, rbuflen); 6758 /* nestbuf is B_ASYNC */ 6759 6760 /* identify this nestbuf */ 6761 nestbuf->b_lblkno = lblkno; 6762 KASSERT(nestbuf->b_vp == udf_node->vnode); 6763 6764 /* CD shedules on raw blkno */ 6765 nestbuf->b_blkno = rblk; 6766 nestbuf->b_proc = NULL; 6767 nestbuf->b_rawblkno = rblk; 6768 nestbuf->b_udf_c_type = what; 6769 6770 /* increment our outstanding bufs counter */ 6771 s = splbio(); 6772 udf_node->outstanding_bufs++; 6773 splx(s); 6774 6775 udf_discstrat_queuebuf(ump, nestbuf); 6776 } 6777 out: 6778 /* if we're synchronously writing, wait for the completion */ 6779 if ((buf->b_flags & B_ASYNC) == 0) 6780 biowait(buf); 6781 6782 DPRINTF(WRITE, ("\tend of write_filebuf\n")); 6783 free(mapping, M_TEMP); 6784 return; 6785 } 6786 6787 /* --------------------------------------------------------------------- */ 6788 6789 6790