zswap.c 51 KB

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  1. // SPDX-License-Identifier: GPL-2.0-or-later
  2. /*
  3. * zswap.c - zswap driver file
  4. *
  5. * zswap is a cache that takes pages that are in the process
  6. * of being swapped out and attempts to compress and store them in a
  7. * RAM-based memory pool. This can result in a significant I/O reduction on
  8. * the swap device and, in the case where decompressing from RAM is faster
  9. * than reading from the swap device, can also improve workload performance.
  10. *
  11. * Copyright (C) 2012 Seth Jennings <sjenning@linux.vnet.ibm.com>
  12. */
  13. #define pr_fmt(fmt) KBUILD_MODNAME ": " fmt
  14. #include <linux/module.h>
  15. #include <linux/cpu.h>
  16. #include <linux/highmem.h>
  17. #include <linux/slab.h>
  18. #include <linux/spinlock.h>
  19. #include <linux/types.h>
  20. #include <linux/atomic.h>
  21. #include <linux/swap.h>
  22. #include <linux/crypto.h>
  23. #include <linux/scatterlist.h>
  24. #include <linux/mempolicy.h>
  25. #include <linux/mempool.h>
  26. #include <crypto/acompress.h>
  27. #include <crypto/scatterwalk.h>
  28. #include <linux/zswap.h>
  29. #include <linux/mm_types.h>
  30. #include <linux/page-flags.h>
  31. #include <linux/swapops.h>
  32. #include <linux/writeback.h>
  33. #include <linux/pagemap.h>
  34. #include <linux/workqueue.h>
  35. #include <linux/list_lru.h>
  36. #include <linux/zsmalloc.h>
  37. #include "swap.h"
  38. #include "internal.h"
  39. /*********************************
  40. * statistics
  41. **********************************/
  42. /* The number of pages currently stored in zswap */
  43. atomic_long_t zswap_stored_pages = ATOMIC_LONG_INIT(0);
  44. /* The number of incompressible pages currently stored in zswap */
  45. static atomic_long_t zswap_stored_incompressible_pages = ATOMIC_LONG_INIT(0);
  46. /*
  47. * The statistics below are not protected from concurrent access for
  48. * performance reasons so they may not be a 100% accurate. However,
  49. * they do provide useful information on roughly how many times a
  50. * certain event is occurring.
  51. */
  52. /* Pool limit was hit (see zswap_max_pool_percent) */
  53. static u64 zswap_pool_limit_hit;
  54. /* Pages written back when pool limit was reached */
  55. static u64 zswap_written_back_pages;
  56. /* Store failed due to a reclaim failure after pool limit was reached */
  57. static u64 zswap_reject_reclaim_fail;
  58. /* Store failed due to compression algorithm failure */
  59. static u64 zswap_reject_compress_fail;
  60. /* Compressed page was too big for the allocator to (optimally) store */
  61. static u64 zswap_reject_compress_poor;
  62. /* Load or writeback failed due to decompression failure */
  63. static u64 zswap_decompress_fail;
  64. /* Store failed because underlying allocator could not get memory */
  65. static u64 zswap_reject_alloc_fail;
  66. /* Store failed because the entry metadata could not be allocated (rare) */
  67. static u64 zswap_reject_kmemcache_fail;
  68. /* Shrinker work queue */
  69. static struct workqueue_struct *shrink_wq;
  70. /* Pool limit was hit, we need to calm down */
  71. static bool zswap_pool_reached_full;
  72. /*********************************
  73. * tunables
  74. **********************************/
  75. #define ZSWAP_PARAM_UNSET ""
  76. static int zswap_setup(void);
  77. /* Enable/disable zswap */
  78. static DEFINE_STATIC_KEY_MAYBE(CONFIG_ZSWAP_DEFAULT_ON, zswap_ever_enabled);
  79. static bool zswap_enabled = IS_ENABLED(CONFIG_ZSWAP_DEFAULT_ON);
  80. static int zswap_enabled_param_set(const char *,
  81. const struct kernel_param *);
  82. static const struct kernel_param_ops zswap_enabled_param_ops = {
  83. .set = zswap_enabled_param_set,
  84. .get = param_get_bool,
  85. };
  86. module_param_cb(enabled, &zswap_enabled_param_ops, &zswap_enabled, 0644);
  87. /* Crypto compressor to use */
  88. static char *zswap_compressor = CONFIG_ZSWAP_COMPRESSOR_DEFAULT;
  89. static int zswap_compressor_param_set(const char *,
  90. const struct kernel_param *);
  91. static const struct kernel_param_ops zswap_compressor_param_ops = {
  92. .set = zswap_compressor_param_set,
  93. .get = param_get_charp,
  94. .free = param_free_charp,
  95. };
  96. module_param_cb(compressor, &zswap_compressor_param_ops,
  97. &zswap_compressor, 0644);
  98. /* The maximum percentage of memory that the compressed pool can occupy */
  99. static unsigned int zswap_max_pool_percent = 20;
  100. module_param_named(max_pool_percent, zswap_max_pool_percent, uint, 0644);
  101. /* The threshold for accepting new pages after the max_pool_percent was hit */
  102. static unsigned int zswap_accept_thr_percent = 90; /* of max pool size */
  103. module_param_named(accept_threshold_percent, zswap_accept_thr_percent,
  104. uint, 0644);
  105. /* Enable/disable memory pressure-based shrinker. */
  106. static bool zswap_shrinker_enabled = IS_ENABLED(
  107. CONFIG_ZSWAP_SHRINKER_DEFAULT_ON);
  108. module_param_named(shrinker_enabled, zswap_shrinker_enabled, bool, 0644);
  109. bool zswap_is_enabled(void)
  110. {
  111. return zswap_enabled;
  112. }
  113. bool zswap_never_enabled(void)
  114. {
  115. return !static_branch_maybe(CONFIG_ZSWAP_DEFAULT_ON, &zswap_ever_enabled);
  116. }
  117. /*********************************
  118. * data structures
  119. **********************************/
  120. struct crypto_acomp_ctx {
  121. struct crypto_acomp *acomp;
  122. struct acomp_req *req;
  123. struct crypto_wait wait;
  124. u8 *buffer;
  125. struct mutex mutex;
  126. };
  127. /*
  128. * The lock ordering is zswap_tree.lock -> zswap_pool.lru_lock.
  129. * The only case where lru_lock is not acquired while holding tree.lock is
  130. * when a zswap_entry is taken off the lru for writeback, in that case it
  131. * needs to be verified that it's still valid in the tree.
  132. */
  133. struct zswap_pool {
  134. struct zs_pool *zs_pool;
  135. struct crypto_acomp_ctx __percpu *acomp_ctx;
  136. struct percpu_ref ref;
  137. struct list_head list;
  138. struct work_struct release_work;
  139. struct hlist_node node;
  140. char tfm_name[CRYPTO_MAX_ALG_NAME];
  141. };
  142. /* Global LRU lists shared by all zswap pools. */
  143. static struct list_lru zswap_list_lru;
  144. /* The lock protects zswap_next_shrink updates. */
  145. static DEFINE_SPINLOCK(zswap_shrink_lock);
  146. static struct mem_cgroup *zswap_next_shrink;
  147. static struct work_struct zswap_shrink_work;
  148. static struct shrinker *zswap_shrinker;
  149. /*
  150. * struct zswap_entry
  151. *
  152. * This structure contains the metadata for tracking a single compressed
  153. * page within zswap.
  154. *
  155. * swpentry - associated swap entry, the offset indexes into the xarray
  156. * length - the length in bytes of the compressed page data. Needed during
  157. * decompression.
  158. * referenced - true if the entry recently entered the zswap pool. Unset by the
  159. * writeback logic. The entry is only reclaimed by the writeback
  160. * logic if referenced is unset. See comments in the shrinker
  161. * section for context.
  162. * pool - the zswap_pool the entry's data is in
  163. * handle - zsmalloc allocation handle that stores the compressed page data
  164. * objcg - the obj_cgroup that the compressed memory is charged to
  165. * lru - handle to the pool's lru used to evict pages.
  166. */
  167. struct zswap_entry {
  168. swp_entry_t swpentry;
  169. unsigned int length;
  170. bool referenced;
  171. struct zswap_pool *pool;
  172. unsigned long handle;
  173. struct obj_cgroup *objcg;
  174. struct list_head lru;
  175. };
  176. static struct xarray *zswap_trees[MAX_SWAPFILES];
  177. static unsigned int nr_zswap_trees[MAX_SWAPFILES];
  178. /* RCU-protected iteration */
  179. static LIST_HEAD(zswap_pools);
  180. /* protects zswap_pools list modification */
  181. static DEFINE_SPINLOCK(zswap_pools_lock);
  182. /* pool counter to provide unique names to zsmalloc */
  183. static atomic_t zswap_pools_count = ATOMIC_INIT(0);
  184. enum zswap_init_type {
  185. ZSWAP_UNINIT,
  186. ZSWAP_INIT_SUCCEED,
  187. ZSWAP_INIT_FAILED
  188. };
  189. static enum zswap_init_type zswap_init_state;
  190. /* used to ensure the integrity of initialization */
  191. static DEFINE_MUTEX(zswap_init_lock);
  192. /* init completed, but couldn't create the initial pool */
  193. static bool zswap_has_pool;
  194. /*********************************
  195. * helpers and fwd declarations
  196. **********************************/
  197. /* One swap address space for each 64M swap space */
  198. #define ZSWAP_ADDRESS_SPACE_SHIFT 14
  199. #define ZSWAP_ADDRESS_SPACE_PAGES (1 << ZSWAP_ADDRESS_SPACE_SHIFT)
  200. static inline struct xarray *swap_zswap_tree(swp_entry_t swp)
  201. {
  202. return &zswap_trees[swp_type(swp)][swp_offset(swp)
  203. >> ZSWAP_ADDRESS_SPACE_SHIFT];
  204. }
  205. #define zswap_pool_debug(msg, p) \
  206. pr_debug("%s pool %s\n", msg, (p)->tfm_name)
  207. /*********************************
  208. * pool functions
  209. **********************************/
  210. static void __zswap_pool_empty(struct percpu_ref *ref);
  211. static struct zswap_pool *zswap_pool_create(char *compressor)
  212. {
  213. struct zswap_pool *pool;
  214. char name[38]; /* 'zswap' + 32 char (max) num + \0 */
  215. int ret, cpu;
  216. if (!zswap_has_pool && !strcmp(compressor, ZSWAP_PARAM_UNSET))
  217. return NULL;
  218. pool = kzalloc_obj(*pool);
  219. if (!pool)
  220. return NULL;
  221. /* unique name for each pool specifically required by zsmalloc */
  222. snprintf(name, 38, "zswap%x", atomic_inc_return(&zswap_pools_count));
  223. pool->zs_pool = zs_create_pool(name);
  224. if (!pool->zs_pool)
  225. goto error;
  226. strscpy(pool->tfm_name, compressor, sizeof(pool->tfm_name));
  227. pool->acomp_ctx = alloc_percpu(*pool->acomp_ctx);
  228. if (!pool->acomp_ctx) {
  229. pr_err("percpu alloc failed\n");
  230. goto error;
  231. }
  232. for_each_possible_cpu(cpu)
  233. mutex_init(&per_cpu_ptr(pool->acomp_ctx, cpu)->mutex);
  234. ret = cpuhp_state_add_instance(CPUHP_MM_ZSWP_POOL_PREPARE,
  235. &pool->node);
  236. if (ret)
  237. goto error;
  238. /* being the current pool takes 1 ref; this func expects the
  239. * caller to always add the new pool as the current pool
  240. */
  241. ret = percpu_ref_init(&pool->ref, __zswap_pool_empty,
  242. PERCPU_REF_ALLOW_REINIT, GFP_KERNEL);
  243. if (ret)
  244. goto ref_fail;
  245. INIT_LIST_HEAD(&pool->list);
  246. zswap_pool_debug("created", pool);
  247. return pool;
  248. ref_fail:
  249. cpuhp_state_remove_instance(CPUHP_MM_ZSWP_POOL_PREPARE, &pool->node);
  250. error:
  251. if (pool->acomp_ctx)
  252. free_percpu(pool->acomp_ctx);
  253. if (pool->zs_pool)
  254. zs_destroy_pool(pool->zs_pool);
  255. kfree(pool);
  256. return NULL;
  257. }
  258. static struct zswap_pool *__zswap_pool_create_fallback(void)
  259. {
  260. if (!crypto_has_acomp(zswap_compressor, 0, 0) &&
  261. strcmp(zswap_compressor, CONFIG_ZSWAP_COMPRESSOR_DEFAULT)) {
  262. pr_err("compressor %s not available, using default %s\n",
  263. zswap_compressor, CONFIG_ZSWAP_COMPRESSOR_DEFAULT);
  264. param_free_charp(&zswap_compressor);
  265. zswap_compressor = CONFIG_ZSWAP_COMPRESSOR_DEFAULT;
  266. }
  267. /* Default compressor should be available. Kconfig bug? */
  268. if (WARN_ON_ONCE(!crypto_has_acomp(zswap_compressor, 0, 0))) {
  269. zswap_compressor = ZSWAP_PARAM_UNSET;
  270. return NULL;
  271. }
  272. return zswap_pool_create(zswap_compressor);
  273. }
  274. static void zswap_pool_destroy(struct zswap_pool *pool)
  275. {
  276. zswap_pool_debug("destroying", pool);
  277. cpuhp_state_remove_instance(CPUHP_MM_ZSWP_POOL_PREPARE, &pool->node);
  278. free_percpu(pool->acomp_ctx);
  279. zs_destroy_pool(pool->zs_pool);
  280. kfree(pool);
  281. }
  282. static void __zswap_pool_release(struct work_struct *work)
  283. {
  284. struct zswap_pool *pool = container_of(work, typeof(*pool),
  285. release_work);
  286. synchronize_rcu();
  287. /* nobody should have been able to get a ref... */
  288. WARN_ON(!percpu_ref_is_zero(&pool->ref));
  289. percpu_ref_exit(&pool->ref);
  290. /* pool is now off zswap_pools list and has no references. */
  291. zswap_pool_destroy(pool);
  292. }
  293. static struct zswap_pool *zswap_pool_current(void);
  294. static void __zswap_pool_empty(struct percpu_ref *ref)
  295. {
  296. struct zswap_pool *pool;
  297. pool = container_of(ref, typeof(*pool), ref);
  298. spin_lock_bh(&zswap_pools_lock);
  299. WARN_ON(pool == zswap_pool_current());
  300. list_del_rcu(&pool->list);
  301. INIT_WORK(&pool->release_work, __zswap_pool_release);
  302. schedule_work(&pool->release_work);
  303. spin_unlock_bh(&zswap_pools_lock);
  304. }
  305. static int __must_check zswap_pool_tryget(struct zswap_pool *pool)
  306. {
  307. if (!pool)
  308. return 0;
  309. return percpu_ref_tryget(&pool->ref);
  310. }
  311. /* The caller must already have a reference. */
  312. static void zswap_pool_get(struct zswap_pool *pool)
  313. {
  314. percpu_ref_get(&pool->ref);
  315. }
  316. static void zswap_pool_put(struct zswap_pool *pool)
  317. {
  318. percpu_ref_put(&pool->ref);
  319. }
  320. static struct zswap_pool *__zswap_pool_current(void)
  321. {
  322. struct zswap_pool *pool;
  323. pool = list_first_or_null_rcu(&zswap_pools, typeof(*pool), list);
  324. WARN_ONCE(!pool && zswap_has_pool,
  325. "%s: no page storage pool!\n", __func__);
  326. return pool;
  327. }
  328. static struct zswap_pool *zswap_pool_current(void)
  329. {
  330. assert_spin_locked(&zswap_pools_lock);
  331. return __zswap_pool_current();
  332. }
  333. static struct zswap_pool *zswap_pool_current_get(void)
  334. {
  335. struct zswap_pool *pool;
  336. rcu_read_lock();
  337. pool = __zswap_pool_current();
  338. if (!zswap_pool_tryget(pool))
  339. pool = NULL;
  340. rcu_read_unlock();
  341. return pool;
  342. }
  343. /* type and compressor must be null-terminated */
  344. static struct zswap_pool *zswap_pool_find_get(char *compressor)
  345. {
  346. struct zswap_pool *pool;
  347. assert_spin_locked(&zswap_pools_lock);
  348. list_for_each_entry_rcu(pool, &zswap_pools, list) {
  349. if (strcmp(pool->tfm_name, compressor))
  350. continue;
  351. /* if we can't get it, it's about to be destroyed */
  352. if (!zswap_pool_tryget(pool))
  353. continue;
  354. return pool;
  355. }
  356. return NULL;
  357. }
  358. static unsigned long zswap_max_pages(void)
  359. {
  360. return totalram_pages() * zswap_max_pool_percent / 100;
  361. }
  362. static unsigned long zswap_accept_thr_pages(void)
  363. {
  364. return zswap_max_pages() * zswap_accept_thr_percent / 100;
  365. }
  366. unsigned long zswap_total_pages(void)
  367. {
  368. struct zswap_pool *pool;
  369. unsigned long total = 0;
  370. rcu_read_lock();
  371. list_for_each_entry_rcu(pool, &zswap_pools, list)
  372. total += zs_get_total_pages(pool->zs_pool);
  373. rcu_read_unlock();
  374. return total;
  375. }
  376. static bool zswap_check_limits(void)
  377. {
  378. unsigned long cur_pages = zswap_total_pages();
  379. unsigned long max_pages = zswap_max_pages();
  380. if (cur_pages >= max_pages) {
  381. zswap_pool_limit_hit++;
  382. zswap_pool_reached_full = true;
  383. } else if (zswap_pool_reached_full &&
  384. cur_pages <= zswap_accept_thr_pages()) {
  385. zswap_pool_reached_full = false;
  386. }
  387. return zswap_pool_reached_full;
  388. }
  389. /*********************************
  390. * param callbacks
  391. **********************************/
  392. static int zswap_compressor_param_set(const char *val, const struct kernel_param *kp)
  393. {
  394. struct zswap_pool *pool, *put_pool = NULL;
  395. char *s = strstrip((char *)val);
  396. bool create_pool = false;
  397. int ret = 0;
  398. mutex_lock(&zswap_init_lock);
  399. switch (zswap_init_state) {
  400. case ZSWAP_UNINIT:
  401. /* Handled in zswap_setup() */
  402. ret = param_set_charp(s, kp);
  403. break;
  404. case ZSWAP_INIT_SUCCEED:
  405. if (!zswap_has_pool || strcmp(s, *(char **)kp->arg))
  406. create_pool = true;
  407. break;
  408. case ZSWAP_INIT_FAILED:
  409. pr_err("can't set param, initialization failed\n");
  410. ret = -ENODEV;
  411. }
  412. mutex_unlock(&zswap_init_lock);
  413. if (!create_pool)
  414. return ret;
  415. if (!crypto_has_acomp(s, 0, 0)) {
  416. pr_err("compressor %s not available\n", s);
  417. return -ENOENT;
  418. }
  419. spin_lock_bh(&zswap_pools_lock);
  420. pool = zswap_pool_find_get(s);
  421. if (pool) {
  422. zswap_pool_debug("using existing", pool);
  423. WARN_ON(pool == zswap_pool_current());
  424. list_del_rcu(&pool->list);
  425. }
  426. spin_unlock_bh(&zswap_pools_lock);
  427. if (!pool)
  428. pool = zswap_pool_create(s);
  429. else {
  430. /*
  431. * Restore the initial ref dropped by percpu_ref_kill()
  432. * when the pool was decommissioned and switch it again
  433. * to percpu mode.
  434. */
  435. percpu_ref_resurrect(&pool->ref);
  436. /* Drop the ref from zswap_pool_find_get(). */
  437. zswap_pool_put(pool);
  438. }
  439. if (pool)
  440. ret = param_set_charp(s, kp);
  441. else
  442. ret = -EINVAL;
  443. spin_lock_bh(&zswap_pools_lock);
  444. if (!ret) {
  445. put_pool = zswap_pool_current();
  446. list_add_rcu(&pool->list, &zswap_pools);
  447. zswap_has_pool = true;
  448. } else if (pool) {
  449. /*
  450. * Add the possibly pre-existing pool to the end of the pools
  451. * list; if it's new (and empty) then it'll be removed and
  452. * destroyed by the put after we drop the lock
  453. */
  454. list_add_tail_rcu(&pool->list, &zswap_pools);
  455. put_pool = pool;
  456. }
  457. spin_unlock_bh(&zswap_pools_lock);
  458. /*
  459. * Drop the ref from either the old current pool,
  460. * or the new pool we failed to add
  461. */
  462. if (put_pool)
  463. percpu_ref_kill(&put_pool->ref);
  464. return ret;
  465. }
  466. static int zswap_enabled_param_set(const char *val,
  467. const struct kernel_param *kp)
  468. {
  469. int ret = -ENODEV;
  470. /* if this is load-time (pre-init) param setting, only set param. */
  471. if (system_state != SYSTEM_RUNNING)
  472. return param_set_bool(val, kp);
  473. mutex_lock(&zswap_init_lock);
  474. switch (zswap_init_state) {
  475. case ZSWAP_UNINIT:
  476. if (zswap_setup())
  477. break;
  478. fallthrough;
  479. case ZSWAP_INIT_SUCCEED:
  480. if (!zswap_has_pool)
  481. pr_err("can't enable, no pool configured\n");
  482. else
  483. ret = param_set_bool(val, kp);
  484. break;
  485. case ZSWAP_INIT_FAILED:
  486. pr_err("can't enable, initialization failed\n");
  487. }
  488. mutex_unlock(&zswap_init_lock);
  489. return ret;
  490. }
  491. /*********************************
  492. * lru functions
  493. **********************************/
  494. /* should be called under RCU */
  495. #ifdef CONFIG_MEMCG
  496. static inline struct mem_cgroup *mem_cgroup_from_entry(struct zswap_entry *entry)
  497. {
  498. return entry->objcg ? obj_cgroup_memcg(entry->objcg) : NULL;
  499. }
  500. #else
  501. static inline struct mem_cgroup *mem_cgroup_from_entry(struct zswap_entry *entry)
  502. {
  503. return NULL;
  504. }
  505. #endif
  506. static inline int entry_to_nid(struct zswap_entry *entry)
  507. {
  508. return page_to_nid(virt_to_page(entry));
  509. }
  510. static void zswap_lru_add(struct list_lru *list_lru, struct zswap_entry *entry)
  511. {
  512. int nid = entry_to_nid(entry);
  513. struct mem_cgroup *memcg;
  514. /*
  515. * Note that it is safe to use rcu_read_lock() here, even in the face of
  516. * concurrent memcg offlining:
  517. *
  518. * 1. list_lru_add() is called before list_lru_one is dead. The
  519. * new entry will be reparented to memcg's parent's list_lru.
  520. * 2. list_lru_add() is called after list_lru_one is dead. The
  521. * new entry will be added directly to memcg's parent's list_lru.
  522. *
  523. * Similar reasoning holds for list_lru_del().
  524. */
  525. rcu_read_lock();
  526. memcg = mem_cgroup_from_entry(entry);
  527. /* will always succeed */
  528. list_lru_add(list_lru, &entry->lru, nid, memcg);
  529. rcu_read_unlock();
  530. }
  531. static void zswap_lru_del(struct list_lru *list_lru, struct zswap_entry *entry)
  532. {
  533. int nid = entry_to_nid(entry);
  534. struct mem_cgroup *memcg;
  535. rcu_read_lock();
  536. memcg = mem_cgroup_from_entry(entry);
  537. /* will always succeed */
  538. list_lru_del(list_lru, &entry->lru, nid, memcg);
  539. rcu_read_unlock();
  540. }
  541. void zswap_lruvec_state_init(struct lruvec *lruvec)
  542. {
  543. atomic_long_set(&lruvec->zswap_lruvec_state.nr_disk_swapins, 0);
  544. }
  545. void zswap_folio_swapin(struct folio *folio)
  546. {
  547. struct lruvec *lruvec;
  548. if (folio) {
  549. lruvec = folio_lruvec(folio);
  550. atomic_long_inc(&lruvec->zswap_lruvec_state.nr_disk_swapins);
  551. }
  552. }
  553. /*
  554. * This function should be called when a memcg is being offlined.
  555. *
  556. * Since the global shrinker shrink_worker() may hold a reference
  557. * of the memcg, we must check and release the reference in
  558. * zswap_next_shrink.
  559. *
  560. * shrink_worker() must handle the case where this function releases
  561. * the reference of memcg being shrunk.
  562. */
  563. void zswap_memcg_offline_cleanup(struct mem_cgroup *memcg)
  564. {
  565. /* lock out zswap shrinker walking memcg tree */
  566. spin_lock(&zswap_shrink_lock);
  567. if (zswap_next_shrink == memcg) {
  568. do {
  569. zswap_next_shrink = mem_cgroup_iter(NULL, zswap_next_shrink, NULL);
  570. } while (zswap_next_shrink && !mem_cgroup_online(zswap_next_shrink));
  571. }
  572. spin_unlock(&zswap_shrink_lock);
  573. }
  574. /*********************************
  575. * zswap entry functions
  576. **********************************/
  577. static struct kmem_cache *zswap_entry_cache;
  578. static struct zswap_entry *zswap_entry_cache_alloc(gfp_t gfp, int nid)
  579. {
  580. struct zswap_entry *entry;
  581. entry = kmem_cache_alloc_node(zswap_entry_cache, gfp, nid);
  582. if (!entry)
  583. return NULL;
  584. return entry;
  585. }
  586. static void zswap_entry_cache_free(struct zswap_entry *entry)
  587. {
  588. kmem_cache_free(zswap_entry_cache, entry);
  589. }
  590. /*
  591. * Carries out the common pattern of freeing an entry's zsmalloc allocation,
  592. * freeing the entry itself, and decrementing the number of stored pages.
  593. */
  594. static void zswap_entry_free(struct zswap_entry *entry)
  595. {
  596. zswap_lru_del(&zswap_list_lru, entry);
  597. zs_free(entry->pool->zs_pool, entry->handle);
  598. zswap_pool_put(entry->pool);
  599. if (entry->objcg) {
  600. obj_cgroup_uncharge_zswap(entry->objcg, entry->length);
  601. obj_cgroup_put(entry->objcg);
  602. }
  603. if (entry->length == PAGE_SIZE)
  604. atomic_long_dec(&zswap_stored_incompressible_pages);
  605. zswap_entry_cache_free(entry);
  606. atomic_long_dec(&zswap_stored_pages);
  607. }
  608. /*********************************
  609. * compressed storage functions
  610. **********************************/
  611. static int zswap_cpu_comp_prepare(unsigned int cpu, struct hlist_node *node)
  612. {
  613. struct zswap_pool *pool = hlist_entry(node, struct zswap_pool, node);
  614. struct crypto_acomp_ctx *acomp_ctx = per_cpu_ptr(pool->acomp_ctx, cpu);
  615. struct crypto_acomp *acomp = NULL;
  616. struct acomp_req *req = NULL;
  617. u8 *buffer = NULL;
  618. int ret;
  619. buffer = kmalloc_node(PAGE_SIZE, GFP_KERNEL, cpu_to_node(cpu));
  620. if (!buffer) {
  621. ret = -ENOMEM;
  622. goto fail;
  623. }
  624. acomp = crypto_alloc_acomp_node(pool->tfm_name, 0, 0, cpu_to_node(cpu));
  625. if (IS_ERR(acomp)) {
  626. pr_err("could not alloc crypto acomp %s : %pe\n",
  627. pool->tfm_name, acomp);
  628. ret = PTR_ERR(acomp);
  629. goto fail;
  630. }
  631. req = acomp_request_alloc(acomp);
  632. if (!req) {
  633. pr_err("could not alloc crypto acomp_request %s\n",
  634. pool->tfm_name);
  635. ret = -ENOMEM;
  636. goto fail;
  637. }
  638. /*
  639. * Only hold the mutex after completing allocations, otherwise we may
  640. * recurse into zswap through reclaim and attempt to hold the mutex
  641. * again resulting in a deadlock.
  642. */
  643. mutex_lock(&acomp_ctx->mutex);
  644. crypto_init_wait(&acomp_ctx->wait);
  645. /*
  646. * if the backend of acomp is async zip, crypto_req_done() will wakeup
  647. * crypto_wait_req(); if the backend of acomp is scomp, the callback
  648. * won't be called, crypto_wait_req() will return without blocking.
  649. */
  650. acomp_request_set_callback(req, CRYPTO_TFM_REQ_MAY_BACKLOG,
  651. crypto_req_done, &acomp_ctx->wait);
  652. acomp_ctx->buffer = buffer;
  653. acomp_ctx->acomp = acomp;
  654. acomp_ctx->req = req;
  655. mutex_unlock(&acomp_ctx->mutex);
  656. return 0;
  657. fail:
  658. if (!IS_ERR_OR_NULL(acomp))
  659. crypto_free_acomp(acomp);
  660. kfree(buffer);
  661. return ret;
  662. }
  663. static int zswap_cpu_comp_dead(unsigned int cpu, struct hlist_node *node)
  664. {
  665. struct zswap_pool *pool = hlist_entry(node, struct zswap_pool, node);
  666. struct crypto_acomp_ctx *acomp_ctx = per_cpu_ptr(pool->acomp_ctx, cpu);
  667. struct acomp_req *req;
  668. struct crypto_acomp *acomp;
  669. u8 *buffer;
  670. if (IS_ERR_OR_NULL(acomp_ctx))
  671. return 0;
  672. mutex_lock(&acomp_ctx->mutex);
  673. req = acomp_ctx->req;
  674. acomp = acomp_ctx->acomp;
  675. buffer = acomp_ctx->buffer;
  676. acomp_ctx->req = NULL;
  677. acomp_ctx->acomp = NULL;
  678. acomp_ctx->buffer = NULL;
  679. mutex_unlock(&acomp_ctx->mutex);
  680. /*
  681. * Do the actual freeing after releasing the mutex to avoid subtle
  682. * locking dependencies causing deadlocks.
  683. */
  684. if (!IS_ERR_OR_NULL(req))
  685. acomp_request_free(req);
  686. if (!IS_ERR_OR_NULL(acomp))
  687. crypto_free_acomp(acomp);
  688. kfree(buffer);
  689. return 0;
  690. }
  691. static struct crypto_acomp_ctx *acomp_ctx_get_cpu_lock(struct zswap_pool *pool)
  692. {
  693. struct crypto_acomp_ctx *acomp_ctx;
  694. for (;;) {
  695. acomp_ctx = raw_cpu_ptr(pool->acomp_ctx);
  696. mutex_lock(&acomp_ctx->mutex);
  697. if (likely(acomp_ctx->req))
  698. return acomp_ctx;
  699. /*
  700. * It is possible that we were migrated to a different CPU after
  701. * getting the per-CPU ctx but before the mutex was acquired. If
  702. * the old CPU got offlined, zswap_cpu_comp_dead() could have
  703. * already freed ctx->req (among other things) and set it to
  704. * NULL. Just try again on the new CPU that we ended up on.
  705. */
  706. mutex_unlock(&acomp_ctx->mutex);
  707. }
  708. }
  709. static void acomp_ctx_put_unlock(struct crypto_acomp_ctx *acomp_ctx)
  710. {
  711. mutex_unlock(&acomp_ctx->mutex);
  712. }
  713. static bool zswap_compress(struct page *page, struct zswap_entry *entry,
  714. struct zswap_pool *pool)
  715. {
  716. struct crypto_acomp_ctx *acomp_ctx;
  717. struct scatterlist input, output;
  718. int comp_ret = 0, alloc_ret = 0;
  719. unsigned int dlen = PAGE_SIZE;
  720. unsigned long handle;
  721. gfp_t gfp;
  722. u8 *dst;
  723. bool mapped = false;
  724. acomp_ctx = acomp_ctx_get_cpu_lock(pool);
  725. dst = acomp_ctx->buffer;
  726. sg_init_table(&input, 1);
  727. sg_set_page(&input, page, PAGE_SIZE, 0);
  728. sg_init_one(&output, dst, PAGE_SIZE);
  729. acomp_request_set_params(acomp_ctx->req, &input, &output, PAGE_SIZE, dlen);
  730. /*
  731. * it maybe looks a little bit silly that we send an asynchronous request,
  732. * then wait for its completion synchronously. This makes the process look
  733. * synchronous in fact.
  734. * Theoretically, acomp supports users send multiple acomp requests in one
  735. * acomp instance, then get those requests done simultaneously. but in this
  736. * case, zswap actually does store and load page by page, there is no
  737. * existing method to send the second page before the first page is done
  738. * in one thread doing zswap.
  739. * but in different threads running on different cpu, we have different
  740. * acomp instance, so multiple threads can do (de)compression in parallel.
  741. */
  742. comp_ret = crypto_wait_req(crypto_acomp_compress(acomp_ctx->req), &acomp_ctx->wait);
  743. dlen = acomp_ctx->req->dlen;
  744. /*
  745. * If a page cannot be compressed into a size smaller than PAGE_SIZE,
  746. * save the content as is without a compression, to keep the LRU order
  747. * of writebacks. If writeback is disabled, reject the page since it
  748. * only adds metadata overhead. swap_writeout() will put the page back
  749. * to the active LRU list in the case.
  750. */
  751. if (comp_ret || !dlen || dlen >= PAGE_SIZE) {
  752. if (!mem_cgroup_zswap_writeback_enabled(
  753. folio_memcg(page_folio(page)))) {
  754. comp_ret = comp_ret ? comp_ret : -EINVAL;
  755. goto unlock;
  756. }
  757. comp_ret = 0;
  758. dlen = PAGE_SIZE;
  759. dst = kmap_local_page(page);
  760. mapped = true;
  761. }
  762. gfp = GFP_NOWAIT | __GFP_NORETRY | __GFP_HIGHMEM | __GFP_MOVABLE;
  763. handle = zs_malloc(pool->zs_pool, dlen, gfp, page_to_nid(page));
  764. if (IS_ERR_VALUE(handle)) {
  765. alloc_ret = PTR_ERR((void *)handle);
  766. goto unlock;
  767. }
  768. zs_obj_write(pool->zs_pool, handle, dst, dlen);
  769. entry->handle = handle;
  770. entry->length = dlen;
  771. unlock:
  772. if (mapped)
  773. kunmap_local(dst);
  774. if (comp_ret == -ENOSPC || alloc_ret == -ENOSPC)
  775. zswap_reject_compress_poor++;
  776. else if (comp_ret)
  777. zswap_reject_compress_fail++;
  778. else if (alloc_ret)
  779. zswap_reject_alloc_fail++;
  780. acomp_ctx_put_unlock(acomp_ctx);
  781. return comp_ret == 0 && alloc_ret == 0;
  782. }
  783. static bool zswap_decompress(struct zswap_entry *entry, struct folio *folio)
  784. {
  785. struct zswap_pool *pool = entry->pool;
  786. struct scatterlist input[2]; /* zsmalloc returns an SG list 1-2 entries */
  787. struct scatterlist output;
  788. struct crypto_acomp_ctx *acomp_ctx;
  789. int ret = 0, dlen;
  790. acomp_ctx = acomp_ctx_get_cpu_lock(pool);
  791. zs_obj_read_sg_begin(pool->zs_pool, entry->handle, input, entry->length);
  792. /* zswap entries of length PAGE_SIZE are not compressed. */
  793. if (entry->length == PAGE_SIZE) {
  794. void *dst;
  795. WARN_ON_ONCE(input->length != PAGE_SIZE);
  796. dst = kmap_local_folio(folio, 0);
  797. memcpy_from_sglist(dst, input, 0, PAGE_SIZE);
  798. dlen = PAGE_SIZE;
  799. kunmap_local(dst);
  800. flush_dcache_folio(folio);
  801. } else {
  802. sg_init_table(&output, 1);
  803. sg_set_folio(&output, folio, PAGE_SIZE, 0);
  804. acomp_request_set_params(acomp_ctx->req, input, &output,
  805. entry->length, PAGE_SIZE);
  806. ret = crypto_acomp_decompress(acomp_ctx->req);
  807. ret = crypto_wait_req(ret, &acomp_ctx->wait);
  808. dlen = acomp_ctx->req->dlen;
  809. }
  810. zs_obj_read_sg_end(pool->zs_pool, entry->handle);
  811. acomp_ctx_put_unlock(acomp_ctx);
  812. if (!ret && dlen == PAGE_SIZE)
  813. return true;
  814. zswap_decompress_fail++;
  815. pr_alert_ratelimited("Decompression error from zswap (%d:%lu %s %u->%d)\n",
  816. swp_type(entry->swpentry),
  817. swp_offset(entry->swpentry),
  818. entry->pool->tfm_name,
  819. entry->length, dlen);
  820. return false;
  821. }
  822. /*********************************
  823. * writeback code
  824. **********************************/
  825. /*
  826. * Attempts to free an entry by adding a folio to the swap cache,
  827. * decompressing the entry data into the folio, and issuing a
  828. * bio write to write the folio back to the swap device.
  829. *
  830. * This can be thought of as a "resumed writeback" of the folio
  831. * to the swap device. We are basically resuming the same swap
  832. * writeback path that was intercepted with the zswap_store()
  833. * in the first place. After the folio has been decompressed into
  834. * the swap cache, the compressed version stored by zswap can be
  835. * freed.
  836. */
  837. static int zswap_writeback_entry(struct zswap_entry *entry,
  838. swp_entry_t swpentry)
  839. {
  840. struct xarray *tree;
  841. pgoff_t offset = swp_offset(swpentry);
  842. struct folio *folio;
  843. struct mempolicy *mpol;
  844. bool folio_was_allocated;
  845. struct swap_info_struct *si;
  846. int ret = 0;
  847. /* try to allocate swap cache folio */
  848. si = get_swap_device(swpentry);
  849. if (!si)
  850. return -EEXIST;
  851. mpol = get_task_policy(current);
  852. folio = swap_cache_alloc_folio(swpentry, GFP_KERNEL, mpol,
  853. NO_INTERLEAVE_INDEX, &folio_was_allocated);
  854. put_swap_device(si);
  855. if (!folio)
  856. return -ENOMEM;
  857. /*
  858. * Found an existing folio, we raced with swapin or concurrent
  859. * shrinker. We generally writeback cold folios from zswap, and
  860. * swapin means the folio just became hot, so skip this folio.
  861. * For unlikely concurrent shrinker case, it will be unlinked
  862. * and freed when invalidated by the concurrent shrinker anyway.
  863. */
  864. if (!folio_was_allocated) {
  865. ret = -EEXIST;
  866. goto out;
  867. }
  868. /*
  869. * folio is locked, and the swapcache is now secured against
  870. * concurrent swapping to and from the slot, and concurrent
  871. * swapoff so we can safely dereference the zswap tree here.
  872. * Verify that the swap entry hasn't been invalidated and recycled
  873. * behind our backs, to avoid overwriting a new swap folio with
  874. * old compressed data. Only when this is successful can the entry
  875. * be dereferenced.
  876. */
  877. tree = swap_zswap_tree(swpentry);
  878. if (entry != xa_load(tree, offset)) {
  879. ret = -ENOMEM;
  880. goto out;
  881. }
  882. if (!zswap_decompress(entry, folio)) {
  883. ret = -EIO;
  884. goto out;
  885. }
  886. xa_erase(tree, offset);
  887. count_vm_event(ZSWPWB);
  888. if (entry->objcg)
  889. count_objcg_events(entry->objcg, ZSWPWB, 1);
  890. zswap_entry_free(entry);
  891. /* folio is up to date */
  892. folio_mark_uptodate(folio);
  893. /* move it to the tail of the inactive list after end_writeback */
  894. folio_set_reclaim(folio);
  895. /* start writeback */
  896. __swap_writepage(folio, NULL);
  897. out:
  898. if (ret && ret != -EEXIST) {
  899. swap_cache_del_folio(folio);
  900. folio_unlock(folio);
  901. }
  902. folio_put(folio);
  903. return ret;
  904. }
  905. /*********************************
  906. * shrinker functions
  907. **********************************/
  908. /*
  909. * The dynamic shrinker is modulated by the following factors:
  910. *
  911. * 1. Each zswap entry has a referenced bit, which the shrinker unsets (giving
  912. * the entry a second chance) before rotating it in the LRU list. If the
  913. * entry is considered again by the shrinker, with its referenced bit unset,
  914. * it is written back. The writeback rate as a result is dynamically
  915. * adjusted by the pool activities - if the pool is dominated by new entries
  916. * (i.e lots of recent zswapouts), these entries will be protected and
  917. * the writeback rate will slow down. On the other hand, if the pool has a
  918. * lot of stagnant entries, these entries will be reclaimed immediately,
  919. * effectively increasing the writeback rate.
  920. *
  921. * 2. Swapins counter: If we observe swapins, it is a sign that we are
  922. * overshrinking and should slow down. We maintain a swapins counter, which
  923. * is consumed and subtract from the number of eligible objects on the LRU
  924. * in zswap_shrinker_count().
  925. *
  926. * 3. Compression ratio. The better the workload compresses, the less gains we
  927. * can expect from writeback. We scale down the number of objects available
  928. * for reclaim by this ratio.
  929. */
  930. static enum lru_status shrink_memcg_cb(struct list_head *item, struct list_lru_one *l,
  931. void *arg)
  932. {
  933. struct zswap_entry *entry = container_of(item, struct zswap_entry, lru);
  934. bool *encountered_page_in_swapcache = (bool *)arg;
  935. swp_entry_t swpentry;
  936. enum lru_status ret = LRU_REMOVED_RETRY;
  937. int writeback_result;
  938. /*
  939. * Second chance algorithm: if the entry has its referenced bit set, give it
  940. * a second chance. Only clear the referenced bit and rotate it in the
  941. * zswap's LRU list.
  942. */
  943. if (entry->referenced) {
  944. entry->referenced = false;
  945. return LRU_ROTATE;
  946. }
  947. /*
  948. * As soon as we drop the LRU lock, the entry can be freed by
  949. * a concurrent invalidation. This means the following:
  950. *
  951. * 1. We extract the swp_entry_t to the stack, allowing
  952. * zswap_writeback_entry() to pin the swap entry and
  953. * then validate the zswap entry against that swap entry's
  954. * tree using pointer value comparison. Only when that
  955. * is successful can the entry be dereferenced.
  956. *
  957. * 2. Usually, objects are taken off the LRU for reclaim. In
  958. * this case this isn't possible, because if reclaim fails
  959. * for whatever reason, we have no means of knowing if the
  960. * entry is alive to put it back on the LRU.
  961. *
  962. * So rotate it before dropping the lock. If the entry is
  963. * written back or invalidated, the free path will unlink
  964. * it. For failures, rotation is the right thing as well.
  965. *
  966. * Temporary failures, where the same entry should be tried
  967. * again immediately, almost never happen for this shrinker.
  968. * We don't do any trylocking; -ENOMEM comes closest,
  969. * but that's extremely rare and doesn't happen spuriously
  970. * either. Don't bother distinguishing this case.
  971. */
  972. list_move_tail(item, &l->list);
  973. /*
  974. * Once the lru lock is dropped, the entry might get freed. The
  975. * swpentry is copied to the stack, and entry isn't deref'd again
  976. * until the entry is verified to still be alive in the tree.
  977. */
  978. swpentry = entry->swpentry;
  979. /*
  980. * It's safe to drop the lock here because we return either
  981. * LRU_REMOVED_RETRY, LRU_RETRY or LRU_STOP.
  982. */
  983. spin_unlock(&l->lock);
  984. writeback_result = zswap_writeback_entry(entry, swpentry);
  985. if (writeback_result) {
  986. zswap_reject_reclaim_fail++;
  987. ret = LRU_RETRY;
  988. /*
  989. * Encountering a page already in swap cache is a sign that we are shrinking
  990. * into the warmer region. We should terminate shrinking (if we're in the dynamic
  991. * shrinker context).
  992. */
  993. if (writeback_result == -EEXIST && encountered_page_in_swapcache) {
  994. ret = LRU_STOP;
  995. *encountered_page_in_swapcache = true;
  996. }
  997. } else {
  998. zswap_written_back_pages++;
  999. }
  1000. return ret;
  1001. }
  1002. static unsigned long zswap_shrinker_scan(struct shrinker *shrinker,
  1003. struct shrink_control *sc)
  1004. {
  1005. unsigned long shrink_ret;
  1006. bool encountered_page_in_swapcache = false;
  1007. if (!zswap_shrinker_enabled ||
  1008. !mem_cgroup_zswap_writeback_enabled(sc->memcg)) {
  1009. sc->nr_scanned = 0;
  1010. return SHRINK_STOP;
  1011. }
  1012. shrink_ret = list_lru_shrink_walk(&zswap_list_lru, sc, &shrink_memcg_cb,
  1013. &encountered_page_in_swapcache);
  1014. if (encountered_page_in_swapcache)
  1015. return SHRINK_STOP;
  1016. return shrink_ret ? shrink_ret : SHRINK_STOP;
  1017. }
  1018. static unsigned long zswap_shrinker_count(struct shrinker *shrinker,
  1019. struct shrink_control *sc)
  1020. {
  1021. struct mem_cgroup *memcg = sc->memcg;
  1022. struct lruvec *lruvec = mem_cgroup_lruvec(memcg, NODE_DATA(sc->nid));
  1023. atomic_long_t *nr_disk_swapins =
  1024. &lruvec->zswap_lruvec_state.nr_disk_swapins;
  1025. unsigned long nr_backing, nr_stored, nr_freeable, nr_disk_swapins_cur,
  1026. nr_remain;
  1027. if (!zswap_shrinker_enabled || !mem_cgroup_zswap_writeback_enabled(memcg))
  1028. return 0;
  1029. /*
  1030. * The shrinker resumes swap writeback, which will enter block
  1031. * and may enter fs. XXX: Harmonize with vmscan.c __GFP_FS
  1032. * rules (may_enter_fs()), which apply on a per-folio basis.
  1033. */
  1034. if (!gfp_has_io_fs(sc->gfp_mask))
  1035. return 0;
  1036. /*
  1037. * For memcg, use the cgroup-wide ZSWAP stats since we don't
  1038. * have them per-node and thus per-lruvec. Careful if memcg is
  1039. * runtime-disabled: we can get sc->memcg == NULL, which is ok
  1040. * for the lruvec, but not for memcg_page_state().
  1041. *
  1042. * Without memcg, use the zswap pool-wide metrics.
  1043. */
  1044. if (!mem_cgroup_disabled()) {
  1045. mem_cgroup_flush_stats(memcg);
  1046. nr_backing = memcg_page_state(memcg, MEMCG_ZSWAP_B) >> PAGE_SHIFT;
  1047. nr_stored = memcg_page_state(memcg, MEMCG_ZSWAPPED);
  1048. } else {
  1049. nr_backing = zswap_total_pages();
  1050. nr_stored = atomic_long_read(&zswap_stored_pages);
  1051. }
  1052. if (!nr_stored)
  1053. return 0;
  1054. nr_freeable = list_lru_shrink_count(&zswap_list_lru, sc);
  1055. if (!nr_freeable)
  1056. return 0;
  1057. /*
  1058. * Subtract from the lru size the number of pages that are recently swapped
  1059. * in from disk. The idea is that had we protect the zswap's LRU by this
  1060. * amount of pages, these disk swapins would not have happened.
  1061. */
  1062. nr_disk_swapins_cur = atomic_long_read(nr_disk_swapins);
  1063. do {
  1064. if (nr_freeable >= nr_disk_swapins_cur)
  1065. nr_remain = 0;
  1066. else
  1067. nr_remain = nr_disk_swapins_cur - nr_freeable;
  1068. } while (!atomic_long_try_cmpxchg(
  1069. nr_disk_swapins, &nr_disk_swapins_cur, nr_remain));
  1070. nr_freeable -= nr_disk_swapins_cur - nr_remain;
  1071. if (!nr_freeable)
  1072. return 0;
  1073. /*
  1074. * Scale the number of freeable pages by the memory saving factor.
  1075. * This ensures that the better zswap compresses memory, the fewer
  1076. * pages we will evict to swap (as it will otherwise incur IO for
  1077. * relatively small memory saving).
  1078. */
  1079. return mult_frac(nr_freeable, nr_backing, nr_stored);
  1080. }
  1081. static struct shrinker *zswap_alloc_shrinker(void)
  1082. {
  1083. struct shrinker *shrinker;
  1084. shrinker =
  1085. shrinker_alloc(SHRINKER_NUMA_AWARE | SHRINKER_MEMCG_AWARE, "mm-zswap");
  1086. if (!shrinker)
  1087. return NULL;
  1088. shrinker->scan_objects = zswap_shrinker_scan;
  1089. shrinker->count_objects = zswap_shrinker_count;
  1090. shrinker->batch = 0;
  1091. shrinker->seeks = DEFAULT_SEEKS;
  1092. return shrinker;
  1093. }
  1094. static int shrink_memcg(struct mem_cgroup *memcg)
  1095. {
  1096. int nid, shrunk = 0, scanned = 0;
  1097. if (!mem_cgroup_zswap_writeback_enabled(memcg))
  1098. return -ENOENT;
  1099. /*
  1100. * Skip zombies because their LRUs are reparented and we would be
  1101. * reclaiming from the parent instead of the dead memcg.
  1102. */
  1103. if (memcg && !mem_cgroup_online(memcg))
  1104. return -ENOENT;
  1105. for_each_node_state(nid, N_NORMAL_MEMORY) {
  1106. unsigned long nr_to_walk = 1;
  1107. shrunk += list_lru_walk_one(&zswap_list_lru, nid, memcg,
  1108. &shrink_memcg_cb, NULL, &nr_to_walk);
  1109. scanned += 1 - nr_to_walk;
  1110. }
  1111. if (!scanned)
  1112. return -ENOENT;
  1113. return shrunk ? 0 : -EAGAIN;
  1114. }
  1115. static void shrink_worker(struct work_struct *w)
  1116. {
  1117. struct mem_cgroup *memcg;
  1118. int ret, failures = 0, attempts = 0;
  1119. unsigned long thr;
  1120. /* Reclaim down to the accept threshold */
  1121. thr = zswap_accept_thr_pages();
  1122. /*
  1123. * Global reclaim will select cgroup in a round-robin fashion from all
  1124. * online memcgs, but memcgs that have no pages in zswap and
  1125. * writeback-disabled memcgs (memory.zswap.writeback=0) are not
  1126. * candidates for shrinking.
  1127. *
  1128. * Shrinking will be aborted if we encounter the following
  1129. * MAX_RECLAIM_RETRIES times:
  1130. * - No writeback-candidate memcgs found in a memcg tree walk.
  1131. * - Shrinking a writeback-candidate memcg failed.
  1132. *
  1133. * We save iteration cursor memcg into zswap_next_shrink,
  1134. * which can be modified by the offline memcg cleaner
  1135. * zswap_memcg_offline_cleanup().
  1136. *
  1137. * Since the offline cleaner is called only once, we cannot leave an
  1138. * offline memcg reference in zswap_next_shrink.
  1139. * We can rely on the cleaner only if we get online memcg under lock.
  1140. *
  1141. * If we get an offline memcg, we cannot determine if the cleaner has
  1142. * already been called or will be called later. We must put back the
  1143. * reference before returning from this function. Otherwise, the
  1144. * offline memcg left in zswap_next_shrink will hold the reference
  1145. * until the next run of shrink_worker().
  1146. */
  1147. do {
  1148. /*
  1149. * Start shrinking from the next memcg after zswap_next_shrink.
  1150. * When the offline cleaner has already advanced the cursor,
  1151. * advancing the cursor here overlooks one memcg, but this
  1152. * should be negligibly rare.
  1153. *
  1154. * If we get an online memcg, keep the extra reference in case
  1155. * the original one obtained by mem_cgroup_iter() is dropped by
  1156. * zswap_memcg_offline_cleanup() while we are shrinking the
  1157. * memcg.
  1158. */
  1159. spin_lock(&zswap_shrink_lock);
  1160. do {
  1161. memcg = mem_cgroup_iter(NULL, zswap_next_shrink, NULL);
  1162. zswap_next_shrink = memcg;
  1163. } while (memcg && !mem_cgroup_tryget_online(memcg));
  1164. spin_unlock(&zswap_shrink_lock);
  1165. if (!memcg) {
  1166. /*
  1167. * Continue shrinking without incrementing failures if
  1168. * we found candidate memcgs in the last tree walk.
  1169. */
  1170. if (!attempts && ++failures == MAX_RECLAIM_RETRIES)
  1171. break;
  1172. attempts = 0;
  1173. goto resched;
  1174. }
  1175. ret = shrink_memcg(memcg);
  1176. /* drop the extra reference */
  1177. mem_cgroup_put(memcg);
  1178. /*
  1179. * There are no writeback-candidate pages in the memcg.
  1180. * This is not an issue as long as we can find another memcg
  1181. * with pages in zswap. Skip this without incrementing attempts
  1182. * and failures.
  1183. */
  1184. if (ret == -ENOENT)
  1185. continue;
  1186. ++attempts;
  1187. if (ret && ++failures == MAX_RECLAIM_RETRIES)
  1188. break;
  1189. resched:
  1190. cond_resched();
  1191. } while (zswap_total_pages() > thr);
  1192. }
  1193. /*********************************
  1194. * main API
  1195. **********************************/
  1196. static bool zswap_store_page(struct page *page,
  1197. struct obj_cgroup *objcg,
  1198. struct zswap_pool *pool)
  1199. {
  1200. swp_entry_t page_swpentry = page_swap_entry(page);
  1201. struct zswap_entry *entry, *old;
  1202. /* allocate entry */
  1203. entry = zswap_entry_cache_alloc(GFP_KERNEL, page_to_nid(page));
  1204. if (!entry) {
  1205. zswap_reject_kmemcache_fail++;
  1206. return false;
  1207. }
  1208. if (!zswap_compress(page, entry, pool))
  1209. goto compress_failed;
  1210. old = xa_store(swap_zswap_tree(page_swpentry),
  1211. swp_offset(page_swpentry),
  1212. entry, GFP_KERNEL);
  1213. if (xa_is_err(old)) {
  1214. int err = xa_err(old);
  1215. WARN_ONCE(err != -ENOMEM, "unexpected xarray error: %d\n", err);
  1216. zswap_reject_alloc_fail++;
  1217. goto store_failed;
  1218. }
  1219. /*
  1220. * We may have had an existing entry that became stale when
  1221. * the folio was redirtied and now the new version is being
  1222. * swapped out. Get rid of the old.
  1223. */
  1224. if (old)
  1225. zswap_entry_free(old);
  1226. /*
  1227. * The entry is successfully compressed and stored in the tree, there is
  1228. * no further possibility of failure. Grab refs to the pool and objcg,
  1229. * charge zswap memory, and increment zswap_stored_pages.
  1230. * The opposite actions will be performed by zswap_entry_free()
  1231. * when the entry is removed from the tree.
  1232. */
  1233. zswap_pool_get(pool);
  1234. if (objcg) {
  1235. obj_cgroup_get(objcg);
  1236. obj_cgroup_charge_zswap(objcg, entry->length);
  1237. }
  1238. atomic_long_inc(&zswap_stored_pages);
  1239. if (entry->length == PAGE_SIZE)
  1240. atomic_long_inc(&zswap_stored_incompressible_pages);
  1241. /*
  1242. * We finish initializing the entry while it's already in xarray.
  1243. * This is safe because:
  1244. *
  1245. * 1. Concurrent stores and invalidations are excluded by folio lock.
  1246. *
  1247. * 2. Writeback is excluded by the entry not being on the LRU yet.
  1248. * The publishing order matters to prevent writeback from seeing
  1249. * an incoherent entry.
  1250. */
  1251. entry->pool = pool;
  1252. entry->swpentry = page_swpentry;
  1253. entry->objcg = objcg;
  1254. entry->referenced = true;
  1255. if (entry->length) {
  1256. INIT_LIST_HEAD(&entry->lru);
  1257. zswap_lru_add(&zswap_list_lru, entry);
  1258. }
  1259. return true;
  1260. store_failed:
  1261. zs_free(pool->zs_pool, entry->handle);
  1262. compress_failed:
  1263. zswap_entry_cache_free(entry);
  1264. return false;
  1265. }
  1266. bool zswap_store(struct folio *folio)
  1267. {
  1268. long nr_pages = folio_nr_pages(folio);
  1269. swp_entry_t swp = folio->swap;
  1270. struct obj_cgroup *objcg = NULL;
  1271. struct mem_cgroup *memcg = NULL;
  1272. struct zswap_pool *pool;
  1273. bool ret = false;
  1274. long index;
  1275. VM_WARN_ON_ONCE(!folio_test_locked(folio));
  1276. VM_WARN_ON_ONCE(!folio_test_swapcache(folio));
  1277. if (!zswap_enabled)
  1278. goto check_old;
  1279. objcg = get_obj_cgroup_from_folio(folio);
  1280. if (objcg && !obj_cgroup_may_zswap(objcg)) {
  1281. memcg = get_mem_cgroup_from_objcg(objcg);
  1282. if (shrink_memcg(memcg)) {
  1283. mem_cgroup_put(memcg);
  1284. goto put_objcg;
  1285. }
  1286. mem_cgroup_put(memcg);
  1287. }
  1288. if (zswap_check_limits())
  1289. goto put_objcg;
  1290. pool = zswap_pool_current_get();
  1291. if (!pool)
  1292. goto put_objcg;
  1293. if (objcg) {
  1294. memcg = get_mem_cgroup_from_objcg(objcg);
  1295. if (memcg_list_lru_alloc(memcg, &zswap_list_lru, GFP_KERNEL)) {
  1296. mem_cgroup_put(memcg);
  1297. goto put_pool;
  1298. }
  1299. mem_cgroup_put(memcg);
  1300. }
  1301. for (index = 0; index < nr_pages; ++index) {
  1302. struct page *page = folio_page(folio, index);
  1303. if (!zswap_store_page(page, objcg, pool))
  1304. goto put_pool;
  1305. }
  1306. if (objcg)
  1307. count_objcg_events(objcg, ZSWPOUT, nr_pages);
  1308. count_vm_events(ZSWPOUT, nr_pages);
  1309. ret = true;
  1310. put_pool:
  1311. zswap_pool_put(pool);
  1312. put_objcg:
  1313. obj_cgroup_put(objcg);
  1314. if (!ret && zswap_pool_reached_full)
  1315. queue_work(shrink_wq, &zswap_shrink_work);
  1316. check_old:
  1317. /*
  1318. * If the zswap store fails or zswap is disabled, we must invalidate
  1319. * the possibly stale entries which were previously stored at the
  1320. * offsets corresponding to each page of the folio. Otherwise,
  1321. * writeback could overwrite the new data in the swapfile.
  1322. */
  1323. if (!ret) {
  1324. unsigned type = swp_type(swp);
  1325. pgoff_t offset = swp_offset(swp);
  1326. struct zswap_entry *entry;
  1327. struct xarray *tree;
  1328. for (index = 0; index < nr_pages; ++index) {
  1329. tree = swap_zswap_tree(swp_entry(type, offset + index));
  1330. entry = xa_erase(tree, offset + index);
  1331. if (entry)
  1332. zswap_entry_free(entry);
  1333. }
  1334. }
  1335. return ret;
  1336. }
  1337. /**
  1338. * zswap_load() - load a folio from zswap
  1339. * @folio: folio to load
  1340. *
  1341. * Return: 0 on success, with the folio unlocked and marked up-to-date, or one
  1342. * of the following error codes:
  1343. *
  1344. * -EIO: if the swapped out content was in zswap, but could not be loaded
  1345. * into the page due to a decompression failure. The folio is unlocked, but
  1346. * NOT marked up-to-date, so that an IO error is emitted (e.g. do_swap_page()
  1347. * will SIGBUS).
  1348. *
  1349. * -EINVAL: if the swapped out content was in zswap, but the page belongs
  1350. * to a large folio, which is not supported by zswap. The folio is unlocked,
  1351. * but NOT marked up-to-date, so that an IO error is emitted (e.g.
  1352. * do_swap_page() will SIGBUS).
  1353. *
  1354. * -ENOENT: if the swapped out content was not in zswap. The folio remains
  1355. * locked on return.
  1356. */
  1357. int zswap_load(struct folio *folio)
  1358. {
  1359. swp_entry_t swp = folio->swap;
  1360. pgoff_t offset = swp_offset(swp);
  1361. bool swapcache = folio_test_swapcache(folio);
  1362. struct xarray *tree = swap_zswap_tree(swp);
  1363. struct zswap_entry *entry;
  1364. VM_WARN_ON_ONCE(!folio_test_locked(folio));
  1365. if (zswap_never_enabled())
  1366. return -ENOENT;
  1367. /*
  1368. * Large folios should not be swapped in while zswap is being used, as
  1369. * they are not properly handled. Zswap does not properly load large
  1370. * folios, and a large folio may only be partially in zswap.
  1371. */
  1372. if (WARN_ON_ONCE(folio_test_large(folio))) {
  1373. folio_unlock(folio);
  1374. return -EINVAL;
  1375. }
  1376. entry = xa_load(tree, offset);
  1377. if (!entry)
  1378. return -ENOENT;
  1379. if (!zswap_decompress(entry, folio)) {
  1380. folio_unlock(folio);
  1381. return -EIO;
  1382. }
  1383. folio_mark_uptodate(folio);
  1384. count_vm_event(ZSWPIN);
  1385. if (entry->objcg)
  1386. count_objcg_events(entry->objcg, ZSWPIN, 1);
  1387. /*
  1388. * When reading into the swapcache, invalidate our entry. The
  1389. * swapcache can be the authoritative owner of the page and
  1390. * its mappings, and the pressure that results from having two
  1391. * in-memory copies outweighs any benefits of caching the
  1392. * compression work.
  1393. *
  1394. * (Most swapins go through the swapcache. The notable
  1395. * exception is the singleton fault on SWP_SYNCHRONOUS_IO
  1396. * files, which reads into a private page and may free it if
  1397. * the fault fails. We remain the primary owner of the entry.)
  1398. */
  1399. if (swapcache) {
  1400. folio_mark_dirty(folio);
  1401. xa_erase(tree, offset);
  1402. zswap_entry_free(entry);
  1403. }
  1404. folio_unlock(folio);
  1405. return 0;
  1406. }
  1407. void zswap_invalidate(swp_entry_t swp)
  1408. {
  1409. pgoff_t offset = swp_offset(swp);
  1410. struct xarray *tree = swap_zswap_tree(swp);
  1411. struct zswap_entry *entry;
  1412. if (xa_empty(tree))
  1413. return;
  1414. entry = xa_erase(tree, offset);
  1415. if (entry)
  1416. zswap_entry_free(entry);
  1417. }
  1418. int zswap_swapon(int type, unsigned long nr_pages)
  1419. {
  1420. struct xarray *trees, *tree;
  1421. unsigned int nr, i;
  1422. nr = DIV_ROUND_UP(nr_pages, ZSWAP_ADDRESS_SPACE_PAGES);
  1423. trees = kvzalloc_objs(*tree, nr);
  1424. if (!trees) {
  1425. pr_err("alloc failed, zswap disabled for swap type %d\n", type);
  1426. return -ENOMEM;
  1427. }
  1428. for (i = 0; i < nr; i++)
  1429. xa_init(trees + i);
  1430. nr_zswap_trees[type] = nr;
  1431. zswap_trees[type] = trees;
  1432. return 0;
  1433. }
  1434. void zswap_swapoff(int type)
  1435. {
  1436. struct xarray *trees = zswap_trees[type];
  1437. unsigned int i;
  1438. if (!trees)
  1439. return;
  1440. /* try_to_unuse() invalidated all the entries already */
  1441. for (i = 0; i < nr_zswap_trees[type]; i++)
  1442. WARN_ON_ONCE(!xa_empty(trees + i));
  1443. kvfree(trees);
  1444. nr_zswap_trees[type] = 0;
  1445. zswap_trees[type] = NULL;
  1446. }
  1447. /*********************************
  1448. * debugfs functions
  1449. **********************************/
  1450. #ifdef CONFIG_DEBUG_FS
  1451. #include <linux/debugfs.h>
  1452. static struct dentry *zswap_debugfs_root;
  1453. static int debugfs_get_total_size(void *data, u64 *val)
  1454. {
  1455. *val = zswap_total_pages() * PAGE_SIZE;
  1456. return 0;
  1457. }
  1458. DEFINE_DEBUGFS_ATTRIBUTE(total_size_fops, debugfs_get_total_size, NULL, "%llu\n");
  1459. static int debugfs_get_stored_pages(void *data, u64 *val)
  1460. {
  1461. *val = atomic_long_read(&zswap_stored_pages);
  1462. return 0;
  1463. }
  1464. DEFINE_DEBUGFS_ATTRIBUTE(stored_pages_fops, debugfs_get_stored_pages, NULL, "%llu\n");
  1465. static int debugfs_get_stored_incompressible_pages(void *data, u64 *val)
  1466. {
  1467. *val = atomic_long_read(&zswap_stored_incompressible_pages);
  1468. return 0;
  1469. }
  1470. DEFINE_DEBUGFS_ATTRIBUTE(stored_incompressible_pages_fops,
  1471. debugfs_get_stored_incompressible_pages, NULL, "%llu\n");
  1472. static int zswap_debugfs_init(void)
  1473. {
  1474. if (!debugfs_initialized())
  1475. return -ENODEV;
  1476. zswap_debugfs_root = debugfs_create_dir("zswap", NULL);
  1477. debugfs_create_u64("pool_limit_hit", 0444,
  1478. zswap_debugfs_root, &zswap_pool_limit_hit);
  1479. debugfs_create_u64("reject_reclaim_fail", 0444,
  1480. zswap_debugfs_root, &zswap_reject_reclaim_fail);
  1481. debugfs_create_u64("reject_alloc_fail", 0444,
  1482. zswap_debugfs_root, &zswap_reject_alloc_fail);
  1483. debugfs_create_u64("reject_kmemcache_fail", 0444,
  1484. zswap_debugfs_root, &zswap_reject_kmemcache_fail);
  1485. debugfs_create_u64("reject_compress_fail", 0444,
  1486. zswap_debugfs_root, &zswap_reject_compress_fail);
  1487. debugfs_create_u64("reject_compress_poor", 0444,
  1488. zswap_debugfs_root, &zswap_reject_compress_poor);
  1489. debugfs_create_u64("decompress_fail", 0444,
  1490. zswap_debugfs_root, &zswap_decompress_fail);
  1491. debugfs_create_u64("written_back_pages", 0444,
  1492. zswap_debugfs_root, &zswap_written_back_pages);
  1493. debugfs_create_file("pool_total_size", 0444,
  1494. zswap_debugfs_root, NULL, &total_size_fops);
  1495. debugfs_create_file("stored_pages", 0444,
  1496. zswap_debugfs_root, NULL, &stored_pages_fops);
  1497. debugfs_create_file("stored_incompressible_pages", 0444,
  1498. zswap_debugfs_root, NULL,
  1499. &stored_incompressible_pages_fops);
  1500. return 0;
  1501. }
  1502. #else
  1503. static int zswap_debugfs_init(void)
  1504. {
  1505. return 0;
  1506. }
  1507. #endif
  1508. /*********************************
  1509. * module init and exit
  1510. **********************************/
  1511. static int zswap_setup(void)
  1512. {
  1513. struct zswap_pool *pool;
  1514. int ret;
  1515. zswap_entry_cache = KMEM_CACHE(zswap_entry, 0);
  1516. if (!zswap_entry_cache) {
  1517. pr_err("entry cache creation failed\n");
  1518. goto cache_fail;
  1519. }
  1520. ret = cpuhp_setup_state_multi(CPUHP_MM_ZSWP_POOL_PREPARE,
  1521. "mm/zswap_pool:prepare",
  1522. zswap_cpu_comp_prepare,
  1523. zswap_cpu_comp_dead);
  1524. if (ret)
  1525. goto hp_fail;
  1526. shrink_wq = alloc_workqueue("zswap-shrink",
  1527. WQ_UNBOUND|WQ_MEM_RECLAIM, 1);
  1528. if (!shrink_wq)
  1529. goto shrink_wq_fail;
  1530. zswap_shrinker = zswap_alloc_shrinker();
  1531. if (!zswap_shrinker)
  1532. goto shrinker_fail;
  1533. if (list_lru_init_memcg(&zswap_list_lru, zswap_shrinker))
  1534. goto lru_fail;
  1535. shrinker_register(zswap_shrinker);
  1536. INIT_WORK(&zswap_shrink_work, shrink_worker);
  1537. pool = __zswap_pool_create_fallback();
  1538. if (pool) {
  1539. pr_info("loaded using pool %s\n", pool->tfm_name);
  1540. list_add(&pool->list, &zswap_pools);
  1541. zswap_has_pool = true;
  1542. static_branch_enable(&zswap_ever_enabled);
  1543. } else {
  1544. pr_err("pool creation failed\n");
  1545. zswap_enabled = false;
  1546. }
  1547. if (zswap_debugfs_init())
  1548. pr_warn("debugfs initialization failed\n");
  1549. zswap_init_state = ZSWAP_INIT_SUCCEED;
  1550. return 0;
  1551. lru_fail:
  1552. shrinker_free(zswap_shrinker);
  1553. shrinker_fail:
  1554. destroy_workqueue(shrink_wq);
  1555. shrink_wq_fail:
  1556. cpuhp_remove_multi_state(CPUHP_MM_ZSWP_POOL_PREPARE);
  1557. hp_fail:
  1558. kmem_cache_destroy(zswap_entry_cache);
  1559. cache_fail:
  1560. /* if built-in, we aren't unloaded on failure; don't allow use */
  1561. zswap_init_state = ZSWAP_INIT_FAILED;
  1562. zswap_enabled = false;
  1563. return -ENOMEM;
  1564. }
  1565. static int __init zswap_init(void)
  1566. {
  1567. if (!zswap_enabled)
  1568. return 0;
  1569. return zswap_setup();
  1570. }
  1571. /* must be late so crypto has time to come up */
  1572. late_initcall(zswap_init);
  1573. MODULE_AUTHOR("Seth Jennings <sjennings@variantweb.net>");
  1574. MODULE_DESCRIPTION("Compressed cache for swap pages");