// SPDX-License-Identifier: GPL-2.0 /* Maximum size of each resync request */ #define RESYNC_BLOCK_SIZE (64*1024) #define RESYNC_PAGES ((RESYNC_BLOCK_SIZE + PAGE_SIZE-1) / PAGE_SIZE) /* * Number of guaranteed raid bios in case of extreme VM load: */ #define NR_RAID_BIOS 256 /* when we get a read error on a read-only array, we redirect to another * device without failing the first device, or trying to over-write to * correct the read error. To keep track of bad blocks on a per-bio * level, we store IO_BLOCKED in the appropriate 'bios' pointer */ #define IO_BLOCKED ((struct bio *)1) /* When we successfully write to a known bad-block, we need to remove the * bad-block marking which must be done from process context. So we record * the success by setting devs[n].bio to IO_MADE_GOOD */ #define IO_MADE_GOOD ((struct bio *)2) #define BIO_SPECIAL(bio) ((unsigned long)bio <= 2) #define MAX_PLUG_BIO 32 /* for managing resync I/O pages */ struct resync_pages { void *raid_bio; struct page *pages[RESYNC_PAGES]; }; struct raid1_plug_cb { struct blk_plug_cb cb; struct bio_list pending; unsigned int count; }; static void rbio_pool_free(void *rbio, void *data) { kfree(rbio); } static inline int resync_alloc_pages(struct resync_pages *rp, gfp_t gfp_flags) { int i; for (i = 0; i < RESYNC_PAGES; i++) { rp->pages[i] = alloc_page(gfp_flags); if (!rp->pages[i]) goto out_free; } return 0; out_free: while (--i >= 0) put_page(rp->pages[i]); return -ENOMEM; } static inline void resync_free_pages(struct resync_pages *rp) { int i; for (i = 0; i < RESYNC_PAGES; i++) put_page(rp->pages[i]); } static inline void resync_get_all_pages(struct resync_pages *rp) { int i; for (i = 0; i < RESYNC_PAGES; i++) get_page(rp->pages[i]); } static inline struct page *resync_fetch_page(struct resync_pages *rp, unsigned idx) { if (WARN_ON_ONCE(idx >= RESYNC_PAGES)) return NULL; return rp->pages[idx]; } /* * 'strct resync_pages' stores actual pages used for doing the resync * IO, and it is per-bio, so make .bi_private points to it. */ static inline struct resync_pages *get_resync_pages(struct bio *bio) { return bio->bi_private; } /* generally called after bio_reset() for reseting bvec */ static void md_bio_reset_resync_pages(struct bio *bio, struct resync_pages *rp, int size) { int idx = 0; /* initialize bvec table again */ do { struct page *page = resync_fetch_page(rp, idx); int len = min_t(int, size, PAGE_SIZE); if (WARN_ON(!bio_add_page(bio, page, len, 0))) { bio->bi_status = BLK_STS_RESOURCE; bio_endio(bio); return; } size -= len; } while (idx++ < RESYNC_PAGES && size > 0); } static inline void raid1_submit_write(struct bio *bio) { struct md_rdev *rdev = (void *)bio->bi_bdev; bio->bi_next = NULL; bio_set_dev(bio, rdev->bdev); if (test_bit(Faulty, &rdev->flags)) bio_io_error(bio); else if (unlikely(bio_op(bio) == REQ_OP_DISCARD && !bdev_max_discard_sectors(bio->bi_bdev))) /* Just ignore it */ bio_endio(bio); else submit_bio_noacct(bio); } static inline bool raid1_add_bio_to_plug(struct mddev *mddev, struct bio *bio, blk_plug_cb_fn unplug, int copies) { struct raid1_plug_cb *plug = NULL; struct blk_plug_cb *cb; /* * If bitmap is not enabled, it's safe to submit the io directly, and * this can get optimal performance. */ if (!mddev->bitmap_ops->enabled(mddev)) { raid1_submit_write(bio); return true; } cb = blk_check_plugged(unplug, mddev, sizeof(*plug)); if (!cb) return false; plug = container_of(cb, struct raid1_plug_cb, cb); bio_list_add(&plug->pending, bio); if (++plug->count / MAX_PLUG_BIO >= copies) { list_del(&cb->list); cb->callback(cb, false); } return true; } /* * current->bio_list will be set under submit_bio() context, in this case bitmap * io will be added to the list and wait for current io submission to finish, * while current io submission must wait for bitmap io to be done. In order to * avoid such deadlock, submit bitmap io asynchronously. */ static inline void raid1_prepare_flush_writes(struct mddev *mddev) { mddev->bitmap_ops->unplug(mddev, current->bio_list == NULL); } /* * Used by fix_read_error() to decay the per rdev read_errors. * We halve the read error count for every hour that has elapsed * since the last recorded read error. */ static inline void check_decay_read_errors(struct mddev *mddev, struct md_rdev *rdev) { long cur_time_mon; unsigned long hours_since_last; unsigned int read_errors = atomic_read(&rdev->read_errors); cur_time_mon = ktime_get_seconds(); if (rdev->last_read_error == 0) { /* first time we've seen a read error */ rdev->last_read_error = cur_time_mon; return; } hours_since_last = (long)(cur_time_mon - rdev->last_read_error) / 3600; rdev->last_read_error = cur_time_mon; /* * if hours_since_last is > the number of bits in read_errors * just set read errors to 0. We do this to avoid * overflowing the shift of read_errors by hours_since_last. */ if (hours_since_last >= 8 * sizeof(read_errors)) atomic_set(&rdev->read_errors, 0); else atomic_set(&rdev->read_errors, read_errors >> hours_since_last); } static inline bool exceed_read_errors(struct mddev *mddev, struct md_rdev *rdev) { int max_read_errors = atomic_read(&mddev->max_corr_read_errors); int read_errors; check_decay_read_errors(mddev, rdev); read_errors = atomic_inc_return(&rdev->read_errors); if (read_errors > max_read_errors) { pr_notice("md/"RAID_1_10_NAME":%s: %pg: Raid device exceeded read_error threshold [cur %d:max %d]\n", mdname(mddev), rdev->bdev, read_errors, max_read_errors); pr_notice("md/"RAID_1_10_NAME":%s: %pg: Failing raid device\n", mdname(mddev), rdev->bdev); md_error(mddev, rdev); return true; } return false; } /** * raid1_check_read_range() - check a given read range for bad blocks, * available read length is returned; * @rdev: the rdev to read; * @this_sector: read position; * @len: read length; * * helper function for read_balance() * * 1) If there are no bad blocks in the range, @len is returned; * 2) If the range are all bad blocks, 0 is returned; * 3) If there are partial bad blocks: * - If the bad block range starts after @this_sector, the length of first * good region is returned; * - If the bad block range starts before @this_sector, 0 is returned and * the @len is updated to the offset into the region before we get to the * good blocks; */ static inline int raid1_check_read_range(struct md_rdev *rdev, sector_t this_sector, int *len) { sector_t first_bad; int bad_sectors; /* no bad block overlap */ if (!is_badblock(rdev, this_sector, *len, &first_bad, &bad_sectors)) return *len; /* * bad block range starts offset into our range so we can return the * number of sectors before the bad blocks start. */ if (first_bad > this_sector) return first_bad - this_sector; /* read range is fully consumed by bad blocks. */ if (this_sector + *len <= first_bad + bad_sectors) return 0; /* * final case, bad block range starts before or at the start of our * range but does not cover our entire range so we still return 0 but * update the length with the number of sectors before we get to the * good ones. */ *len = first_bad + bad_sectors - this_sector; return 0; } /* * Check if read should choose the first rdev. * * Balance on the whole device if no resync is going on (recovery is ok) or * below the resync window. Otherwise, take the first readable disk. */ static inline bool raid1_should_read_first(struct mddev *mddev, sector_t this_sector, int len) { if ((mddev->recovery_cp < this_sector + len)) return true; if (mddev_is_clustered(mddev) && md_cluster_ops->area_resyncing(mddev, READ, this_sector, this_sector + len)) return true; return false; }