xref: /illumos-gate/usr/src/cmd/fs.d/ufs/fsck/dup_avl.c (revision 51ccf66eff01cf7e19106ce91bc35ef397259faf)
1 /*
2  * CDDL HEADER START
3  *
4  * The contents of this file are subject to the terms of the
5  * Common Development and Distribution License (the "License").
6  * You may not use this file except in compliance with the License.
7  *
8  * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE
9  * or http://www.opensolaris.org/os/licensing.
10  * See the License for the specific language governing permissions
11  * and limitations under the License.
12  *
13  * When distributing Covered Code, include this CDDL HEADER in each
14  * file and include the License file at usr/src/OPENSOLARIS.LICENSE.
15  * If applicable, add the following below this CDDL HEADER, with the
16  * fields enclosed by brackets "[]" replaced with your own identifying
17  * information: Portions Copyright [yyyy] [name of copyright owner]
18  *
19  * CDDL HEADER END
20  */
21 /*
22  * Copyright 2008 Sun Microsystems, Inc.  All rights reserved.
23  * Use is subject to license terms.
24  */
25 
26 #pragma ident	"%Z%%M%	%I%	%E% SMI"
27 
28 /*
29  * Keep track of duplicate fragment references (elsewhere called
30  * blocks for ancient historical reasons).
31  *
32  * The duplicates are kept in a binary tree to attempt to minimize
33  * search times when checking the block lists of all active inodes
34  * for multiple uses.  This is opposed to using a simple linear list
35  * that is traversed for every block, as is used in the traditional
36  * fsck.  It can be very time-expensive if there's more than just a
37  * very few duplicates, and typically there are either none or lots.
38  *
39  * For each multiply-claimed fragment, we note all of the claiming
40  * inodes and their corresponding logical block numbers.  This allows
41  * reporting exactly which parts of which files were damaged, which
42  * provides at least a chance of recovering the bulk of the data on
43  * a seriously-corrupted filesystem.
44  */
45 #include <stdio.h>
46 #include <stdlib.h>
47 #include <unistd.h>
48 #include <sys/avl.h>
49 #define	_KERNEL
50 #include <sys/fs/ufs_fsdir.h>	/* for struct direct */
51 #undef _KERNEL
52 #include <sys/debug.h>
53 #include "fsck.h"
54 
55 #define	OFFSETOF(type, elt) ((size_t)(&((type *)NULL)->elt))
56 
57 /*
58  * For each physical fragment with multiple claimants, the specifics
59  * of each claim are recorded. This means there are N+1 AVL trees in
60  * use: one for each fragment's claimant table, plus one that orders
61  * the fragments themselves.
62  *
63  * The table of fragments simply has the physical fragment number
64  * (pfn) and has the root of the tree of the associated claimants.  It
65  * is keyed by the pfn and called dup_frags.
66  *
67  * The subsidiary trees list inodes and logical fragment number (lfn)
68  * for each claimant.  They are keyed first by inode number and then
69  * by lfn.  Both are needed, as it is possible for one inode to have
70  * multiple claims on the same fragment.
71  */
72 
73 typedef struct claimant {
74 	fsck_ino_t cl_inode;
75 	daddr32_t cl_lfn;
76 	avl_node_t cl_avl;
77 } claimant_t;
78 
79 typedef struct fragment {
80 	daddr32_t fr_pfn;
81 	avl_tree_t fr_claimants;
82 	avl_node_t fr_avl;
83 } fragment_t;
84 
85 typedef struct reference {
86 	daddr32_t ref_lfn;
87 	daddr32_t ref_pfn;
88 	avl_node_t ref_avl;
89 } reference_t;
90 
91 typedef struct inode_dup {
92 	fsck_ino_t id_ino;
93 	avl_tree_t id_fragments;
94 	avl_node_t id_avl;
95 } inode_dup_t;
96 
97 static avl_tree_t dup_frags;
98 
99 static void free_invert_frags(avl_tree_t *);
100 static void report_dup_lfn_pfn(daddr32_t, daddr32_t, daddr32_t, daddr32_t);
101 static inode_dup_t *new_inode_dup(fsck_ino_t);
102 static void invert_frags(avl_tree_t *, avl_tree_t *);
103 static void report_inode_dups(inode_dup_t *);
104 static int by_ino_cmp(const void *, const void *);
105 static int by_lfn_cmp(const void *, const void *);
106 static claimant_t *alloc_claimant(fsck_ino_t, daddr32_t);
107 static fragment_t *alloc_dup(daddr32_t);
108 static int claimant_cmp(const void *, const void *);
109 static int fragment_cmp(const void *, const void *);
110 static int decrement_claimant(fragment_t *, fsck_ino_t, daddr32_t);
111 static int increment_claimant(fragment_t *, fsck_ino_t, daddr32_t);
112 
113 /*
114  * Simple accessor function for the outside world so only we need to
115  * see and interpret our data structures.
116  */
117 int
118 have_dups(void)
119 {
120 	return (avl_numnodes(&dup_frags) > 0);
121 }
122 
123 /*
124  * Locates, creates, and deletes a record of a duplicate reference.
125  *
126  * For DB_INCR, returns true if the dup was added to the tree.
127  * For DB_DECR, returns true if the dup was in the tree.
128  */
129 int
130 find_dup_ref(daddr32_t fragno, fsck_ino_t ino, daddr32_t lfn, int flags)
131 {
132 	fragment_t key;
133 	fragment_t *dup;
134 	avl_index_t where;
135 	int added = 0;
136 	int removed = 0;
137 
138 	if (avl_first(&dup_frags) == NULL) {
139 		if (flags & DB_CREATE)
140 			avl_create(&dup_frags, fragment_cmp,
141 			    sizeof (fragment_t),
142 			    OFFSETOF(fragment_t, fr_avl));
143 		else
144 			return (0);
145 	}
146 
147 	key.fr_pfn = fragno;
148 	dup = avl_find(&dup_frags, (void *)&key, &where);
149 	if ((dup == NULL) & (flags & DB_CREATE)) {
150 		dup = alloc_dup(fragno);
151 		avl_insert(&dup_frags, (void *)dup, where);
152 	}
153 
154 	if (dup != NULL) {
155 		if (flags & DB_INCR) {
156 			if (debug)
157 				(void) printf(
158 				    "adding claim by ino %d as lfn %d\n",
159 				    ino, lfn);
160 			added = increment_claimant(dup, ino, lfn);
161 		} else if (flags & DB_DECR) {
162 			/*
163 			 * Note that dup may be invalidated by this call.
164 			 */
165 			removed = decrement_claimant(dup, ino, lfn);
166 			if (debug)
167 				(void) printf(
168 		    "check for claimant ino %d lfn %d returned %d\n",
169 				    ino, lfn, removed);
170 		}
171 	}
172 
173 	return (added || removed || (dup != NULL));
174 }
175 
176 /*
177  * Dump the duplicates table in a relatively user-friendly form.
178  * The idea is that the output can be useful when trying to manually
179  * work out which block belongs to which of the claiming inodes.
180  *
181  * What we have is a tree of duplicates indexed by physical
182  * fragment number.  What we want to report is:
183  *
184  *    Inode %d:
185  *        Logical Offset 0x%08llx,             Physical Fragment  %d
186  *        Logical Offsets 0x%08llx - 0x%08llx, Physical Fragments %d - %d
187  *        ...
188  *    Inode %d:
189  *        Logical Offsets 0x%08llx - 0x%08llx, Physical Fragments %d - %d
190  *    ...
191  */
192 int
193 report_dups(int quiet)
194 {
195 	int overlaps;
196 	inode_dup_t *inode;
197 	fragment_t *dup;
198 	avl_tree_t inode_frags;
199 
200 	overlaps = 0;
201 	ASSERT(have_dups());
202 	/*
203 	 * Figure out how many actual dups are still around.
204 	 * This tells us whether or not we can mark the
205 	 * filesystem clean.
206 	 */
207 	dup = avl_first(&dup_frags);
208 	while (dup != NULL) {
209 		if (avl_numnodes(&dup->fr_claimants) > 1) {
210 			overlaps++;
211 			break;
212 		}
213 		dup = AVL_NEXT(&dup_frags, dup);
214 	}
215 
216 	/*
217 	 * Now report on every object that still exists that
218 	 * had *any* dups associated with it.
219 	 */
220 	if (!quiet) {
221 		(void) puts("\nSome blocks that were found to be in "
222 		    "multiple files are still\nassigned to "
223 		    "file(s).\nFragments sorted by inode and "
224 		    "logical offsets:");
225 
226 		invert_frags(&dup_frags, &inode_frags);
227 		inode = avl_first(&inode_frags);
228 		while (inode != NULL) {
229 			report_inode_dups(inode);
230 			inode = AVL_NEXT(&inode_frags, inode);
231 		}
232 		(void) printf("\n");
233 
234 		free_invert_frags(&inode_frags);
235 	}
236 
237 	return (overlaps);
238 }
239 
240 static void
241 report_inode_dups(inode_dup_t *inode)
242 {
243 	reference_t *dup;
244 	daddr32_t first_lfn, last_lfn, first_pfn, last_pfn;
245 
246 	(void) printf("Inode %d:\n", inode->id_ino);
247 	dup = avl_first(&inode->id_fragments);
248 	first_lfn = last_lfn = dup->ref_lfn;
249 	first_pfn = last_pfn = dup->ref_pfn;
250 	while ((dup = AVL_NEXT(&inode->id_fragments, dup)) != NULL) {
251 		if (((last_lfn + 1) != dup->ref_lfn) ||
252 		    ((last_pfn + 1) != dup->ref_pfn)) {
253 			report_dup_lfn_pfn(first_lfn, last_lfn,
254 			    first_pfn, last_pfn);
255 			first_lfn = last_lfn = dup->ref_lfn;
256 			first_pfn = last_pfn = dup->ref_pfn;
257 		}
258 	}
259 	report_dup_lfn_pfn(first_lfn, last_lfn, first_pfn, last_pfn);
260 }
261 
262 static void
263 report_dup_lfn_pfn(daddr32_t first_lfn, daddr32_t last_lfn,
264 	daddr32_t first_pfn, daddr32_t last_pfn)
265 {
266 	if ((first_lfn == last_lfn) && (first_pfn == last_pfn)) {
267 		(void) printf(
268 	    "  Logical Offset  0x%08llx               Physical Fragment  %d\n",
269 		    (longlong_t)first_lfn * sblock.fs_fsize, first_pfn);
270 	} else {
271 		(void) printf(
272 		    "  Logical Offsets 0x%08llx - 0x%08llx, "
273 		    "Physical Fragments %d - %d\n",
274 		    (longlong_t)first_lfn * sblock.fs_fsize,
275 		    (longlong_t)last_lfn * sblock.fs_fsize,
276 		    first_pfn, last_pfn);
277 	}
278 }
279 
280 /*
281  * Given a tree of fragment_ts, each element of which has an integral
282  * sub-tree of claimant_ts, produce a tree of inode_dup_ts, each element
283  * of which has an integral sub-tree of reference_ts.
284  */
285 static void
286 invert_frags(avl_tree_t *source, avl_tree_t *target)
287 {
288 	fragment_t *src_frag;
289 	claimant_t *src_claim;
290 	inode_dup_t *tgt_inode;
291 	inode_dup_t tgt_inode_key;
292 	reference_t *tgt_ref;
293 	reference_t tgt_ref_key;
294 	avl_index_t where;
295 
296 	avl_create(target, by_ino_cmp, sizeof (inode_dup_t),
297 	    OFFSETOF(inode_dup_t, id_avl));
298 
299 	src_frag = avl_first(source);
300 	while (src_frag != NULL) {
301 		src_claim = avl_first(&src_frag->fr_claimants);
302 		while (src_claim != NULL) {
303 			/*
304 			 * Have we seen this inode before?
305 			 */
306 			tgt_inode_key.id_ino = src_claim->cl_inode;
307 			tgt_inode = avl_find(target, (void *)&tgt_inode_key,
308 			    &where);
309 			if (tgt_inode == NULL) {
310 				/*
311 				 * No, so set up a record for it.
312 				 */
313 				tgt_inode = new_inode_dup(src_claim->cl_inode);
314 				avl_insert(target, (void *)tgt_inode, where);
315 			}
316 			/*
317 			 * Now, how about this logical fragment?  In
318 			 * theory, we should never see a duplicate, since
319 			 * a given lfn only exists once for a given inode.
320 			 * As such, we ignore duplicate hits.
321 			 */
322 			tgt_ref_key.ref_lfn = src_claim->cl_lfn;
323 			tgt_ref = avl_find(&tgt_inode->id_fragments,
324 			    (void *)&tgt_ref_key, &where);
325 			if (tgt_ref == NULL) {
326 				/*
327 				 * Haven't seen it, add it.
328 				 */
329 				tgt_ref = (reference_t *)malloc(
330 				    sizeof (reference_t));
331 				if (tgt_ref == NULL)
332 					errexit("Out of memory in "
333 					    "invert_frags\n");
334 				tgt_ref->ref_lfn = src_claim->cl_lfn;
335 				tgt_ref->ref_pfn = src_frag->fr_pfn;
336 				avl_insert(&tgt_inode->id_fragments,
337 				    (void *)tgt_ref, where);
338 			}
339 			src_claim = AVL_NEXT(&src_frag->fr_claimants,
340 			    src_claim);
341 		}
342 		src_frag = AVL_NEXT(source, src_frag);
343 	}
344 }
345 
346 /*
347  * Discard memory associated with the inverted fragments tree created
348  * by report_dups() via invert_frags().
349  */
350 static void
351 free_invert_frags(avl_tree_t *tree)
352 {
353 	void *outer = NULL;	/* traversal cookie */
354 	void *inner;		/* traversal cookie */
355 	inode_dup_t *inode_dup;
356 	reference_t *ref_dup;
357 
358 	while ((inode_dup = avl_destroy_nodes(tree, &outer)) != NULL) {
359 		inner = NULL;
360 		while ((ref_dup = avl_destroy_nodes(&inode_dup->id_fragments,
361 		    &inner)) != NULL) {
362 			free((void *)ref_dup);
363 		}
364 		avl_destroy(&inode_dup->id_fragments);
365 		free((void *)inode_dup);
366 	}
367 	avl_destroy(tree);
368 }
369 
370 /*
371  * Discard all memory allocations associated with the current duplicates
372  * table.
373  */
374 void
375 free_dup_state(void)
376 {
377 	void *dup_cookie = NULL;
378 	void *claim_cookie;
379 	fragment_t *fragv;
380 	claimant_t *claimv;
381 
382 	while ((fragv = avl_destroy_nodes(&dup_frags, &dup_cookie)) != NULL) {
383 		claim_cookie = NULL;
384 		while ((claimv = avl_destroy_nodes(&fragv->fr_claimants,
385 		    &claim_cookie)) != NULL) {
386 			free((void *)claimv);
387 		}
388 		avl_destroy(&fragv->fr_claimants);
389 		free((void *)fragv);
390 	}
391 	avl_destroy(&dup_frags);
392 }
393 
394 /*
395  * If the given claimant has not been seen before, add it to DUP's
396  * list of them.  It's not fatal for the same PFN/INODE/LFN to get
397  * added twice, because pass1b() will add the same dups that pass1()
398  * did, plus one.
399  */
400 static int
401 increment_claimant(fragment_t *dup, fsck_ino_t ino, daddr32_t lfn)
402 {
403 	avl_index_t where;
404 	claimant_t *claimant;
405 	claimant_t key;
406 	int added = 0;
407 
408 	key.cl_inode = ino;
409 	key.cl_lfn = lfn;
410 	claimant = avl_find(&dup->fr_claimants, &key, &where);
411 	if (claimant == NULL) {
412 		if (debug)
413 			(void) printf("inserting claimant\n");
414 		claimant = alloc_claimant(ino, lfn);
415 		avl_insert(&dup->fr_claimants, (void *)claimant, where);
416 		statemap[ino] |= INCLEAR;
417 		/*
418 		 * If the inode is to be cleared and has zero links then remove
419 		 * the zero link bit as it will be cleared anyway. If INZLINK
420 		 * is being removed and it's a directory inode then add the
421 		 * inode to the orphan directory list.
422 		 */
423 		if (statemap[ino] & INZLINK) {
424 			statemap[ino] &= ~INZLINK;
425 			if (statemap[ino] & DSTATE) {
426 				add_orphan_dir(ino);
427 			}
428 		}
429 		added = 1;
430 	}
431 
432 	return (added);
433 }
434 
435 /*
436  * If the given claimant is on DUP's list, remove it.  It is not
437  * an error for the claimant to not be on the list.
438  */
439 static int
440 decrement_claimant(fragment_t *dup, fsck_ino_t ino, daddr32_t lfn)
441 {
442 	avl_index_t where;
443 	claimant_t *claimant;
444 	claimant_t key;
445 	int busy = 0;
446 
447 	key.cl_inode = ino;
448 	key.cl_lfn = lfn;
449 	claimant = avl_find(&dup->fr_claimants, &key, &where);
450 	if (claimant != NULL) {
451 		avl_remove(&dup->fr_claimants, claimant);
452 		if (avl_numnodes(&dup->fr_claimants) == 0) {
453 			avl_destroy(&dup->fr_claimants);
454 			avl_remove(&dup_frags, (void *)dup);
455 			free((void *)dup);
456 		} else {
457 			busy = 1;
458 		}
459 	}
460 
461 	return (busy);
462 }
463 
464 static claimant_t *
465 alloc_claimant(fsck_ino_t inode, daddr32_t lfn)
466 {
467 	claimant_t *new = (claimant_t *)malloc(sizeof (claimant_t));
468 
469 	if (new == NULL)
470 		errexit("Out of memory in alloc_claimant()\n");
471 
472 	new->cl_inode = inode;
473 	new->cl_lfn = lfn;
474 
475 	return (new);
476 }
477 
478 static fragment_t *
479 alloc_dup(daddr32_t pfn)
480 {
481 	fragment_t *new = (fragment_t *)malloc(sizeof (fragment_t));
482 
483 	if (new == NULL)
484 		errexit("Out of memory in alloc_dup()\n");
485 
486 	new->fr_pfn = pfn;
487 	avl_create(&new->fr_claimants, claimant_cmp, sizeof (fragment_t),
488 	    OFFSETOF(claimant_t, cl_avl));
489 
490 	return (new);
491 }
492 
493 /*
494  * Compare two fragment_t instances for avl_find().  It requires a
495  * return value of -1/0/1, so we can't just hand back left - right.
496  */
497 static int
498 fragment_cmp(const void *vlp, const void *vrp)
499 {
500 	const fragment_t *lp = (const fragment_t *)vlp;
501 	const fragment_t *rp = (const fragment_t *)vrp;
502 	int cmp = lp->fr_pfn - rp->fr_pfn;
503 
504 	if (cmp < 0)
505 		cmp = -1;
506 	else if (cmp > 0)
507 		cmp = 1;
508 
509 	return (cmp);
510 }
511 
512 /*
513  * Compare two claimant_t instances for avl_find().  It requires a
514  * return value of -1/0/1, so we can't just hand back left - right.
515  */
516 static int
517 claimant_cmp(const void *vlp, const void *vrp)
518 {
519 	const claimant_t *lp = (const claimant_t *)vlp;
520 	const claimant_t *rp = (const claimant_t *)vrp;
521 	int cmp;
522 
523 	cmp = lp->cl_inode - rp->cl_inode;
524 	if (cmp == 0) {
525 		/*
526 		 * lfn < 0 is a wildcard lfn match.
527 		 */
528 		if ((lp->cl_lfn >= 0) && (rp->cl_lfn >= 0))
529 			cmp = lp->cl_lfn - rp->cl_lfn;
530 	}
531 
532 	if (cmp < 0)
533 		cmp = -1;
534 	else if (cmp > 0)
535 		cmp = 1;
536 
537 	return (cmp);
538 }
539 
540 static int
541 by_ino_cmp(const void *vlp, const void *vrp)
542 {
543 	const inode_dup_t *lp = (const inode_dup_t *)vlp;
544 	const inode_dup_t *rp = (const inode_dup_t *)vrp;
545 	int cmp;
546 
547 	cmp = lp->id_ino - rp->id_ino;
548 
549 	if (cmp < 0)
550 		cmp = -1;
551 	else if (cmp > 0)
552 		cmp = 1;
553 
554 	return (cmp);
555 }
556 
557 static int
558 by_lfn_cmp(const void *vlp, const void *vrp)
559 {
560 	const reference_t *lp = (const reference_t *)vlp;
561 	const reference_t *rp = (const reference_t *)vrp;
562 	int cmp;
563 
564 	cmp = lp->ref_lfn - rp->ref_lfn;
565 
566 	if (cmp < 0)
567 		cmp = -1;
568 	else if (cmp > 0)
569 		cmp = 1;
570 
571 	return (cmp);
572 }
573 
574 static inode_dup_t *
575 new_inode_dup(fsck_ino_t inode)
576 {
577 	inode_dup_t *new;
578 
579 	new = (inode_dup_t *)malloc(sizeof (inode_dup_t));
580 	if (new == NULL)
581 		errexit("Out of memory in new_inode_dup\n");
582 	new->id_ino = inode;
583 	avl_create(&new->id_fragments, by_lfn_cmp, sizeof (reference_t),
584 	    OFFSETOF(reference_t, ref_avl));
585 
586 	return (new);
587 }
588