2 * Copyright 2009, 2010 Jeffrey W. Roberson <jeff@FreeBSD.org>
5 * Redistribution and use in source and binary forms, with or without
6 * modification, are permitted provided that the following conditions
8 * 1. Redistributions of source code must retain the above copyright
9 * notice, this list of conditions and the following disclaimer.
10 * 2. Redistributions in binary form must reproduce the above copyright
11 * notice, this list of conditions and the following disclaimer in the
12 * documentation and/or other materials provided with the distribution.
14 * THIS SOFTWARE IS PROVIDED BY THE AUTHORS AND CONTRIBUTORS ``AS IS'' AND
15 * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
16 * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
17 * ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHORS OR CONTRIBUTORS BE LIABLE
18 * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
19 * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
20 * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
21 * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
22 * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
23 * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
27 #include <sys/cdefs.h>
28 __FBSDID("$FreeBSD$");
30 #include <sys/param.h>
32 #include <sys/disklabel.h>
33 #include <sys/mount.h>
36 #include <ufs/ufs/ufsmount.h>
37 #include <ufs/ufs/dinode.h>
38 #include <ufs/ufs/dir.h>
39 #include <ufs/ffs/fs.h>
56 #define DOTDOT_OFFSET DIRECTSIZ(1)
57 #define SUJ_HASHSIZE 2048
58 #define SUJ_HASHMASK (SUJ_HASHSIZE - 1)
59 #define SUJ_HASH(x) ((x * 2654435761) & SUJ_HASHMASK)
62 TAILQ_ENTRY(suj_seg) ss_next;
63 struct jsegrec ss_rec;
68 TAILQ_ENTRY(suj_rec) sr_next;
71 TAILQ_HEAD(srechd, suj_rec);
74 LIST_ENTRY(suj_ino) si_next;
75 struct srechd si_recs;
76 struct srechd si_newrecs;
77 struct srechd si_movs;
78 struct jtrncrec *si_trunc;
89 LIST_HEAD(inohd, suj_ino);
92 LIST_ENTRY(suj_blk) sb_next;
93 struct srechd sb_recs;
96 LIST_HEAD(blkhd, suj_blk);
99 LIST_ENTRY(data_blk) db_next;
107 LIST_ENTRY(ino_blk) ib_next;
112 LIST_HEAD(iblkhd, ino_blk);
115 LIST_ENTRY(suj_cg) sc_next;
116 struct blkhd sc_blkhash[SUJ_HASHSIZE];
117 struct inohd sc_inohash[SUJ_HASHSIZE];
118 struct iblkhd sc_iblkhash[SUJ_HASHSIZE];
119 struct ino_blk *sc_lastiblk;
120 struct suj_ino *sc_lastino;
121 struct suj_blk *sc_lastblk;
128 LIST_HEAD(cghd, suj_cg) cghash[SUJ_HASHSIZE];
129 LIST_HEAD(dblkhd, data_blk) dbhash[SUJ_HASHSIZE];
130 struct suj_cg *lastcg;
131 struct data_blk *lastblk;
133 TAILQ_HEAD(seghd, suj_seg) allsegs;
135 static struct uufsd *disk = NULL;
136 static struct fs *fs = NULL;
140 * Summary statistics.
149 static jmp_buf jmpbuf;
151 typedef void (*ino_visitor)(ino_t, ufs_lbn_t, ufs2_daddr_t, int);
152 static void err_suj(const char *, ...) __dead2;
153 static void ino_trunc(ino_t, off_t);
154 static void ino_decr(ino_t);
155 static void ino_adjust(struct suj_ino *);
156 static void ino_build(struct suj_ino *);
157 static int blk_isfree(ufs2_daddr_t);
166 err(EX_OSERR, "malloc(%zu)", n);
171 * When hit a fatal error in journalling check, print out
172 * the error and then offer to fallback to normal fsck.
175 err_suj(const char * restrict fmt, ...)
180 (void)fprintf(stdout, "%s: ", cdevname);
183 (void)vfprintf(stdout, fmt, ap);
190 * Open the given provider, load superblock.
193 opendisk(const char *devnam)
197 disk = malloc(sizeof(*disk));
199 err(EX_OSERR, "malloc(%zu)", sizeof(*disk));
200 if (ufs_disk_fillout(disk, devnam) == -1) {
201 err(EX_OSERR, "ufs_disk_fillout(%s) failed: %s", devnam,
205 if (real_dev_bsize == 0 && ioctl(disk->d_fd, DIOCGSECTORSIZE,
206 &real_dev_bsize) == -1)
207 real_dev_bsize = secsize;
209 printf("dev_bsize %u\n", real_dev_bsize);
213 * Mark file system as clean, write the super-block back, close the disk.
216 closedisk(const char *devnam)
222 * Recompute the fs summary info from correct cs summaries.
224 bzero(&fs->fs_cstotal, sizeof(struct csum_total));
225 for (i = 0; i < fs->fs_ncg; i++) {
226 cgsum = &fs->fs_cs(fs, i);
227 fs->fs_cstotal.cs_nffree += cgsum->cs_nffree;
228 fs->fs_cstotal.cs_nbfree += cgsum->cs_nbfree;
229 fs->fs_cstotal.cs_nifree += cgsum->cs_nifree;
230 fs->fs_cstotal.cs_ndir += cgsum->cs_ndir;
232 fs->fs_pendinginodes = 0;
233 fs->fs_pendingblocks = 0;
235 fs->fs_time = time(NULL);
236 fs->fs_mtime = time(NULL);
237 if (sbwrite(disk, 0) == -1)
238 err(EX_OSERR, "sbwrite(%s)", devnam);
239 if (ufs_disk_close(disk) == -1)
240 err(EX_OSERR, "ufs_disk_close(%s)", devnam);
247 * Lookup a cg by number in the hash so we can keep track of which cgs
248 * need stats rebuilt.
250 static struct suj_cg *
256 if (cgx < 0 || cgx >= fs->fs_ncg)
257 err_suj("Bad cg number %d\n", cgx);
258 if (lastcg && lastcg->sc_cgx == cgx)
260 hd = &cghash[SUJ_HASH(cgx)];
261 LIST_FOREACH(sc, hd, sc_next)
262 if (sc->sc_cgx == cgx) {
266 sc = errmalloc(sizeof(*sc));
267 bzero(sc, sizeof(*sc));
268 sc->sc_cgbuf = errmalloc(fs->fs_bsize);
269 sc->sc_cgp = (struct cg *)sc->sc_cgbuf;
271 LIST_INSERT_HEAD(hd, sc, sc_next);
272 if (bread(disk, fsbtodb(fs, cgtod(fs, sc->sc_cgx)), sc->sc_cgbuf,
274 err_suj("Unable to read cylinder group %d\n", sc->sc_cgx);
280 * Lookup an inode number in the hash and allocate a suj_ino if it does
283 static struct suj_ino *
284 ino_lookup(ino_t ino, int creat)
286 struct suj_ino *sino;
290 sc = cg_lookup(ino_to_cg(fs, ino));
291 if (sc->sc_lastino && sc->sc_lastino->si_ino == ino)
292 return (sc->sc_lastino);
293 hd = &sc->sc_inohash[SUJ_HASH(ino)];
294 LIST_FOREACH(sino, hd, si_next)
295 if (sino->si_ino == ino)
299 sino = errmalloc(sizeof(*sino));
300 bzero(sino, sizeof(*sino));
302 TAILQ_INIT(&sino->si_recs);
303 TAILQ_INIT(&sino->si_newrecs);
304 TAILQ_INIT(&sino->si_movs);
305 LIST_INSERT_HEAD(hd, sino, si_next);
311 * Lookup a block number in the hash and allocate a suj_blk if it does
314 static struct suj_blk *
315 blk_lookup(ufs2_daddr_t blk, int creat)
317 struct suj_blk *sblk;
321 sc = cg_lookup(dtog(fs, blk));
322 if (sc->sc_lastblk && sc->sc_lastblk->sb_blk == blk)
323 return (sc->sc_lastblk);
324 hd = &sc->sc_blkhash[SUJ_HASH(fragstoblks(fs, blk))];
325 LIST_FOREACH(sblk, hd, sb_next)
326 if (sblk->sb_blk == blk)
330 sblk = errmalloc(sizeof(*sblk));
331 bzero(sblk, sizeof(*sblk));
333 TAILQ_INIT(&sblk->sb_recs);
334 LIST_INSERT_HEAD(hd, sblk, sb_next);
339 static struct data_blk *
340 dblk_lookup(ufs2_daddr_t blk)
342 struct data_blk *dblk;
345 hd = &dbhash[SUJ_HASH(fragstoblks(fs, blk))];
346 if (lastblk && lastblk->db_blk == blk)
348 LIST_FOREACH(dblk, hd, db_next)
349 if (dblk->db_blk == blk)
352 * The inode block wasn't located, allocate a new one.
354 dblk = errmalloc(sizeof(*dblk));
355 bzero(dblk, sizeof(*dblk));
356 LIST_INSERT_HEAD(hd, dblk, db_next);
362 dblk_read(ufs2_daddr_t blk, int size)
364 struct data_blk *dblk;
366 dblk = dblk_lookup(blk);
368 * I doubt size mismatches can happen in practice but it is trivial
371 if (size != dblk->db_size) {
374 dblk->db_buf = errmalloc(size);
375 dblk->db_size = size;
376 if (bread(disk, fsbtodb(fs, blk), dblk->db_buf, size) == -1)
377 err_suj("Failed to read data block %jd\n", blk);
379 return (dblk->db_buf);
383 dblk_dirty(ufs2_daddr_t blk)
385 struct data_blk *dblk;
387 dblk = dblk_lookup(blk);
394 struct data_blk *dblk;
397 for (i = 0; i < SUJ_HASHSIZE; i++) {
398 LIST_FOREACH(dblk, &dbhash[i], db_next) {
399 if (dblk->db_dirty == 0 || dblk->db_size == 0)
401 if (bwrite(disk, fsbtodb(fs, dblk->db_blk),
402 dblk->db_buf, dblk->db_size) == -1)
403 err_suj("Unable to write block %jd\n",
409 static union dinode *
412 struct ino_blk *iblk;
418 blk = ino_to_fsba(fs, ino);
419 sc = cg_lookup(ino_to_cg(fs, ino));
420 iblk = sc->sc_lastiblk;
421 if (iblk && iblk->ib_blk == blk)
423 hd = &sc->sc_iblkhash[SUJ_HASH(fragstoblks(fs, blk))];
424 LIST_FOREACH(iblk, hd, ib_next)
425 if (iblk->ib_blk == blk)
428 * The inode block wasn't located, allocate a new one.
430 iblk = errmalloc(sizeof(*iblk));
431 bzero(iblk, sizeof(*iblk));
432 iblk->ib_buf = errmalloc(fs->fs_bsize);
434 LIST_INSERT_HEAD(hd, iblk, ib_next);
435 if (bread(disk, fsbtodb(fs, blk), iblk->ib_buf, fs->fs_bsize) == -1)
436 err_suj("Failed to read inode block %jd\n", blk);
438 sc->sc_lastiblk = iblk;
439 off = ino_to_fsbo(fs, ino);
440 if (fs->fs_magic == FS_UFS1_MAGIC)
441 return (union dinode *)&((struct ufs1_dinode *)iblk->ib_buf)[off];
443 return (union dinode *)&((struct ufs2_dinode *)iblk->ib_buf)[off];
449 struct ino_blk *iblk;
454 blk = ino_to_fsba(fs, ino);
455 sc = cg_lookup(ino_to_cg(fs, ino));
456 iblk = sc->sc_lastiblk;
457 if (iblk && iblk->ib_blk == blk) {
461 hd = &sc->sc_iblkhash[SUJ_HASH(fragstoblks(fs, blk))];
462 LIST_FOREACH(iblk, hd, ib_next) {
463 if (iblk->ib_blk == blk) {
473 iblk_write(struct ino_blk *iblk)
476 if (iblk->ib_dirty == 0)
478 if (bwrite(disk, fsbtodb(fs, iblk->ib_blk), iblk->ib_buf,
480 err_suj("Failed to write inode block %jd\n", iblk->ib_blk);
484 blk_overlaps(struct jblkrec *brec, ufs2_daddr_t start, int frags)
491 bstart = brec->jb_blkno + brec->jb_oldfrags;
492 bend = bstart + brec->jb_frags;
493 if (start < bend && end > bstart)
499 blk_equals(struct jblkrec *brec, ino_t ino, ufs_lbn_t lbn, ufs2_daddr_t start,
503 if (brec->jb_ino != ino || brec->jb_lbn != lbn)
505 if (brec->jb_blkno + brec->jb_oldfrags != start)
507 if (brec->jb_frags != frags)
513 blk_setmask(struct jblkrec *brec, int *mask)
517 for (i = brec->jb_oldfrags; i < brec->jb_oldfrags + brec->jb_frags; i++)
522 * Determine whether a given block has been reallocated to a new location.
523 * Returns a mask of overlapping bits if any frags have been reused or
524 * zero if the block has not been re-used and the contents can be trusted.
526 * This is used to ensure that an orphaned pointer due to truncate is safe
527 * to be freed. The mask value can be used to free partial blocks.
530 blk_freemask(ufs2_daddr_t blk, ino_t ino, ufs_lbn_t lbn, int frags)
532 struct suj_blk *sblk;
533 struct suj_rec *srec;
534 struct jblkrec *brec;
539 * To be certain we're not freeing a reallocated block we lookup
540 * this block in the blk hash and see if there is an allocation
541 * journal record that overlaps with any fragments in the block
542 * we're concerned with. If any fragments have ben reallocated
543 * the block has already been freed and re-used for another purpose.
546 sblk = blk_lookup(blknum(fs, blk), 0);
549 off = blk - sblk->sb_blk;
550 TAILQ_FOREACH(srec, &sblk->sb_recs, sr_next) {
551 brec = (struct jblkrec *)srec->sr_rec;
553 * If the block overlaps but does not match
554 * exactly it's a new allocation. If it matches
555 * exactly this record refers to the current
558 if (blk_overlaps(brec, blk, frags) == 0)
560 if (blk_equals(brec, ino, lbn, blk, frags) == 1)
563 blk_setmask(brec, &mask);
566 printf("blk_freemask: blk %jd sblk %jd off %d mask 0x%X\n",
567 blk, sblk->sb_blk, off, mask);
568 return (mask >> off);
572 * Determine whether it is safe to follow an indirect. It is not safe
573 * if any part of the indirect has been reallocated or the last journal
574 * entry was an allocation. Just allocated indirects may not have valid
575 * pointers yet and all of their children will have their own records.
576 * It is also not safe to follow an indirect if the cg bitmap has been
577 * cleared as a new allocation may write to the block prior to the journal
580 * Returns 1 if it's safe to follow the indirect and 0 otherwise.
583 blk_isindir(ufs2_daddr_t blk, ino_t ino, ufs_lbn_t lbn)
585 struct suj_blk *sblk;
586 struct jblkrec *brec;
588 sblk = blk_lookup(blk, 0);
591 if (TAILQ_EMPTY(&sblk->sb_recs))
593 brec = (struct jblkrec *)TAILQ_LAST(&sblk->sb_recs, srechd)->sr_rec;
594 if (blk_equals(brec, ino, lbn, blk, fs->fs_frag))
595 if (brec->jb_op == JOP_FREEBLK)
596 return (!blk_isfree(blk));
601 * Clear an inode from the cg bitmap. If the inode was already clear return
602 * 0 so the caller knows it does not have to check the inode contents.
605 ino_free(ino_t ino, int mode)
612 cg = ino_to_cg(fs, ino);
613 ino = ino % fs->fs_ipg;
616 inosused = cg_inosused(cgp);
618 * The bitmap may never have made it to the disk so we have to
619 * conditionally clear. We can avoid writing the cg in this case.
621 if (isclr(inosused, ino))
624 clrbit(inosused, ino);
625 if (ino < cgp->cg_irotor)
626 cgp->cg_irotor = ino;
627 cgp->cg_cs.cs_nifree++;
628 if ((mode & IFMT) == IFDIR) {
630 cgp->cg_cs.cs_ndir--;
638 * Free 'frags' frags starting at filesystem block 'bno' skipping any frags
642 blk_free(ufs2_daddr_t bno, int mask, int frags)
644 ufs1_daddr_t fragno, cgbno;
651 printf("Freeing %d frags at blk %jd\n", frags, bno);
655 cgbno = dtogd(fs, bno);
656 blksfree = cg_blksfree(cgp);
659 * If it's not allocated we only wrote the journal entry
660 * and never the bitmaps. Here we unconditionally clear and
661 * resolve the cg summary later.
663 if (frags == fs->fs_frag && mask == 0) {
664 fragno = fragstoblks(fs, cgbno);
665 ffs_setblock(fs, blksfree, fragno);
669 * deallocate the fragment
671 for (i = 0; i < frags; i++)
672 if ((mask & (1 << i)) == 0 && isclr(blksfree, cgbno +i)) {
674 setbit(blksfree, cgbno + i);
681 * Returns 1 if the whole block starting at 'bno' is marked free and 0
685 blk_isfree(ufs2_daddr_t bno)
689 sc = cg_lookup(dtog(fs, bno));
690 return ffs_isblock(fs, cg_blksfree(sc->sc_cgp), dtogd(fs, bno));
694 * Fetch an indirect block to find the block at a given lbn. The lbn
695 * may be negative to fetch a specific indirect block pointer or positive
696 * to fetch a specific block.
699 indir_blkatoff(ufs2_daddr_t blk, ino_t ino, ufs_lbn_t cur, ufs_lbn_t lbn)
710 level = lbn_level(cur);
712 err_suj("Invalid indir lbn %jd\n", lbn);
713 if (level == 0 && lbn < 0)
714 err_suj("Invalid lbn %jd\n", lbn);
715 bap2 = (void *)dblk_read(blk, fs->fs_bsize);
718 base = -(cur + level);
719 for (i = level; i > 0; i--)
720 lbnadd *= NINDIR(fs);
722 i = (lbn - base) / lbnadd;
724 i = (-lbn - base) / lbnadd;
725 if (i < 0 || i >= NINDIR(fs))
726 err_suj("Invalid indirect index %d produced by lbn %jd\n",
729 cur = base + (i * lbnadd);
731 cur = -(base + (i * lbnadd)) - (level - 1);
732 if (fs->fs_magic == FS_UFS1_MAGIC)
739 err_suj("Invalid lbn %jd at level 0\n", lbn);
740 return indir_blkatoff(blk, ino, cur, lbn);
744 * Finds the disk block address at the specified lbn within the inode
745 * specified by ip. This follows the whole tree and honors di_size and
746 * di_extsize so it is a true test of reachability. The lbn may be
747 * negative if an extattr or indirect block is requested.
750 ino_blkatoff(union dinode *ip, ino_t ino, ufs_lbn_t lbn, int *frags)
758 * Handle extattr blocks first.
760 if (lbn < 0 && lbn >= -NXADDR) {
762 if (lbn > lblkno(fs, ip->dp2.di_extsize - 1))
764 *frags = numfrags(fs, sblksize(fs, ip->dp2.di_extsize, lbn));
765 return (ip->dp2.di_extb[lbn]);
768 * Now direct and indirect.
770 if (DIP(ip, di_mode) == IFLNK &&
771 DIP(ip, di_size) < fs->fs_maxsymlinklen)
773 if (lbn >= 0 && lbn < NDADDR) {
774 *frags = numfrags(fs, sblksize(fs, DIP(ip, di_size), lbn));
775 return (DIP(ip, di_db[lbn]));
777 *frags = fs->fs_frag;
779 for (i = 0, tmpval = NINDIR(fs), cur = NDADDR; i < NIADDR; i++,
780 tmpval *= NINDIR(fs), cur = next) {
783 return (DIP(ip, di_ib[i]));
785 * Determine whether the lbn in question is within this tree.
787 if (lbn < 0 && -lbn >= next)
789 if (lbn > 0 && lbn >= next)
791 return indir_blkatoff(DIP(ip, di_ib[i]), ino, -cur - i, lbn);
793 err_suj("lbn %jd not in ino\n", lbn);
798 * Determine whether a block exists at a particular lbn in an inode.
799 * Returns 1 if found, 0 if not. lbn may be negative for indirects
803 blk_isat(ino_t ino, ufs_lbn_t lbn, ufs2_daddr_t blk, int *frags)
810 if (DIP(ip, di_nlink) == 0 || DIP(ip, di_mode) == 0)
812 nblk = ino_blkatoff(ip, ino, lbn, frags);
814 return (nblk == blk);
818 * Clear the directory entry at diroff that should point to child. Minimal
819 * checking is done and it is assumed that this path was verified with isat.
822 ino_clrat(ino_t parent, off_t diroff, ino_t child)
834 printf("Clearing inode %d from parent %d at offset %jd\n",
835 child, parent, diroff);
837 lbn = lblkno(fs, diroff);
838 doff = blkoff(fs, diroff);
839 dip = ino_read(parent);
840 blk = ino_blkatoff(dip, parent, lbn, &frags);
841 blksize = sblksize(fs, DIP(dip, di_size), lbn);
842 block = dblk_read(blk, blksize);
843 dp = (struct direct *)&block[doff];
844 if (dp->d_ino != child)
845 errx(1, "Inode %d does not exist in %d at %jd",
846 child, parent, diroff);
850 * The actual .. reference count will already have been removed
851 * from the parent by the .. remref record.
856 * Determines whether a pointer to an inode exists within a directory
857 * at a specified offset. Returns the mode of the found entry.
860 ino_isat(ino_t parent, off_t diroff, ino_t child, int *mode, int *isdot)
873 dip = ino_read(parent);
874 *mode = DIP(dip, di_mode);
875 if ((*mode & IFMT) != IFDIR) {
878 * This can happen if the parent inode
882 printf("Directory %d has bad mode %o\n",
885 printf("Directory %d zero inode\n", parent);
889 lbn = lblkno(fs, diroff);
890 doff = blkoff(fs, diroff);
891 blksize = sblksize(fs, DIP(dip, di_size), lbn);
892 if (diroff + DIRECTSIZ(1) > DIP(dip, di_size) || doff >= blksize) {
894 printf("ino %d absent from %d due to offset %jd"
895 " exceeding size %jd\n",
896 child, parent, diroff, DIP(dip, di_size));
899 blk = ino_blkatoff(dip, parent, lbn, &frags);
902 printf("Sparse directory %d", parent);
905 block = dblk_read(blk, blksize);
907 * Walk through the records from the start of the block to be
908 * certain we hit a valid record and not some junk in the middle
909 * of a file name. Stop when we reach or pass the expected offset.
911 dpoff = (doff / DIRBLKSIZ) * DIRBLKSIZ;
913 dp = (struct direct *)&block[dpoff];
916 if (dp->d_reclen == 0)
918 dpoff += dp->d_reclen;
919 } while (dpoff <= doff);
920 if (dpoff > fs->fs_bsize)
921 err_suj("Corrupt directory block in dir ino %d\n", parent);
925 printf("ino %d not found in %d, lbn %jd, dpoff %d\n",
926 child, parent, lbn, dpoff);
930 * We found the item in question. Record the mode and whether it's
931 * a . or .. link for the caller.
933 if (dp->d_ino == child) {
936 else if (dp->d_namlen == 2 &&
937 dp->d_name[0] == '.' && dp->d_name[1] == '.')
939 *mode = DTTOIF(dp->d_type);
943 printf("ino %d doesn't match dirent ino %d in parent %d\n",
944 child, dp->d_ino, parent);
948 #define VISIT_INDIR 0x0001
949 #define VISIT_EXT 0x0002
950 #define VISIT_ROOT 0x0004 /* Operation came via root & valid pointers. */
953 * Read an indirect level which may or may not be linked into an inode.
956 indir_visit(ino_t ino, ufs_lbn_t lbn, ufs2_daddr_t blk, uint64_t *frags,
957 ino_visitor visitor, int flags)
968 * Don't visit indirect blocks with contents we can't trust. This
969 * should only happen when indir_visit() is called to complete a
970 * truncate that never finished and not when a pointer is found via
975 level = lbn_level(lbn);
977 err_suj("Invalid level for lbn %jd\n", lbn);
978 if ((flags & VISIT_ROOT) == 0 && blk_isindir(blk, ino, lbn) == 0) {
980 printf("blk %jd ino %d lbn %jd(%d) is not indir.\n",
981 blk, ino, lbn, level);
985 for (i = level; i > 0; i--)
986 lbnadd *= NINDIR(fs);
987 bap1 = (void *)dblk_read(blk, fs->fs_bsize);
989 for (i = 0; i < NINDIR(fs); i++) {
990 if (fs->fs_magic == FS_UFS1_MAGIC)
997 nlbn = -lbn + i * lbnadd;
998 (*frags) += fs->fs_frag;
999 visitor(ino, nlbn, nblk, fs->fs_frag);
1001 nlbn = (lbn + 1) - (i * lbnadd);
1002 indir_visit(ino, nlbn, nblk, frags, visitor, flags);
1006 if (flags & VISIT_INDIR) {
1007 (*frags) += fs->fs_frag;
1008 visitor(ino, lbn, blk, fs->fs_frag);
1013 * Visit each block in an inode as specified by 'flags' and call a
1014 * callback function. The callback may inspect or free blocks. The
1015 * count of frags found according to the size in the file is returned.
1016 * This is not valid for sparse files but may be used to determine
1017 * the correct di_blocks for a file.
1020 ino_visit(union dinode *ip, ino_t ino, ino_visitor visitor, int flags)
1031 size = DIP(ip, di_size);
1032 mode = DIP(ip, di_mode) & IFMT;
1034 if ((flags & VISIT_EXT) &&
1035 fs->fs_magic == FS_UFS2_MAGIC && ip->dp2.di_extsize) {
1036 for (i = 0; i < NXADDR; i++) {
1037 if (ip->dp2.di_extb[i] == 0)
1039 frags = sblksize(fs, ip->dp2.di_extsize, i);
1040 frags = numfrags(fs, frags);
1042 visitor(ino, -1 - i, ip->dp2.di_extb[i], frags);
1045 /* Skip datablocks for short links and devices. */
1046 if (mode == IFBLK || mode == IFCHR ||
1047 (mode == IFLNK && size < fs->fs_maxsymlinklen))
1049 for (i = 0; i < NDADDR; i++) {
1050 if (DIP(ip, di_db[i]) == 0)
1052 frags = sblksize(fs, size, i);
1053 frags = numfrags(fs, frags);
1055 visitor(ino, i, DIP(ip, di_db[i]), frags);
1058 * We know the following indirects are real as we're following
1059 * real pointers to them.
1061 flags |= VISIT_ROOT;
1062 for (i = 0, tmpval = NINDIR(fs), lbn = NDADDR; i < NIADDR; i++,
1064 nextlbn = lbn + tmpval;
1065 tmpval *= NINDIR(fs);
1066 if (DIP(ip, di_ib[i]) == 0)
1068 indir_visit(ino, -lbn - i, DIP(ip, di_ib[i]), &fragcnt, visitor,
1075 * Null visitor function used when we just want to count blocks and
1080 null_visit(ino_t ino, ufs_lbn_t lbn, ufs2_daddr_t blk, int frags)
1087 * Recalculate di_blocks when we discover that a block allocation or
1088 * free was not successfully completed. The kernel does not roll this back
1089 * because it would be too expensive to compute which indirects were
1090 * reachable at the time the inode was written.
1093 ino_adjblks(struct suj_ino *sino)
1104 /* No need to adjust zero'd inodes. */
1105 if (DIP(ip, di_mode) == 0)
1108 * Visit all blocks and count them as well as recording the last
1109 * valid lbn in the file. If the file size doesn't agree with the
1110 * last lbn we need to truncate to fix it. Otherwise just adjust
1114 frags = ino_visit(ip, ino, null_visit, VISIT_INDIR | VISIT_EXT);
1115 blocks = fsbtodb(fs, frags);
1117 * We assume the size and direct block list is kept coherent by
1118 * softdep. For files that have extended into indirects we truncate
1119 * to the size in the inode or the maximum size permitted by
1120 * populated indirects.
1122 if (visitlbn >= NDADDR) {
1123 isize = DIP(ip, di_size);
1124 size = lblktosize(fs, visitlbn + 1);
1127 /* Always truncate to free any unpopulated indirects. */
1128 ino_trunc(sino->si_ino, isize);
1131 if (blocks == DIP(ip, di_blocks))
1134 printf("ino %d adjusting block count from %jd to %jd\n",
1135 ino, DIP(ip, di_blocks), blocks);
1136 DIP_SET(ip, di_blocks, blocks);
1141 blk_free_visit(ino_t ino, ufs_lbn_t lbn, ufs2_daddr_t blk, int frags)
1145 mask = blk_freemask(blk, ino, lbn, frags);
1147 printf("blk %jd freemask 0x%X\n", blk, mask);
1148 blk_free(blk, mask, frags);
1152 * Free a block or tree of blocks that was previously rooted in ino at
1153 * the given lbn. If the lbn is an indirect all children are freed
1157 blk_free_lbn(ufs2_daddr_t blk, ino_t ino, ufs_lbn_t lbn, int frags, int follow)
1162 mask = blk_freemask(blk, ino, lbn, frags);
1164 printf("blk %jd freemask 0x%X\n", blk, mask);
1166 if (lbn <= -NDADDR && follow && mask == 0)
1167 indir_visit(ino, lbn, blk, &resid, blk_free_visit, VISIT_INDIR);
1169 blk_free(blk, mask, frags);
1173 ino_setskip(struct suj_ino *sino, ino_t parent)
1178 if (ino_isat(sino->si_ino, DOTDOT_OFFSET, parent, &mode, &isdot))
1179 sino->si_skipparent = 1;
1183 ino_remref(ino_t parent, ino_t child, uint64_t diroff, int isdotdot)
1185 struct suj_ino *sino;
1186 struct suj_rec *srec;
1187 struct jrefrec *rrec;
1190 * Lookup this inode to see if we have a record for it.
1192 sino = ino_lookup(child, 0);
1194 * Tell any child directories we've already removed their
1195 * parent link cnt. Don't try to adjust our link down again.
1197 if (sino != NULL && isdotdot == 0)
1198 ino_setskip(sino, parent);
1200 * No valid record for this inode. Just drop the on-disk
1203 if (sino == NULL || sino->si_hasrecs == 0) {
1208 * Use ino_adjust() if ino_check() has already processed this
1209 * child. If we lose the last non-dot reference to a
1210 * directory it will be discarded.
1212 if (sino->si_linkadj) {
1215 sino->si_dotlinks--;
1220 * If we haven't yet processed this inode we need to make
1221 * sure we will successfully discover the lost path. If not
1222 * use nlinkadj to remember.
1224 TAILQ_FOREACH(srec, &sino->si_recs, sr_next) {
1225 rrec = (struct jrefrec *)srec->sr_rec;
1226 if (rrec->jr_parent == parent &&
1227 rrec->jr_diroff == diroff)
1230 sino->si_nlinkadj++;
1234 * Free the children of a directory when the directory is discarded.
1237 ino_free_children(ino_t ino, ufs_lbn_t lbn, ufs2_daddr_t blk, int frags)
1239 struct suj_ino *sino;
1248 sino = ino_lookup(ino, 0);
1250 skipparent = sino->si_skipparent;
1253 size = lfragtosize(fs, frags);
1254 block = dblk_read(blk, size);
1255 dp = (struct direct *)&block[0];
1256 for (dpoff = 0; dpoff < size && dp->d_reclen; dpoff += dp->d_reclen) {
1257 dp = (struct direct *)&block[dpoff];
1258 if (dp->d_ino == 0 || dp->d_ino == WINO)
1260 if (dp->d_namlen == 1 && dp->d_name[0] == '.')
1262 isdotdot = dp->d_namlen == 2 && dp->d_name[0] == '.' &&
1263 dp->d_name[1] == '.';
1264 if (isdotdot && skipparent == 1)
1267 printf("Directory %d removing ino %d name %s\n",
1268 ino, dp->d_ino, dp->d_name);
1269 diroff = lblktosize(fs, lbn) + dpoff;
1270 ino_remref(ino, dp->d_ino, diroff, isdotdot);
1275 * Reclaim an inode, freeing all blocks and decrementing all children's
1276 * link counts. Free the inode back to the cg.
1279 ino_reclaim(union dinode *ip, ino_t ino, int mode)
1284 err_suj("Attempting to free ROOTINO\n");
1286 printf("Truncating and freeing ino %d, nlink %d, mode %o\n",
1287 ino, DIP(ip, di_nlink), DIP(ip, di_mode));
1289 /* We are freeing an inode or directory. */
1290 if ((DIP(ip, di_mode) & IFMT) == IFDIR)
1291 ino_visit(ip, ino, ino_free_children, 0);
1292 DIP_SET(ip, di_nlink, 0);
1293 ino_visit(ip, ino, blk_free_visit, VISIT_EXT | VISIT_INDIR);
1294 /* Here we have to clear the inode and release any blocks it holds. */
1295 gen = DIP(ip, di_gen);
1296 if (fs->fs_magic == FS_UFS1_MAGIC)
1297 bzero(ip, sizeof(struct ufs1_dinode));
1299 bzero(ip, sizeof(struct ufs2_dinode));
1300 DIP_SET(ip, di_gen, gen);
1302 ino_free(ino, mode);
1307 * Adjust an inode's link count down by one when a directory goes away.
1318 nlink = DIP(ip, di_nlink);
1319 mode = DIP(ip, di_mode);
1321 err_suj("Inode %d link count %d invalid\n", ino, nlink);
1323 err_suj("Inode %d has a link of %d with 0 mode\n", ino, nlink);
1325 if ((mode & IFMT) == IFDIR)
1329 if (nlink < reqlink) {
1331 printf("ino %d not enough links to live %d < %d\n",
1332 ino, nlink, reqlink);
1333 ino_reclaim(ip, ino, mode);
1336 DIP_SET(ip, di_nlink, nlink);
1341 * Adjust the inode link count to 'nlink'. If the count reaches zero
1345 ino_adjust(struct suj_ino *sino)
1347 struct jrefrec *rrec;
1348 struct suj_rec *srec;
1349 struct suj_ino *stmp;
1358 nlink = sino->si_nlink;
1360 mode = sino->si_mode & IFMT;
1362 * If it's a directory with no dot links, it was truncated before
1363 * the name was cleared. We need to clear the dirent that
1366 if (mode == IFDIR && nlink == 1 && sino->si_dotlinks == 0) {
1367 sino->si_nlink = nlink = 0;
1368 TAILQ_FOREACH(srec, &sino->si_recs, sr_next) {
1369 rrec = (struct jrefrec *)srec->sr_rec;
1370 if (ino_isat(rrec->jr_parent, rrec->jr_diroff, ino,
1371 &recmode, &isdot) == 0)
1373 ino_clrat(rrec->jr_parent, rrec->jr_diroff, ino);
1377 errx(1, "Directory %d name not found", ino);
1380 * If it's a directory with no real names pointing to it go ahead
1381 * and truncate it. This will free any children.
1383 if (mode == IFDIR && nlink - sino->si_dotlinks == 0) {
1384 sino->si_nlink = nlink = 0;
1386 * Mark any .. links so they know not to free this inode
1387 * when they are removed.
1389 TAILQ_FOREACH(srec, &sino->si_recs, sr_next) {
1390 rrec = (struct jrefrec *)srec->sr_rec;
1391 if (rrec->jr_diroff == DOTDOT_OFFSET) {
1392 stmp = ino_lookup(rrec->jr_parent, 0);
1394 ino_setskip(stmp, ino);
1399 mode = DIP(ip, di_mode) & IFMT;
1400 if (nlink > LINK_MAX)
1402 "ino %d nlink manipulation error, new link %d, old link %d\n",
1403 ino, nlink, DIP(ip, di_nlink));
1405 printf("Adjusting ino %d, nlink %d, old link %d lastmode %o\n",
1406 ino, nlink, DIP(ip, di_nlink), sino->si_mode);
1409 printf("ino %d, zero inode freeing bitmap\n", ino);
1410 ino_free(ino, sino->si_mode);
1413 /* XXX Should be an assert? */
1414 if (mode != sino->si_mode && debug)
1415 printf("ino %d, mode %o != %o\n", ino, mode, sino->si_mode);
1416 if ((mode & IFMT) == IFDIR)
1420 /* If the inode doesn't have enough links to live, free it. */
1421 if (nlink < reqlink) {
1423 printf("ino %d not enough links to live %d < %d\n",
1424 ino, nlink, reqlink);
1425 ino_reclaim(ip, ino, mode);
1428 /* If required write the updated link count. */
1429 if (DIP(ip, di_nlink) == nlink) {
1431 printf("ino %d, link matches, skipping.\n", ino);
1434 DIP_SET(ip, di_nlink, nlink);
1439 * Truncate some or all blocks in an indirect, freeing any that are required
1440 * and zeroing the indirect.
1443 indir_trunc(ino_t ino, ufs_lbn_t lbn, ufs2_daddr_t blk, ufs_lbn_t lastlbn)
1458 level = lbn_level(lbn);
1460 err_suj("Invalid level for lbn %jd\n", lbn);
1462 for (i = level; i > 0; i--)
1463 lbnadd *= NINDIR(fs);
1464 bap1 = (void *)dblk_read(blk, fs->fs_bsize);
1465 bap2 = (void *)bap1;
1466 for (i = 0; i < NINDIR(fs); i++) {
1467 if (fs->fs_magic == FS_UFS1_MAGIC)
1474 nlbn = (lbn + 1) - (i * lbnadd);
1476 * Calculate the lbn of the next indirect to
1477 * determine if any of this indirect must be
1480 next = -(lbn + level) + ((i+1) * lbnadd);
1481 if (next <= lastlbn)
1483 indir_trunc(ino, nlbn, nblk, lastlbn);
1484 /* If all of this indirect was reclaimed, free it. */
1485 nlbn = next - lbnadd;
1489 nlbn = -lbn + i * lbnadd;
1494 blk_free(nblk, 0, fs->fs_frag);
1495 if (fs->fs_magic == FS_UFS1_MAGIC)
1505 * Truncate an inode to the minimum of the given size or the last populated
1506 * block after any over size have been discarded. The kernel would allocate
1507 * the last block in the file but fsck does not and neither do we. This
1508 * code never extends files, only shrinks them.
1511 ino_trunc(ino_t ino, off_t size)
1515 uint64_t totalfrags;
1527 mode = DIP(ip, di_mode) & IFMT;
1528 cursize = DIP(ip, di_size);
1530 printf("Truncating ino %d, mode %o to size %jd from size %jd\n",
1531 ino, mode, size, cursize);
1533 /* Skip datablocks for short links and devices. */
1534 if (mode == 0 || mode == IFBLK || mode == IFCHR ||
1535 (mode == IFLNK && cursize < fs->fs_maxsymlinklen))
1540 lastlbn = lblkno(fs, blkroundup(fs, size));
1541 for (i = lastlbn; i < NDADDR; i++) {
1542 if (DIP(ip, di_db[i]) == 0)
1544 frags = sblksize(fs, cursize, i);
1545 frags = numfrags(fs, frags);
1546 blk_free(DIP(ip, di_db[i]), 0, frags);
1547 DIP_SET(ip, di_db[i], 0);
1550 * Follow indirect blocks, freeing anything required.
1552 for (i = 0, tmpval = NINDIR(fs), lbn = NDADDR; i < NIADDR; i++,
1554 nextlbn = lbn + tmpval;
1555 tmpval *= NINDIR(fs);
1556 /* If we're not freeing any in this indirect range skip it. */
1557 if (lastlbn >= nextlbn)
1559 if (DIP(ip, di_ib[i]) == 0)
1561 indir_trunc(ino, -lbn - i, DIP(ip, di_ib[i]), lastlbn);
1562 /* If we freed everything in this indirect free the indir. */
1565 blk_free(DIP(ip, di_ib[i]), 0, frags);
1566 DIP_SET(ip, di_ib[i], 0);
1570 * Now that we've freed any whole blocks that exceed the desired
1571 * truncation size, figure out how many blocks remain and what the
1572 * last populated lbn is. We will set the size to this last lbn
1573 * rather than worrying about allocating the final lbn as the kernel
1574 * would've done. This is consistent with normal fsck behavior.
1577 totalfrags = ino_visit(ip, ino, null_visit, VISIT_INDIR | VISIT_EXT);
1578 if (size > lblktosize(fs, visitlbn + 1))
1579 size = lblktosize(fs, visitlbn + 1);
1581 * If we're truncating direct blocks we have to adjust frags
1584 if (visitlbn < NDADDR && totalfrags) {
1585 long oldspace, newspace;
1587 bn = DIP(ip, di_db[visitlbn]);
1589 err_suj("Bad blk at ino %d lbn %jd\n", ino, visitlbn);
1590 oldspace = sblksize(fs, cursize, visitlbn);
1591 newspace = sblksize(fs, size, visitlbn);
1592 if (oldspace != newspace) {
1593 bn += numfrags(fs, newspace);
1594 frags = numfrags(fs, oldspace - newspace);
1595 blk_free(bn, 0, frags);
1596 totalfrags -= frags;
1599 DIP_SET(ip, di_blocks, fsbtodb(fs, totalfrags));
1600 DIP_SET(ip, di_size, size);
1602 * If we've truncated into the middle of a block or frag we have
1603 * to zero it here. Otherwise the file could extend into
1604 * uninitialized space later.
1606 off = blkoff(fs, size);
1607 if (off && DIP(ip, di_mode) != IFDIR) {
1611 bn = ino_blkatoff(ip, ino, visitlbn, &frags);
1613 err_suj("Block missing from ino %d at lbn %jd\n",
1615 clrsize = frags * fs->fs_fsize;
1616 buf = dblk_read(bn, clrsize);
1619 bzero(buf, clrsize);
1626 * Process records available for one inode and determine whether the
1627 * link count is correct or needs adjusting.
1630 ino_check(struct suj_ino *sino)
1632 struct suj_rec *srec;
1633 struct jrefrec *rrec;
1643 if (sino->si_hasrecs == 0)
1646 rrec = (struct jrefrec *)TAILQ_FIRST(&sino->si_recs)->sr_rec;
1647 nlink = rrec->jr_nlink;
1650 removes = sino->si_nlinkadj;
1651 TAILQ_FOREACH(srec, &sino->si_recs, sr_next) {
1652 rrec = (struct jrefrec *)srec->sr_rec;
1653 isat = ino_isat(rrec->jr_parent, rrec->jr_diroff,
1654 rrec->jr_ino, &mode, &isdot);
1655 if (isat && (mode & IFMT) != (rrec->jr_mode & IFMT))
1656 err_suj("Inode mode/directory type mismatch %o != %o\n",
1657 mode, rrec->jr_mode);
1659 printf("jrefrec: op %d ino %d, nlink %d, parent %d, "
1660 "diroff %jd, mode %o, isat %d, isdot %d\n",
1661 rrec->jr_op, rrec->jr_ino, rrec->jr_nlink,
1662 rrec->jr_parent, rrec->jr_diroff, rrec->jr_mode,
1664 mode = rrec->jr_mode & IFMT;
1665 if (rrec->jr_op == JOP_REMREF)
1672 * The number of links that remain are the starting link count
1673 * subtracted by the total number of removes with the total
1674 * links discovered back in. An incomplete remove thus
1675 * makes no change to the link count but an add increases
1679 printf("ino %d nlink %d newlinks %d removes %d dotlinks %d\n",
1680 ino, nlink, newlinks, removes, dotlinks);
1683 sino->si_linkadj = 1;
1684 sino->si_nlink = nlink;
1685 sino->si_dotlinks = dotlinks;
1686 sino->si_mode = mode;
1691 * Process records available for one block and determine whether it is
1692 * still allocated and whether the owning inode needs to be updated or
1696 blk_check(struct suj_blk *sblk)
1698 struct suj_rec *srec;
1699 struct jblkrec *brec;
1700 struct suj_ino *sino;
1707 * Each suj_blk actually contains records for any fragments in that
1708 * block. As a result we must evaluate each record individually.
1711 TAILQ_FOREACH(srec, &sblk->sb_recs, sr_next) {
1712 brec = (struct jblkrec *)srec->sr_rec;
1713 frags = brec->jb_frags;
1714 blk = brec->jb_blkno + brec->jb_oldfrags;
1715 isat = blk_isat(brec->jb_ino, brec->jb_lbn, blk, &frags);
1716 if (sino == NULL || sino->si_ino != brec->jb_ino) {
1717 sino = ino_lookup(brec->jb_ino, 1);
1718 sino->si_blkadj = 1;
1721 printf("op %d blk %jd ino %d lbn %jd frags %d isat %d (%d)\n",
1722 brec->jb_op, blk, brec->jb_ino, brec->jb_lbn,
1723 brec->jb_frags, isat, frags);
1725 * If we found the block at this address we still have to
1726 * determine if we need to free the tail end that was
1727 * added by adding contiguous fragments from the same block.
1730 if (frags == brec->jb_frags)
1732 mask = blk_freemask(blk, brec->jb_ino, brec->jb_lbn,
1736 frags = brec->jb_frags - frags;
1737 blk_free(blk, mask, frags);
1741 * The block wasn't found, attempt to free it. It won't be
1742 * freed if it was actually reallocated. If this was an
1743 * allocation we don't want to follow indirects as they
1744 * may not be written yet. Any children of the indirect will
1745 * have their own records. If it's a free we need to
1746 * recursively free children.
1748 blk_free_lbn(blk, brec->jb_ino, brec->jb_lbn, brec->jb_frags,
1749 brec->jb_op == JOP_FREEBLK);
1754 * Walk the list of inode records for this cg and resolve moved and duplicate
1755 * inode references now that we have a complete picture.
1758 cg_build(struct suj_cg *sc)
1760 struct suj_ino *sino;
1763 for (i = 0; i < SUJ_HASHSIZE; i++)
1764 LIST_FOREACH(sino, &sc->sc_inohash[i], si_next)
1769 * Handle inodes requiring truncation. This must be done prior to
1770 * looking up any inodes in directories.
1773 cg_trunc(struct suj_cg *sc)
1775 struct suj_ino *sino;
1778 for (i = 0; i < SUJ_HASHSIZE; i++) {
1779 LIST_FOREACH(sino, &sc->sc_inohash[i], si_next) {
1780 if (sino->si_trunc) {
1781 ino_trunc(sino->si_ino,
1782 sino->si_trunc->jt_size);
1783 sino->si_blkadj = 0;
1784 sino->si_trunc = NULL;
1786 if (sino->si_blkadj)
1793 cg_adj_blk(struct suj_cg *sc)
1795 struct suj_ino *sino;
1798 for (i = 0; i < SUJ_HASHSIZE; i++) {
1799 LIST_FOREACH(sino, &sc->sc_inohash[i], si_next) {
1800 if (sino->si_blkadj)
1807 * Free any partially allocated blocks and then resolve inode block
1811 cg_check_blk(struct suj_cg *sc)
1813 struct suj_blk *sblk;
1817 for (i = 0; i < SUJ_HASHSIZE; i++)
1818 LIST_FOREACH(sblk, &sc->sc_blkhash[i], sb_next)
1823 * Walk the list of inode records for this cg, recovering any
1824 * changes which were not complete at the time of crash.
1827 cg_check_ino(struct suj_cg *sc)
1829 struct suj_ino *sino;
1832 for (i = 0; i < SUJ_HASHSIZE; i++)
1833 LIST_FOREACH(sino, &sc->sc_inohash[i], si_next)
1838 * Write a potentially dirty cg. Recalculate the summary information and
1839 * update the superblock summary.
1842 cg_write(struct suj_cg *sc)
1844 ufs1_daddr_t fragno, cgbno, maxbno;
1850 if (sc->sc_dirty == 0)
1853 * Fix the frag and cluster summary.
1856 cgp->cg_cs.cs_nbfree = 0;
1857 cgp->cg_cs.cs_nffree = 0;
1858 bzero(&cgp->cg_frsum, sizeof(cgp->cg_frsum));
1859 maxbno = fragstoblks(fs, fs->fs_fpg);
1860 if (fs->fs_contigsumsize > 0) {
1861 for (i = 1; i <= fs->fs_contigsumsize; i++)
1862 cg_clustersum(cgp)[i] = 0;
1863 bzero(cg_clustersfree(cgp), howmany(maxbno, CHAR_BIT));
1865 blksfree = cg_blksfree(cgp);
1866 for (cgbno = 0; cgbno < maxbno; cgbno++) {
1867 if (ffs_isfreeblock(fs, blksfree, cgbno))
1869 if (ffs_isblock(fs, blksfree, cgbno)) {
1870 ffs_clusteracct(fs, cgp, cgbno, 1);
1871 cgp->cg_cs.cs_nbfree++;
1874 fragno = blkstofrags(fs, cgbno);
1875 blk = blkmap(fs, blksfree, fragno);
1876 ffs_fragacct(fs, blk, cgp->cg_frsum, 1);
1877 for (i = 0; i < fs->fs_frag; i++)
1878 if (isset(blksfree, fragno + i))
1879 cgp->cg_cs.cs_nffree++;
1882 * Update the superblock cg summary from our now correct values
1883 * before writing the block.
1885 fs->fs_cs(fs, sc->sc_cgx) = cgp->cg_cs;
1886 if (bwrite(disk, fsbtodb(fs, cgtod(fs, sc->sc_cgx)), sc->sc_cgbuf,
1887 fs->fs_bsize) == -1)
1888 err_suj("Unable to write cylinder group %d\n", sc->sc_cgx);
1892 * Write out any modified inodes.
1895 cg_write_inos(struct suj_cg *sc)
1897 struct ino_blk *iblk;
1900 for (i = 0; i < SUJ_HASHSIZE; i++)
1901 LIST_FOREACH(iblk, &sc->sc_iblkhash[i], ib_next)
1907 cg_apply(void (*apply)(struct suj_cg *))
1912 for (i = 0; i < SUJ_HASHSIZE; i++)
1913 LIST_FOREACH(scg, &cghash[i], sc_next)
1918 * Process the unlinked but referenced file list. Freeing all inodes.
1928 ino = fs->fs_sujfree;
1932 mode = DIP(ip, di_mode) & IFMT;
1933 inon = DIP(ip, di_freelink);
1934 DIP_SET(ip, di_freelink, 0);
1936 * XXX Should this be an errx?
1938 if (DIP(ip, di_nlink) == 0) {
1940 printf("Freeing unlinked ino %d mode %o\n",
1942 ino_reclaim(ip, ino, mode);
1944 printf("Skipping ino %d mode %o with link %d\n",
1945 ino, mode, DIP(ip, di_nlink));
1951 * Append a new record to the list of records requiring processing.
1954 ino_append(union jrec *rec)
1956 struct jrefrec *refrec;
1957 struct jmvrec *mvrec;
1958 struct suj_ino *sino;
1959 struct suj_rec *srec;
1961 mvrec = &rec->rec_jmvrec;
1962 refrec = &rec->rec_jrefrec;
1963 if (debug && mvrec->jm_op == JOP_MVREF)
1964 printf("ino move: ino %d, parent %d, diroff %jd, oldoff %jd\n",
1965 mvrec->jm_ino, mvrec->jm_parent, mvrec->jm_newoff,
1968 (refrec->jr_op == JOP_ADDREF || refrec->jr_op == JOP_REMREF))
1969 printf("ino ref: op %d, ino %d, nlink %d, "
1970 "parent %d, diroff %jd\n",
1971 refrec->jr_op, refrec->jr_ino, refrec->jr_nlink,
1972 refrec->jr_parent, refrec->jr_diroff);
1973 sino = ino_lookup(((struct jrefrec *)rec)->jr_ino, 1);
1974 sino->si_hasrecs = 1;
1975 srec = errmalloc(sizeof(*srec));
1977 TAILQ_INSERT_TAIL(&sino->si_newrecs, srec, sr_next);
1981 * Add a reference adjustment to the sino list and eliminate dups. The
1982 * primary loop in ino_build_ref() checks for dups but new ones may be
1983 * created as a result of offset adjustments.
1986 ino_add_ref(struct suj_ino *sino, struct suj_rec *srec)
1988 struct jrefrec *refrec;
1989 struct suj_rec *srn;
1990 struct jrefrec *rrn;
1992 refrec = (struct jrefrec *)srec->sr_rec;
1994 * We walk backwards so that the oldest link count is preserved. If
1995 * an add record conflicts with a remove keep the remove. Redundant
1996 * removes are eliminated in ino_build_ref. Otherwise we keep the
1997 * oldest record at a given location.
1999 for (srn = TAILQ_LAST(&sino->si_recs, srechd); srn;
2000 srn = TAILQ_PREV(srn, srechd, sr_next)) {
2001 rrn = (struct jrefrec *)srn->sr_rec;
2002 if (rrn->jr_parent != refrec->jr_parent ||
2003 rrn->jr_diroff != refrec->jr_diroff)
2005 if (rrn->jr_op == JOP_REMREF || refrec->jr_op == JOP_ADDREF) {
2006 rrn->jr_mode = refrec->jr_mode;
2012 * Replace the record in place with the old nlink in case
2013 * we replace the head of the list. Abandon srec as a dup.
2015 refrec->jr_nlink = rrn->jr_nlink;
2016 srn->sr_rec = srec->sr_rec;
2019 TAILQ_INSERT_TAIL(&sino->si_recs, srec, sr_next);
2023 * Create a duplicate of a reference at a previous location.
2026 ino_dup_ref(struct suj_ino *sino, struct jrefrec *refrec, off_t diroff)
2028 struct jrefrec *rrn;
2029 struct suj_rec *srn;
2031 rrn = errmalloc(sizeof(*refrec));
2033 rrn->jr_op = JOP_ADDREF;
2034 rrn->jr_diroff = diroff;
2035 srn = errmalloc(sizeof(*srn));
2036 srn->sr_rec = (union jrec *)rrn;
2037 ino_add_ref(sino, srn);
2041 * Add a reference to the list at all known locations. We follow the offset
2042 * changes for a single instance and create duplicate add refs at each so
2043 * that we can tolerate any version of the directory block. Eliminate
2044 * removes which collide with adds that are seen in the journal. They should
2045 * not adjust the link count down.
2048 ino_build_ref(struct suj_ino *sino, struct suj_rec *srec)
2050 struct jrefrec *refrec;
2051 struct jmvrec *mvrec;
2052 struct suj_rec *srp;
2053 struct suj_rec *srn;
2054 struct jrefrec *rrn;
2057 refrec = (struct jrefrec *)srec->sr_rec;
2059 * Search for a mvrec that matches this offset. Whether it's an add
2060 * or a remove we can delete the mvref after creating a dup record in
2063 if (!TAILQ_EMPTY(&sino->si_movs)) {
2064 diroff = refrec->jr_diroff;
2065 for (srn = TAILQ_LAST(&sino->si_movs, srechd); srn; srn = srp) {
2066 srp = TAILQ_PREV(srn, srechd, sr_next);
2067 mvrec = (struct jmvrec *)srn->sr_rec;
2068 if (mvrec->jm_parent != refrec->jr_parent ||
2069 mvrec->jm_newoff != diroff)
2071 diroff = mvrec->jm_oldoff;
2072 TAILQ_REMOVE(&sino->si_movs, srn, sr_next);
2074 ino_dup_ref(sino, refrec, diroff);
2078 * If a remove wasn't eliminated by an earlier add just append it to
2081 if (refrec->jr_op == JOP_REMREF) {
2082 ino_add_ref(sino, srec);
2086 * Walk the list of records waiting to be added to the list. We
2087 * must check for moves that apply to our current offset and remove
2088 * them from the list. Remove any duplicates to eliminate removes
2089 * with corresponding adds.
2091 TAILQ_FOREACH_SAFE(srn, &sino->si_newrecs, sr_next, srp) {
2092 switch (srn->sr_rec->rec_jrefrec.jr_op) {
2095 * This should actually be an error we should
2096 * have a remove for every add journaled.
2098 rrn = (struct jrefrec *)srn->sr_rec;
2099 if (rrn->jr_parent != refrec->jr_parent ||
2100 rrn->jr_diroff != refrec->jr_diroff)
2102 TAILQ_REMOVE(&sino->si_newrecs, srn, sr_next);
2106 * Once we remove the current iteration of the
2107 * record at this address we're done.
2109 rrn = (struct jrefrec *)srn->sr_rec;
2110 if (rrn->jr_parent != refrec->jr_parent ||
2111 rrn->jr_diroff != refrec->jr_diroff)
2113 TAILQ_REMOVE(&sino->si_newrecs, srn, sr_next);
2114 ino_add_ref(sino, srec);
2118 * Update our diroff based on any moves that match
2119 * and remove the move.
2121 mvrec = (struct jmvrec *)srn->sr_rec;
2122 if (mvrec->jm_parent != refrec->jr_parent ||
2123 mvrec->jm_oldoff != refrec->jr_diroff)
2125 ino_dup_ref(sino, refrec, mvrec->jm_oldoff);
2126 refrec->jr_diroff = mvrec->jm_newoff;
2127 TAILQ_REMOVE(&sino->si_newrecs, srn, sr_next);
2130 err_suj("ino_build_ref: Unknown op %d\n",
2131 srn->sr_rec->rec_jrefrec.jr_op);
2134 ino_add_ref(sino, srec);
2138 * Walk the list of new records and add them in-order resolving any
2139 * dups and adjusted offsets.
2142 ino_build(struct suj_ino *sino)
2144 struct suj_rec *srec;
2146 while ((srec = TAILQ_FIRST(&sino->si_newrecs)) != NULL) {
2147 TAILQ_REMOVE(&sino->si_newrecs, srec, sr_next);
2148 switch (srec->sr_rec->rec_jrefrec.jr_op) {
2151 ino_build_ref(sino, srec);
2155 * Add this mvrec to the queue of pending mvs.
2157 TAILQ_INSERT_TAIL(&sino->si_movs, srec, sr_next);
2160 err_suj("ino_build: Unknown op %d\n",
2161 srec->sr_rec->rec_jrefrec.jr_op);
2164 if (TAILQ_EMPTY(&sino->si_recs))
2165 sino->si_hasrecs = 0;
2169 * Modify journal records so they refer to the base block number
2170 * and a start and end frag range. This is to facilitate the discovery
2171 * of overlapping fragment allocations.
2174 blk_build(struct jblkrec *blkrec)
2176 struct suj_rec *srec;
2177 struct suj_blk *sblk;
2178 struct jblkrec *blkrn;
2183 printf("blk_build: op %d blkno %jd frags %d oldfrags %d "
2185 blkrec->jb_op, blkrec->jb_blkno, blkrec->jb_frags,
2186 blkrec->jb_oldfrags, blkrec->jb_ino, blkrec->jb_lbn);
2188 blk = blknum(fs, blkrec->jb_blkno);
2189 frag = fragnum(fs, blkrec->jb_blkno);
2190 sblk = blk_lookup(blk, 1);
2192 * Rewrite the record using oldfrags to indicate the offset into
2193 * the block. Leave jb_frags as the actual allocated count.
2195 blkrec->jb_blkno -= frag;
2196 blkrec->jb_oldfrags = frag;
2197 if (blkrec->jb_oldfrags + blkrec->jb_frags > fs->fs_frag)
2198 err_suj("Invalid fragment count %d oldfrags %d\n",
2199 blkrec->jb_frags, frag);
2201 * Detect dups. If we detect a dup we always discard the oldest
2202 * record as it is superseded by the new record. This speeds up
2203 * later stages but also eliminates free records which are used
2204 * to indicate that the contents of indirects can be trusted.
2206 TAILQ_FOREACH(srec, &sblk->sb_recs, sr_next) {
2207 blkrn = (struct jblkrec *)srec->sr_rec;
2208 if (blkrn->jb_ino != blkrec->jb_ino ||
2209 blkrn->jb_lbn != blkrec->jb_lbn ||
2210 blkrn->jb_blkno != blkrec->jb_blkno ||
2211 blkrn->jb_frags != blkrec->jb_frags ||
2212 blkrn->jb_oldfrags != blkrec->jb_oldfrags)
2215 printf("Removed dup.\n");
2216 /* Discard the free which is a dup with an alloc. */
2217 if (blkrec->jb_op == JOP_FREEBLK)
2219 TAILQ_REMOVE(&sblk->sb_recs, srec, sr_next);
2223 srec = errmalloc(sizeof(*srec));
2224 srec->sr_rec = (union jrec *)blkrec;
2225 TAILQ_INSERT_TAIL(&sblk->sb_recs, srec, sr_next);
2229 ino_build_trunc(struct jtrncrec *rec)
2231 struct suj_ino *sino;
2234 printf("ino_build_trunc: op %d ino %d, size %jd\n",
2235 rec->jt_op, rec->jt_ino, rec->jt_size);
2236 sino = ino_lookup(rec->jt_ino, 1);
2237 if (rec->jt_op == JOP_SYNC) {
2238 sino->si_trunc = NULL;
2241 if (sino->si_trunc == NULL || sino->si_trunc->jt_size > rec->jt_size)
2242 sino->si_trunc = rec;
2246 * Build up tables of the operations we need to recover.
2251 struct suj_seg *seg;
2256 TAILQ_FOREACH(seg, &allsegs, ss_next) {
2258 printf("seg %jd has %d records, oldseq %jd.\n",
2259 seg->ss_rec.jsr_seq, seg->ss_rec.jsr_cnt,
2260 seg->ss_rec.jsr_oldest);
2262 rec = (union jrec *)seg->ss_blk;
2263 for (i = 0; i < seg->ss_rec.jsr_cnt; off += JREC_SIZE, rec++) {
2264 /* skip the segrec. */
2265 if ((off % real_dev_bsize) == 0)
2267 switch (rec->rec_jrefrec.jr_op) {
2275 blk_build((struct jblkrec *)rec);
2279 ino_build_trunc((struct jtrncrec *)rec);
2282 err_suj("Unknown journal operation %d (%d)\n",
2283 rec->rec_jrefrec.jr_op, off);
2291 * Prune the journal segments to those we care about based on the
2292 * oldest sequence in the newest segment. Order the segment list
2293 * based on sequence number.
2298 struct suj_seg *seg;
2299 struct suj_seg *segn;
2304 printf("Pruning up to %jd\n", oldseq);
2305 /* First free the expired segments. */
2306 TAILQ_FOREACH_SAFE(seg, &allsegs, ss_next, segn) {
2307 if (seg->ss_rec.jsr_seq >= oldseq)
2309 TAILQ_REMOVE(&allsegs, seg, ss_next);
2313 /* Next ensure that segments are ordered properly. */
2314 seg = TAILQ_FIRST(&allsegs);
2317 printf("Empty journal\n");
2320 newseq = seg->ss_rec.jsr_seq;
2322 seg = TAILQ_LAST(&allsegs, seghd);
2323 if (seg->ss_rec.jsr_seq >= newseq)
2325 TAILQ_REMOVE(&allsegs, seg, ss_next);
2326 TAILQ_INSERT_HEAD(&allsegs, seg, ss_next);
2327 newseq = seg->ss_rec.jsr_seq;
2330 if (newseq != oldseq) {
2331 err_suj("Journal file sequence mismatch %jd != %jd\n",
2335 * The kernel may asynchronously write segments which can create
2336 * gaps in the sequence space. Throw away any segments after the
2337 * gap as the kernel guarantees only those that are contiguously
2338 * reachable are marked as completed.
2341 TAILQ_FOREACH_SAFE(seg, &allsegs, ss_next, segn) {
2342 if (!discard && newseq++ == seg->ss_rec.jsr_seq) {
2343 jrecs += seg->ss_rec.jsr_cnt;
2344 jbytes += seg->ss_rec.jsr_blocks * real_dev_bsize;
2349 printf("Journal order mismatch %jd != %jd pruning\n",
2350 newseq-1, seg->ss_rec.jsr_seq);
2351 TAILQ_REMOVE(&allsegs, seg, ss_next);
2356 printf("Processing journal segments from %jd to %jd\n",
2361 * Verify the journal inode before attempting to read records.
2364 suj_verifyino(union dinode *ip)
2367 if (DIP(ip, di_nlink) != 1) {
2368 printf("Invalid link count %d for journal inode %d\n",
2369 DIP(ip, di_nlink), sujino);
2373 if ((DIP(ip, di_flags) & (SF_IMMUTABLE | SF_NOUNLINK)) !=
2374 (SF_IMMUTABLE | SF_NOUNLINK)) {
2375 printf("Invalid flags 0x%X for journal inode %d\n",
2376 DIP(ip, di_flags), sujino);
2380 if (DIP(ip, di_mode) != (IFREG | IREAD)) {
2381 printf("Invalid mode %o for journal inode %d\n",
2382 DIP(ip, di_mode), sujino);
2386 if (DIP(ip, di_size) < SUJ_MIN || DIP(ip, di_size) > SUJ_MAX) {
2387 printf("Invalid size %jd for journal inode %d\n",
2388 DIP(ip, di_size), sujino);
2392 if (DIP(ip, di_modrev) != fs->fs_mtime) {
2393 printf("Journal timestamp does not match fs mount time\n");
2401 struct jextent *jb_extent; /* Extent array. */
2402 int jb_avail; /* Available extents. */
2403 int jb_used; /* Last used extent. */
2404 int jb_head; /* Allocator head. */
2405 int jb_off; /* Allocator extent offset. */
2408 ufs2_daddr_t je_daddr; /* Disk block address. */
2409 int je_blocks; /* Disk block count. */
2412 struct jblocks *suj_jblocks;
2414 static struct jblocks *
2415 jblocks_create(void)
2417 struct jblocks *jblocks;
2420 jblocks = errmalloc(sizeof(*jblocks));
2421 jblocks->jb_avail = 10;
2422 jblocks->jb_used = 0;
2423 jblocks->jb_head = 0;
2424 jblocks->jb_off = 0;
2425 size = sizeof(struct jextent) * jblocks->jb_avail;
2426 jblocks->jb_extent = errmalloc(size);
2427 bzero(jblocks->jb_extent, size);
2433 * Return the next available disk block and the amount of contiguous
2434 * free space it contains.
2437 jblocks_next(struct jblocks *jblocks, int bytes, int *actual)
2439 struct jextent *jext;
2444 blocks = bytes / disk->d_bsize;
2445 jext = &jblocks->jb_extent[jblocks->jb_head];
2446 freecnt = jext->je_blocks - jblocks->jb_off;
2448 jblocks->jb_off = 0;
2449 if (++jblocks->jb_head > jblocks->jb_used)
2451 jext = &jblocks->jb_extent[jblocks->jb_head];
2452 freecnt = jext->je_blocks;
2454 if (freecnt > blocks)
2456 *actual = freecnt * disk->d_bsize;
2457 daddr = jext->je_daddr + jblocks->jb_off;
2463 * Advance the allocation head by a specified number of bytes, consuming
2464 * one journal segment.
2467 jblocks_advance(struct jblocks *jblocks, int bytes)
2470 jblocks->jb_off += bytes / disk->d_bsize;
2474 jblocks_destroy(struct jblocks *jblocks)
2477 free(jblocks->jb_extent);
2482 jblocks_add(struct jblocks *jblocks, ufs2_daddr_t daddr, int blocks)
2484 struct jextent *jext;
2487 jext = &jblocks->jb_extent[jblocks->jb_used];
2488 /* Adding the first block. */
2489 if (jext->je_daddr == 0) {
2490 jext->je_daddr = daddr;
2491 jext->je_blocks = blocks;
2494 /* Extending the last extent. */
2495 if (jext->je_daddr + jext->je_blocks == daddr) {
2496 jext->je_blocks += blocks;
2499 /* Adding a new extent. */
2500 if (++jblocks->jb_used == jblocks->jb_avail) {
2501 jblocks->jb_avail *= 2;
2502 size = sizeof(struct jextent) * jblocks->jb_avail;
2503 jext = errmalloc(size);
2505 bcopy(jblocks->jb_extent, jext,
2506 sizeof(struct jextent) * jblocks->jb_used);
2507 free(jblocks->jb_extent);
2508 jblocks->jb_extent = jext;
2510 jext = &jblocks->jb_extent[jblocks->jb_used];
2511 jext->je_daddr = daddr;
2512 jext->je_blocks = blocks;
2518 * Add a file block from the journal to the extent map. We can't read
2519 * each file block individually because the kernel treats it as a circular
2520 * buffer and segments may span mutliple contiguous blocks.
2523 suj_add_block(ino_t ino, ufs_lbn_t lbn, ufs2_daddr_t blk, int frags)
2526 jblocks_add(suj_jblocks, fsbtodb(fs, blk), fsbtodb(fs, frags));
2532 uint8_t block[1 * 1024 * 1024];
2533 struct suj_seg *seg;
2534 struct jsegrec *recn;
2535 struct jsegrec *rec;
2544 * Read records until we exhaust the journal space. If we find
2545 * an invalid record we start searching for a valid segment header
2546 * at the next block. This is because we don't have a head/tail
2547 * pointer and must recover the information indirectly. At the gap
2548 * between the head and tail we won't necessarily have a valid
2553 size = sizeof(block);
2554 blk = jblocks_next(suj_jblocks, size, &readsize);
2559 * Read 1MB at a time and scan for records within this block.
2561 if (bread(disk, blk, &block, size) == -1) {
2562 err_suj("Error reading journal block %jd\n",
2565 for (rec = (void *)block; size; size -= recsize,
2566 rec = (struct jsegrec *)((uintptr_t)rec + recsize)) {
2567 recsize = real_dev_bsize;
2568 if (rec->jsr_time != fs->fs_mtime) {
2570 printf("Rec time %jd != fs mtime %jd\n",
2571 rec->jsr_time, fs->fs_mtime);
2572 jblocks_advance(suj_jblocks, recsize);
2575 if (rec->jsr_cnt == 0) {
2577 printf("Found illegal count %d\n",
2579 jblocks_advance(suj_jblocks, recsize);
2582 blocks = rec->jsr_blocks;
2583 recsize = blocks * real_dev_bsize;
2584 if (recsize > size) {
2586 * We may just have run out of buffer, restart
2587 * the loop to re-read from this spot.
2589 if (size < fs->fs_bsize &&
2591 recsize <= fs->fs_bsize)
2594 printf("Found invalid segsize %d > %d\n",
2596 recsize = real_dev_bsize;
2597 jblocks_advance(suj_jblocks, recsize);
2601 * Verify that all blocks in the segment are present.
2603 for (i = 1; i < blocks; i++) {
2604 recn = (void *)((uintptr_t)rec) + i *
2606 if (recn->jsr_seq == rec->jsr_seq &&
2607 recn->jsr_time == rec->jsr_time)
2610 printf("Incomplete record %jd (%d)\n",
2612 recsize = i * real_dev_bsize;
2613 jblocks_advance(suj_jblocks, recsize);
2616 seg = errmalloc(sizeof(*seg));
2617 seg->ss_blk = errmalloc(recsize);
2619 bcopy((void *)rec, seg->ss_blk, recsize);
2620 if (rec->jsr_oldest > oldseq)
2621 oldseq = rec->jsr_oldest;
2622 TAILQ_INSERT_TAIL(&allsegs, seg, ss_next);
2623 jblocks_advance(suj_jblocks, recsize);
2629 * Search a directory block for the SUJ_FILE.
2632 suj_find(ino_t ino, ufs_lbn_t lbn, ufs2_daddr_t blk, int frags)
2634 char block[MAXBSIZE];
2641 bytes = lfragtosize(fs, frags);
2642 if (bread(disk, fsbtodb(fs, blk), block, bytes) <= 0)
2643 err_suj("Failed to read ROOTINO directory block %jd\n", blk);
2644 for (off = 0; off < bytes; off += dp->d_reclen) {
2645 dp = (struct direct *)&block[off];
2646 if (dp->d_reclen == 0)
2650 if (dp->d_namlen != strlen(SUJ_FILE))
2652 if (bcmp(dp->d_name, SUJ_FILE, dp->d_namlen) != 0)
2660 * Orchestrate the verification of a filesystem via the softupdates journal.
2663 suj_check(const char *filesys)
2669 struct suj_seg *seg;
2670 struct suj_seg *segn;
2673 TAILQ_INIT(&allsegs);
2676 * Set an exit point when SUJ check failed
2678 retval = setjmp(jmpbuf);
2680 pwarn("UNEXPECTED SU+J INCONSISTENCY\n");
2681 TAILQ_FOREACH_SAFE(seg, &allsegs, ss_next, segn) {
2682 TAILQ_REMOVE(&allsegs, seg, ss_next);
2686 if (reply("FALLBACK TO FULL FSCK") == 0) {
2694 * Find the journal inode.
2696 ip = ino_read(ROOTINO);
2698 ino_visit(ip, ROOTINO, suj_find, 0);
2700 printf("Journal inode removed. Use tunefs to re-create.\n");
2701 sblock.fs_flags &= ~FS_SUJ;
2702 sblock.fs_sujfree = 0;
2706 * Fetch the journal inode and verify it.
2708 jip = ino_read(sujino);
2709 printf("** SU+J Recovering %s\n", filesys);
2710 if (suj_verifyino(jip) != 0)
2713 * Build a list of journal blocks in jblocks before parsing the
2714 * available journal blocks in with suj_read().
2716 printf("** Reading %jd byte journal from inode %d.\n",
2717 DIP(jip, di_size), sujino);
2718 suj_jblocks = jblocks_create();
2719 blocks = ino_visit(jip, sujino, suj_add_block, 0);
2720 if (blocks != numfrags(fs, DIP(jip, di_size))) {
2721 printf("Sparse journal inode %d.\n", sujino);
2725 jblocks_destroy(suj_jblocks);
2727 if (preen || reply("RECOVER")) {
2728 printf("** Building recovery table.\n");
2732 printf("** Resolving unreferenced inode list.\n");
2734 printf("** Processing journal entries.\n");
2736 cg_apply(cg_check_blk);
2737 cg_apply(cg_adj_blk);
2738 cg_apply(cg_check_ino);
2740 if (preen == 0 && (jrecs > 0 || jbytes > 0) && reply("WRITE CHANGES") == 0)
2743 * To remain idempotent with partial truncations the free bitmaps
2744 * must be written followed by indirect blocks and lastly inode
2745 * blocks. This preserves access to the modified pointers until
2750 cg_apply(cg_write_inos);
2751 /* Write back superblock. */
2753 if (jrecs > 0 || jbytes > 0) {
2754 printf("** %jd journal records in %jd bytes for %.2f%% utilization\n",
2755 jrecs, jbytes, ((float)jrecs / (float)(jbytes / JREC_SIZE)) * 100);
2756 printf("** Freed %jd inodes (%jd dirs) %jd blocks, and %jd frags.\n",
2757 freeinos, freedir, freeblocks, freefrags);
projects / FreeBSD / releng / 9.1.git / blob