dm-log.c 20 KB

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  1. /*
  2. * Copyright (C) 2003 Sistina Software
  3. * Copyright (C) 2004-2008 Red Hat, Inc. All rights reserved.
  4. *
  5. * This file is released under the LGPL.
  6. */
  7. #include <linux/init.h>
  8. #include <linux/slab.h>
  9. #include <linux/module.h>
  10. #include <linux/vmalloc.h>
  11. #include <linux/dm-io.h>
  12. #include <linux/dm-dirty-log.h>
  13. #include <linux/device-mapper.h>
  14. #define DM_MSG_PREFIX "dirty region log"
  15. static LIST_HEAD(_log_types);
  16. static DEFINE_SPINLOCK(_lock);
  17. static struct dm_dirty_log_type *__find_dirty_log_type(const char *name)
  18. {
  19. struct dm_dirty_log_type *log_type;
  20. list_for_each_entry(log_type, &_log_types, list)
  21. if (!strcmp(name, log_type->name))
  22. return log_type;
  23. return NULL;
  24. }
  25. static struct dm_dirty_log_type *_get_dirty_log_type(const char *name)
  26. {
  27. struct dm_dirty_log_type *log_type;
  28. spin_lock(&_lock);
  29. log_type = __find_dirty_log_type(name);
  30. if (log_type && !try_module_get(log_type->module))
  31. log_type = NULL;
  32. spin_unlock(&_lock);
  33. return log_type;
  34. }
  35. /*
  36. * get_type
  37. * @type_name
  38. *
  39. * Attempt to retrieve the dm_dirty_log_type by name. If not already
  40. * available, attempt to load the appropriate module.
  41. *
  42. * Log modules are named "dm-log-" followed by the 'type_name'.
  43. * Modules may contain multiple types.
  44. * This function will first try the module "dm-log-<type_name>",
  45. * then truncate 'type_name' on the last '-' and try again.
  46. *
  47. * For example, if type_name was "clustered-disk", it would search
  48. * 'dm-log-clustered-disk' then 'dm-log-clustered'.
  49. *
  50. * Returns: dirty_log_type* on success, NULL on failure
  51. */
  52. static struct dm_dirty_log_type *get_type(const char *type_name)
  53. {
  54. char *p, *type_name_dup;
  55. struct dm_dirty_log_type *log_type;
  56. if (!type_name)
  57. return NULL;
  58. log_type = _get_dirty_log_type(type_name);
  59. if (log_type)
  60. return log_type;
  61. type_name_dup = kstrdup(type_name, GFP_KERNEL);
  62. if (!type_name_dup) {
  63. DMWARN("No memory left to attempt log module load for \"%s\"",
  64. type_name);
  65. return NULL;
  66. }
  67. while (request_module("dm-log-%s", type_name_dup) ||
  68. !(log_type = _get_dirty_log_type(type_name))) {
  69. p = strrchr(type_name_dup, '-');
  70. if (!p)
  71. break;
  72. p[0] = '\0';
  73. }
  74. if (!log_type)
  75. DMWARN("Module for logging type \"%s\" not found.", type_name);
  76. kfree(type_name_dup);
  77. return log_type;
  78. }
  79. static void put_type(struct dm_dirty_log_type *type)
  80. {
  81. if (!type)
  82. return;
  83. spin_lock(&_lock);
  84. if (!__find_dirty_log_type(type->name))
  85. goto out;
  86. module_put(type->module);
  87. out:
  88. spin_unlock(&_lock);
  89. }
  90. int dm_dirty_log_type_register(struct dm_dirty_log_type *type)
  91. {
  92. int r = 0;
  93. spin_lock(&_lock);
  94. if (!__find_dirty_log_type(type->name))
  95. list_add(&type->list, &_log_types);
  96. else
  97. r = -EEXIST;
  98. spin_unlock(&_lock);
  99. return r;
  100. }
  101. EXPORT_SYMBOL(dm_dirty_log_type_register);
  102. int dm_dirty_log_type_unregister(struct dm_dirty_log_type *type)
  103. {
  104. spin_lock(&_lock);
  105. if (!__find_dirty_log_type(type->name)) {
  106. spin_unlock(&_lock);
  107. return -EINVAL;
  108. }
  109. list_del(&type->list);
  110. spin_unlock(&_lock);
  111. return 0;
  112. }
  113. EXPORT_SYMBOL(dm_dirty_log_type_unregister);
  114. struct dm_dirty_log *dm_dirty_log_create(const char *type_name,
  115. struct dm_target *ti,
  116. int (*flush_callback_fn)(struct dm_target *ti),
  117. unsigned int argc, char **argv)
  118. {
  119. struct dm_dirty_log_type *type;
  120. struct dm_dirty_log *log;
  121. log = kmalloc(sizeof(*log), GFP_KERNEL);
  122. if (!log)
  123. return NULL;
  124. type = get_type(type_name);
  125. if (!type) {
  126. kfree(log);
  127. return NULL;
  128. }
  129. log->flush_callback_fn = flush_callback_fn;
  130. log->type = type;
  131. if (type->ctr(log, ti, argc, argv)) {
  132. kfree(log);
  133. put_type(type);
  134. return NULL;
  135. }
  136. return log;
  137. }
  138. EXPORT_SYMBOL(dm_dirty_log_create);
  139. void dm_dirty_log_destroy(struct dm_dirty_log *log)
  140. {
  141. log->type->dtr(log);
  142. put_type(log->type);
  143. kfree(log);
  144. }
  145. EXPORT_SYMBOL(dm_dirty_log_destroy);
  146. /*-----------------------------------------------------------------
  147. * Persistent and core logs share a lot of their implementation.
  148. * FIXME: need a reload method to be called from a resume
  149. *---------------------------------------------------------------*/
  150. /*
  151. * Magic for persistent mirrors: "MiRr"
  152. */
  153. #define MIRROR_MAGIC 0x4D695272
  154. /*
  155. * The on-disk version of the metadata.
  156. */
  157. #define MIRROR_DISK_VERSION 2
  158. #define LOG_OFFSET 2
  159. struct log_header_disk {
  160. __le32 magic;
  161. /*
  162. * Simple, incrementing version. no backward
  163. * compatibility.
  164. */
  165. __le32 version;
  166. __le64 nr_regions;
  167. } __packed;
  168. struct log_header_core {
  169. uint32_t magic;
  170. uint32_t version;
  171. uint64_t nr_regions;
  172. };
  173. struct log_c {
  174. struct dm_target *ti;
  175. int touched_dirtied;
  176. int touched_cleaned;
  177. int flush_failed;
  178. uint32_t region_size;
  179. unsigned int region_count;
  180. region_t sync_count;
  181. unsigned bitset_uint32_count;
  182. uint32_t *clean_bits;
  183. uint32_t *sync_bits;
  184. uint32_t *recovering_bits; /* FIXME: this seems excessive */
  185. int sync_search;
  186. /* Resync flag */
  187. enum sync {
  188. DEFAULTSYNC, /* Synchronize if necessary */
  189. NOSYNC, /* Devices known to be already in sync */
  190. FORCESYNC, /* Force a sync to happen */
  191. } sync;
  192. struct dm_io_request io_req;
  193. /*
  194. * Disk log fields
  195. */
  196. int log_dev_failed;
  197. int log_dev_flush_failed;
  198. struct dm_dev *log_dev;
  199. struct log_header_core header;
  200. struct dm_io_region header_location;
  201. struct log_header_disk *disk_header;
  202. };
  203. /*
  204. * The touched member needs to be updated every time we access
  205. * one of the bitsets.
  206. */
  207. static inline int log_test_bit(uint32_t *bs, unsigned bit)
  208. {
  209. return test_bit_le(bit, bs) ? 1 : 0;
  210. }
  211. static inline void log_set_bit(struct log_c *l,
  212. uint32_t *bs, unsigned bit)
  213. {
  214. __set_bit_le(bit, bs);
  215. l->touched_cleaned = 1;
  216. }
  217. static inline void log_clear_bit(struct log_c *l,
  218. uint32_t *bs, unsigned bit)
  219. {
  220. __clear_bit_le(bit, bs);
  221. l->touched_dirtied = 1;
  222. }
  223. /*----------------------------------------------------------------
  224. * Header IO
  225. *--------------------------------------------------------------*/
  226. static void header_to_disk(struct log_header_core *core, struct log_header_disk *disk)
  227. {
  228. disk->magic = cpu_to_le32(core->magic);
  229. disk->version = cpu_to_le32(core->version);
  230. disk->nr_regions = cpu_to_le64(core->nr_regions);
  231. }
  232. static void header_from_disk(struct log_header_core *core, struct log_header_disk *disk)
  233. {
  234. core->magic = le32_to_cpu(disk->magic);
  235. core->version = le32_to_cpu(disk->version);
  236. core->nr_regions = le64_to_cpu(disk->nr_regions);
  237. }
  238. static int rw_header(struct log_c *lc, int op)
  239. {
  240. lc->io_req.bi_op = op;
  241. lc->io_req.bi_op_flags = 0;
  242. return dm_io(&lc->io_req, 1, &lc->header_location, NULL);
  243. }
  244. static int flush_header(struct log_c *lc)
  245. {
  246. struct dm_io_region null_location = {
  247. .bdev = lc->header_location.bdev,
  248. .sector = 0,
  249. .count = 0,
  250. };
  251. lc->io_req.bi_op = REQ_OP_WRITE;
  252. lc->io_req.bi_op_flags = WRITE_FLUSH;
  253. return dm_io(&lc->io_req, 1, &null_location, NULL);
  254. }
  255. static int read_header(struct log_c *log)
  256. {
  257. int r;
  258. r = rw_header(log, REQ_OP_READ);
  259. if (r)
  260. return r;
  261. header_from_disk(&log->header, log->disk_header);
  262. /* New log required? */
  263. if (log->sync != DEFAULTSYNC || log->header.magic != MIRROR_MAGIC) {
  264. log->header.magic = MIRROR_MAGIC;
  265. log->header.version = MIRROR_DISK_VERSION;
  266. log->header.nr_regions = 0;
  267. }
  268. #ifdef __LITTLE_ENDIAN
  269. if (log->header.version == 1)
  270. log->header.version = 2;
  271. #endif
  272. if (log->header.version != MIRROR_DISK_VERSION) {
  273. DMWARN("incompatible disk log version");
  274. return -EINVAL;
  275. }
  276. return 0;
  277. }
  278. static int _check_region_size(struct dm_target *ti, uint32_t region_size)
  279. {
  280. if (region_size < 2 || region_size > ti->len)
  281. return 0;
  282. if (!is_power_of_2(region_size))
  283. return 0;
  284. return 1;
  285. }
  286. /*----------------------------------------------------------------
  287. * core log constructor/destructor
  288. *
  289. * argv contains region_size followed optionally by [no]sync
  290. *--------------------------------------------------------------*/
  291. #define BYTE_SHIFT 3
  292. static int create_log_context(struct dm_dirty_log *log, struct dm_target *ti,
  293. unsigned int argc, char **argv,
  294. struct dm_dev *dev)
  295. {
  296. enum sync sync = DEFAULTSYNC;
  297. struct log_c *lc;
  298. uint32_t region_size;
  299. unsigned int region_count;
  300. size_t bitset_size, buf_size;
  301. int r;
  302. char dummy;
  303. if (argc < 1 || argc > 2) {
  304. DMWARN("wrong number of arguments to dirty region log");
  305. return -EINVAL;
  306. }
  307. if (argc > 1) {
  308. if (!strcmp(argv[1], "sync"))
  309. sync = FORCESYNC;
  310. else if (!strcmp(argv[1], "nosync"))
  311. sync = NOSYNC;
  312. else {
  313. DMWARN("unrecognised sync argument to "
  314. "dirty region log: %s", argv[1]);
  315. return -EINVAL;
  316. }
  317. }
  318. if (sscanf(argv[0], "%u%c", &region_size, &dummy) != 1 ||
  319. !_check_region_size(ti, region_size)) {
  320. DMWARN("invalid region size %s", argv[0]);
  321. return -EINVAL;
  322. }
  323. region_count = dm_sector_div_up(ti->len, region_size);
  324. lc = kmalloc(sizeof(*lc), GFP_KERNEL);
  325. if (!lc) {
  326. DMWARN("couldn't allocate core log");
  327. return -ENOMEM;
  328. }
  329. lc->ti = ti;
  330. lc->touched_dirtied = 0;
  331. lc->touched_cleaned = 0;
  332. lc->flush_failed = 0;
  333. lc->region_size = region_size;
  334. lc->region_count = region_count;
  335. lc->sync = sync;
  336. /*
  337. * Work out how many "unsigned long"s we need to hold the bitset.
  338. */
  339. bitset_size = dm_round_up(region_count,
  340. sizeof(*lc->clean_bits) << BYTE_SHIFT);
  341. bitset_size >>= BYTE_SHIFT;
  342. lc->bitset_uint32_count = bitset_size / sizeof(*lc->clean_bits);
  343. /*
  344. * Disk log?
  345. */
  346. if (!dev) {
  347. lc->clean_bits = vmalloc(bitset_size);
  348. if (!lc->clean_bits) {
  349. DMWARN("couldn't allocate clean bitset");
  350. kfree(lc);
  351. return -ENOMEM;
  352. }
  353. lc->disk_header = NULL;
  354. } else {
  355. lc->log_dev = dev;
  356. lc->log_dev_failed = 0;
  357. lc->log_dev_flush_failed = 0;
  358. lc->header_location.bdev = lc->log_dev->bdev;
  359. lc->header_location.sector = 0;
  360. /*
  361. * Buffer holds both header and bitset.
  362. */
  363. buf_size =
  364. dm_round_up((LOG_OFFSET << SECTOR_SHIFT) + bitset_size,
  365. bdev_logical_block_size(lc->header_location.
  366. bdev));
  367. if (buf_size > i_size_read(dev->bdev->bd_inode)) {
  368. DMWARN("log device %s too small: need %llu bytes",
  369. dev->name, (unsigned long long)buf_size);
  370. kfree(lc);
  371. return -EINVAL;
  372. }
  373. lc->header_location.count = buf_size >> SECTOR_SHIFT;
  374. lc->io_req.mem.type = DM_IO_VMA;
  375. lc->io_req.notify.fn = NULL;
  376. lc->io_req.client = dm_io_client_create();
  377. if (IS_ERR(lc->io_req.client)) {
  378. r = PTR_ERR(lc->io_req.client);
  379. DMWARN("couldn't allocate disk io client");
  380. kfree(lc);
  381. return r;
  382. }
  383. lc->disk_header = vmalloc(buf_size);
  384. if (!lc->disk_header) {
  385. DMWARN("couldn't allocate disk log buffer");
  386. dm_io_client_destroy(lc->io_req.client);
  387. kfree(lc);
  388. return -ENOMEM;
  389. }
  390. lc->io_req.mem.ptr.vma = lc->disk_header;
  391. lc->clean_bits = (void *)lc->disk_header +
  392. (LOG_OFFSET << SECTOR_SHIFT);
  393. }
  394. memset(lc->clean_bits, -1, bitset_size);
  395. lc->sync_bits = vmalloc(bitset_size);
  396. if (!lc->sync_bits) {
  397. DMWARN("couldn't allocate sync bitset");
  398. if (!dev)
  399. vfree(lc->clean_bits);
  400. else
  401. dm_io_client_destroy(lc->io_req.client);
  402. vfree(lc->disk_header);
  403. kfree(lc);
  404. return -ENOMEM;
  405. }
  406. memset(lc->sync_bits, (sync == NOSYNC) ? -1 : 0, bitset_size);
  407. lc->sync_count = (sync == NOSYNC) ? region_count : 0;
  408. lc->recovering_bits = vzalloc(bitset_size);
  409. if (!lc->recovering_bits) {
  410. DMWARN("couldn't allocate sync bitset");
  411. vfree(lc->sync_bits);
  412. if (!dev)
  413. vfree(lc->clean_bits);
  414. else
  415. dm_io_client_destroy(lc->io_req.client);
  416. vfree(lc->disk_header);
  417. kfree(lc);
  418. return -ENOMEM;
  419. }
  420. lc->sync_search = 0;
  421. log->context = lc;
  422. return 0;
  423. }
  424. static int core_ctr(struct dm_dirty_log *log, struct dm_target *ti,
  425. unsigned int argc, char **argv)
  426. {
  427. return create_log_context(log, ti, argc, argv, NULL);
  428. }
  429. static void destroy_log_context(struct log_c *lc)
  430. {
  431. vfree(lc->sync_bits);
  432. vfree(lc->recovering_bits);
  433. kfree(lc);
  434. }
  435. static void core_dtr(struct dm_dirty_log *log)
  436. {
  437. struct log_c *lc = (struct log_c *) log->context;
  438. vfree(lc->clean_bits);
  439. destroy_log_context(lc);
  440. }
  441. /*----------------------------------------------------------------
  442. * disk log constructor/destructor
  443. *
  444. * argv contains log_device region_size followed optionally by [no]sync
  445. *--------------------------------------------------------------*/
  446. static int disk_ctr(struct dm_dirty_log *log, struct dm_target *ti,
  447. unsigned int argc, char **argv)
  448. {
  449. int r;
  450. struct dm_dev *dev;
  451. if (argc < 2 || argc > 3) {
  452. DMWARN("wrong number of arguments to disk dirty region log");
  453. return -EINVAL;
  454. }
  455. r = dm_get_device(ti, argv[0], dm_table_get_mode(ti->table), &dev);
  456. if (r)
  457. return r;
  458. r = create_log_context(log, ti, argc - 1, argv + 1, dev);
  459. if (r) {
  460. dm_put_device(ti, dev);
  461. return r;
  462. }
  463. return 0;
  464. }
  465. static void disk_dtr(struct dm_dirty_log *log)
  466. {
  467. struct log_c *lc = (struct log_c *) log->context;
  468. dm_put_device(lc->ti, lc->log_dev);
  469. vfree(lc->disk_header);
  470. dm_io_client_destroy(lc->io_req.client);
  471. destroy_log_context(lc);
  472. }
  473. static void fail_log_device(struct log_c *lc)
  474. {
  475. if (lc->log_dev_failed)
  476. return;
  477. lc->log_dev_failed = 1;
  478. dm_table_event(lc->ti->table);
  479. }
  480. static int disk_resume(struct dm_dirty_log *log)
  481. {
  482. int r;
  483. unsigned i;
  484. struct log_c *lc = (struct log_c *) log->context;
  485. size_t size = lc->bitset_uint32_count * sizeof(uint32_t);
  486. /* read the disk header */
  487. r = read_header(lc);
  488. if (r) {
  489. DMWARN("%s: Failed to read header on dirty region log device",
  490. lc->log_dev->name);
  491. fail_log_device(lc);
  492. /*
  493. * If the log device cannot be read, we must assume
  494. * all regions are out-of-sync. If we simply return
  495. * here, the state will be uninitialized and could
  496. * lead us to return 'in-sync' status for regions
  497. * that are actually 'out-of-sync'.
  498. */
  499. lc->header.nr_regions = 0;
  500. }
  501. /* set or clear any new bits -- device has grown */
  502. if (lc->sync == NOSYNC)
  503. for (i = lc->header.nr_regions; i < lc->region_count; i++)
  504. /* FIXME: amazingly inefficient */
  505. log_set_bit(lc, lc->clean_bits, i);
  506. else
  507. for (i = lc->header.nr_regions; i < lc->region_count; i++)
  508. /* FIXME: amazingly inefficient */
  509. log_clear_bit(lc, lc->clean_bits, i);
  510. /* clear any old bits -- device has shrunk */
  511. for (i = lc->region_count; i % (sizeof(*lc->clean_bits) << BYTE_SHIFT); i++)
  512. log_clear_bit(lc, lc->clean_bits, i);
  513. /* copy clean across to sync */
  514. memcpy(lc->sync_bits, lc->clean_bits, size);
  515. lc->sync_count = memweight(lc->clean_bits,
  516. lc->bitset_uint32_count * sizeof(uint32_t));
  517. lc->sync_search = 0;
  518. /* set the correct number of regions in the header */
  519. lc->header.nr_regions = lc->region_count;
  520. header_to_disk(&lc->header, lc->disk_header);
  521. /* write the new header */
  522. r = rw_header(lc, REQ_OP_WRITE);
  523. if (!r) {
  524. r = flush_header(lc);
  525. if (r)
  526. lc->log_dev_flush_failed = 1;
  527. }
  528. if (r) {
  529. DMWARN("%s: Failed to write header on dirty region log device",
  530. lc->log_dev->name);
  531. fail_log_device(lc);
  532. }
  533. return r;
  534. }
  535. static uint32_t core_get_region_size(struct dm_dirty_log *log)
  536. {
  537. struct log_c *lc = (struct log_c *) log->context;
  538. return lc->region_size;
  539. }
  540. static int core_resume(struct dm_dirty_log *log)
  541. {
  542. struct log_c *lc = (struct log_c *) log->context;
  543. lc->sync_search = 0;
  544. return 0;
  545. }
  546. static int core_is_clean(struct dm_dirty_log *log, region_t region)
  547. {
  548. struct log_c *lc = (struct log_c *) log->context;
  549. return log_test_bit(lc->clean_bits, region);
  550. }
  551. static int core_in_sync(struct dm_dirty_log *log, region_t region, int block)
  552. {
  553. struct log_c *lc = (struct log_c *) log->context;
  554. return log_test_bit(lc->sync_bits, region);
  555. }
  556. static int core_flush(struct dm_dirty_log *log)
  557. {
  558. /* no op */
  559. return 0;
  560. }
  561. static int disk_flush(struct dm_dirty_log *log)
  562. {
  563. int r, i;
  564. struct log_c *lc = log->context;
  565. /* only write if the log has changed */
  566. if (!lc->touched_cleaned && !lc->touched_dirtied)
  567. return 0;
  568. if (lc->touched_cleaned && log->flush_callback_fn &&
  569. log->flush_callback_fn(lc->ti)) {
  570. /*
  571. * At this point it is impossible to determine which
  572. * regions are clean and which are dirty (without
  573. * re-reading the log off disk). So mark all of them
  574. * dirty.
  575. */
  576. lc->flush_failed = 1;
  577. for (i = 0; i < lc->region_count; i++)
  578. log_clear_bit(lc, lc->clean_bits, i);
  579. }
  580. r = rw_header(lc, REQ_OP_WRITE);
  581. if (r)
  582. fail_log_device(lc);
  583. else {
  584. if (lc->touched_dirtied) {
  585. r = flush_header(lc);
  586. if (r) {
  587. lc->log_dev_flush_failed = 1;
  588. fail_log_device(lc);
  589. } else
  590. lc->touched_dirtied = 0;
  591. }
  592. lc->touched_cleaned = 0;
  593. }
  594. return r;
  595. }
  596. static void core_mark_region(struct dm_dirty_log *log, region_t region)
  597. {
  598. struct log_c *lc = (struct log_c *) log->context;
  599. log_clear_bit(lc, lc->clean_bits, region);
  600. }
  601. static void core_clear_region(struct dm_dirty_log *log, region_t region)
  602. {
  603. struct log_c *lc = (struct log_c *) log->context;
  604. if (likely(!lc->flush_failed))
  605. log_set_bit(lc, lc->clean_bits, region);
  606. }
  607. static int core_get_resync_work(struct dm_dirty_log *log, region_t *region)
  608. {
  609. struct log_c *lc = (struct log_c *) log->context;
  610. if (lc->sync_search >= lc->region_count)
  611. return 0;
  612. do {
  613. *region = find_next_zero_bit_le(lc->sync_bits,
  614. lc->region_count,
  615. lc->sync_search);
  616. lc->sync_search = *region + 1;
  617. if (*region >= lc->region_count)
  618. return 0;
  619. } while (log_test_bit(lc->recovering_bits, *region));
  620. log_set_bit(lc, lc->recovering_bits, *region);
  621. return 1;
  622. }
  623. static void core_set_region_sync(struct dm_dirty_log *log, region_t region,
  624. int in_sync)
  625. {
  626. struct log_c *lc = (struct log_c *) log->context;
  627. log_clear_bit(lc, lc->recovering_bits, region);
  628. if (in_sync) {
  629. log_set_bit(lc, lc->sync_bits, region);
  630. lc->sync_count++;
  631. } else if (log_test_bit(lc->sync_bits, region)) {
  632. lc->sync_count--;
  633. log_clear_bit(lc, lc->sync_bits, region);
  634. }
  635. }
  636. static region_t core_get_sync_count(struct dm_dirty_log *log)
  637. {
  638. struct log_c *lc = (struct log_c *) log->context;
  639. return lc->sync_count;
  640. }
  641. #define DMEMIT_SYNC \
  642. if (lc->sync != DEFAULTSYNC) \
  643. DMEMIT("%ssync ", lc->sync == NOSYNC ? "no" : "")
  644. static int core_status(struct dm_dirty_log *log, status_type_t status,
  645. char *result, unsigned int maxlen)
  646. {
  647. int sz = 0;
  648. struct log_c *lc = log->context;
  649. switch(status) {
  650. case STATUSTYPE_INFO:
  651. DMEMIT("1 %s", log->type->name);
  652. break;
  653. case STATUSTYPE_TABLE:
  654. DMEMIT("%s %u %u ", log->type->name,
  655. lc->sync == DEFAULTSYNC ? 1 : 2, lc->region_size);
  656. DMEMIT_SYNC;
  657. }
  658. return sz;
  659. }
  660. static int disk_status(struct dm_dirty_log *log, status_type_t status,
  661. char *result, unsigned int maxlen)
  662. {
  663. int sz = 0;
  664. struct log_c *lc = log->context;
  665. switch(status) {
  666. case STATUSTYPE_INFO:
  667. DMEMIT("3 %s %s %c", log->type->name, lc->log_dev->name,
  668. lc->log_dev_flush_failed ? 'F' :
  669. lc->log_dev_failed ? 'D' :
  670. 'A');
  671. break;
  672. case STATUSTYPE_TABLE:
  673. DMEMIT("%s %u %s %u ", log->type->name,
  674. lc->sync == DEFAULTSYNC ? 2 : 3, lc->log_dev->name,
  675. lc->region_size);
  676. DMEMIT_SYNC;
  677. }
  678. return sz;
  679. }
  680. static struct dm_dirty_log_type _core_type = {
  681. .name = "core",
  682. .module = THIS_MODULE,
  683. .ctr = core_ctr,
  684. .dtr = core_dtr,
  685. .resume = core_resume,
  686. .get_region_size = core_get_region_size,
  687. .is_clean = core_is_clean,
  688. .in_sync = core_in_sync,
  689. .flush = core_flush,
  690. .mark_region = core_mark_region,
  691. .clear_region = core_clear_region,
  692. .get_resync_work = core_get_resync_work,
  693. .set_region_sync = core_set_region_sync,
  694. .get_sync_count = core_get_sync_count,
  695. .status = core_status,
  696. };
  697. static struct dm_dirty_log_type _disk_type = {
  698. .name = "disk",
  699. .module = THIS_MODULE,
  700. .ctr = disk_ctr,
  701. .dtr = disk_dtr,
  702. .postsuspend = disk_flush,
  703. .resume = disk_resume,
  704. .get_region_size = core_get_region_size,
  705. .is_clean = core_is_clean,
  706. .in_sync = core_in_sync,
  707. .flush = disk_flush,
  708. .mark_region = core_mark_region,
  709. .clear_region = core_clear_region,
  710. .get_resync_work = core_get_resync_work,
  711. .set_region_sync = core_set_region_sync,
  712. .get_sync_count = core_get_sync_count,
  713. .status = disk_status,
  714. };
  715. static int __init dm_dirty_log_init(void)
  716. {
  717. int r;
  718. r = dm_dirty_log_type_register(&_core_type);
  719. if (r)
  720. DMWARN("couldn't register core log");
  721. r = dm_dirty_log_type_register(&_disk_type);
  722. if (r) {
  723. DMWARN("couldn't register disk type");
  724. dm_dirty_log_type_unregister(&_core_type);
  725. }
  726. return r;
  727. }
  728. static void __exit dm_dirty_log_exit(void)
  729. {
  730. dm_dirty_log_type_unregister(&_disk_type);
  731. dm_dirty_log_type_unregister(&_core_type);
  732. }
  733. module_init(dm_dirty_log_init);
  734. module_exit(dm_dirty_log_exit);
  735. MODULE_DESCRIPTION(DM_NAME " dirty region log");
  736. MODULE_AUTHOR("Joe Thornber, Heinz Mauelshagen <dm-devel@redhat.com>");
  737. MODULE_LICENSE("GPL");