dm-zoned-metadata.c 71 KB

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  1. // SPDX-License-Identifier: GPL-2.0-only
  2. /*
  3. * Copyright (C) 2017 Western Digital Corporation or its affiliates.
  4. *
  5. * This file is released under the GPL.
  6. */
  7. #include "dm-zoned.h"
  8. #include <linux/module.h>
  9. #include <linux/crc32.h>
  10. #include <linux/sched/mm.h>
  11. #define DM_MSG_PREFIX "zoned metadata"
  12. /*
  13. * Metadata version.
  14. */
  15. #define DMZ_META_VER 2
  16. /*
  17. * On-disk super block magic.
  18. */
  19. #define DMZ_MAGIC ((((unsigned int)('D')) << 24) | \
  20. (((unsigned int)('Z')) << 16) | \
  21. (((unsigned int)('B')) << 8) | \
  22. ((unsigned int)('D')))
  23. /*
  24. * On disk super block.
  25. * This uses only 512 B but uses on disk a full 4KB block. This block is
  26. * followed on disk by the mapping table of chunks to zones and the bitmap
  27. * blocks indicating zone block validity.
  28. * The overall resulting metadata format is:
  29. * (1) Super block (1 block)
  30. * (2) Chunk mapping table (nr_map_blocks)
  31. * (3) Bitmap blocks (nr_bitmap_blocks)
  32. * All metadata blocks are stored in conventional zones, starting from
  33. * the first conventional zone found on disk.
  34. */
  35. struct dmz_super {
  36. /* Magic number */
  37. __le32 magic; /* 4 */
  38. /* Metadata version number */
  39. __le32 version; /* 8 */
  40. /* Generation number */
  41. __le64 gen; /* 16 */
  42. /* This block number */
  43. __le64 sb_block; /* 24 */
  44. /* The number of metadata blocks, including this super block */
  45. __le32 nr_meta_blocks; /* 28 */
  46. /* The number of sequential zones reserved for reclaim */
  47. __le32 nr_reserved_seq; /* 32 */
  48. /* The number of entries in the mapping table */
  49. __le32 nr_chunks; /* 36 */
  50. /* The number of blocks used for the chunk mapping table */
  51. __le32 nr_map_blocks; /* 40 */
  52. /* The number of blocks used for the block bitmaps */
  53. __le32 nr_bitmap_blocks; /* 44 */
  54. /* Checksum */
  55. __le32 crc; /* 48 */
  56. /* DM-Zoned label */
  57. u8 dmz_label[32]; /* 80 */
  58. /* DM-Zoned UUID */
  59. u8 dmz_uuid[16]; /* 96 */
  60. /* Device UUID */
  61. u8 dev_uuid[16]; /* 112 */
  62. /* Padding to full 512B sector */
  63. u8 reserved[400]; /* 512 */
  64. };
  65. /*
  66. * Chunk mapping entry: entries are indexed by chunk number
  67. * and give the zone ID (dzone_id) mapping the chunk on disk.
  68. * This zone may be sequential or random. If it is a sequential
  69. * zone, a second zone (bzone_id) used as a write buffer may
  70. * also be specified. This second zone will always be a randomly
  71. * writeable zone.
  72. */
  73. struct dmz_map {
  74. __le32 dzone_id;
  75. __le32 bzone_id;
  76. };
  77. /*
  78. * Chunk mapping table metadata: 512 8-bytes entries per 4KB block.
  79. */
  80. #define DMZ_MAP_ENTRIES (DMZ_BLOCK_SIZE / sizeof(struct dmz_map))
  81. #define DMZ_MAP_ENTRIES_SHIFT (ilog2(DMZ_MAP_ENTRIES))
  82. #define DMZ_MAP_ENTRIES_MASK (DMZ_MAP_ENTRIES - 1)
  83. #define DMZ_MAP_UNMAPPED UINT_MAX
  84. /*
  85. * Meta data block descriptor (for cached metadata blocks).
  86. */
  87. struct dmz_mblock {
  88. struct rb_node node;
  89. struct list_head link;
  90. sector_t no;
  91. unsigned int ref;
  92. unsigned long state;
  93. struct page *page;
  94. void *data;
  95. };
  96. /*
  97. * Metadata block state flags.
  98. */
  99. enum {
  100. DMZ_META_DIRTY,
  101. DMZ_META_READING,
  102. DMZ_META_WRITING,
  103. DMZ_META_ERROR,
  104. };
  105. /*
  106. * Super block information (one per metadata set).
  107. */
  108. struct dmz_sb {
  109. sector_t block;
  110. struct dmz_dev *dev;
  111. struct dmz_mblock *mblk;
  112. struct dmz_super *sb;
  113. struct dm_zone *zone;
  114. };
  115. /*
  116. * In-memory metadata.
  117. */
  118. struct dmz_metadata {
  119. struct dmz_dev *dev;
  120. unsigned int nr_devs;
  121. char devname[BDEVNAME_SIZE];
  122. char label[BDEVNAME_SIZE];
  123. uuid_t uuid;
  124. sector_t zone_bitmap_size;
  125. unsigned int zone_nr_bitmap_blocks;
  126. unsigned int zone_bits_per_mblk;
  127. sector_t zone_nr_blocks;
  128. sector_t zone_nr_blocks_shift;
  129. sector_t zone_nr_sectors;
  130. sector_t zone_nr_sectors_shift;
  131. unsigned int nr_bitmap_blocks;
  132. unsigned int nr_map_blocks;
  133. unsigned int nr_zones;
  134. unsigned int nr_useable_zones;
  135. unsigned int nr_meta_blocks;
  136. unsigned int nr_meta_zones;
  137. unsigned int nr_data_zones;
  138. unsigned int nr_cache_zones;
  139. unsigned int nr_rnd_zones;
  140. unsigned int nr_reserved_seq;
  141. unsigned int nr_chunks;
  142. /* Zone information array */
  143. struct xarray zones;
  144. struct dmz_sb sb[2];
  145. unsigned int mblk_primary;
  146. unsigned int sb_version;
  147. u64 sb_gen;
  148. unsigned int min_nr_mblks;
  149. unsigned int max_nr_mblks;
  150. atomic_t nr_mblks;
  151. struct rw_semaphore mblk_sem;
  152. struct mutex mblk_flush_lock;
  153. spinlock_t mblk_lock;
  154. struct rb_root mblk_rbtree;
  155. struct list_head mblk_lru_list;
  156. struct list_head mblk_dirty_list;
  157. struct shrinker *mblk_shrinker;
  158. /* Zone allocation management */
  159. struct mutex map_lock;
  160. struct dmz_mblock **map_mblk;
  161. unsigned int nr_cache;
  162. atomic_t unmap_nr_cache;
  163. struct list_head unmap_cache_list;
  164. struct list_head map_cache_list;
  165. atomic_t nr_reserved_seq_zones;
  166. struct list_head reserved_seq_zones_list;
  167. wait_queue_head_t free_wq;
  168. };
  169. #define dmz_zmd_info(zmd, format, args...) \
  170. DMINFO("(%s): " format, (zmd)->label, ## args)
  171. #define dmz_zmd_err(zmd, format, args...) \
  172. DMERR("(%s): " format, (zmd)->label, ## args)
  173. #define dmz_zmd_warn(zmd, format, args...) \
  174. DMWARN("(%s): " format, (zmd)->label, ## args)
  175. #define dmz_zmd_debug(zmd, format, args...) \
  176. DMDEBUG("(%s): " format, (zmd)->label, ## args)
  177. /*
  178. * Various accessors
  179. */
  180. static unsigned int dmz_dev_zone_id(struct dmz_metadata *zmd, struct dm_zone *zone)
  181. {
  182. if (WARN_ON(!zone))
  183. return 0;
  184. return zone->id - zone->dev->zone_offset;
  185. }
  186. sector_t dmz_start_sect(struct dmz_metadata *zmd, struct dm_zone *zone)
  187. {
  188. unsigned int zone_id = dmz_dev_zone_id(zmd, zone);
  189. return (sector_t)zone_id << zmd->zone_nr_sectors_shift;
  190. }
  191. sector_t dmz_start_block(struct dmz_metadata *zmd, struct dm_zone *zone)
  192. {
  193. unsigned int zone_id = dmz_dev_zone_id(zmd, zone);
  194. return (sector_t)zone_id << zmd->zone_nr_blocks_shift;
  195. }
  196. unsigned int dmz_zone_nr_blocks(struct dmz_metadata *zmd)
  197. {
  198. return zmd->zone_nr_blocks;
  199. }
  200. unsigned int dmz_zone_nr_sectors(struct dmz_metadata *zmd)
  201. {
  202. return zmd->zone_nr_sectors;
  203. }
  204. unsigned int dmz_zone_nr_sectors_shift(struct dmz_metadata *zmd)
  205. {
  206. return zmd->zone_nr_sectors_shift;
  207. }
  208. unsigned int dmz_nr_zones(struct dmz_metadata *zmd)
  209. {
  210. return zmd->nr_zones;
  211. }
  212. unsigned int dmz_nr_chunks(struct dmz_metadata *zmd)
  213. {
  214. return zmd->nr_chunks;
  215. }
  216. unsigned int dmz_nr_rnd_zones(struct dmz_metadata *zmd, int idx)
  217. {
  218. return zmd->dev[idx].nr_rnd;
  219. }
  220. unsigned int dmz_nr_unmap_rnd_zones(struct dmz_metadata *zmd, int idx)
  221. {
  222. return atomic_read(&zmd->dev[idx].unmap_nr_rnd);
  223. }
  224. unsigned int dmz_nr_cache_zones(struct dmz_metadata *zmd)
  225. {
  226. return zmd->nr_cache;
  227. }
  228. unsigned int dmz_nr_unmap_cache_zones(struct dmz_metadata *zmd)
  229. {
  230. return atomic_read(&zmd->unmap_nr_cache);
  231. }
  232. unsigned int dmz_nr_seq_zones(struct dmz_metadata *zmd, int idx)
  233. {
  234. return zmd->dev[idx].nr_seq;
  235. }
  236. unsigned int dmz_nr_unmap_seq_zones(struct dmz_metadata *zmd, int idx)
  237. {
  238. return atomic_read(&zmd->dev[idx].unmap_nr_seq);
  239. }
  240. static struct dm_zone *dmz_get(struct dmz_metadata *zmd, unsigned int zone_id)
  241. {
  242. return xa_load(&zmd->zones, zone_id);
  243. }
  244. static struct dm_zone *dmz_insert(struct dmz_metadata *zmd,
  245. unsigned int zone_id, struct dmz_dev *dev)
  246. {
  247. struct dm_zone *zone = kzalloc_obj(struct dm_zone);
  248. if (!zone)
  249. return ERR_PTR(-ENOMEM);
  250. if (xa_insert(&zmd->zones, zone_id, zone, GFP_KERNEL)) {
  251. kfree(zone);
  252. return ERR_PTR(-EBUSY);
  253. }
  254. INIT_LIST_HEAD(&zone->link);
  255. atomic_set(&zone->refcount, 0);
  256. zone->id = zone_id;
  257. zone->chunk = DMZ_MAP_UNMAPPED;
  258. zone->dev = dev;
  259. return zone;
  260. }
  261. const char *dmz_metadata_label(struct dmz_metadata *zmd)
  262. {
  263. return (const char *)zmd->label;
  264. }
  265. bool dmz_check_dev(struct dmz_metadata *zmd)
  266. {
  267. unsigned int i;
  268. for (i = 0; i < zmd->nr_devs; i++) {
  269. if (!dmz_check_bdev(&zmd->dev[i]))
  270. return false;
  271. }
  272. return true;
  273. }
  274. bool dmz_dev_is_dying(struct dmz_metadata *zmd)
  275. {
  276. unsigned int i;
  277. for (i = 0; i < zmd->nr_devs; i++) {
  278. if (dmz_bdev_is_dying(&zmd->dev[i]))
  279. return true;
  280. }
  281. return false;
  282. }
  283. /*
  284. * Lock/unlock mapping table.
  285. * The map lock also protects all the zone lists.
  286. */
  287. void dmz_lock_map(struct dmz_metadata *zmd)
  288. {
  289. mutex_lock(&zmd->map_lock);
  290. }
  291. void dmz_unlock_map(struct dmz_metadata *zmd)
  292. {
  293. mutex_unlock(&zmd->map_lock);
  294. }
  295. /*
  296. * Lock/unlock metadata access. This is a "read" lock on a semaphore
  297. * that prevents metadata flush from running while metadata are being
  298. * modified. The actual metadata write mutual exclusion is achieved with
  299. * the map lock and zone state management (active and reclaim state are
  300. * mutually exclusive).
  301. */
  302. void dmz_lock_metadata(struct dmz_metadata *zmd)
  303. {
  304. down_read(&zmd->mblk_sem);
  305. }
  306. void dmz_unlock_metadata(struct dmz_metadata *zmd)
  307. {
  308. up_read(&zmd->mblk_sem);
  309. }
  310. /*
  311. * Lock/unlock flush: prevent concurrent executions
  312. * of dmz_flush_metadata as well as metadata modification in reclaim
  313. * while flush is being executed.
  314. */
  315. void dmz_lock_flush(struct dmz_metadata *zmd)
  316. {
  317. mutex_lock(&zmd->mblk_flush_lock);
  318. }
  319. void dmz_unlock_flush(struct dmz_metadata *zmd)
  320. {
  321. mutex_unlock(&zmd->mblk_flush_lock);
  322. }
  323. /*
  324. * Allocate a metadata block.
  325. */
  326. static struct dmz_mblock *dmz_alloc_mblock(struct dmz_metadata *zmd,
  327. sector_t mblk_no)
  328. {
  329. struct dmz_mblock *mblk = NULL;
  330. /* See if we can reuse cached blocks */
  331. if (zmd->max_nr_mblks && atomic_read(&zmd->nr_mblks) > zmd->max_nr_mblks) {
  332. spin_lock(&zmd->mblk_lock);
  333. mblk = list_first_entry_or_null(&zmd->mblk_lru_list,
  334. struct dmz_mblock, link);
  335. if (mblk) {
  336. list_del_init(&mblk->link);
  337. rb_erase(&mblk->node, &zmd->mblk_rbtree);
  338. mblk->no = mblk_no;
  339. }
  340. spin_unlock(&zmd->mblk_lock);
  341. if (mblk)
  342. return mblk;
  343. }
  344. /* Allocate a new block */
  345. mblk = kmalloc_obj(struct dmz_mblock, GFP_NOIO);
  346. if (!mblk)
  347. return NULL;
  348. mblk->page = alloc_page(GFP_NOIO);
  349. if (!mblk->page) {
  350. kfree(mblk);
  351. return NULL;
  352. }
  353. RB_CLEAR_NODE(&mblk->node);
  354. INIT_LIST_HEAD(&mblk->link);
  355. mblk->ref = 0;
  356. mblk->state = 0;
  357. mblk->no = mblk_no;
  358. mblk->data = page_address(mblk->page);
  359. atomic_inc(&zmd->nr_mblks);
  360. return mblk;
  361. }
  362. /*
  363. * Free a metadata block.
  364. */
  365. static void dmz_free_mblock(struct dmz_metadata *zmd, struct dmz_mblock *mblk)
  366. {
  367. __free_pages(mblk->page, 0);
  368. kfree(mblk);
  369. atomic_dec(&zmd->nr_mblks);
  370. }
  371. /*
  372. * Insert a metadata block in the rbtree.
  373. */
  374. static void dmz_insert_mblock(struct dmz_metadata *zmd, struct dmz_mblock *mblk)
  375. {
  376. struct rb_root *root = &zmd->mblk_rbtree;
  377. struct rb_node **new = &(root->rb_node), *parent = NULL;
  378. struct dmz_mblock *b;
  379. /* Figure out where to put the new node */
  380. while (*new) {
  381. b = container_of(*new, struct dmz_mblock, node);
  382. parent = *new;
  383. new = (b->no < mblk->no) ? &((*new)->rb_left) : &((*new)->rb_right);
  384. }
  385. /* Add new node and rebalance tree */
  386. rb_link_node(&mblk->node, parent, new);
  387. rb_insert_color(&mblk->node, root);
  388. }
  389. /*
  390. * Lookup a metadata block in the rbtree. If the block is found, increment
  391. * its reference count.
  392. */
  393. static struct dmz_mblock *dmz_get_mblock_fast(struct dmz_metadata *zmd,
  394. sector_t mblk_no)
  395. {
  396. struct rb_root *root = &zmd->mblk_rbtree;
  397. struct rb_node *node = root->rb_node;
  398. struct dmz_mblock *mblk;
  399. while (node) {
  400. mblk = container_of(node, struct dmz_mblock, node);
  401. if (mblk->no == mblk_no) {
  402. /*
  403. * If this is the first reference to the block,
  404. * remove it from the LRU list.
  405. */
  406. mblk->ref++;
  407. if (mblk->ref == 1 &&
  408. !test_bit(DMZ_META_DIRTY, &mblk->state))
  409. list_del_init(&mblk->link);
  410. return mblk;
  411. }
  412. node = (mblk->no < mblk_no) ? node->rb_left : node->rb_right;
  413. }
  414. return NULL;
  415. }
  416. /*
  417. * Metadata block BIO end callback.
  418. */
  419. static void dmz_mblock_bio_end_io(struct bio *bio)
  420. {
  421. struct dmz_mblock *mblk = bio->bi_private;
  422. int flag;
  423. if (bio->bi_status)
  424. set_bit(DMZ_META_ERROR, &mblk->state);
  425. if (bio_op(bio) == REQ_OP_WRITE)
  426. flag = DMZ_META_WRITING;
  427. else
  428. flag = DMZ_META_READING;
  429. clear_bit_unlock(flag, &mblk->state);
  430. smp_mb__after_atomic();
  431. wake_up_bit(&mblk->state, flag);
  432. bio_put(bio);
  433. }
  434. /*
  435. * Read an uncached metadata block from disk and add it to the cache.
  436. */
  437. static struct dmz_mblock *dmz_get_mblock_slow(struct dmz_metadata *zmd,
  438. sector_t mblk_no)
  439. {
  440. struct dmz_mblock *mblk, *m;
  441. sector_t block = zmd->sb[zmd->mblk_primary].block + mblk_no;
  442. struct dmz_dev *dev = zmd->sb[zmd->mblk_primary].dev;
  443. struct bio *bio;
  444. if (dmz_bdev_is_dying(dev))
  445. return ERR_PTR(-EIO);
  446. /* Get a new block and a BIO to read it */
  447. mblk = dmz_alloc_mblock(zmd, mblk_no);
  448. if (!mblk)
  449. return ERR_PTR(-ENOMEM);
  450. bio = bio_alloc(dev->bdev, 1, REQ_OP_READ | REQ_META | REQ_PRIO,
  451. GFP_NOIO);
  452. spin_lock(&zmd->mblk_lock);
  453. /*
  454. * Make sure that another context did not start reading
  455. * the block already.
  456. */
  457. m = dmz_get_mblock_fast(zmd, mblk_no);
  458. if (m) {
  459. spin_unlock(&zmd->mblk_lock);
  460. dmz_free_mblock(zmd, mblk);
  461. bio_put(bio);
  462. return m;
  463. }
  464. mblk->ref++;
  465. set_bit(DMZ_META_READING, &mblk->state);
  466. dmz_insert_mblock(zmd, mblk);
  467. spin_unlock(&zmd->mblk_lock);
  468. /* Submit read BIO */
  469. bio->bi_iter.bi_sector = dmz_blk2sect(block);
  470. bio->bi_private = mblk;
  471. bio->bi_end_io = dmz_mblock_bio_end_io;
  472. __bio_add_page(bio, mblk->page, DMZ_BLOCK_SIZE, 0);
  473. submit_bio(bio);
  474. return mblk;
  475. }
  476. /*
  477. * Free metadata blocks.
  478. */
  479. static unsigned long dmz_shrink_mblock_cache(struct dmz_metadata *zmd,
  480. unsigned long limit)
  481. {
  482. struct dmz_mblock *mblk;
  483. unsigned long count = 0;
  484. if (!zmd->max_nr_mblks)
  485. return 0;
  486. while (!list_empty(&zmd->mblk_lru_list) &&
  487. atomic_read(&zmd->nr_mblks) > zmd->min_nr_mblks &&
  488. count < limit) {
  489. mblk = list_first_entry(&zmd->mblk_lru_list,
  490. struct dmz_mblock, link);
  491. list_del_init(&mblk->link);
  492. rb_erase(&mblk->node, &zmd->mblk_rbtree);
  493. dmz_free_mblock(zmd, mblk);
  494. count++;
  495. }
  496. return count;
  497. }
  498. /*
  499. * For mblock shrinker: get the number of unused metadata blocks in the cache.
  500. */
  501. static unsigned long dmz_mblock_shrinker_count(struct shrinker *shrink,
  502. struct shrink_control *sc)
  503. {
  504. struct dmz_metadata *zmd = shrink->private_data;
  505. return atomic_read(&zmd->nr_mblks);
  506. }
  507. /*
  508. * For mblock shrinker: scan unused metadata blocks and shrink the cache.
  509. */
  510. static unsigned long dmz_mblock_shrinker_scan(struct shrinker *shrink,
  511. struct shrink_control *sc)
  512. {
  513. struct dmz_metadata *zmd = shrink->private_data;
  514. unsigned long count;
  515. spin_lock(&zmd->mblk_lock);
  516. count = dmz_shrink_mblock_cache(zmd, sc->nr_to_scan);
  517. spin_unlock(&zmd->mblk_lock);
  518. return count ? count : SHRINK_STOP;
  519. }
  520. /*
  521. * Release a metadata block.
  522. */
  523. static void dmz_release_mblock(struct dmz_metadata *zmd,
  524. struct dmz_mblock *mblk)
  525. {
  526. if (!mblk)
  527. return;
  528. spin_lock(&zmd->mblk_lock);
  529. mblk->ref--;
  530. if (mblk->ref == 0) {
  531. if (test_bit(DMZ_META_ERROR, &mblk->state)) {
  532. rb_erase(&mblk->node, &zmd->mblk_rbtree);
  533. dmz_free_mblock(zmd, mblk);
  534. } else if (!test_bit(DMZ_META_DIRTY, &mblk->state)) {
  535. list_add_tail(&mblk->link, &zmd->mblk_lru_list);
  536. dmz_shrink_mblock_cache(zmd, 1);
  537. }
  538. }
  539. spin_unlock(&zmd->mblk_lock);
  540. }
  541. /*
  542. * Get a metadata block from the rbtree. If the block
  543. * is not present, read it from disk.
  544. */
  545. static struct dmz_mblock *dmz_get_mblock(struct dmz_metadata *zmd,
  546. sector_t mblk_no)
  547. {
  548. struct dmz_mblock *mblk;
  549. struct dmz_dev *dev = zmd->sb[zmd->mblk_primary].dev;
  550. /* Check rbtree */
  551. spin_lock(&zmd->mblk_lock);
  552. mblk = dmz_get_mblock_fast(zmd, mblk_no);
  553. spin_unlock(&zmd->mblk_lock);
  554. if (!mblk) {
  555. /* Cache miss: read the block from disk */
  556. mblk = dmz_get_mblock_slow(zmd, mblk_no);
  557. if (IS_ERR(mblk))
  558. return mblk;
  559. }
  560. /* Wait for on-going read I/O and check for error */
  561. wait_on_bit_io(&mblk->state, DMZ_META_READING,
  562. TASK_UNINTERRUPTIBLE);
  563. if (test_bit(DMZ_META_ERROR, &mblk->state)) {
  564. dmz_release_mblock(zmd, mblk);
  565. dmz_check_bdev(dev);
  566. return ERR_PTR(-EIO);
  567. }
  568. return mblk;
  569. }
  570. /*
  571. * Mark a metadata block dirty.
  572. */
  573. static void dmz_dirty_mblock(struct dmz_metadata *zmd, struct dmz_mblock *mblk)
  574. {
  575. spin_lock(&zmd->mblk_lock);
  576. if (!test_and_set_bit(DMZ_META_DIRTY, &mblk->state))
  577. list_add_tail(&mblk->link, &zmd->mblk_dirty_list);
  578. spin_unlock(&zmd->mblk_lock);
  579. }
  580. /*
  581. * Issue a metadata block write BIO.
  582. */
  583. static int dmz_write_mblock(struct dmz_metadata *zmd, struct dmz_mblock *mblk,
  584. unsigned int set)
  585. {
  586. struct dmz_dev *dev = zmd->sb[set].dev;
  587. sector_t block = zmd->sb[set].block + mblk->no;
  588. struct bio *bio;
  589. if (dmz_bdev_is_dying(dev))
  590. return -EIO;
  591. bio = bio_alloc(dev->bdev, 1, REQ_OP_WRITE | REQ_META | REQ_PRIO,
  592. GFP_NOIO);
  593. set_bit(DMZ_META_WRITING, &mblk->state);
  594. bio->bi_iter.bi_sector = dmz_blk2sect(block);
  595. bio->bi_private = mblk;
  596. bio->bi_end_io = dmz_mblock_bio_end_io;
  597. __bio_add_page(bio, mblk->page, DMZ_BLOCK_SIZE, 0);
  598. submit_bio(bio);
  599. return 0;
  600. }
  601. /*
  602. * Read/write a metadata block.
  603. */
  604. static int dmz_rdwr_block(struct dmz_dev *dev, enum req_op op,
  605. sector_t block, struct page *page)
  606. {
  607. struct bio *bio;
  608. int ret;
  609. if (WARN_ON(!dev))
  610. return -EIO;
  611. if (dmz_bdev_is_dying(dev))
  612. return -EIO;
  613. bio = bio_alloc(dev->bdev, 1, op | REQ_SYNC | REQ_META | REQ_PRIO,
  614. GFP_NOIO);
  615. bio->bi_iter.bi_sector = dmz_blk2sect(block);
  616. __bio_add_page(bio, page, DMZ_BLOCK_SIZE, 0);
  617. ret = submit_bio_wait(bio);
  618. bio_put(bio);
  619. if (ret)
  620. dmz_check_bdev(dev);
  621. return ret;
  622. }
  623. /*
  624. * Write super block of the specified metadata set.
  625. */
  626. static int dmz_write_sb(struct dmz_metadata *zmd, unsigned int set)
  627. {
  628. struct dmz_mblock *mblk = zmd->sb[set].mblk;
  629. struct dmz_super *sb = zmd->sb[set].sb;
  630. struct dmz_dev *dev = zmd->sb[set].dev;
  631. sector_t sb_block;
  632. u64 sb_gen = zmd->sb_gen + 1;
  633. int ret;
  634. sb->magic = cpu_to_le32(DMZ_MAGIC);
  635. sb->version = cpu_to_le32(zmd->sb_version);
  636. if (zmd->sb_version > 1) {
  637. BUILD_BUG_ON(UUID_SIZE != 16);
  638. export_uuid(sb->dmz_uuid, &zmd->uuid);
  639. memcpy(sb->dmz_label, zmd->label, BDEVNAME_SIZE);
  640. export_uuid(sb->dev_uuid, &dev->uuid);
  641. }
  642. sb->gen = cpu_to_le64(sb_gen);
  643. /*
  644. * The metadata always references the absolute block address,
  645. * ie relative to the entire block range, not the per-device
  646. * block address.
  647. */
  648. sb_block = zmd->sb[set].zone->id << zmd->zone_nr_blocks_shift;
  649. sb->sb_block = cpu_to_le64(sb_block);
  650. sb->nr_meta_blocks = cpu_to_le32(zmd->nr_meta_blocks);
  651. sb->nr_reserved_seq = cpu_to_le32(zmd->nr_reserved_seq);
  652. sb->nr_chunks = cpu_to_le32(zmd->nr_chunks);
  653. sb->nr_map_blocks = cpu_to_le32(zmd->nr_map_blocks);
  654. sb->nr_bitmap_blocks = cpu_to_le32(zmd->nr_bitmap_blocks);
  655. sb->crc = 0;
  656. sb->crc = cpu_to_le32(crc32_le(sb_gen, (unsigned char *)sb, DMZ_BLOCK_SIZE));
  657. ret = dmz_rdwr_block(dev, REQ_OP_WRITE, zmd->sb[set].block,
  658. mblk->page);
  659. if (ret == 0)
  660. ret = blkdev_issue_flush(dev->bdev);
  661. return ret;
  662. }
  663. /*
  664. * Write dirty metadata blocks to the specified set.
  665. */
  666. static int dmz_write_dirty_mblocks(struct dmz_metadata *zmd,
  667. struct list_head *write_list,
  668. unsigned int set)
  669. {
  670. struct dmz_mblock *mblk;
  671. struct dmz_dev *dev = zmd->sb[set].dev;
  672. struct blk_plug plug;
  673. int ret = 0, nr_mblks_submitted = 0;
  674. /* Issue writes */
  675. blk_start_plug(&plug);
  676. list_for_each_entry(mblk, write_list, link) {
  677. ret = dmz_write_mblock(zmd, mblk, set);
  678. if (ret)
  679. break;
  680. nr_mblks_submitted++;
  681. }
  682. blk_finish_plug(&plug);
  683. /* Wait for completion */
  684. list_for_each_entry(mblk, write_list, link) {
  685. if (!nr_mblks_submitted)
  686. break;
  687. wait_on_bit_io(&mblk->state, DMZ_META_WRITING,
  688. TASK_UNINTERRUPTIBLE);
  689. if (test_bit(DMZ_META_ERROR, &mblk->state)) {
  690. clear_bit(DMZ_META_ERROR, &mblk->state);
  691. dmz_check_bdev(dev);
  692. ret = -EIO;
  693. }
  694. nr_mblks_submitted--;
  695. }
  696. /* Flush drive cache (this will also sync data) */
  697. if (ret == 0)
  698. ret = blkdev_issue_flush(dev->bdev);
  699. return ret;
  700. }
  701. /*
  702. * Log dirty metadata blocks.
  703. */
  704. static int dmz_log_dirty_mblocks(struct dmz_metadata *zmd,
  705. struct list_head *write_list)
  706. {
  707. unsigned int log_set = zmd->mblk_primary ^ 0x1;
  708. int ret;
  709. /* Write dirty blocks to the log */
  710. ret = dmz_write_dirty_mblocks(zmd, write_list, log_set);
  711. if (ret)
  712. return ret;
  713. /*
  714. * No error so far: now validate the log by updating the
  715. * log index super block generation.
  716. */
  717. ret = dmz_write_sb(zmd, log_set);
  718. if (ret)
  719. return ret;
  720. return 0;
  721. }
  722. /*
  723. * Flush dirty metadata blocks.
  724. */
  725. int dmz_flush_metadata(struct dmz_metadata *zmd)
  726. {
  727. struct dmz_mblock *mblk;
  728. struct list_head write_list;
  729. struct dmz_dev *dev;
  730. int ret;
  731. if (WARN_ON(!zmd))
  732. return 0;
  733. INIT_LIST_HEAD(&write_list);
  734. /*
  735. * Make sure that metadata blocks are stable before logging: take
  736. * the write lock on the metadata semaphore to prevent target BIOs
  737. * from modifying metadata.
  738. */
  739. down_write(&zmd->mblk_sem);
  740. dev = zmd->sb[zmd->mblk_primary].dev;
  741. /*
  742. * This is called from the target flush work and reclaim work.
  743. * Concurrent execution is not allowed.
  744. */
  745. dmz_lock_flush(zmd);
  746. if (dmz_bdev_is_dying(dev)) {
  747. ret = -EIO;
  748. goto out;
  749. }
  750. /* Get dirty blocks */
  751. spin_lock(&zmd->mblk_lock);
  752. list_splice_init(&zmd->mblk_dirty_list, &write_list);
  753. spin_unlock(&zmd->mblk_lock);
  754. /* If there are no dirty metadata blocks, just flush the device cache */
  755. if (list_empty(&write_list)) {
  756. ret = blkdev_issue_flush(dev->bdev);
  757. goto err;
  758. }
  759. /*
  760. * The primary metadata set is still clean. Keep it this way until
  761. * all updates are successful in the secondary set. That is, use
  762. * the secondary set as a log.
  763. */
  764. ret = dmz_log_dirty_mblocks(zmd, &write_list);
  765. if (ret)
  766. goto err;
  767. /*
  768. * The log is on disk. It is now safe to update in place
  769. * in the primary metadata set.
  770. */
  771. ret = dmz_write_dirty_mblocks(zmd, &write_list, zmd->mblk_primary);
  772. if (ret)
  773. goto err;
  774. ret = dmz_write_sb(zmd, zmd->mblk_primary);
  775. if (ret)
  776. goto err;
  777. while (!list_empty(&write_list)) {
  778. mblk = list_first_entry(&write_list, struct dmz_mblock, link);
  779. list_del_init(&mblk->link);
  780. spin_lock(&zmd->mblk_lock);
  781. clear_bit(DMZ_META_DIRTY, &mblk->state);
  782. if (mblk->ref == 0)
  783. list_add_tail(&mblk->link, &zmd->mblk_lru_list);
  784. spin_unlock(&zmd->mblk_lock);
  785. }
  786. zmd->sb_gen++;
  787. out:
  788. dmz_unlock_flush(zmd);
  789. up_write(&zmd->mblk_sem);
  790. return ret;
  791. err:
  792. if (!list_empty(&write_list)) {
  793. spin_lock(&zmd->mblk_lock);
  794. list_splice(&write_list, &zmd->mblk_dirty_list);
  795. spin_unlock(&zmd->mblk_lock);
  796. }
  797. if (!dmz_check_bdev(dev))
  798. ret = -EIO;
  799. goto out;
  800. }
  801. /*
  802. * Check super block.
  803. */
  804. static int dmz_check_sb(struct dmz_metadata *zmd, struct dmz_sb *dsb,
  805. bool tertiary)
  806. {
  807. struct dmz_super *sb = dsb->sb;
  808. struct dmz_dev *dev = dsb->dev;
  809. unsigned int nr_meta_zones, nr_data_zones;
  810. u32 crc, stored_crc;
  811. u64 gen, sb_block;
  812. if (le32_to_cpu(sb->magic) != DMZ_MAGIC) {
  813. dmz_dev_err(dev, "Invalid meta magic (needed 0x%08x, got 0x%08x)",
  814. DMZ_MAGIC, le32_to_cpu(sb->magic));
  815. return -ENXIO;
  816. }
  817. zmd->sb_version = le32_to_cpu(sb->version);
  818. if (zmd->sb_version > DMZ_META_VER) {
  819. dmz_dev_err(dev, "Invalid meta version (needed %d, got %d)",
  820. DMZ_META_VER, zmd->sb_version);
  821. return -EINVAL;
  822. }
  823. if (zmd->sb_version < 2 && tertiary) {
  824. dmz_dev_err(dev, "Tertiary superblocks are not supported");
  825. return -EINVAL;
  826. }
  827. gen = le64_to_cpu(sb->gen);
  828. stored_crc = le32_to_cpu(sb->crc);
  829. sb->crc = 0;
  830. crc = crc32_le(gen, (unsigned char *)sb, DMZ_BLOCK_SIZE);
  831. if (crc != stored_crc) {
  832. dmz_dev_err(dev, "Invalid checksum (needed 0x%08x, got 0x%08x)",
  833. crc, stored_crc);
  834. return -ENXIO;
  835. }
  836. sb_block = le64_to_cpu(sb->sb_block);
  837. if (sb_block != (u64)dsb->zone->id << zmd->zone_nr_blocks_shift) {
  838. dmz_dev_err(dev, "Invalid superblock position (is %llu expected %llu)",
  839. sb_block, (u64)dsb->zone->id << zmd->zone_nr_blocks_shift);
  840. return -EINVAL;
  841. }
  842. if (zmd->sb_version > 1) {
  843. uuid_t sb_uuid;
  844. import_uuid(&sb_uuid, sb->dmz_uuid);
  845. if (uuid_is_null(&sb_uuid)) {
  846. dmz_dev_err(dev, "NULL DM-Zoned uuid");
  847. return -ENXIO;
  848. } else if (uuid_is_null(&zmd->uuid)) {
  849. uuid_copy(&zmd->uuid, &sb_uuid);
  850. } else if (!uuid_equal(&zmd->uuid, &sb_uuid)) {
  851. dmz_dev_err(dev, "mismatching DM-Zoned uuid, is %pUl expected %pUl",
  852. &sb_uuid, &zmd->uuid);
  853. return -ENXIO;
  854. }
  855. if (!strlen(zmd->label))
  856. memcpy(zmd->label, sb->dmz_label, BDEVNAME_SIZE);
  857. else if (memcmp(zmd->label, sb->dmz_label, BDEVNAME_SIZE)) {
  858. dmz_dev_err(dev, "mismatching DM-Zoned label, is %s expected %s",
  859. sb->dmz_label, zmd->label);
  860. return -ENXIO;
  861. }
  862. import_uuid(&dev->uuid, sb->dev_uuid);
  863. if (uuid_is_null(&dev->uuid)) {
  864. dmz_dev_err(dev, "NULL device uuid");
  865. return -ENXIO;
  866. }
  867. if (tertiary) {
  868. /*
  869. * Generation number should be 0, but it doesn't
  870. * really matter if it isn't.
  871. */
  872. if (gen != 0)
  873. dmz_dev_warn(dev, "Invalid generation %llu",
  874. gen);
  875. return 0;
  876. }
  877. }
  878. nr_meta_zones = (le32_to_cpu(sb->nr_meta_blocks) + zmd->zone_nr_blocks - 1)
  879. >> zmd->zone_nr_blocks_shift;
  880. if (!nr_meta_zones ||
  881. (zmd->nr_devs <= 1 && nr_meta_zones >= zmd->nr_rnd_zones) ||
  882. (zmd->nr_devs > 1 && nr_meta_zones >= zmd->nr_cache_zones)) {
  883. dmz_dev_err(dev, "Invalid number of metadata blocks");
  884. return -ENXIO;
  885. }
  886. if (!le32_to_cpu(sb->nr_reserved_seq) ||
  887. le32_to_cpu(sb->nr_reserved_seq) >= (zmd->nr_useable_zones - nr_meta_zones)) {
  888. dmz_dev_err(dev, "Invalid number of reserved sequential zones");
  889. return -ENXIO;
  890. }
  891. nr_data_zones = zmd->nr_useable_zones -
  892. (nr_meta_zones * 2 + le32_to_cpu(sb->nr_reserved_seq));
  893. if (le32_to_cpu(sb->nr_chunks) > nr_data_zones) {
  894. dmz_dev_err(dev, "Invalid number of chunks %u / %u",
  895. le32_to_cpu(sb->nr_chunks), nr_data_zones);
  896. return -ENXIO;
  897. }
  898. /* OK */
  899. zmd->nr_meta_blocks = le32_to_cpu(sb->nr_meta_blocks);
  900. zmd->nr_reserved_seq = le32_to_cpu(sb->nr_reserved_seq);
  901. zmd->nr_chunks = le32_to_cpu(sb->nr_chunks);
  902. zmd->nr_map_blocks = le32_to_cpu(sb->nr_map_blocks);
  903. zmd->nr_bitmap_blocks = le32_to_cpu(sb->nr_bitmap_blocks);
  904. zmd->nr_meta_zones = nr_meta_zones;
  905. zmd->nr_data_zones = nr_data_zones;
  906. return 0;
  907. }
  908. /*
  909. * Read the first or second super block from disk.
  910. */
  911. static int dmz_read_sb(struct dmz_metadata *zmd, struct dmz_sb *sb, int set)
  912. {
  913. dmz_zmd_debug(zmd, "read superblock set %d dev %pg block %llu",
  914. set, sb->dev->bdev, sb->block);
  915. return dmz_rdwr_block(sb->dev, REQ_OP_READ,
  916. sb->block, sb->mblk->page);
  917. }
  918. /*
  919. * Determine the position of the secondary super blocks on disk.
  920. * This is used only if a corruption of the primary super block
  921. * is detected.
  922. */
  923. static int dmz_lookup_secondary_sb(struct dmz_metadata *zmd)
  924. {
  925. unsigned int zone_nr_blocks = zmd->zone_nr_blocks;
  926. struct dmz_mblock *mblk;
  927. unsigned int zone_id = zmd->sb[0].zone->id;
  928. int i;
  929. /* Allocate a block */
  930. mblk = dmz_alloc_mblock(zmd, 0);
  931. if (!mblk)
  932. return -ENOMEM;
  933. zmd->sb[1].mblk = mblk;
  934. zmd->sb[1].sb = mblk->data;
  935. /* Bad first super block: search for the second one */
  936. zmd->sb[1].block = zmd->sb[0].block + zone_nr_blocks;
  937. zmd->sb[1].zone = dmz_get(zmd, zone_id + 1);
  938. zmd->sb[1].dev = zmd->sb[0].dev;
  939. for (i = 1; i < zmd->nr_rnd_zones; i++) {
  940. if (dmz_read_sb(zmd, &zmd->sb[1], 1) != 0)
  941. break;
  942. if (le32_to_cpu(zmd->sb[1].sb->magic) == DMZ_MAGIC)
  943. return 0;
  944. zmd->sb[1].block += zone_nr_blocks;
  945. zmd->sb[1].zone = dmz_get(zmd, zone_id + i);
  946. }
  947. dmz_free_mblock(zmd, mblk);
  948. zmd->sb[1].mblk = NULL;
  949. zmd->sb[1].zone = NULL;
  950. zmd->sb[1].dev = NULL;
  951. return -EIO;
  952. }
  953. /*
  954. * Read a super block from disk.
  955. */
  956. static int dmz_get_sb(struct dmz_metadata *zmd, struct dmz_sb *sb, int set)
  957. {
  958. struct dmz_mblock *mblk;
  959. int ret;
  960. /* Allocate a block */
  961. mblk = dmz_alloc_mblock(zmd, 0);
  962. if (!mblk)
  963. return -ENOMEM;
  964. sb->mblk = mblk;
  965. sb->sb = mblk->data;
  966. /* Read super block */
  967. ret = dmz_read_sb(zmd, sb, set);
  968. if (ret) {
  969. dmz_free_mblock(zmd, mblk);
  970. sb->mblk = NULL;
  971. return ret;
  972. }
  973. return 0;
  974. }
  975. /*
  976. * Recover a metadata set.
  977. */
  978. static int dmz_recover_mblocks(struct dmz_metadata *zmd, unsigned int dst_set)
  979. {
  980. unsigned int src_set = dst_set ^ 0x1;
  981. struct page *page;
  982. int i, ret;
  983. dmz_dev_warn(zmd->sb[dst_set].dev,
  984. "Metadata set %u invalid: recovering", dst_set);
  985. if (dst_set == 0)
  986. zmd->sb[0].block = dmz_start_block(zmd, zmd->sb[0].zone);
  987. else
  988. zmd->sb[1].block = dmz_start_block(zmd, zmd->sb[1].zone);
  989. page = alloc_page(GFP_NOIO);
  990. if (!page)
  991. return -ENOMEM;
  992. /* Copy metadata blocks */
  993. for (i = 1; i < zmd->nr_meta_blocks; i++) {
  994. ret = dmz_rdwr_block(zmd->sb[src_set].dev, REQ_OP_READ,
  995. zmd->sb[src_set].block + i, page);
  996. if (ret)
  997. goto out;
  998. ret = dmz_rdwr_block(zmd->sb[dst_set].dev, REQ_OP_WRITE,
  999. zmd->sb[dst_set].block + i, page);
  1000. if (ret)
  1001. goto out;
  1002. }
  1003. /* Finalize with the super block */
  1004. if (!zmd->sb[dst_set].mblk) {
  1005. zmd->sb[dst_set].mblk = dmz_alloc_mblock(zmd, 0);
  1006. if (!zmd->sb[dst_set].mblk) {
  1007. ret = -ENOMEM;
  1008. goto out;
  1009. }
  1010. zmd->sb[dst_set].sb = zmd->sb[dst_set].mblk->data;
  1011. }
  1012. ret = dmz_write_sb(zmd, dst_set);
  1013. out:
  1014. __free_pages(page, 0);
  1015. return ret;
  1016. }
  1017. /*
  1018. * Get super block from disk.
  1019. */
  1020. static int dmz_load_sb(struct dmz_metadata *zmd)
  1021. {
  1022. bool sb_good[2] = {false, false};
  1023. u64 sb_gen[2] = {0, 0};
  1024. int ret;
  1025. if (!zmd->sb[0].zone) {
  1026. dmz_zmd_err(zmd, "Primary super block zone not set");
  1027. return -ENXIO;
  1028. }
  1029. /* Read and check the primary super block */
  1030. zmd->sb[0].block = dmz_start_block(zmd, zmd->sb[0].zone);
  1031. zmd->sb[0].dev = zmd->sb[0].zone->dev;
  1032. ret = dmz_get_sb(zmd, &zmd->sb[0], 0);
  1033. if (ret) {
  1034. dmz_dev_err(zmd->sb[0].dev, "Read primary super block failed");
  1035. return ret;
  1036. }
  1037. ret = dmz_check_sb(zmd, &zmd->sb[0], false);
  1038. /* Read and check secondary super block */
  1039. if (ret == 0) {
  1040. sb_good[0] = true;
  1041. if (!zmd->sb[1].zone) {
  1042. unsigned int zone_id =
  1043. zmd->sb[0].zone->id + zmd->nr_meta_zones;
  1044. zmd->sb[1].zone = dmz_get(zmd, zone_id);
  1045. }
  1046. zmd->sb[1].block = dmz_start_block(zmd, zmd->sb[1].zone);
  1047. zmd->sb[1].dev = zmd->sb[0].dev;
  1048. ret = dmz_get_sb(zmd, &zmd->sb[1], 1);
  1049. } else
  1050. ret = dmz_lookup_secondary_sb(zmd);
  1051. if (ret) {
  1052. dmz_dev_err(zmd->sb[1].dev, "Read secondary super block failed");
  1053. return ret;
  1054. }
  1055. ret = dmz_check_sb(zmd, &zmd->sb[1], false);
  1056. if (ret == 0)
  1057. sb_good[1] = true;
  1058. /* Use highest generation sb first */
  1059. if (!sb_good[0] && !sb_good[1]) {
  1060. dmz_zmd_err(zmd, "No valid super block found");
  1061. return -EIO;
  1062. }
  1063. if (sb_good[0])
  1064. sb_gen[0] = le64_to_cpu(zmd->sb[0].sb->gen);
  1065. else {
  1066. ret = dmz_recover_mblocks(zmd, 0);
  1067. if (ret) {
  1068. dmz_dev_err(zmd->sb[0].dev,
  1069. "Recovery of superblock 0 failed");
  1070. return -EIO;
  1071. }
  1072. }
  1073. if (sb_good[1])
  1074. sb_gen[1] = le64_to_cpu(zmd->sb[1].sb->gen);
  1075. else {
  1076. ret = dmz_recover_mblocks(zmd, 1);
  1077. if (ret) {
  1078. dmz_dev_err(zmd->sb[1].dev,
  1079. "Recovery of superblock 1 failed");
  1080. return -EIO;
  1081. }
  1082. }
  1083. if (sb_gen[0] >= sb_gen[1]) {
  1084. zmd->sb_gen = sb_gen[0];
  1085. zmd->mblk_primary = 0;
  1086. } else {
  1087. zmd->sb_gen = sb_gen[1];
  1088. zmd->mblk_primary = 1;
  1089. }
  1090. dmz_dev_debug(zmd->sb[zmd->mblk_primary].dev,
  1091. "Using super block %u (gen %llu)",
  1092. zmd->mblk_primary, zmd->sb_gen);
  1093. if (zmd->sb_version > 1) {
  1094. int i;
  1095. struct dmz_sb *sb;
  1096. sb = kzalloc_obj(struct dmz_sb);
  1097. if (!sb)
  1098. return -ENOMEM;
  1099. for (i = 1; i < zmd->nr_devs; i++) {
  1100. sb->block = 0;
  1101. sb->zone = dmz_get(zmd, zmd->dev[i].zone_offset);
  1102. sb->dev = &zmd->dev[i];
  1103. if (!dmz_is_meta(sb->zone)) {
  1104. dmz_dev_err(sb->dev,
  1105. "Tertiary super block zone %u not marked as metadata zone",
  1106. sb->zone->id);
  1107. ret = -EINVAL;
  1108. goto out_kfree;
  1109. }
  1110. ret = dmz_get_sb(zmd, sb, i + 1);
  1111. if (ret) {
  1112. dmz_dev_err(sb->dev,
  1113. "Read tertiary super block failed");
  1114. dmz_free_mblock(zmd, sb->mblk);
  1115. goto out_kfree;
  1116. }
  1117. ret = dmz_check_sb(zmd, sb, true);
  1118. dmz_free_mblock(zmd, sb->mblk);
  1119. if (ret == -EINVAL)
  1120. goto out_kfree;
  1121. }
  1122. out_kfree:
  1123. kfree(sb);
  1124. }
  1125. return ret;
  1126. }
  1127. /*
  1128. * Initialize a zone descriptor.
  1129. */
  1130. static int dmz_init_zone(struct blk_zone *blkz, unsigned int num, void *data)
  1131. {
  1132. struct dmz_dev *dev = data;
  1133. struct dmz_metadata *zmd = dev->metadata;
  1134. int idx = num + dev->zone_offset;
  1135. struct dm_zone *zone;
  1136. zone = dmz_insert(zmd, idx, dev);
  1137. if (IS_ERR(zone))
  1138. return PTR_ERR(zone);
  1139. if (blkz->len != zmd->zone_nr_sectors) {
  1140. if (zmd->sb_version > 1) {
  1141. /* Ignore the eventual runt (smaller) zone */
  1142. set_bit(DMZ_OFFLINE, &zone->flags);
  1143. return 0;
  1144. } else if (blkz->start + blkz->len == dev->capacity)
  1145. return 0;
  1146. return -ENXIO;
  1147. }
  1148. /*
  1149. * Devices that have zones with a capacity smaller than the zone size
  1150. * (e.g. NVMe zoned namespaces) are not supported.
  1151. */
  1152. if (blkz->capacity != blkz->len)
  1153. return -ENXIO;
  1154. switch (blkz->type) {
  1155. case BLK_ZONE_TYPE_CONVENTIONAL:
  1156. set_bit(DMZ_RND, &zone->flags);
  1157. break;
  1158. case BLK_ZONE_TYPE_SEQWRITE_REQ:
  1159. case BLK_ZONE_TYPE_SEQWRITE_PREF:
  1160. set_bit(DMZ_SEQ, &zone->flags);
  1161. break;
  1162. default:
  1163. return -ENXIO;
  1164. }
  1165. if (dmz_is_rnd(zone))
  1166. zone->wp_block = 0;
  1167. else
  1168. zone->wp_block = dmz_sect2blk(blkz->wp - blkz->start);
  1169. if (blkz->cond == BLK_ZONE_COND_OFFLINE)
  1170. set_bit(DMZ_OFFLINE, &zone->flags);
  1171. else if (blkz->cond == BLK_ZONE_COND_READONLY)
  1172. set_bit(DMZ_READ_ONLY, &zone->flags);
  1173. else {
  1174. zmd->nr_useable_zones++;
  1175. if (dmz_is_rnd(zone)) {
  1176. zmd->nr_rnd_zones++;
  1177. if (zmd->nr_devs == 1 && !zmd->sb[0].zone) {
  1178. /* Primary super block zone */
  1179. zmd->sb[0].zone = zone;
  1180. }
  1181. }
  1182. if (zmd->nr_devs > 1 && num == 0) {
  1183. /*
  1184. * Tertiary superblock zones are always at the
  1185. * start of the zoned devices, so mark them
  1186. * as metadata zone.
  1187. */
  1188. set_bit(DMZ_META, &zone->flags);
  1189. }
  1190. }
  1191. return 0;
  1192. }
  1193. static int dmz_emulate_zones(struct dmz_metadata *zmd, struct dmz_dev *dev)
  1194. {
  1195. int idx;
  1196. sector_t zone_offset = 0;
  1197. for (idx = 0; idx < dev->nr_zones; idx++) {
  1198. struct dm_zone *zone;
  1199. zone = dmz_insert(zmd, idx, dev);
  1200. if (IS_ERR(zone))
  1201. return PTR_ERR(zone);
  1202. set_bit(DMZ_CACHE, &zone->flags);
  1203. zone->wp_block = 0;
  1204. zmd->nr_cache_zones++;
  1205. zmd->nr_useable_zones++;
  1206. if (dev->capacity - zone_offset < zmd->zone_nr_sectors) {
  1207. /* Disable runt zone */
  1208. set_bit(DMZ_OFFLINE, &zone->flags);
  1209. break;
  1210. }
  1211. zone_offset += zmd->zone_nr_sectors;
  1212. }
  1213. return 0;
  1214. }
  1215. /*
  1216. * Free zones descriptors.
  1217. */
  1218. static void dmz_drop_zones(struct dmz_metadata *zmd)
  1219. {
  1220. int idx;
  1221. for (idx = 0; idx < zmd->nr_zones; idx++) {
  1222. struct dm_zone *zone = xa_load(&zmd->zones, idx);
  1223. kfree(zone);
  1224. xa_erase(&zmd->zones, idx);
  1225. }
  1226. xa_destroy(&zmd->zones);
  1227. }
  1228. /*
  1229. * Allocate and initialize zone descriptors using the zone
  1230. * information from disk.
  1231. */
  1232. static int dmz_init_zones(struct dmz_metadata *zmd)
  1233. {
  1234. int i, ret;
  1235. struct dmz_dev *zoned_dev = &zmd->dev[0];
  1236. /* Init */
  1237. zmd->zone_nr_sectors = zmd->dev[0].zone_nr_sectors;
  1238. zmd->zone_nr_sectors_shift = ilog2(zmd->zone_nr_sectors);
  1239. zmd->zone_nr_blocks = dmz_sect2blk(zmd->zone_nr_sectors);
  1240. zmd->zone_nr_blocks_shift = ilog2(zmd->zone_nr_blocks);
  1241. zmd->zone_bitmap_size = zmd->zone_nr_blocks >> 3;
  1242. zmd->zone_nr_bitmap_blocks =
  1243. max_t(sector_t, 1, zmd->zone_bitmap_size >> DMZ_BLOCK_SHIFT);
  1244. zmd->zone_bits_per_mblk = min_t(sector_t, zmd->zone_nr_blocks,
  1245. DMZ_BLOCK_SIZE_BITS);
  1246. /* Allocate zone array */
  1247. zmd->nr_zones = 0;
  1248. for (i = 0; i < zmd->nr_devs; i++) {
  1249. struct dmz_dev *dev = &zmd->dev[i];
  1250. dev->metadata = zmd;
  1251. zmd->nr_zones += dev->nr_zones;
  1252. atomic_set(&dev->unmap_nr_rnd, 0);
  1253. INIT_LIST_HEAD(&dev->unmap_rnd_list);
  1254. INIT_LIST_HEAD(&dev->map_rnd_list);
  1255. atomic_set(&dev->unmap_nr_seq, 0);
  1256. INIT_LIST_HEAD(&dev->unmap_seq_list);
  1257. INIT_LIST_HEAD(&dev->map_seq_list);
  1258. }
  1259. if (!zmd->nr_zones) {
  1260. DMERR("(%s): No zones found", zmd->devname);
  1261. return -ENXIO;
  1262. }
  1263. xa_init(&zmd->zones);
  1264. DMDEBUG("(%s): Using %zu B for zone information",
  1265. zmd->devname, sizeof(struct dm_zone) * zmd->nr_zones);
  1266. if (zmd->nr_devs > 1) {
  1267. ret = dmz_emulate_zones(zmd, &zmd->dev[0]);
  1268. if (ret < 0) {
  1269. DMDEBUG("(%s): Failed to emulate zones, error %d",
  1270. zmd->devname, ret);
  1271. dmz_drop_zones(zmd);
  1272. return ret;
  1273. }
  1274. /*
  1275. * Primary superblock zone is always at zone 0 when multiple
  1276. * drives are present.
  1277. */
  1278. zmd->sb[0].zone = dmz_get(zmd, 0);
  1279. for (i = 1; i < zmd->nr_devs; i++) {
  1280. zoned_dev = &zmd->dev[i];
  1281. ret = blkdev_report_zones(zoned_dev->bdev, 0,
  1282. BLK_ALL_ZONES,
  1283. dmz_init_zone, zoned_dev);
  1284. if (ret < 0) {
  1285. DMDEBUG("(%s): Failed to report zones, error %d",
  1286. zmd->devname, ret);
  1287. dmz_drop_zones(zmd);
  1288. return ret;
  1289. }
  1290. }
  1291. return 0;
  1292. }
  1293. /*
  1294. * Get zone information and initialize zone descriptors. At the same
  1295. * time, determine where the super block should be: first block of the
  1296. * first randomly writable zone.
  1297. */
  1298. ret = blkdev_report_zones(zoned_dev->bdev, 0, BLK_ALL_ZONES,
  1299. dmz_init_zone, zoned_dev);
  1300. if (ret < 0) {
  1301. DMDEBUG("(%s): Failed to report zones, error %d",
  1302. zmd->devname, ret);
  1303. dmz_drop_zones(zmd);
  1304. return ret;
  1305. }
  1306. return 0;
  1307. }
  1308. static int dmz_update_zone_cb(struct blk_zone *blkz, unsigned int idx,
  1309. void *data)
  1310. {
  1311. struct dm_zone *zone = data;
  1312. clear_bit(DMZ_OFFLINE, &zone->flags);
  1313. clear_bit(DMZ_READ_ONLY, &zone->flags);
  1314. if (blkz->cond == BLK_ZONE_COND_OFFLINE)
  1315. set_bit(DMZ_OFFLINE, &zone->flags);
  1316. else if (blkz->cond == BLK_ZONE_COND_READONLY)
  1317. set_bit(DMZ_READ_ONLY, &zone->flags);
  1318. if (dmz_is_seq(zone))
  1319. zone->wp_block = dmz_sect2blk(blkz->wp - blkz->start);
  1320. else
  1321. zone->wp_block = 0;
  1322. return 0;
  1323. }
  1324. /*
  1325. * Update a zone information.
  1326. */
  1327. static int dmz_update_zone(struct dmz_metadata *zmd, struct dm_zone *zone)
  1328. {
  1329. struct dmz_dev *dev = zone->dev;
  1330. unsigned int noio_flag;
  1331. int ret;
  1332. if (dev->flags & DMZ_BDEV_REGULAR)
  1333. return 0;
  1334. /*
  1335. * Get zone information from disk. Since blkdev_report_zones() uses
  1336. * GFP_KERNEL by default for memory allocations, set the per-task
  1337. * PF_MEMALLOC_NOIO flag so that all allocations are done as if
  1338. * GFP_NOIO was specified.
  1339. */
  1340. noio_flag = memalloc_noio_save();
  1341. ret = blkdev_report_zones(dev->bdev, dmz_start_sect(zmd, zone), 1,
  1342. dmz_update_zone_cb, zone);
  1343. memalloc_noio_restore(noio_flag);
  1344. if (ret == 0)
  1345. ret = -EIO;
  1346. if (ret < 0) {
  1347. dmz_dev_err(dev, "Get zone %u report failed",
  1348. zone->id);
  1349. dmz_check_bdev(dev);
  1350. return ret;
  1351. }
  1352. return 0;
  1353. }
  1354. /*
  1355. * Check a zone write pointer position when the zone is marked
  1356. * with the sequential write error flag.
  1357. */
  1358. static int dmz_handle_seq_write_err(struct dmz_metadata *zmd,
  1359. struct dm_zone *zone)
  1360. {
  1361. struct dmz_dev *dev = zone->dev;
  1362. unsigned int wp = 0;
  1363. int ret;
  1364. wp = zone->wp_block;
  1365. ret = dmz_update_zone(zmd, zone);
  1366. if (ret)
  1367. return ret;
  1368. dmz_dev_warn(dev, "Processing zone %u write error (zone wp %u/%u)",
  1369. zone->id, zone->wp_block, wp);
  1370. if (zone->wp_block < wp) {
  1371. dmz_invalidate_blocks(zmd, zone, zone->wp_block,
  1372. wp - zone->wp_block);
  1373. }
  1374. return 0;
  1375. }
  1376. /*
  1377. * Reset a zone write pointer.
  1378. */
  1379. static int dmz_reset_zone(struct dmz_metadata *zmd, struct dm_zone *zone)
  1380. {
  1381. int ret;
  1382. /*
  1383. * Ignore offline zones, read only zones,
  1384. * and conventional zones.
  1385. */
  1386. if (dmz_is_offline(zone) ||
  1387. dmz_is_readonly(zone) ||
  1388. dmz_is_rnd(zone))
  1389. return 0;
  1390. if (!dmz_is_empty(zone) || dmz_seq_write_err(zone)) {
  1391. struct dmz_dev *dev = zone->dev;
  1392. unsigned int noio_flag;
  1393. noio_flag = memalloc_noio_save();
  1394. ret = blkdev_zone_mgmt(dev->bdev, REQ_OP_ZONE_RESET,
  1395. dmz_start_sect(zmd, zone),
  1396. zmd->zone_nr_sectors);
  1397. memalloc_noio_restore(noio_flag);
  1398. if (ret) {
  1399. dmz_dev_err(dev, "Reset zone %u failed %d",
  1400. zone->id, ret);
  1401. return ret;
  1402. }
  1403. }
  1404. /* Clear write error bit and rewind write pointer position */
  1405. clear_bit(DMZ_SEQ_WRITE_ERR, &zone->flags);
  1406. zone->wp_block = 0;
  1407. return 0;
  1408. }
  1409. static void dmz_get_zone_weight(struct dmz_metadata *zmd, struct dm_zone *zone);
  1410. /*
  1411. * Initialize chunk mapping.
  1412. */
  1413. static int dmz_load_mapping(struct dmz_metadata *zmd)
  1414. {
  1415. struct dm_zone *dzone, *bzone;
  1416. struct dmz_mblock *dmap_mblk = NULL;
  1417. struct dmz_map *dmap;
  1418. unsigned int i = 0, e = 0, chunk = 0;
  1419. unsigned int dzone_id;
  1420. unsigned int bzone_id;
  1421. /* Metadata block array for the chunk mapping table */
  1422. zmd->map_mblk = kzalloc_objs(struct dmz_mblock *, zmd->nr_map_blocks);
  1423. if (!zmd->map_mblk)
  1424. return -ENOMEM;
  1425. /* Get chunk mapping table blocks and initialize zone mapping */
  1426. while (chunk < zmd->nr_chunks) {
  1427. if (!dmap_mblk) {
  1428. /* Get mapping block */
  1429. dmap_mblk = dmz_get_mblock(zmd, i + 1);
  1430. if (IS_ERR(dmap_mblk))
  1431. return PTR_ERR(dmap_mblk);
  1432. zmd->map_mblk[i] = dmap_mblk;
  1433. dmap = dmap_mblk->data;
  1434. i++;
  1435. e = 0;
  1436. }
  1437. /* Check data zone */
  1438. dzone_id = le32_to_cpu(dmap[e].dzone_id);
  1439. if (dzone_id == DMZ_MAP_UNMAPPED)
  1440. goto next;
  1441. if (dzone_id >= zmd->nr_zones) {
  1442. dmz_zmd_err(zmd, "Chunk %u mapping: invalid data zone ID %u",
  1443. chunk, dzone_id);
  1444. return -EIO;
  1445. }
  1446. dzone = dmz_get(zmd, dzone_id);
  1447. if (!dzone) {
  1448. dmz_zmd_err(zmd, "Chunk %u mapping: data zone %u not present",
  1449. chunk, dzone_id);
  1450. return -EIO;
  1451. }
  1452. set_bit(DMZ_DATA, &dzone->flags);
  1453. dzone->chunk = chunk;
  1454. dmz_get_zone_weight(zmd, dzone);
  1455. if (dmz_is_cache(dzone))
  1456. list_add_tail(&dzone->link, &zmd->map_cache_list);
  1457. else if (dmz_is_rnd(dzone))
  1458. list_add_tail(&dzone->link, &dzone->dev->map_rnd_list);
  1459. else
  1460. list_add_tail(&dzone->link, &dzone->dev->map_seq_list);
  1461. /* Check buffer zone */
  1462. bzone_id = le32_to_cpu(dmap[e].bzone_id);
  1463. if (bzone_id == DMZ_MAP_UNMAPPED)
  1464. goto next;
  1465. if (bzone_id >= zmd->nr_zones) {
  1466. dmz_zmd_err(zmd, "Chunk %u mapping: invalid buffer zone ID %u",
  1467. chunk, bzone_id);
  1468. return -EIO;
  1469. }
  1470. bzone = dmz_get(zmd, bzone_id);
  1471. if (!bzone) {
  1472. dmz_zmd_err(zmd, "Chunk %u mapping: buffer zone %u not present",
  1473. chunk, bzone_id);
  1474. return -EIO;
  1475. }
  1476. if (!dmz_is_rnd(bzone) && !dmz_is_cache(bzone)) {
  1477. dmz_zmd_err(zmd, "Chunk %u mapping: invalid buffer zone %u",
  1478. chunk, bzone_id);
  1479. return -EIO;
  1480. }
  1481. set_bit(DMZ_DATA, &bzone->flags);
  1482. set_bit(DMZ_BUF, &bzone->flags);
  1483. bzone->chunk = chunk;
  1484. bzone->bzone = dzone;
  1485. dzone->bzone = bzone;
  1486. dmz_get_zone_weight(zmd, bzone);
  1487. if (dmz_is_cache(bzone))
  1488. list_add_tail(&bzone->link, &zmd->map_cache_list);
  1489. else
  1490. list_add_tail(&bzone->link, &bzone->dev->map_rnd_list);
  1491. next:
  1492. chunk++;
  1493. e++;
  1494. if (e >= DMZ_MAP_ENTRIES)
  1495. dmap_mblk = NULL;
  1496. }
  1497. /*
  1498. * At this point, only meta zones and mapped data zones were
  1499. * fully initialized. All remaining zones are unmapped data
  1500. * zones. Finish initializing those here.
  1501. */
  1502. for (i = 0; i < zmd->nr_zones; i++) {
  1503. dzone = dmz_get(zmd, i);
  1504. if (!dzone)
  1505. continue;
  1506. if (dmz_is_meta(dzone))
  1507. continue;
  1508. if (dmz_is_offline(dzone))
  1509. continue;
  1510. if (dmz_is_cache(dzone))
  1511. zmd->nr_cache++;
  1512. else if (dmz_is_rnd(dzone))
  1513. dzone->dev->nr_rnd++;
  1514. else
  1515. dzone->dev->nr_seq++;
  1516. if (dmz_is_data(dzone)) {
  1517. /* Already initialized */
  1518. continue;
  1519. }
  1520. /* Unmapped data zone */
  1521. set_bit(DMZ_DATA, &dzone->flags);
  1522. dzone->chunk = DMZ_MAP_UNMAPPED;
  1523. if (dmz_is_cache(dzone)) {
  1524. list_add_tail(&dzone->link, &zmd->unmap_cache_list);
  1525. atomic_inc(&zmd->unmap_nr_cache);
  1526. } else if (dmz_is_rnd(dzone)) {
  1527. list_add_tail(&dzone->link,
  1528. &dzone->dev->unmap_rnd_list);
  1529. atomic_inc(&dzone->dev->unmap_nr_rnd);
  1530. } else if (atomic_read(&zmd->nr_reserved_seq_zones) < zmd->nr_reserved_seq) {
  1531. list_add_tail(&dzone->link, &zmd->reserved_seq_zones_list);
  1532. set_bit(DMZ_RESERVED, &dzone->flags);
  1533. atomic_inc(&zmd->nr_reserved_seq_zones);
  1534. dzone->dev->nr_seq--;
  1535. } else {
  1536. list_add_tail(&dzone->link,
  1537. &dzone->dev->unmap_seq_list);
  1538. atomic_inc(&dzone->dev->unmap_nr_seq);
  1539. }
  1540. }
  1541. return 0;
  1542. }
  1543. /*
  1544. * Set a data chunk mapping.
  1545. */
  1546. static void dmz_set_chunk_mapping(struct dmz_metadata *zmd, unsigned int chunk,
  1547. unsigned int dzone_id, unsigned int bzone_id)
  1548. {
  1549. struct dmz_mblock *dmap_mblk = zmd->map_mblk[chunk >> DMZ_MAP_ENTRIES_SHIFT];
  1550. struct dmz_map *dmap = dmap_mblk->data;
  1551. int map_idx = chunk & DMZ_MAP_ENTRIES_MASK;
  1552. dmap[map_idx].dzone_id = cpu_to_le32(dzone_id);
  1553. dmap[map_idx].bzone_id = cpu_to_le32(bzone_id);
  1554. dmz_dirty_mblock(zmd, dmap_mblk);
  1555. }
  1556. /*
  1557. * The list of mapped zones is maintained in LRU order.
  1558. * This rotates a zone at the end of its map list.
  1559. */
  1560. static void __dmz_lru_zone(struct dmz_metadata *zmd, struct dm_zone *zone)
  1561. {
  1562. if (list_empty(&zone->link))
  1563. return;
  1564. list_del_init(&zone->link);
  1565. if (dmz_is_seq(zone)) {
  1566. /* LRU rotate sequential zone */
  1567. list_add_tail(&zone->link, &zone->dev->map_seq_list);
  1568. } else if (dmz_is_cache(zone)) {
  1569. /* LRU rotate cache zone */
  1570. list_add_tail(&zone->link, &zmd->map_cache_list);
  1571. } else {
  1572. /* LRU rotate random zone */
  1573. list_add_tail(&zone->link, &zone->dev->map_rnd_list);
  1574. }
  1575. }
  1576. /*
  1577. * The list of mapped random zones is maintained
  1578. * in LRU order. This rotates a zone at the end of the list.
  1579. */
  1580. static void dmz_lru_zone(struct dmz_metadata *zmd, struct dm_zone *zone)
  1581. {
  1582. __dmz_lru_zone(zmd, zone);
  1583. if (zone->bzone)
  1584. __dmz_lru_zone(zmd, zone->bzone);
  1585. }
  1586. /*
  1587. * Wait for any zone to be freed.
  1588. */
  1589. static void dmz_wait_for_free_zones(struct dmz_metadata *zmd)
  1590. {
  1591. DEFINE_WAIT(wait);
  1592. prepare_to_wait(&zmd->free_wq, &wait, TASK_UNINTERRUPTIBLE);
  1593. dmz_unlock_map(zmd);
  1594. dmz_unlock_metadata(zmd);
  1595. io_schedule_timeout(HZ);
  1596. dmz_lock_metadata(zmd);
  1597. dmz_lock_map(zmd);
  1598. finish_wait(&zmd->free_wq, &wait);
  1599. }
  1600. /*
  1601. * Lock a zone for reclaim (set the zone RECLAIM bit).
  1602. * Returns false if the zone cannot be locked or if it is already locked
  1603. * and 1 otherwise.
  1604. */
  1605. int dmz_lock_zone_reclaim(struct dm_zone *zone)
  1606. {
  1607. /* Active zones cannot be reclaimed */
  1608. if (dmz_is_active(zone))
  1609. return 0;
  1610. return !test_and_set_bit(DMZ_RECLAIM, &zone->flags);
  1611. }
  1612. /*
  1613. * Clear a zone reclaim flag.
  1614. */
  1615. void dmz_unlock_zone_reclaim(struct dm_zone *zone)
  1616. {
  1617. WARN_ON(dmz_is_active(zone));
  1618. WARN_ON(!dmz_in_reclaim(zone));
  1619. clear_bit_unlock(DMZ_RECLAIM, &zone->flags);
  1620. smp_mb__after_atomic();
  1621. wake_up_bit(&zone->flags, DMZ_RECLAIM);
  1622. }
  1623. /*
  1624. * Wait for a zone reclaim to complete.
  1625. */
  1626. static void dmz_wait_for_reclaim(struct dmz_metadata *zmd, struct dm_zone *zone)
  1627. {
  1628. dmz_unlock_map(zmd);
  1629. dmz_unlock_metadata(zmd);
  1630. set_bit(DMZ_RECLAIM_TERMINATE, &zone->flags);
  1631. wait_on_bit_timeout(&zone->flags, DMZ_RECLAIM, TASK_UNINTERRUPTIBLE, HZ);
  1632. clear_bit(DMZ_RECLAIM_TERMINATE, &zone->flags);
  1633. dmz_lock_metadata(zmd);
  1634. dmz_lock_map(zmd);
  1635. }
  1636. /*
  1637. * Select a cache or random write zone for reclaim.
  1638. */
  1639. static struct dm_zone *dmz_get_rnd_zone_for_reclaim(struct dmz_metadata *zmd,
  1640. unsigned int idx, bool idle)
  1641. {
  1642. struct dm_zone *dzone = NULL;
  1643. struct dm_zone *zone, *maxw_z = NULL;
  1644. struct list_head *zone_list;
  1645. /* If we have cache zones select from the cache zone list */
  1646. if (zmd->nr_cache) {
  1647. zone_list = &zmd->map_cache_list;
  1648. /* Try to relaim random zones, too, when idle */
  1649. if (idle && list_empty(zone_list))
  1650. zone_list = &zmd->dev[idx].map_rnd_list;
  1651. } else
  1652. zone_list = &zmd->dev[idx].map_rnd_list;
  1653. /*
  1654. * Find the buffer zone with the heaviest weight or the first (oldest)
  1655. * data zone that can be reclaimed.
  1656. */
  1657. list_for_each_entry(zone, zone_list, link) {
  1658. if (dmz_is_buf(zone)) {
  1659. dzone = zone->bzone;
  1660. if (dmz_is_rnd(dzone) && dzone->dev->dev_idx != idx)
  1661. continue;
  1662. if (!maxw_z || maxw_z->weight < dzone->weight)
  1663. maxw_z = dzone;
  1664. } else {
  1665. dzone = zone;
  1666. if (dmz_lock_zone_reclaim(dzone))
  1667. return dzone;
  1668. }
  1669. }
  1670. if (maxw_z && dmz_lock_zone_reclaim(maxw_z))
  1671. return maxw_z;
  1672. /*
  1673. * If we come here, none of the zones inspected could be locked for
  1674. * reclaim. Try again, being more aggressive, that is, find the
  1675. * first zone that can be reclaimed regardless of its weitght.
  1676. */
  1677. list_for_each_entry(zone, zone_list, link) {
  1678. if (dmz_is_buf(zone)) {
  1679. dzone = zone->bzone;
  1680. if (dmz_is_rnd(dzone) && dzone->dev->dev_idx != idx)
  1681. continue;
  1682. } else
  1683. dzone = zone;
  1684. if (dmz_lock_zone_reclaim(dzone))
  1685. return dzone;
  1686. }
  1687. return NULL;
  1688. }
  1689. /*
  1690. * Select a buffered sequential zone for reclaim.
  1691. */
  1692. static struct dm_zone *dmz_get_seq_zone_for_reclaim(struct dmz_metadata *zmd,
  1693. unsigned int idx)
  1694. {
  1695. struct dm_zone *zone;
  1696. list_for_each_entry(zone, &zmd->dev[idx].map_seq_list, link) {
  1697. if (!zone->bzone)
  1698. continue;
  1699. if (dmz_lock_zone_reclaim(zone))
  1700. return zone;
  1701. }
  1702. return NULL;
  1703. }
  1704. /*
  1705. * Select a zone for reclaim.
  1706. */
  1707. struct dm_zone *dmz_get_zone_for_reclaim(struct dmz_metadata *zmd,
  1708. unsigned int dev_idx, bool idle)
  1709. {
  1710. struct dm_zone *zone = NULL;
  1711. /*
  1712. * Search for a zone candidate to reclaim: 2 cases are possible.
  1713. * (1) There is no free sequential zones. Then a random data zone
  1714. * cannot be reclaimed. So choose a sequential zone to reclaim so
  1715. * that afterward a random zone can be reclaimed.
  1716. * (2) At least one free sequential zone is available, then choose
  1717. * the oldest random zone (data or buffer) that can be locked.
  1718. */
  1719. dmz_lock_map(zmd);
  1720. if (list_empty(&zmd->reserved_seq_zones_list))
  1721. zone = dmz_get_seq_zone_for_reclaim(zmd, dev_idx);
  1722. if (!zone)
  1723. zone = dmz_get_rnd_zone_for_reclaim(zmd, dev_idx, idle);
  1724. dmz_unlock_map(zmd);
  1725. return zone;
  1726. }
  1727. /*
  1728. * Get the zone mapping a chunk, if the chunk is mapped already.
  1729. * If no mapping exist and the operation is WRITE, a zone is
  1730. * allocated and used to map the chunk.
  1731. * The zone returned will be set to the active state.
  1732. */
  1733. struct dm_zone *dmz_get_chunk_mapping(struct dmz_metadata *zmd,
  1734. unsigned int chunk, enum req_op op)
  1735. {
  1736. struct dmz_mblock *dmap_mblk = zmd->map_mblk[chunk >> DMZ_MAP_ENTRIES_SHIFT];
  1737. struct dmz_map *dmap = dmap_mblk->data;
  1738. int dmap_idx = chunk & DMZ_MAP_ENTRIES_MASK;
  1739. unsigned int dzone_id;
  1740. struct dm_zone *dzone = NULL;
  1741. int ret = 0;
  1742. int alloc_flags = zmd->nr_cache ? DMZ_ALLOC_CACHE : DMZ_ALLOC_RND;
  1743. dmz_lock_map(zmd);
  1744. again:
  1745. /* Get the chunk mapping */
  1746. dzone_id = le32_to_cpu(dmap[dmap_idx].dzone_id);
  1747. if (dzone_id == DMZ_MAP_UNMAPPED) {
  1748. /*
  1749. * Read or discard in unmapped chunks are fine. But for
  1750. * writes, we need a mapping, so get one.
  1751. */
  1752. if (op != REQ_OP_WRITE)
  1753. goto out;
  1754. /* Allocate a random zone */
  1755. dzone = dmz_alloc_zone(zmd, 0, alloc_flags);
  1756. if (!dzone) {
  1757. if (dmz_dev_is_dying(zmd)) {
  1758. dzone = ERR_PTR(-EIO);
  1759. goto out;
  1760. }
  1761. dmz_wait_for_free_zones(zmd);
  1762. goto again;
  1763. }
  1764. dmz_map_zone(zmd, dzone, chunk);
  1765. } else {
  1766. /* The chunk is already mapped: get the mapping zone */
  1767. dzone = dmz_get(zmd, dzone_id);
  1768. if (!dzone) {
  1769. dzone = ERR_PTR(-EIO);
  1770. goto out;
  1771. }
  1772. if (dzone->chunk != chunk) {
  1773. dzone = ERR_PTR(-EIO);
  1774. goto out;
  1775. }
  1776. /* Repair write pointer if the sequential dzone has error */
  1777. if (dmz_seq_write_err(dzone)) {
  1778. ret = dmz_handle_seq_write_err(zmd, dzone);
  1779. if (ret) {
  1780. dzone = ERR_PTR(-EIO);
  1781. goto out;
  1782. }
  1783. clear_bit(DMZ_SEQ_WRITE_ERR, &dzone->flags);
  1784. }
  1785. }
  1786. /*
  1787. * If the zone is being reclaimed, the chunk mapping may change
  1788. * to a different zone. So wait for reclaim and retry. Otherwise,
  1789. * activate the zone (this will prevent reclaim from touching it).
  1790. */
  1791. if (dmz_in_reclaim(dzone)) {
  1792. dmz_wait_for_reclaim(zmd, dzone);
  1793. goto again;
  1794. }
  1795. dmz_activate_zone(dzone);
  1796. dmz_lru_zone(zmd, dzone);
  1797. out:
  1798. dmz_unlock_map(zmd);
  1799. return dzone;
  1800. }
  1801. /*
  1802. * Write and discard change the block validity of data zones and their buffer
  1803. * zones. Check here that valid blocks are still present. If all blocks are
  1804. * invalid, the zones can be unmapped on the fly without waiting for reclaim
  1805. * to do it.
  1806. */
  1807. void dmz_put_chunk_mapping(struct dmz_metadata *zmd, struct dm_zone *dzone)
  1808. {
  1809. struct dm_zone *bzone;
  1810. dmz_lock_map(zmd);
  1811. bzone = dzone->bzone;
  1812. if (bzone) {
  1813. if (dmz_weight(bzone))
  1814. dmz_lru_zone(zmd, bzone);
  1815. else {
  1816. /* Empty buffer zone: reclaim it */
  1817. dmz_unmap_zone(zmd, bzone);
  1818. dmz_free_zone(zmd, bzone);
  1819. bzone = NULL;
  1820. }
  1821. }
  1822. /* Deactivate the data zone */
  1823. dmz_deactivate_zone(dzone);
  1824. if (dmz_is_active(dzone) || bzone || dmz_weight(dzone))
  1825. dmz_lru_zone(zmd, dzone);
  1826. else {
  1827. /* Unbuffered inactive empty data zone: reclaim it */
  1828. dmz_unmap_zone(zmd, dzone);
  1829. dmz_free_zone(zmd, dzone);
  1830. }
  1831. dmz_unlock_map(zmd);
  1832. }
  1833. /*
  1834. * Allocate and map a random zone to buffer a chunk
  1835. * already mapped to a sequential zone.
  1836. */
  1837. struct dm_zone *dmz_get_chunk_buffer(struct dmz_metadata *zmd,
  1838. struct dm_zone *dzone)
  1839. {
  1840. struct dm_zone *bzone;
  1841. int alloc_flags = zmd->nr_cache ? DMZ_ALLOC_CACHE : DMZ_ALLOC_RND;
  1842. dmz_lock_map(zmd);
  1843. again:
  1844. bzone = dzone->bzone;
  1845. if (bzone)
  1846. goto out;
  1847. /* Allocate a random zone */
  1848. bzone = dmz_alloc_zone(zmd, 0, alloc_flags);
  1849. if (!bzone) {
  1850. if (dmz_dev_is_dying(zmd)) {
  1851. bzone = ERR_PTR(-EIO);
  1852. goto out;
  1853. }
  1854. dmz_wait_for_free_zones(zmd);
  1855. goto again;
  1856. }
  1857. /* Update the chunk mapping */
  1858. dmz_set_chunk_mapping(zmd, dzone->chunk, dzone->id, bzone->id);
  1859. set_bit(DMZ_BUF, &bzone->flags);
  1860. bzone->chunk = dzone->chunk;
  1861. bzone->bzone = dzone;
  1862. dzone->bzone = bzone;
  1863. if (dmz_is_cache(bzone))
  1864. list_add_tail(&bzone->link, &zmd->map_cache_list);
  1865. else
  1866. list_add_tail(&bzone->link, &bzone->dev->map_rnd_list);
  1867. out:
  1868. dmz_unlock_map(zmd);
  1869. return bzone;
  1870. }
  1871. /*
  1872. * Get an unmapped (free) zone.
  1873. * This must be called with the mapping lock held.
  1874. */
  1875. struct dm_zone *dmz_alloc_zone(struct dmz_metadata *zmd, unsigned int dev_idx,
  1876. unsigned long flags)
  1877. {
  1878. struct list_head *list;
  1879. struct dm_zone *zone;
  1880. int i;
  1881. /* Schedule reclaim to ensure free zones are available */
  1882. if (!(flags & DMZ_ALLOC_RECLAIM)) {
  1883. for (i = 0; i < zmd->nr_devs; i++)
  1884. dmz_schedule_reclaim(zmd->dev[i].reclaim);
  1885. }
  1886. i = 0;
  1887. again:
  1888. if (flags & DMZ_ALLOC_CACHE)
  1889. list = &zmd->unmap_cache_list;
  1890. else if (flags & DMZ_ALLOC_RND)
  1891. list = &zmd->dev[dev_idx].unmap_rnd_list;
  1892. else
  1893. list = &zmd->dev[dev_idx].unmap_seq_list;
  1894. if (list_empty(list)) {
  1895. /*
  1896. * No free zone: return NULL if this is for not reclaim.
  1897. */
  1898. if (!(flags & DMZ_ALLOC_RECLAIM))
  1899. return NULL;
  1900. /*
  1901. * Try to allocate from other devices
  1902. */
  1903. if (i < zmd->nr_devs) {
  1904. dev_idx = (dev_idx + 1) % zmd->nr_devs;
  1905. i++;
  1906. goto again;
  1907. }
  1908. /*
  1909. * Fallback to the reserved sequential zones
  1910. */
  1911. zone = list_first_entry_or_null(&zmd->reserved_seq_zones_list,
  1912. struct dm_zone, link);
  1913. if (zone) {
  1914. list_del_init(&zone->link);
  1915. atomic_dec(&zmd->nr_reserved_seq_zones);
  1916. }
  1917. return zone;
  1918. }
  1919. zone = list_first_entry(list, struct dm_zone, link);
  1920. list_del_init(&zone->link);
  1921. if (dmz_is_cache(zone))
  1922. atomic_dec(&zmd->unmap_nr_cache);
  1923. else if (dmz_is_rnd(zone))
  1924. atomic_dec(&zone->dev->unmap_nr_rnd);
  1925. else
  1926. atomic_dec(&zone->dev->unmap_nr_seq);
  1927. if (dmz_is_offline(zone)) {
  1928. dmz_zmd_warn(zmd, "Zone %u is offline", zone->id);
  1929. zone = NULL;
  1930. goto again;
  1931. }
  1932. if (dmz_is_meta(zone)) {
  1933. dmz_zmd_warn(zmd, "Zone %u has metadata", zone->id);
  1934. zone = NULL;
  1935. goto again;
  1936. }
  1937. return zone;
  1938. }
  1939. /*
  1940. * Free a zone.
  1941. * This must be called with the mapping lock held.
  1942. */
  1943. void dmz_free_zone(struct dmz_metadata *zmd, struct dm_zone *zone)
  1944. {
  1945. /* If this is a sequential zone, reset it */
  1946. if (dmz_is_seq(zone))
  1947. dmz_reset_zone(zmd, zone);
  1948. /* Return the zone to its type unmap list */
  1949. if (dmz_is_cache(zone)) {
  1950. list_add_tail(&zone->link, &zmd->unmap_cache_list);
  1951. atomic_inc(&zmd->unmap_nr_cache);
  1952. } else if (dmz_is_rnd(zone)) {
  1953. list_add_tail(&zone->link, &zone->dev->unmap_rnd_list);
  1954. atomic_inc(&zone->dev->unmap_nr_rnd);
  1955. } else if (dmz_is_reserved(zone)) {
  1956. list_add_tail(&zone->link, &zmd->reserved_seq_zones_list);
  1957. atomic_inc(&zmd->nr_reserved_seq_zones);
  1958. } else {
  1959. list_add_tail(&zone->link, &zone->dev->unmap_seq_list);
  1960. atomic_inc(&zone->dev->unmap_nr_seq);
  1961. }
  1962. wake_up_all(&zmd->free_wq);
  1963. }
  1964. /*
  1965. * Map a chunk to a zone.
  1966. * This must be called with the mapping lock held.
  1967. */
  1968. void dmz_map_zone(struct dmz_metadata *zmd, struct dm_zone *dzone,
  1969. unsigned int chunk)
  1970. {
  1971. /* Set the chunk mapping */
  1972. dmz_set_chunk_mapping(zmd, chunk, dzone->id,
  1973. DMZ_MAP_UNMAPPED);
  1974. dzone->chunk = chunk;
  1975. if (dmz_is_cache(dzone))
  1976. list_add_tail(&dzone->link, &zmd->map_cache_list);
  1977. else if (dmz_is_rnd(dzone))
  1978. list_add_tail(&dzone->link, &dzone->dev->map_rnd_list);
  1979. else
  1980. list_add_tail(&dzone->link, &dzone->dev->map_seq_list);
  1981. }
  1982. /*
  1983. * Unmap a zone.
  1984. * This must be called with the mapping lock held.
  1985. */
  1986. void dmz_unmap_zone(struct dmz_metadata *zmd, struct dm_zone *zone)
  1987. {
  1988. unsigned int chunk = zone->chunk;
  1989. unsigned int dzone_id;
  1990. if (chunk == DMZ_MAP_UNMAPPED) {
  1991. /* Already unmapped */
  1992. return;
  1993. }
  1994. if (test_and_clear_bit(DMZ_BUF, &zone->flags)) {
  1995. /*
  1996. * Unmapping the chunk buffer zone: clear only
  1997. * the chunk buffer mapping
  1998. */
  1999. dzone_id = zone->bzone->id;
  2000. zone->bzone->bzone = NULL;
  2001. zone->bzone = NULL;
  2002. } else {
  2003. /*
  2004. * Unmapping the chunk data zone: the zone must
  2005. * not be buffered.
  2006. */
  2007. if (WARN_ON(zone->bzone)) {
  2008. zone->bzone->bzone = NULL;
  2009. zone->bzone = NULL;
  2010. }
  2011. dzone_id = DMZ_MAP_UNMAPPED;
  2012. }
  2013. dmz_set_chunk_mapping(zmd, chunk, dzone_id, DMZ_MAP_UNMAPPED);
  2014. zone->chunk = DMZ_MAP_UNMAPPED;
  2015. list_del_init(&zone->link);
  2016. }
  2017. /*
  2018. * Set @nr_bits bits in @bitmap starting from @bit.
  2019. * Return the number of bits changed from 0 to 1.
  2020. */
  2021. static unsigned int dmz_set_bits(unsigned long *bitmap,
  2022. unsigned int bit, unsigned int nr_bits)
  2023. {
  2024. unsigned long *addr;
  2025. unsigned int end = bit + nr_bits;
  2026. unsigned int n = 0;
  2027. while (bit < end) {
  2028. if (((bit & (BITS_PER_LONG - 1)) == 0) &&
  2029. ((end - bit) >= BITS_PER_LONG)) {
  2030. /* Try to set the whole word at once */
  2031. addr = bitmap + BIT_WORD(bit);
  2032. if (*addr == 0) {
  2033. *addr = ULONG_MAX;
  2034. n += BITS_PER_LONG;
  2035. bit += BITS_PER_LONG;
  2036. continue;
  2037. }
  2038. }
  2039. if (!test_and_set_bit(bit, bitmap))
  2040. n++;
  2041. bit++;
  2042. }
  2043. return n;
  2044. }
  2045. /*
  2046. * Get the bitmap block storing the bit for chunk_block in zone.
  2047. */
  2048. static struct dmz_mblock *dmz_get_bitmap(struct dmz_metadata *zmd,
  2049. struct dm_zone *zone,
  2050. sector_t chunk_block)
  2051. {
  2052. sector_t bitmap_block = 1 + zmd->nr_map_blocks +
  2053. (sector_t)(zone->id * zmd->zone_nr_bitmap_blocks) +
  2054. (chunk_block >> DMZ_BLOCK_SHIFT_BITS);
  2055. return dmz_get_mblock(zmd, bitmap_block);
  2056. }
  2057. /*
  2058. * Copy the valid blocks bitmap of from_zone to the bitmap of to_zone.
  2059. */
  2060. int dmz_copy_valid_blocks(struct dmz_metadata *zmd, struct dm_zone *from_zone,
  2061. struct dm_zone *to_zone)
  2062. {
  2063. struct dmz_mblock *from_mblk, *to_mblk;
  2064. sector_t chunk_block = 0;
  2065. /* Get the zones bitmap blocks */
  2066. while (chunk_block < zmd->zone_nr_blocks) {
  2067. from_mblk = dmz_get_bitmap(zmd, from_zone, chunk_block);
  2068. if (IS_ERR(from_mblk))
  2069. return PTR_ERR(from_mblk);
  2070. to_mblk = dmz_get_bitmap(zmd, to_zone, chunk_block);
  2071. if (IS_ERR(to_mblk)) {
  2072. dmz_release_mblock(zmd, from_mblk);
  2073. return PTR_ERR(to_mblk);
  2074. }
  2075. memcpy(to_mblk->data, from_mblk->data, DMZ_BLOCK_SIZE);
  2076. dmz_dirty_mblock(zmd, to_mblk);
  2077. dmz_release_mblock(zmd, to_mblk);
  2078. dmz_release_mblock(zmd, from_mblk);
  2079. chunk_block += zmd->zone_bits_per_mblk;
  2080. }
  2081. to_zone->weight = from_zone->weight;
  2082. return 0;
  2083. }
  2084. /*
  2085. * Merge the valid blocks bitmap of from_zone into the bitmap of to_zone,
  2086. * starting from chunk_block.
  2087. */
  2088. int dmz_merge_valid_blocks(struct dmz_metadata *zmd, struct dm_zone *from_zone,
  2089. struct dm_zone *to_zone, sector_t chunk_block)
  2090. {
  2091. unsigned int nr_blocks;
  2092. int ret;
  2093. /* Get the zones bitmap blocks */
  2094. while (chunk_block < zmd->zone_nr_blocks) {
  2095. /* Get a valid region from the source zone */
  2096. ret = dmz_first_valid_block(zmd, from_zone, &chunk_block);
  2097. if (ret <= 0)
  2098. return ret;
  2099. nr_blocks = ret;
  2100. ret = dmz_validate_blocks(zmd, to_zone, chunk_block, nr_blocks);
  2101. if (ret)
  2102. return ret;
  2103. chunk_block += nr_blocks;
  2104. }
  2105. return 0;
  2106. }
  2107. /*
  2108. * Validate all the blocks in the range [block..block+nr_blocks-1].
  2109. */
  2110. int dmz_validate_blocks(struct dmz_metadata *zmd, struct dm_zone *zone,
  2111. sector_t chunk_block, unsigned int nr_blocks)
  2112. {
  2113. unsigned int count, bit, nr_bits;
  2114. unsigned int zone_nr_blocks = zmd->zone_nr_blocks;
  2115. struct dmz_mblock *mblk;
  2116. unsigned int n = 0;
  2117. dmz_zmd_debug(zmd, "=> VALIDATE zone %u, block %llu, %u blocks",
  2118. zone->id, (unsigned long long)chunk_block,
  2119. nr_blocks);
  2120. WARN_ON(chunk_block + nr_blocks > zone_nr_blocks);
  2121. while (nr_blocks) {
  2122. /* Get bitmap block */
  2123. mblk = dmz_get_bitmap(zmd, zone, chunk_block);
  2124. if (IS_ERR(mblk))
  2125. return PTR_ERR(mblk);
  2126. /* Set bits */
  2127. bit = chunk_block & DMZ_BLOCK_MASK_BITS;
  2128. nr_bits = min(nr_blocks, zmd->zone_bits_per_mblk - bit);
  2129. count = dmz_set_bits((unsigned long *)mblk->data, bit, nr_bits);
  2130. if (count) {
  2131. dmz_dirty_mblock(zmd, mblk);
  2132. n += count;
  2133. }
  2134. dmz_release_mblock(zmd, mblk);
  2135. nr_blocks -= nr_bits;
  2136. chunk_block += nr_bits;
  2137. }
  2138. if (likely(zone->weight + n <= zone_nr_blocks))
  2139. zone->weight += n;
  2140. else {
  2141. dmz_zmd_warn(zmd, "Zone %u: weight %u should be <= %u",
  2142. zone->id, zone->weight,
  2143. zone_nr_blocks - n);
  2144. zone->weight = zone_nr_blocks;
  2145. }
  2146. return 0;
  2147. }
  2148. /*
  2149. * Clear nr_bits bits in bitmap starting from bit.
  2150. * Return the number of bits cleared.
  2151. */
  2152. static int dmz_clear_bits(unsigned long *bitmap, int bit, int nr_bits)
  2153. {
  2154. unsigned long *addr;
  2155. int end = bit + nr_bits;
  2156. int n = 0;
  2157. while (bit < end) {
  2158. if (((bit & (BITS_PER_LONG - 1)) == 0) &&
  2159. ((end - bit) >= BITS_PER_LONG)) {
  2160. /* Try to clear whole word at once */
  2161. addr = bitmap + BIT_WORD(bit);
  2162. if (*addr == ULONG_MAX) {
  2163. *addr = 0;
  2164. n += BITS_PER_LONG;
  2165. bit += BITS_PER_LONG;
  2166. continue;
  2167. }
  2168. }
  2169. if (test_and_clear_bit(bit, bitmap))
  2170. n++;
  2171. bit++;
  2172. }
  2173. return n;
  2174. }
  2175. /*
  2176. * Invalidate all the blocks in the range [block..block+nr_blocks-1].
  2177. */
  2178. int dmz_invalidate_blocks(struct dmz_metadata *zmd, struct dm_zone *zone,
  2179. sector_t chunk_block, unsigned int nr_blocks)
  2180. {
  2181. unsigned int count, bit, nr_bits;
  2182. struct dmz_mblock *mblk;
  2183. unsigned int n = 0;
  2184. dmz_zmd_debug(zmd, "=> INVALIDATE zone %u, block %llu, %u blocks",
  2185. zone->id, (u64)chunk_block, nr_blocks);
  2186. WARN_ON(chunk_block + nr_blocks > zmd->zone_nr_blocks);
  2187. while (nr_blocks) {
  2188. /* Get bitmap block */
  2189. mblk = dmz_get_bitmap(zmd, zone, chunk_block);
  2190. if (IS_ERR(mblk))
  2191. return PTR_ERR(mblk);
  2192. /* Clear bits */
  2193. bit = chunk_block & DMZ_BLOCK_MASK_BITS;
  2194. nr_bits = min(nr_blocks, zmd->zone_bits_per_mblk - bit);
  2195. count = dmz_clear_bits((unsigned long *)mblk->data,
  2196. bit, nr_bits);
  2197. if (count) {
  2198. dmz_dirty_mblock(zmd, mblk);
  2199. n += count;
  2200. }
  2201. dmz_release_mblock(zmd, mblk);
  2202. nr_blocks -= nr_bits;
  2203. chunk_block += nr_bits;
  2204. }
  2205. if (zone->weight >= n)
  2206. zone->weight -= n;
  2207. else {
  2208. dmz_zmd_warn(zmd, "Zone %u: weight %u should be >= %u",
  2209. zone->id, zone->weight, n);
  2210. zone->weight = 0;
  2211. }
  2212. return 0;
  2213. }
  2214. /*
  2215. * Get a block bit value.
  2216. */
  2217. static int dmz_test_block(struct dmz_metadata *zmd, struct dm_zone *zone,
  2218. sector_t chunk_block)
  2219. {
  2220. struct dmz_mblock *mblk;
  2221. int ret;
  2222. WARN_ON(chunk_block >= zmd->zone_nr_blocks);
  2223. /* Get bitmap block */
  2224. mblk = dmz_get_bitmap(zmd, zone, chunk_block);
  2225. if (IS_ERR(mblk))
  2226. return PTR_ERR(mblk);
  2227. /* Get offset */
  2228. ret = test_bit(chunk_block & DMZ_BLOCK_MASK_BITS,
  2229. (unsigned long *) mblk->data) != 0;
  2230. dmz_release_mblock(zmd, mblk);
  2231. return ret;
  2232. }
  2233. /*
  2234. * Return the number of blocks from chunk_block to the first block with a bit
  2235. * value specified by set. Search at most nr_blocks blocks from chunk_block.
  2236. */
  2237. static int dmz_to_next_set_block(struct dmz_metadata *zmd, struct dm_zone *zone,
  2238. sector_t chunk_block, unsigned int nr_blocks,
  2239. int set)
  2240. {
  2241. struct dmz_mblock *mblk;
  2242. unsigned int bit, set_bit, nr_bits;
  2243. unsigned int zone_bits = zmd->zone_bits_per_mblk;
  2244. unsigned long *bitmap;
  2245. int n = 0;
  2246. WARN_ON(chunk_block + nr_blocks > zmd->zone_nr_blocks);
  2247. while (nr_blocks) {
  2248. /* Get bitmap block */
  2249. mblk = dmz_get_bitmap(zmd, zone, chunk_block);
  2250. if (IS_ERR(mblk))
  2251. return PTR_ERR(mblk);
  2252. /* Get offset */
  2253. bitmap = (unsigned long *) mblk->data;
  2254. bit = chunk_block & DMZ_BLOCK_MASK_BITS;
  2255. nr_bits = min(nr_blocks, zone_bits - bit);
  2256. if (set)
  2257. set_bit = find_next_bit(bitmap, zone_bits, bit);
  2258. else
  2259. set_bit = find_next_zero_bit(bitmap, zone_bits, bit);
  2260. dmz_release_mblock(zmd, mblk);
  2261. n += set_bit - bit;
  2262. if (set_bit < zone_bits)
  2263. break;
  2264. nr_blocks -= nr_bits;
  2265. chunk_block += nr_bits;
  2266. }
  2267. return n;
  2268. }
  2269. /*
  2270. * Test if chunk_block is valid. If it is, the number of consecutive
  2271. * valid blocks from chunk_block will be returned.
  2272. */
  2273. int dmz_block_valid(struct dmz_metadata *zmd, struct dm_zone *zone,
  2274. sector_t chunk_block)
  2275. {
  2276. int valid;
  2277. valid = dmz_test_block(zmd, zone, chunk_block);
  2278. if (valid <= 0)
  2279. return valid;
  2280. /* The block is valid: get the number of valid blocks from block */
  2281. return dmz_to_next_set_block(zmd, zone, chunk_block,
  2282. zmd->zone_nr_blocks - chunk_block, 0);
  2283. }
  2284. /*
  2285. * Find the first valid block from @chunk_block in @zone.
  2286. * If such a block is found, its number is returned using
  2287. * @chunk_block and the total number of valid blocks from @chunk_block
  2288. * is returned.
  2289. */
  2290. int dmz_first_valid_block(struct dmz_metadata *zmd, struct dm_zone *zone,
  2291. sector_t *chunk_block)
  2292. {
  2293. sector_t start_block = *chunk_block;
  2294. int ret;
  2295. ret = dmz_to_next_set_block(zmd, zone, start_block,
  2296. zmd->zone_nr_blocks - start_block, 1);
  2297. if (ret < 0)
  2298. return ret;
  2299. start_block += ret;
  2300. *chunk_block = start_block;
  2301. return dmz_to_next_set_block(zmd, zone, start_block,
  2302. zmd->zone_nr_blocks - start_block, 0);
  2303. }
  2304. /*
  2305. * Count the number of bits set starting from bit up to bit + nr_bits - 1.
  2306. */
  2307. static int dmz_count_bits(void *bitmap, int bit, int nr_bits)
  2308. {
  2309. unsigned long *addr;
  2310. int end = bit + nr_bits;
  2311. int n = 0;
  2312. while (bit < end) {
  2313. if (((bit & (BITS_PER_LONG - 1)) == 0) &&
  2314. ((end - bit) >= BITS_PER_LONG)) {
  2315. addr = (unsigned long *)bitmap + BIT_WORD(bit);
  2316. if (*addr == ULONG_MAX) {
  2317. n += BITS_PER_LONG;
  2318. bit += BITS_PER_LONG;
  2319. continue;
  2320. }
  2321. }
  2322. if (test_bit(bit, bitmap))
  2323. n++;
  2324. bit++;
  2325. }
  2326. return n;
  2327. }
  2328. /*
  2329. * Get a zone weight.
  2330. */
  2331. static void dmz_get_zone_weight(struct dmz_metadata *zmd, struct dm_zone *zone)
  2332. {
  2333. struct dmz_mblock *mblk;
  2334. sector_t chunk_block = 0;
  2335. unsigned int bit, nr_bits;
  2336. unsigned int nr_blocks = zmd->zone_nr_blocks;
  2337. void *bitmap;
  2338. int n = 0;
  2339. while (nr_blocks) {
  2340. /* Get bitmap block */
  2341. mblk = dmz_get_bitmap(zmd, zone, chunk_block);
  2342. if (IS_ERR(mblk)) {
  2343. n = 0;
  2344. break;
  2345. }
  2346. /* Count bits in this block */
  2347. bitmap = mblk->data;
  2348. bit = chunk_block & DMZ_BLOCK_MASK_BITS;
  2349. nr_bits = min(nr_blocks, zmd->zone_bits_per_mblk - bit);
  2350. n += dmz_count_bits(bitmap, bit, nr_bits);
  2351. dmz_release_mblock(zmd, mblk);
  2352. nr_blocks -= nr_bits;
  2353. chunk_block += nr_bits;
  2354. }
  2355. zone->weight = n;
  2356. }
  2357. /*
  2358. * Cleanup the zoned metadata resources.
  2359. */
  2360. static void dmz_cleanup_metadata(struct dmz_metadata *zmd)
  2361. {
  2362. struct rb_root *root;
  2363. struct dmz_mblock *mblk, *next;
  2364. int i;
  2365. /* Release zone mapping resources */
  2366. if (zmd->map_mblk) {
  2367. for (i = 0; i < zmd->nr_map_blocks; i++)
  2368. dmz_release_mblock(zmd, zmd->map_mblk[i]);
  2369. kfree(zmd->map_mblk);
  2370. zmd->map_mblk = NULL;
  2371. }
  2372. /* Release super blocks */
  2373. for (i = 0; i < 2; i++) {
  2374. if (zmd->sb[i].mblk) {
  2375. dmz_free_mblock(zmd, zmd->sb[i].mblk);
  2376. zmd->sb[i].mblk = NULL;
  2377. }
  2378. }
  2379. /* Free cached blocks */
  2380. while (!list_empty(&zmd->mblk_dirty_list)) {
  2381. mblk = list_first_entry(&zmd->mblk_dirty_list,
  2382. struct dmz_mblock, link);
  2383. dmz_zmd_warn(zmd, "mblock %llu still in dirty list (ref %u)",
  2384. (u64)mblk->no, mblk->ref);
  2385. list_del_init(&mblk->link);
  2386. rb_erase(&mblk->node, &zmd->mblk_rbtree);
  2387. dmz_free_mblock(zmd, mblk);
  2388. }
  2389. while (!list_empty(&zmd->mblk_lru_list)) {
  2390. mblk = list_first_entry(&zmd->mblk_lru_list,
  2391. struct dmz_mblock, link);
  2392. list_del_init(&mblk->link);
  2393. rb_erase(&mblk->node, &zmd->mblk_rbtree);
  2394. dmz_free_mblock(zmd, mblk);
  2395. }
  2396. /* Sanity checks: the mblock rbtree should now be empty */
  2397. root = &zmd->mblk_rbtree;
  2398. rbtree_postorder_for_each_entry_safe(mblk, next, root, node) {
  2399. dmz_zmd_warn(zmd, "mblock %llu ref %u still in rbtree",
  2400. (u64)mblk->no, mblk->ref);
  2401. mblk->ref = 0;
  2402. dmz_free_mblock(zmd, mblk);
  2403. }
  2404. /* Free the zone descriptors */
  2405. dmz_drop_zones(zmd);
  2406. mutex_destroy(&zmd->mblk_flush_lock);
  2407. mutex_destroy(&zmd->map_lock);
  2408. }
  2409. static void dmz_print_dev(struct dmz_metadata *zmd, int num)
  2410. {
  2411. struct dmz_dev *dev = &zmd->dev[num];
  2412. if (!bdev_is_zoned(dev->bdev))
  2413. dmz_dev_info(dev, "Regular block device");
  2414. else
  2415. dmz_dev_info(dev, "Host-managed zoned block device");
  2416. if (zmd->sb_version > 1) {
  2417. sector_t sector_offset =
  2418. dev->zone_offset << zmd->zone_nr_sectors_shift;
  2419. dmz_dev_info(dev, " %llu 512-byte logical sectors (offset %llu)",
  2420. (u64)dev->capacity, (u64)sector_offset);
  2421. dmz_dev_info(dev, " %u zones of %llu 512-byte logical sectors (offset %llu)",
  2422. dev->nr_zones, (u64)zmd->zone_nr_sectors,
  2423. (u64)dev->zone_offset);
  2424. } else {
  2425. dmz_dev_info(dev, " %llu 512-byte logical sectors",
  2426. (u64)dev->capacity);
  2427. dmz_dev_info(dev, " %u zones of %llu 512-byte logical sectors",
  2428. dev->nr_zones, (u64)zmd->zone_nr_sectors);
  2429. }
  2430. }
  2431. /*
  2432. * Initialize the zoned metadata.
  2433. */
  2434. int dmz_ctr_metadata(struct dmz_dev *dev, int num_dev,
  2435. struct dmz_metadata **metadata,
  2436. const char *devname)
  2437. {
  2438. struct dmz_metadata *zmd;
  2439. unsigned int i;
  2440. struct dm_zone *zone;
  2441. int ret;
  2442. zmd = kzalloc_obj(struct dmz_metadata);
  2443. if (!zmd)
  2444. return -ENOMEM;
  2445. strcpy(zmd->devname, devname);
  2446. zmd->dev = dev;
  2447. zmd->nr_devs = num_dev;
  2448. zmd->mblk_rbtree = RB_ROOT;
  2449. init_rwsem(&zmd->mblk_sem);
  2450. mutex_init(&zmd->mblk_flush_lock);
  2451. spin_lock_init(&zmd->mblk_lock);
  2452. INIT_LIST_HEAD(&zmd->mblk_lru_list);
  2453. INIT_LIST_HEAD(&zmd->mblk_dirty_list);
  2454. mutex_init(&zmd->map_lock);
  2455. atomic_set(&zmd->unmap_nr_cache, 0);
  2456. INIT_LIST_HEAD(&zmd->unmap_cache_list);
  2457. INIT_LIST_HEAD(&zmd->map_cache_list);
  2458. atomic_set(&zmd->nr_reserved_seq_zones, 0);
  2459. INIT_LIST_HEAD(&zmd->reserved_seq_zones_list);
  2460. init_waitqueue_head(&zmd->free_wq);
  2461. /* Initialize zone descriptors */
  2462. ret = dmz_init_zones(zmd);
  2463. if (ret)
  2464. goto err;
  2465. /* Get super block */
  2466. ret = dmz_load_sb(zmd);
  2467. if (ret)
  2468. goto err;
  2469. /* Set metadata zones starting from sb_zone */
  2470. for (i = 0; i < zmd->nr_meta_zones << 1; i++) {
  2471. zone = dmz_get(zmd, zmd->sb[0].zone->id + i);
  2472. if (!zone) {
  2473. dmz_zmd_err(zmd,
  2474. "metadata zone %u not present", i);
  2475. ret = -ENXIO;
  2476. goto err;
  2477. }
  2478. if (!dmz_is_rnd(zone) && !dmz_is_cache(zone)) {
  2479. dmz_zmd_err(zmd,
  2480. "metadata zone %d is not random", i);
  2481. ret = -ENXIO;
  2482. goto err;
  2483. }
  2484. set_bit(DMZ_META, &zone->flags);
  2485. }
  2486. /* Load mapping table */
  2487. ret = dmz_load_mapping(zmd);
  2488. if (ret)
  2489. goto err;
  2490. /*
  2491. * Cache size boundaries: allow at least 2 super blocks, the chunk map
  2492. * blocks and enough blocks to be able to cache the bitmap blocks of
  2493. * up to 16 zones when idle (min_nr_mblks). Otherwise, if busy, allow
  2494. * the cache to add 512 more metadata blocks.
  2495. */
  2496. zmd->min_nr_mblks = 2 + zmd->nr_map_blocks + zmd->zone_nr_bitmap_blocks * 16;
  2497. zmd->max_nr_mblks = zmd->min_nr_mblks + 512;
  2498. /* Metadata cache shrinker */
  2499. zmd->mblk_shrinker = shrinker_alloc(0, "dm-zoned-meta:(%u:%u)",
  2500. MAJOR(dev->bdev->bd_dev),
  2501. MINOR(dev->bdev->bd_dev));
  2502. if (!zmd->mblk_shrinker) {
  2503. ret = -ENOMEM;
  2504. dmz_zmd_err(zmd, "Allocate metadata cache shrinker failed");
  2505. goto err;
  2506. }
  2507. zmd->mblk_shrinker->count_objects = dmz_mblock_shrinker_count;
  2508. zmd->mblk_shrinker->scan_objects = dmz_mblock_shrinker_scan;
  2509. zmd->mblk_shrinker->private_data = zmd;
  2510. shrinker_register(zmd->mblk_shrinker);
  2511. dmz_zmd_info(zmd, "DM-Zoned metadata version %d", zmd->sb_version);
  2512. for (i = 0; i < zmd->nr_devs; i++)
  2513. dmz_print_dev(zmd, i);
  2514. dmz_zmd_info(zmd, " %u zones of %llu 512-byte logical sectors",
  2515. zmd->nr_zones, (u64)zmd->zone_nr_sectors);
  2516. dmz_zmd_debug(zmd, " %u metadata zones",
  2517. zmd->nr_meta_zones * 2);
  2518. dmz_zmd_debug(zmd, " %u data zones for %u chunks",
  2519. zmd->nr_data_zones, zmd->nr_chunks);
  2520. dmz_zmd_debug(zmd, " %u cache zones (%u unmapped)",
  2521. zmd->nr_cache, atomic_read(&zmd->unmap_nr_cache));
  2522. for (i = 0; i < zmd->nr_devs; i++) {
  2523. dmz_zmd_debug(zmd, " %u random zones (%u unmapped)",
  2524. dmz_nr_rnd_zones(zmd, i),
  2525. dmz_nr_unmap_rnd_zones(zmd, i));
  2526. dmz_zmd_debug(zmd, " %u sequential zones (%u unmapped)",
  2527. dmz_nr_seq_zones(zmd, i),
  2528. dmz_nr_unmap_seq_zones(zmd, i));
  2529. }
  2530. dmz_zmd_debug(zmd, " %u reserved sequential data zones",
  2531. zmd->nr_reserved_seq);
  2532. dmz_zmd_debug(zmd, "Format:");
  2533. dmz_zmd_debug(zmd, "%u metadata blocks per set (%u max cache)",
  2534. zmd->nr_meta_blocks, zmd->max_nr_mblks);
  2535. dmz_zmd_debug(zmd, " %u data zone mapping blocks",
  2536. zmd->nr_map_blocks);
  2537. dmz_zmd_debug(zmd, " %u bitmap blocks",
  2538. zmd->nr_bitmap_blocks);
  2539. *metadata = zmd;
  2540. return 0;
  2541. err:
  2542. dmz_cleanup_metadata(zmd);
  2543. kfree(zmd);
  2544. *metadata = NULL;
  2545. return ret;
  2546. }
  2547. /*
  2548. * Cleanup the zoned metadata resources.
  2549. */
  2550. void dmz_dtr_metadata(struct dmz_metadata *zmd)
  2551. {
  2552. shrinker_free(zmd->mblk_shrinker);
  2553. dmz_cleanup_metadata(zmd);
  2554. kfree(zmd);
  2555. }