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inpcb: Use netisr_ncpus for listing inpcbs.
[dragonfly.git] / sbin / hammer / cmd_dedup.c
blob1560a451ac964cc06d0109b0aef029d772308e9b
1 /*
2 * Copyright (c) 2010 The DragonFly Project. All rights reserved.
3 *
4 * This code is derived from software contributed to The DragonFly Project
5 * by Ilya Dryomov <idryomov@gmail.com>
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 *
11 * 1. Redistributions of source code must retain the above copyright
12 * notice, this list of conditions and the following disclaimer.
13 * 2. Redistributions in binary form must reproduce the above copyright
14 * notice, this list of conditions and the following disclaimer in
15 * the documentation and/or other materials provided with the
16 * distribution.
17 * 3. Neither the name of The DragonFly Project nor the names of its
18 * contributors may be used to endorse or promote products derived
19 * from this software without specific, prior written permission.
20 *
21 * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
22 * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
23 * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS
24 * FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE
25 * COPYRIGHT HOLDERS OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT,
26 * INCIDENTAL, SPECIAL, EXEMPLARY OR CONSEQUENTIAL DAMAGES (INCLUDING,
27 * BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
28 * LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED
29 * AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY,
30 * OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT
31 * OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
32 * SUCH DAMAGE.
33 */
34
35 #include <libutil.h>
36 #include <crypto/sha2/sha2.h>
37
38 #include "hammer.h"
39
40 #define DEDUP_BUF (64 * 1024)
41
42 /* Sorted list of block CRCs - light version for dedup-simulate */
43 struct sim_dedup_entry_rb_tree;
44 RB_HEAD(sim_dedup_entry_rb_tree, sim_dedup_entry) sim_dedup_tree =
45 RB_INITIALIZER(&sim_dedup_tree);
46 RB_PROTOTYPE2(sim_dedup_entry_rb_tree, sim_dedup_entry, rb_entry,
47 rb_sim_dedup_entry_compare, hammer_crc_t);
48
49 struct sim_dedup_entry {
50 hammer_crc_t crc;
51 uint64_t ref_blks; /* number of blocks referenced */
52 uint64_t ref_size; /* size of data referenced */
53 RB_ENTRY(sim_dedup_entry) rb_entry;
54 };
55
56 struct dedup_entry {
57 struct hammer_btree_leaf_elm leaf;
58 union {
59 struct {
60 uint64_t ref_blks;
61 uint64_t ref_size;
62 } de;
63 RB_HEAD(sha_dedup_entry_rb_tree, sha_dedup_entry) fict_root;
64 } u;
65 uint8_t flags;
66 RB_ENTRY(dedup_entry) rb_entry;
67 };
68
69 #define HAMMER_DEDUP_ENTRY_FICTITIOUS 0x0001
70
71 struct sha_dedup_entry {
72 struct hammer_btree_leaf_elm leaf;
73 uint64_t ref_blks;
74 uint64_t ref_size;
75 uint8_t sha_hash[SHA256_DIGEST_LENGTH];
76 RB_ENTRY(sha_dedup_entry) fict_entry;
77 };
78
79 /* Sorted list of HAMMER B-Tree keys */
80 struct dedup_entry_rb_tree;
81 struct sha_dedup_entry_rb_tree;
82
83 RB_HEAD(dedup_entry_rb_tree, dedup_entry) dedup_tree =
84 RB_INITIALIZER(&dedup_tree);
85 RB_PROTOTYPE2(dedup_entry_rb_tree, dedup_entry, rb_entry,
86 rb_dedup_entry_compare, hammer_crc_t);
87
88 RB_PROTOTYPE(sha_dedup_entry_rb_tree, sha_dedup_entry, fict_entry,
89 rb_sha_dedup_entry_compare);
90
91 /*
92 * Pass2 list - contains entries that were not dedup'ed because ioctl failed
93 */
94 STAILQ_HEAD(, pass2_dedup_entry) pass2_dedup_queue =
95 STAILQ_HEAD_INITIALIZER(pass2_dedup_queue);
96
97 struct pass2_dedup_entry {
98 struct hammer_btree_leaf_elm leaf;
99 STAILQ_ENTRY(pass2_dedup_entry) sq_entry;
100 };
101
102 #define DEDUP_PASS2 0x0001 /* process_btree_elm() mode */
103
104 static int SigInfoFlag;
105 static int SigAlrmFlag;
106 static int64_t DedupDataReads;
107 static int64_t DedupCurrentRecords;
108 static int64_t DedupTotalRecords;
109 static uint32_t DedupCrcStart;
110 static uint32_t DedupCrcEnd;
111 static uint64_t MemoryUse;
112
113 /* PFS global ids - we deal with just one PFS at a run */
114 static int glob_fd;
115 static struct hammer_ioc_pseudofs_rw glob_pfs;
116
117 /*
118 * Global accounting variables
119 *
120 * Last three don't have to be 64-bit, just to be safe..
121 */
122 static uint64_t dedup_alloc_size;
123 static uint64_t dedup_ref_size;
124 static uint64_t dedup_skipped_size;
125 static uint64_t dedup_crc_failures;
126 static uint64_t dedup_sha_failures;
127 static uint64_t dedup_underflows;
128 static uint64_t dedup_successes_count;
129 static uint64_t dedup_successes_bytes;
130
131 static int rb_sim_dedup_entry_compare(struct sim_dedup_entry *sim_de1,
132 struct sim_dedup_entry *sim_de2);
133 static int rb_dedup_entry_compare(struct dedup_entry *de1,
134 struct dedup_entry *de2);
135 static int rb_sha_dedup_entry_compare(struct sha_dedup_entry *sha_de1,
136 struct sha_dedup_entry *sha_de2);
137 typedef int (*scan_pfs_cb_t)(hammer_btree_leaf_elm_t scan_leaf, int flags);
138 static void scan_pfs(char *filesystem, scan_pfs_cb_t func, const char *id);
139 static int collect_btree_elm(hammer_btree_leaf_elm_t scan_leaf, int flags);
140 static int count_btree_elm(hammer_btree_leaf_elm_t scan_leaf, int flags);
141 static int process_btree_elm(hammer_btree_leaf_elm_t scan_leaf, int flags);
142 static int upgrade_chksum(hammer_btree_leaf_elm_t leaf, uint8_t *sha_hash);
143 static void dump_simulated_dedup(void);
144 static void dump_real_dedup(void);
145 static void dedup_usage(int code);
146
147 RB_GENERATE2(sim_dedup_entry_rb_tree, sim_dedup_entry, rb_entry,
148 rb_sim_dedup_entry_compare, hammer_crc_t, crc);
149 RB_GENERATE2(dedup_entry_rb_tree, dedup_entry, rb_entry,
150 rb_dedup_entry_compare, hammer_crc_t, leaf.data_crc);
151 RB_GENERATE(sha_dedup_entry_rb_tree, sha_dedup_entry, fict_entry,
152 rb_sha_dedup_entry_compare);
153
154 static int
155 rb_sim_dedup_entry_compare(struct sim_dedup_entry *sim_de1,
156 struct sim_dedup_entry *sim_de2)
157 {
158 if (sim_de1->crc < sim_de2->crc)
159 return (-1);
160 if (sim_de1->crc > sim_de2->crc)
161 return (1);
162
163 return (0);
164 }
165
166 static int
167 rb_dedup_entry_compare(struct dedup_entry *de1, struct dedup_entry *de2)
168 {
169 if (de1->leaf.data_crc < de2->leaf.data_crc)
170 return (-1);
171 if (de1->leaf.data_crc > de2->leaf.data_crc)
172 return (1);
173
174 return (0);
175 }
176
177 static int
178 rb_sha_dedup_entry_compare(struct sha_dedup_entry *sha_de1,
179 struct sha_dedup_entry *sha_de2)
180 {
181 unsigned long *h1 = (unsigned long *)&sha_de1->sha_hash;
182 unsigned long *h2 = (unsigned long *)&sha_de2->sha_hash;
183 int i;
184
185 for (i = 0; i < SHA256_DIGEST_LENGTH / (int)sizeof(unsigned long); ++i) {
186 if (h1[i] < h2[i])
187 return (-1);
188 if (h1[i] > h2[i])
189 return (1);
190 }
191
192 return (0);
193 }
194
195 /*
196 * dedup-simulate <filesystem>
197 */
198 void
199 hammer_cmd_dedup_simulate(char **av, int ac)
200 {
201 struct sim_dedup_entry *sim_de;
202
203 if (ac != 1)
204 dedup_usage(1);
205
206 glob_fd = getpfs(&glob_pfs, av[0]);
207
208 /*
209 * Collection passes (memory limited)
210 */
211 printf("Dedup-simulate running\n");
212 do {
213 DedupCrcStart = DedupCrcEnd;
214 DedupCrcEnd = 0;
215 MemoryUse = 0;
216
217 if (VerboseOpt) {
218 printf("B-Tree pass crc-range %08x-max\n",
219 DedupCrcStart);
220 fflush(stdout);
221 }
222 scan_pfs(av[0], collect_btree_elm, "simu-pass");
223
224 if (VerboseOpt >= 2)
225 dump_simulated_dedup();
226
227 /*
228 * Calculate simulated dedup ratio and get rid of the tree
229 */
230 while ((sim_de = RB_ROOT(&sim_dedup_tree)) != NULL) {
231 assert(sim_de->ref_blks != 0);
232 dedup_ref_size += sim_de->ref_size;
233 dedup_alloc_size += sim_de->ref_size / sim_de->ref_blks;
234
235 RB_REMOVE(sim_dedup_entry_rb_tree, &sim_dedup_tree, sim_de);
236 free(sim_de);
237 }
238 if (DedupCrcEnd && VerboseOpt == 0)
239 printf(".");
240 } while (DedupCrcEnd);
241
242 printf("Dedup-simulate %s succeeded\n", av[0]);
243 relpfs(glob_fd, &glob_pfs);
244
245 printf("Simulated dedup ratio = %.2f\n",
246 (dedup_alloc_size != 0) ?
247 (double)dedup_ref_size / dedup_alloc_size : 0);
248 }
249
250 /*
251 * dedup <filesystem>
252 */
253 void
254 hammer_cmd_dedup(char **av, int ac)
255 {
256 struct dedup_entry *de;
257 struct sha_dedup_entry *sha_de;
258 struct pass2_dedup_entry *pass2_de;
259 char *tmp;
260 char buf[8];
261 int needfree = 0;
262
263 if (TimeoutOpt > 0)
264 alarm(TimeoutOpt);
265
266 if (ac != 1)
267 dedup_usage(1);
268
269 STAILQ_INIT(&pass2_dedup_queue);
270
271 glob_fd = getpfs(&glob_pfs, av[0]);
272
273 /*
274 * A cycle file is _required_ for resuming dedup after the timeout
275 * specified with -t has expired. If no -c option, then place a
276 * .dedup.cycle file either in the PFS snapshots directory or in
277 * the default snapshots directory.
278 */
279 if (!CyclePath) {
280 if (glob_pfs.ondisk->snapshots[0] != '/')
281 asprintf(&tmp, "%s/%s/.dedup.cycle",
282 SNAPSHOTS_BASE, av[0]);
283 else
284 asprintf(&tmp, "%s/.dedup.cycle",
285 glob_pfs.ondisk->snapshots);
286 CyclePath = tmp;
287 needfree = 1;
288 }
289
290 /*
291 * Pre-pass to cache the btree
292 */
293 scan_pfs(av[0], count_btree_elm, "pre-pass ");
294 DedupTotalRecords = DedupCurrentRecords;
295
296 /*
297 * Collection passes (memory limited)
298 */
299 printf("Dedup running\n");
300 do {
301 DedupCrcStart = DedupCrcEnd;
302 DedupCrcEnd = 0;
303 MemoryUse = 0;
304
305 if (VerboseOpt) {
306 printf("B-Tree pass crc-range %08x-max\n",
307 DedupCrcStart);
308 fflush(stdout);
309 }
310 scan_pfs(av[0], process_btree_elm, "main-pass");
311
312 while ((pass2_de = STAILQ_FIRST(&pass2_dedup_queue)) != NULL) {
313 if (process_btree_elm(&pass2_de->leaf, DEDUP_PASS2))
314 dedup_skipped_size -= pass2_de->leaf.data_len;
315
316 STAILQ_REMOVE_HEAD(&pass2_dedup_queue, sq_entry);
317 free(pass2_de);
318 }
319 assert(STAILQ_EMPTY(&pass2_dedup_queue));
320
321 if (VerboseOpt >= 2)
322 dump_real_dedup();
323
324 /*
325 * Calculate dedup ratio and get rid of the trees
326 */
327 while ((de = RB_ROOT(&dedup_tree)) != NULL) {
328 if (de->flags & HAMMER_DEDUP_ENTRY_FICTITIOUS) {
329 while ((sha_de = RB_ROOT(&de->u.fict_root)) != NULL) {
330 assert(sha_de->ref_blks != 0);
331 dedup_ref_size += sha_de->ref_size;
332 dedup_alloc_size += sha_de->ref_size / sha_de->ref_blks;
333
334 RB_REMOVE(sha_dedup_entry_rb_tree,
335 &de->u.fict_root, sha_de);
336 free(sha_de);
337 }
338 assert(RB_EMPTY(&de->u.fict_root));
339 } else {
340 assert(de->u.de.ref_blks != 0);
341 dedup_ref_size += de->u.de.ref_size;
342 dedup_alloc_size += de->u.de.ref_size / de->u.de.ref_blks;
343 }
344
345 RB_REMOVE(dedup_entry_rb_tree, &dedup_tree, de);
346 free(de);
347 }
348 assert(RB_EMPTY(&dedup_tree));
349 if (DedupCrcEnd && VerboseOpt == 0)
350 printf(".");
351 } while (DedupCrcEnd);
352
353 printf("Dedup %s succeeded\n", av[0]);
354 relpfs(glob_fd, &glob_pfs);
355
356 humanize_unsigned(buf, sizeof(buf), dedup_ref_size, "B", 1024);
357 printf("Dedup ratio = %.2f (in this run)\n"
358 " %8s referenced\n",
359 ((dedup_alloc_size != 0) ?
360 (double)dedup_ref_size / dedup_alloc_size : 0),
361 buf
362 );
363 humanize_unsigned(buf, sizeof(buf), dedup_alloc_size, "B", 1024);
364 printf(" %8s allocated\n", buf);
365 humanize_unsigned(buf, sizeof(buf), dedup_skipped_size, "B", 1024);
366 printf(" %8s skipped\n", buf);
367 printf(" %8jd CRC collisions\n"
368 " %8jd SHA collisions\n"
369 " %8jd big-block underflows\n"
370 " %8jd new dedup records\n"
371 " %8jd new dedup bytes\n",
372 (intmax_t)dedup_crc_failures,
373 (intmax_t)dedup_sha_failures,
374 (intmax_t)dedup_underflows,
375 (intmax_t)dedup_successes_count,
376 (intmax_t)dedup_successes_bytes
377 );
378
379 /* Once completed remove cycle file */
380 hammer_reset_cycle();
381
382 /* We don't want to mess up with other directives */
383 if (needfree) {
384 free(tmp);
385 CyclePath = NULL;
386 }
387 }
388
389 static int
390 count_btree_elm(hammer_btree_leaf_elm_t scan_leaf __unused, int flags __unused)
391 {
392 return(1);
393 }
394
395 static int
396 collect_btree_elm(hammer_btree_leaf_elm_t scan_leaf, int flags __unused)
397 {
398 struct sim_dedup_entry *sim_de;
399
400 /*
401 * If we are using too much memory we have to clean some out, which
402 * will cause the run to use multiple passes. Be careful of integer
403 * overflows!
404 */
405 if (MemoryUse > MemoryLimit) {
406 DedupCrcEnd = DedupCrcStart +
407 (uint32_t)(DedupCrcEnd - DedupCrcStart - 1) / 2;
408 if (VerboseOpt) {
409 printf("memory limit crc-range %08x-%08x\n",
410 DedupCrcStart, DedupCrcEnd);
411 fflush(stdout);
412 }
413 for (;;) {
414 sim_de = RB_MAX(sim_dedup_entry_rb_tree,
415 &sim_dedup_tree);
416 if (sim_de == NULL || sim_de->crc < DedupCrcEnd)
417 break;
418 RB_REMOVE(sim_dedup_entry_rb_tree,
419 &sim_dedup_tree, sim_de);
420 MemoryUse -= sizeof(*sim_de);
421 free(sim_de);
422 }
423 }
424
425 /*
426 * Collect statistics based on the CRC only, do not try to read
427 * any data blocks or run SHA hashes.
428 */
429 sim_de = RB_LOOKUP(sim_dedup_entry_rb_tree, &sim_dedup_tree,
430 scan_leaf->data_crc);
431
432 if (sim_de == NULL) {
433 sim_de = calloc(1, sizeof(*sim_de));
434 sim_de->crc = scan_leaf->data_crc;
435 RB_INSERT(sim_dedup_entry_rb_tree, &sim_dedup_tree, sim_de);
436 MemoryUse += sizeof(*sim_de);
437 }
438
439 sim_de->ref_blks += 1;
440 sim_de->ref_size += scan_leaf->data_len;
441 return (1);
442 }
443
444 static __inline int
445 validate_dedup_pair(hammer_btree_leaf_elm_t p, hammer_btree_leaf_elm_t q)
446 {
447 if (HAMMER_ZONE(p->data_offset) != HAMMER_ZONE(q->data_offset)) {
448 return (1);
449 }
450 if (p->data_len != q->data_len) {
451 return (1);
452 }
453
454 return (0);
455 }
456
457 #define DEDUP_TECH_FAILURE 1
458 #define DEDUP_CMP_FAILURE 2
459 #define DEDUP_INVALID_ZONE 3
460 #define DEDUP_UNDERFLOW 4
461 #define DEDUP_VERS_FAILURE 5
462
463 static __inline int
464 deduplicate(hammer_btree_leaf_elm_t p, hammer_btree_leaf_elm_t q)
465 {
466 struct hammer_ioc_dedup dedup;
467
468 bzero(&dedup, sizeof(dedup));
469
470 /*
471 * If data_offset fields are the same there is no need to run ioctl,
472 * candidate is already dedup'ed.
473 */
474 if (p->data_offset == q->data_offset) {
475 return (0);
476 }
477
478 dedup.elm1 = p->base;
479 dedup.elm2 = q->base;
480 RunningIoctl = 1;
481 if (ioctl(glob_fd, HAMMERIOC_DEDUP, &dedup) < 0) {
482 if (errno == EOPNOTSUPP) {
483 /* must be at least version 5 */
484 return (DEDUP_VERS_FAILURE);
485 }
486 /* Technical failure - locking or w/e */
487 return (DEDUP_TECH_FAILURE);
488 }
489 if (dedup.head.flags & HAMMER_IOC_DEDUP_CMP_FAILURE) {
490 return (DEDUP_CMP_FAILURE);
491 }
492 if (dedup.head.flags & HAMMER_IOC_DEDUP_INVALID_ZONE) {
493 return (DEDUP_INVALID_ZONE);
494 }
495 if (dedup.head.flags & HAMMER_IOC_DEDUP_UNDERFLOW) {
496 return (DEDUP_UNDERFLOW);
497 }
498 RunningIoctl = 0;
499 ++dedup_successes_count;
500 dedup_successes_bytes += p->data_len;
501 return (0);
502 }
503
504 static int
505 process_btree_elm(hammer_btree_leaf_elm_t scan_leaf, int flags)
506 {
507 struct dedup_entry *de;
508 struct sha_dedup_entry *sha_de, temp;
509 struct pass2_dedup_entry *pass2_de;
510 int error;
511
512 /*
513 * If we are using too much memory we have to clean some out, which
514 * will cause the run to use multiple passes. Be careful of integer
515 * overflows!
516 */
517 while (MemoryUse > MemoryLimit) {
518 DedupCrcEnd = DedupCrcStart +
519 (uint32_t)(DedupCrcEnd - DedupCrcStart - 1) / 2;
520 if (VerboseOpt) {
521 printf("memory limit crc-range %08x-%08x\n",
522 DedupCrcStart, DedupCrcEnd);
523 fflush(stdout);
524 }
525
526 for (;;) {
527 de = RB_MAX(dedup_entry_rb_tree, &dedup_tree);
528 if (de == NULL || de->leaf.data_crc < DedupCrcEnd)
529 break;
530 if (de->flags & HAMMER_DEDUP_ENTRY_FICTITIOUS) {
531 while ((sha_de = RB_ROOT(&de->u.fict_root)) !=
532 NULL) {
533 RB_REMOVE(sha_dedup_entry_rb_tree,
534 &de->u.fict_root, sha_de);
535 MemoryUse -= sizeof(*sha_de);
536 free(sha_de);
537 }
538 }
539 RB_REMOVE(dedup_entry_rb_tree, &dedup_tree, de);
540 MemoryUse -= sizeof(*de);
541 free(de);
542 }
543 }
544
545 /*
546 * Collect statistics based on the CRC. Colliding CRCs usually
547 * cause a SHA sub-tree to be created under the de.
548 *
549 * Trivial case if de not found.
550 */
551 de = RB_LOOKUP(dedup_entry_rb_tree, &dedup_tree, scan_leaf->data_crc);
552 if (de == NULL) {
553 de = calloc(1, sizeof(*de));
554 de->leaf = *scan_leaf;
555 RB_INSERT(dedup_entry_rb_tree, &dedup_tree, de);
556 MemoryUse += sizeof(*de);
557 goto upgrade_stats;
558 }
559
560 /*
561 * Found entry in CRC tree
562 */
563 if (de->flags & HAMMER_DEDUP_ENTRY_FICTITIOUS) {
564 /*
565 * Optimize the case where a CRC failure results in multiple
566 * SHA entries. If we unconditionally issue a data-read a
567 * degenerate situation where a colliding CRC's second SHA
568 * entry contains the lion's share of the deduplication
569 * candidates will result in excessive data block reads.
570 *
571 * Deal with the degenerate case by looking for a matching
572 * data_offset/data_len in the SHA elements we already have
573 * before reading the data block and generating a new SHA.
574 */
575 RB_FOREACH(sha_de, sha_dedup_entry_rb_tree, &de->u.fict_root) {
576 if (sha_de->leaf.data_offset ==
577 scan_leaf->data_offset &&
578 sha_de->leaf.data_len == scan_leaf->data_len) {
579 memcpy(temp.sha_hash, sha_de->sha_hash,
580 SHA256_DIGEST_LENGTH);
581 break;
582 }
583 }
584
585 /*
586 * Entry in CRC tree is fictitious, so we already had problems
587 * with this CRC. Upgrade (compute SHA) the candidate and
588 * dive into SHA subtree. If upgrade fails insert the candidate
589 * into Pass2 list (it will be processed later).
590 */
591 if (sha_de == NULL) {
592 if (upgrade_chksum(scan_leaf, temp.sha_hash))
593 goto pass2_insert;
594
595 sha_de = RB_FIND(sha_dedup_entry_rb_tree,
596 &de->u.fict_root, &temp);
597 }
598
599 /*
600 * Nothing in SHA subtree so far, so this is a new
601 * 'dataset'. Insert new entry into SHA subtree.
602 */
603 if (sha_de == NULL) {
604 sha_de = calloc(1, sizeof(*sha_de));
605 sha_de->leaf = *scan_leaf;
606 memcpy(sha_de->sha_hash, temp.sha_hash,
607 SHA256_DIGEST_LENGTH);
608 RB_INSERT(sha_dedup_entry_rb_tree, &de->u.fict_root,
609 sha_de);
610 MemoryUse += sizeof(*sha_de);
611 goto upgrade_stats_sha;
612 }
613
614 /*
615 * Found entry in SHA subtree, it means we have a potential
616 * dedup pair. Validate it (zones have to match and data_len
617 * field have to be the same too. If validation fails, treat
618 * it as a SHA collision (jump to sha256_failure).
619 */
620 if (validate_dedup_pair(&sha_de->leaf, scan_leaf))
621 goto sha256_failure;
622
623 /*
624 * We have a valid dedup pair (SHA match, validated).
625 *
626 * In case of technical failure (dedup pair was good, but
627 * ioctl failed anyways) insert the candidate into Pass2 list
628 * (we will try to dedup it after we are done with the rest of
629 * the tree).
630 *
631 * If ioctl fails because either of blocks is in the non-dedup
632 * zone (we can dedup only in LARGE_DATA and SMALL_DATA) don't
633 * bother with the candidate and terminate early.
634 *
635 * If ioctl fails because of big-block underflow replace the
636 * leaf node that found dedup entry represents with scan_leaf.
637 */
638 error = deduplicate(&sha_de->leaf, scan_leaf);
639 switch(error) {
640 case 0:
641 goto upgrade_stats_sha;
642 case DEDUP_TECH_FAILURE:
643 goto pass2_insert;
644 case DEDUP_CMP_FAILURE:
645 goto sha256_failure;
646 case DEDUP_INVALID_ZONE:
647 goto terminate_early;
648 case DEDUP_UNDERFLOW:
649 ++dedup_underflows;
650 sha_de->leaf = *scan_leaf;
651 memcpy(sha_de->sha_hash, temp.sha_hash,
652 SHA256_DIGEST_LENGTH);
653 goto upgrade_stats_sha;
654 case DEDUP_VERS_FAILURE:
655 errx(1, "HAMMER filesystem must be at least "
656 "version 5 to dedup");
657 default:
658 fprintf(stderr, "Unknown error\n");
659 goto terminate_early;
660 }
661
662 /*
663 * Ooh la la.. SHA-256 collision. Terminate early, there's
664 * nothing we can do here.
665 */
666 sha256_failure:
667 ++dedup_sha_failures;
668 goto terminate_early;
669 } else {
670 /*
671 * Candidate CRC is good for now (we found an entry in CRC
672 * tree and it's not fictitious). This means we have a
673 * potential dedup pair.
674 */
675 if (validate_dedup_pair(&de->leaf, scan_leaf))
676 goto crc_failure;
677
678 /*
679 * We have a valid dedup pair (CRC match, validated)
680 */
681 error = deduplicate(&de->leaf, scan_leaf);
682 switch(error) {
683 case 0:
684 goto upgrade_stats;
685 case DEDUP_TECH_FAILURE:
686 goto pass2_insert;
687 case DEDUP_CMP_FAILURE:
688 goto crc_failure;
689 case DEDUP_INVALID_ZONE:
690 goto terminate_early;
691 case DEDUP_UNDERFLOW:
692 ++dedup_underflows;
693 de->leaf = *scan_leaf;
694 goto upgrade_stats;
695 case DEDUP_VERS_FAILURE:
696 errx(1, "HAMMER filesystem must be at least "
697 "version 5 to dedup");
698 default:
699 fprintf(stderr, "Unknown error\n");
700 goto terminate_early;
701 }
702
703 crc_failure:
704 /*
705 * We got a CRC collision - either ioctl failed because of
706 * the comparison failure or validation of the potential
707 * dedup pair went bad. In all cases insert both blocks
708 * into SHA subtree (this requires checksum upgrade) and mark
709 * entry that corresponds to this CRC in the CRC tree
710 * fictitious, so that all futher operations with this CRC go
711 * through SHA subtree.
712 */
713 ++dedup_crc_failures;
714
715 /*
716 * Insert block that was represented by now fictitious dedup
717 * entry (create a new SHA entry and preserve stats of the
718 * old CRC one). If checksum upgrade fails insert the
719 * candidate into Pass2 list and return - keep both trees
720 * unmodified.
721 */
722 sha_de = calloc(1, sizeof(*sha_de));
723 sha_de->leaf = de->leaf;
724 sha_de->ref_blks = de->u.de.ref_blks;
725 sha_de->ref_size = de->u.de.ref_size;
726 if (upgrade_chksum(&sha_de->leaf, sha_de->sha_hash)) {
727 free(sha_de);
728 goto pass2_insert;
729 }
730 MemoryUse += sizeof(*sha_de);
731
732 RB_INIT(&de->u.fict_root);
733 /*
734 * Here we can insert without prior checking because the tree
735 * is empty at this point
736 */
737 RB_INSERT(sha_dedup_entry_rb_tree, &de->u.fict_root, sha_de);
738
739 /*
740 * Mark entry in CRC tree fictitious
741 */
742 de->flags |= HAMMER_DEDUP_ENTRY_FICTITIOUS;
743
744 /*
745 * Upgrade checksum of the candidate and insert it into
746 * SHA subtree. If upgrade fails insert the candidate into
747 * Pass2 list.
748 */
749 if (upgrade_chksum(scan_leaf, temp.sha_hash)) {
750 goto pass2_insert;
751 }
752 sha_de = RB_FIND(sha_dedup_entry_rb_tree, &de->u.fict_root,
753 &temp);
754 if (sha_de != NULL)
755 /* There is an entry with this SHA already, but the only
756 * RB-tree element at this point is that entry we just
757 * added. We know for sure these blocks are different
758 * (this is crc_failure branch) so treat it as SHA
759 * collision.
760 */
761 goto sha256_failure;
762
763 sha_de = calloc(1, sizeof(*sha_de));
764 sha_de->leaf = *scan_leaf;
765 memcpy(sha_de->sha_hash, temp.sha_hash, SHA256_DIGEST_LENGTH);
766 RB_INSERT(sha_dedup_entry_rb_tree, &de->u.fict_root, sha_de);
767 MemoryUse += sizeof(*sha_de);
768 goto upgrade_stats_sha;
769 }
770
771 upgrade_stats:
772 de->u.de.ref_blks += 1;
773 de->u.de.ref_size += scan_leaf->data_len;
774 return (1);
775
776 upgrade_stats_sha:
777 sha_de->ref_blks += 1;
778 sha_de->ref_size += scan_leaf->data_len;
779 return (1);
780
781 pass2_insert:
782 /*
783 * If in pass2 mode don't insert anything, fall through to
784 * terminate_early
785 */
786 if ((flags & DEDUP_PASS2) == 0) {
787 pass2_de = calloc(1, sizeof(*pass2_de));
788 pass2_de->leaf = *scan_leaf;
789 STAILQ_INSERT_TAIL(&pass2_dedup_queue, pass2_de, sq_entry);
790 dedup_skipped_size += scan_leaf->data_len;
791 return (1);
792 }
793
794 terminate_early:
795 /*
796 * Early termination path. Fixup stats.
797 */
798 dedup_alloc_size += scan_leaf->data_len;
799 dedup_ref_size += scan_leaf->data_len;
800 return (0);
801 }
802
803 static int
804 upgrade_chksum(hammer_btree_leaf_elm_t leaf, uint8_t *sha_hash)
805 {
806 struct hammer_ioc_data data;
807 char *buf = malloc(DEDUP_BUF);
808 SHA256_CTX ctx;
809 int error;
810
811 bzero(&data, sizeof(data));
812 data.elm = leaf->base;
813 data.ubuf = buf;
814 data.size = DEDUP_BUF;
815
816 error = 0;
817 if (ioctl(glob_fd, HAMMERIOC_GET_DATA, &data) < 0) {
818 fprintf(stderr, "Get-data failed: %s\n", strerror(errno));
819 error = 1;
820 goto done;
821 }
822 DedupDataReads += leaf->data_len;
823
824 if (data.leaf.data_len != leaf->data_len) {
825 error = 1;
826 goto done;
827 }
828
829 if (data.leaf.base.btype == HAMMER_BTREE_TYPE_RECORD &&
830 data.leaf.base.rec_type == HAMMER_RECTYPE_DATA) {
831 SHA256_Init(&ctx);
832 SHA256_Update(&ctx, (void *)buf, data.leaf.data_len);
833 SHA256_Final(sha_hash, &ctx);
834 }
835
836 done:
837 free(buf);
838 return (error);
839 }
840
841 static void
842 sigAlrm(int signo __unused)
843 {
844 SigAlrmFlag = 1;
845 }
846
847 static void
848 sigInfo(int signo __unused)
849 {
850 SigInfoFlag = 1;
851 }
852
853 static void
854 scan_pfs(char *filesystem, scan_pfs_cb_t func, const char *id)
855 {
856 struct hammer_ioc_mirror_rw mirror;
857 hammer_ioc_mrecord_any_t mrec;
858 struct hammer_btree_leaf_elm elm;
859 char *buf = malloc(DEDUP_BUF);
860 char buf1[8];
861 char buf2[8];
862 int offset, bytes;
863
864 SigInfoFlag = 0;
865 DedupDataReads = 0;
866 DedupCurrentRecords = 0;
867 signal(SIGINFO, sigInfo);
868 signal(SIGALRM, sigAlrm);
869
870 /*
871 * Deduplication happens per element so hammer(8) is in full
872 * control of the ioctl()s to actually perform it. SIGALRM
873 * needs to be handled within hammer(8) but a checkpoint
874 * is needed for resuming. Use cycle file for that.
875 *
876 * Try to obtain the previous obj_id from the cycle file and
877 * if not available just start from the beginning.
878 */
879 bzero(&mirror, sizeof(mirror));
880 hammer_key_beg_init(&mirror.key_beg);
881 hammer_get_cycle(&mirror.key_beg, &mirror.tid_beg);
882
883 if (mirror.key_beg.obj_id != (int64_t)HAMMER_MIN_OBJID) {
884 if (VerboseOpt)
885 fprintf(stderr, "%s: mirror-read: Resuming at object %016jx\n",
886 id, (uintmax_t)mirror.key_beg.obj_id);
887 }
888
889 hammer_key_end_init(&mirror.key_end);
890
891 mirror.tid_beg = glob_pfs.ondisk->sync_beg_tid;
892 mirror.tid_end = glob_pfs.ondisk->sync_end_tid;
893 mirror.head.flags |= HAMMER_IOC_MIRROR_NODATA; /* we want only keys */
894 mirror.ubuf = buf;
895 mirror.size = DEDUP_BUF;
896 mirror.pfs_id = glob_pfs.pfs_id;
897 mirror.shared_uuid = glob_pfs.ondisk->shared_uuid;
898
899 if (VerboseOpt && DedupCrcStart == 0) {
900 printf("%s %s: objspace %016jx:%04x %016jx:%04x\n",
901 id, filesystem,
902 (uintmax_t)mirror.key_beg.obj_id,
903 mirror.key_beg.localization,
904 (uintmax_t)mirror.key_end.obj_id,
905 mirror.key_end.localization);
906 printf("%s %s: pfs_id %d\n",
907 id, filesystem, glob_pfs.pfs_id);
908 }
909 fflush(stdout);
910 fflush(stderr);
911
912 do {
913 mirror.count = 0;
914 mirror.pfs_id = glob_pfs.pfs_id;
915 mirror.shared_uuid = glob_pfs.ondisk->shared_uuid;
916 if (ioctl(glob_fd, HAMMERIOC_MIRROR_READ, &mirror) < 0)
917 err(1, "Mirror-read %s failed", filesystem);
918 if (mirror.head.flags & HAMMER_IOC_HEAD_ERROR)
919 errx(1, "Mirror-read %s fatal error %d",
920 filesystem, mirror.head.error);
921 if (mirror.count) {
922 offset = 0;
923 while (offset < mirror.count) {
924 mrec = (void *)((char *)buf + offset);
925 bytes = HAMMER_HEAD_DOALIGN(mrec->head.rec_size);
926 if (offset + bytes > mirror.count)
927 errx(1, "Misaligned record");
928 assert((mrec->head.type &
929 HAMMER_MRECF_TYPE_MASK) ==
930 HAMMER_MREC_TYPE_REC);
931 offset += bytes;
932 elm = mrec->rec.leaf;
933 if (elm.base.btype != HAMMER_BTREE_TYPE_RECORD)
934 continue;
935 if (elm.base.rec_type != HAMMER_RECTYPE_DATA)
936 continue;
937 ++DedupCurrentRecords;
938 if (DedupCrcStart != DedupCrcEnd) {
939 if (elm.data_crc < DedupCrcStart)
940 continue;
941 if (DedupCrcEnd &&
942 elm.data_crc >= DedupCrcEnd) {
943 continue;
944 }
945 }
946 func(&elm, 0);
947 }
948 }
949 mirror.key_beg = mirror.key_cur;
950 if (DidInterrupt || SigAlrmFlag) {
951 if (VerboseOpt)
952 fprintf(stderr, "%s\n",
953 (DidInterrupt ? "Interrupted" : "Timeout"));
954 hammer_set_cycle(&mirror.key_cur, mirror.tid_beg);
955 if (VerboseOpt)
956 fprintf(stderr, "Cyclefile %s updated for "
957 "continuation\n", CyclePath);
958 exit(1);
959 }
960 if (SigInfoFlag) {
961 if (DedupTotalRecords) {
962 humanize_unsigned(buf1, sizeof(buf1),
963 DedupDataReads,
964 "B", 1024);
965 humanize_unsigned(buf2, sizeof(buf2),
966 dedup_successes_bytes,
967 "B", 1024);
968 fprintf(stderr, "%s count %7jd/%jd "
969 "(%02d.%02d%%) "
970 "ioread %s newddup %s\n",
971 id,
972 (intmax_t)DedupCurrentRecords,
973 (intmax_t)DedupTotalRecords,
974 (int)(DedupCurrentRecords * 100 /
975 DedupTotalRecords),
976 (int)(DedupCurrentRecords * 10000 /
977 DedupTotalRecords % 100),
978 buf1, buf2);
979 } else {
980 fprintf(stderr, "%s count %-7jd\n",
981 id,
982 (intmax_t)DedupCurrentRecords);
983 }
984 SigInfoFlag = 0;
985 }
986 } while (mirror.count != 0);
987
988 signal(SIGINFO, SIG_IGN);
989 signal(SIGALRM, SIG_IGN);
990
991 free(buf);
992 }
993
994 static void
995 dump_simulated_dedup(void)
996 {
997 struct sim_dedup_entry *sim_de;
998
999 printf("=== Dumping simulated dedup entries:\n");
1000 RB_FOREACH(sim_de, sim_dedup_entry_rb_tree, &sim_dedup_tree) {
1001 printf("\tcrc=%08x cnt=%ju size=%ju\n",
1002 sim_de->crc,
1003 (intmax_t)sim_de->ref_blks,
1004 (intmax_t)sim_de->ref_size);
1005 }
1006 printf("end of dump ===\n");
1007 }
1008
1009 static void
1010 dump_real_dedup(void)
1011 {
1012 struct dedup_entry *de;
1013 struct sha_dedup_entry *sha_de;
1014 int i;
1015
1016 printf("=== Dumping dedup entries:\n");
1017 RB_FOREACH(de, dedup_entry_rb_tree, &dedup_tree) {
1018 if (de->flags & HAMMER_DEDUP_ENTRY_FICTITIOUS) {
1019 printf("\tcrc=%08x fictitious\n", de->leaf.data_crc);
1020
1021 RB_FOREACH(sha_de, sha_dedup_entry_rb_tree, &de->u.fict_root) {
1022 printf("\t\tcrc=%08x cnt=%ju size=%ju\n\t"
1023 "\t\tsha=",
1024 sha_de->leaf.data_crc,
1025 (intmax_t)sha_de->ref_blks,
1026 (intmax_t)sha_de->ref_size);
1027 for (i = 0; i < SHA256_DIGEST_LENGTH; ++i)
1028 printf("%02x", sha_de->sha_hash[i]);
1029 printf("\n");
1030 }
1031 } else {
1032 printf("\tcrc=%08x cnt=%ju size=%ju\n",
1033 de->leaf.data_crc,
1034 (intmax_t)de->u.de.ref_blks,
1035 (intmax_t)de->u.de.ref_size);
1036 }
1037 }
1038 printf("end of dump ===\n");
1039 }
1040
1041 static void
1042 dedup_usage(int code)
1043 {
1044 fprintf(stderr,
1045 "hammer dedup-simulate <filesystem>\n"
1046 "hammer dedup <filesystem>\n"
1047 );
1048 exit(code);
1049 }
DragonFly BSD