#define _GNU_SOURCE #include #include #include #include #include #include #include #include #include #include #include #include #include #include "bcache.h" #include "dm-logging.h" #include "log.h" #define SECTOR_SHIFT 9L //---------------------------------------------------------------- // Assumes the list is not empty. static inline struct dm_list *_list_pop(struct dm_list *head) { struct dm_list *l; l = head->n; dm_list_del(l); return l; } //---------------------------------------------------------------- struct control_block { struct dm_list list; void *context; struct iocb cb; }; struct cb_set { struct dm_list free; struct dm_list allocated; struct control_block *vec; } control_block_set; static struct cb_set *_cb_set_create(unsigned nr) { int i; struct cb_set *cbs = malloc(sizeof(*cbs)); if (!cbs) return NULL; cbs->vec = malloc(nr * sizeof(*cbs->vec)); if (!cbs->vec) { free(cbs); return NULL; } dm_list_init(&cbs->free); dm_list_init(&cbs->allocated); for (i = 0; i < nr; i++) dm_list_add(&cbs->free, &cbs->vec[i].list); return cbs; } static bool _cb_set_destroy(struct cb_set *cbs) { if (!dm_list_empty(&cbs->allocated)) { // FIXME: I think we should propogate this up. log_error("async io still in flight"); return false; } free(cbs->vec); free(cbs); return 0; } static struct control_block *_cb_alloc(struct cb_set *cbs, void *context) { struct control_block *cb; if (dm_list_empty(&cbs->free)) return NULL; cb = dm_list_item(_list_pop(&cbs->free), struct control_block); cb->context = context; dm_list_add(&cbs->allocated, &cb->list); return cb; } static void _cb_free(struct cb_set *cbs, struct control_block *cb) { dm_list_del(&cb->list); dm_list_add_h(&cbs->free, &cb->list); } static struct control_block *_iocb_to_cb(struct iocb *icb) { return dm_list_struct_base(icb, struct control_block, cb); } //---------------------------------------------------------------- // FIXME: write a sync engine too enum dir { DIR_READ, DIR_WRITE }; struct io_engine { io_context_t aio_context; struct cb_set *cbs; }; static struct io_engine *_engine_create(unsigned max_io) { int r; struct io_engine *e = malloc(sizeof(*e)); if (!e) return NULL; e->aio_context = 0; r = io_setup(max_io, &e->aio_context); if (r < 0) { log_warn("io_setup failed"); return NULL; } e->cbs = _cb_set_create(max_io); if (!e->cbs) { log_warn("couldn't create control block set"); free(e); return NULL; } return e; } static void _engine_destroy(struct io_engine *e) { _cb_set_destroy(e->cbs); io_destroy(e->aio_context); free(e); } static bool _engine_issue(struct io_engine *e, int fd, enum dir d, sector_t sb, sector_t se, void *data, void *context) { int r; struct iocb *cb_array[1]; struct control_block *cb; if (((uint64_t) data) & (PAGE_SIZE - 1)) { log_err("misaligned data buffer"); return false; } cb = _cb_alloc(e->cbs, context); if (!cb) { log_err("couldn't allocate control block"); return false; } memset(&cb->cb, 0, sizeof(cb->cb)); cb->cb.aio_fildes = (int) fd; cb->cb.u.c.buf = data; cb->cb.u.c.offset = sb << SECTOR_SHIFT; cb->cb.u.c.nbytes = (se - sb) << SECTOR_SHIFT; cb->cb.aio_lio_opcode = (d == DIR_READ) ? IO_CMD_PREAD : IO_CMD_PWRITE; cb_array[0] = &cb->cb; r = io_submit(e->aio_context, 1, cb_array); if (r < 0) { log_sys_error("io_submit", ""); _cb_free(e->cbs, cb); return false; } return true; } #define MAX_IO 64 typedef void complete_fn(void *context, int io_error); static bool _engine_wait(struct io_engine *e, complete_fn fn) { int i, r; struct io_event event[MAX_IO]; struct control_block *cb; memset(&event, 0, sizeof(event)); r = io_getevents(e->aio_context, 1, MAX_IO, event, NULL); if (r < 0) { log_sys_error("io_getevents", ""); return false; } for (i = 0; i < r; i++) { struct io_event *ev = event + i; cb = _iocb_to_cb((struct iocb *) ev->obj); if (ev->res == cb->cb.u.c.nbytes) fn((void *) cb->context, 0); else if ((int) ev->res < 0) fn(cb->context, (int) ev->res); else { log_err("short io"); fn(cb->context, -ENODATA); } _cb_free(e->cbs, cb); } return true; } //---------------------------------------------------------------- #define MIN_BLOCKS 16 #define WRITEBACK_LOW_THRESHOLD_PERCENT 33 #define WRITEBACK_HIGH_THRESHOLD_PERCENT 66 //---------------------------------------------------------------- static void *_alloc_aligned(size_t len, size_t alignment) { void *result = NULL; int r = posix_memalign(&result, alignment, len); if (r) return NULL; return result; } //---------------------------------------------------------------- static bool _test_flags(struct block *b, unsigned bits) { return (b->flags & bits) != 0; } static void _set_flags(struct block *b, unsigned bits) { b->flags |= bits; } static void _clear_flags(struct block *b, unsigned bits) { b->flags &= ~bits; } //---------------------------------------------------------------- enum block_flags { BF_IO_PENDING = (1 << 0), BF_DIRTY = (1 << 1), }; struct bcache { int fd; sector_t block_sectors; uint64_t nr_data_blocks; uint64_t nr_cache_blocks; struct io_engine *engine; void *raw_data; struct block *raw_blocks; /* * Lists that categorise the blocks. */ unsigned nr_locked; unsigned nr_dirty; unsigned nr_io_pending; struct dm_list free; struct dm_list errored; struct dm_list dirty; struct dm_list clean; struct dm_list io_pending; /* * Hash table. */ unsigned nr_buckets; unsigned hash_mask; struct dm_list *buckets; /* * Statistics */ unsigned read_hits; unsigned read_misses; unsigned write_zeroes; unsigned write_hits; unsigned write_misses; unsigned prefetches; }; //---------------------------------------------------------------- /* 2^63 + 2^61 - 2^57 + 2^54 - 2^51 - 2^18 + 1 */ #define GOLDEN_RATIO_PRIME_64 0x9e37fffffffc0001UL static unsigned _hash(struct bcache *cache, int fd, uint64_t index) { uint64_t h = (index << 10) & fd; h *= GOLDEN_RATIO_PRIME_64; return h & cache->hash_mask; } static struct block *_hash_lookup(struct bcache *cache, int fd, uint64_t index) { struct block *b; unsigned h = _hash(cache, fd, index); dm_list_iterate_items_gen (b, cache->buckets + h, hash) if (b->index == index) return b; return NULL; } static void _hash_insert(struct block *b) { unsigned h = _hash(b->cache, b->fd, b->index); dm_list_add_h(b->cache->buckets + h, &b->hash); } static void _hash_remove(struct block *b) { dm_list_del(&b->hash); } /* * Must return a power of 2. */ static unsigned _calc_nr_buckets(unsigned nr_blocks) { unsigned r = 8; unsigned n = nr_blocks / 4; if (n < 8) n = 8; while (r < n) r <<= 1; return r; } static int _hash_table_init(struct bcache *cache, unsigned nr_entries) { unsigned i; cache->nr_buckets = _calc_nr_buckets(nr_entries); cache->hash_mask = cache->nr_buckets - 1; cache->buckets = malloc(cache->nr_buckets * sizeof(*cache->buckets)); if (!cache->buckets) return -ENOMEM; for (i = 0; i < cache->nr_buckets; i++) dm_list_init(cache->buckets + i); return 0; } static void _hash_table_exit(struct bcache *cache) { free(cache->buckets); } //---------------------------------------------------------------- static int _init_free_list(struct bcache *cache, unsigned count) { unsigned i; size_t block_size = cache->block_sectors << SECTOR_SHIFT; unsigned char *data = (unsigned char *) _alloc_aligned(count * block_size, PAGE_SIZE); /* Allocate the data for each block. We page align the data. */ if (!data) return -ENOMEM; cache->raw_data = data; cache->raw_blocks = malloc(count * sizeof(*cache->raw_blocks)); if (!cache->raw_blocks) free(cache->raw_data); for (i = 0; i < count; i++) { struct block *b = cache->raw_blocks + i; b->cache = cache; b->data = data + (block_size * i); dm_list_add(&cache->free, &b->list); } return 0; } static void _exit_free_list(struct bcache *cache) { free(cache->raw_data); free(cache->raw_blocks); } static struct block *_alloc_block(struct bcache *cache) { struct block *b = dm_list_struct_base(_list_pop(&cache->free), struct block, list); return b; } /*---------------------------------------------------------------- * Clean/dirty list management. * Always use these methods to ensure nr_dirty_ is correct. *--------------------------------------------------------------*/ static void _unlink_block(struct block *b) { if (_test_flags(b, BF_DIRTY)) b->cache->nr_dirty--; dm_list_del(&b->list); } static void _link_block(struct block *b) { struct bcache *cache = b->cache; if (_test_flags(b, BF_DIRTY)) { dm_list_add(&cache->dirty, &b->list); cache->nr_dirty++; } else dm_list_add(&cache->clean, &b->list); } static void _relink(struct block *b) { _unlink_block(b); _link_block(b); } /*---------------------------------------------------------------- * Low level IO handling * * We cannot have two concurrent writes on the same block. * eg, background writeback, put with dirty, flush? * * To avoid this we introduce some restrictions: * * i) A held block can never be written back. * ii) You cannot get a block until writeback has completed. * *--------------------------------------------------------------*/ /* * |b->list| should be valid (either pointing to itself, on one of the other * lists. */ static bool _issue_low_level(struct block *b, enum dir d) { struct bcache *cache = b->cache; sector_t sb = b->index * cache->block_sectors; sector_t se = sb + cache->block_sectors; if (_test_flags(b, BF_IO_PENDING)) return false; _set_flags(b, BF_IO_PENDING); return _engine_issue(cache->engine, cache->fd, d, sb, se, b->data, b); } static inline bool _issue_read(struct block *b) { return _issue_low_level(b, DIR_READ); } static inline bool _issue_write(struct block *b) { return _issue_low_level(b, DIR_WRITE); } static void _complete_io(void *context, int err) { struct block *b = context; struct bcache *cache = b->cache; b->error = err; _clear_flags(b, BF_IO_PENDING); cache->nr_io_pending--; /* * b is on the io_pending list, so we don't want to use unlink_block. * Which would incorrectly adjust nr_dirty. */ dm_list_del(&b->list); if (b->error) dm_list_add(&cache->errored, &b->list); else { _clear_flags(b, BF_DIRTY); _link_block(b); } } static int _wait_io(struct bcache *cache) { return _engine_wait(cache->engine, _complete_io); } /*---------------------------------------------------------------- * High level IO handling *--------------------------------------------------------------*/ static void _wait_all(struct bcache *cache) { while (!dm_list_empty(&cache->io_pending)) _wait_io(cache); } static void _wait_specific(struct block *b) { while (_test_flags(b, BF_IO_PENDING)) _wait_io(b->cache); } static unsigned _writeback(struct bcache *cache, unsigned count) { unsigned actual = 0; struct block *b, *tmp; dm_list_iterate_items_gen_safe (b, tmp, &cache->dirty, list) { if (actual == count) break; // We can't writeback anything that's still in use. if (!b->ref_count) { _issue_write(b); actual++; } } return actual; } /*---------------------------------------------------------------- * High level allocation *--------------------------------------------------------------*/ static struct block *_find_unused_clean_block(struct bcache *cache) { struct block *b; dm_list_iterate_items (b, &cache->clean) { if (!b->ref_count) { _unlink_block(b); _hash_remove(b); return b; } } return NULL; } static struct block *_new_block(struct bcache *cache, block_address index) { struct block *b; b = _alloc_block(cache); while (!b && cache->nr_locked < cache->nr_cache_blocks) { b = _find_unused_clean_block(cache); if (!b) { if (dm_list_empty(&cache->io_pending)) _writeback(cache, 16); _wait_io(cache); } } if (b) { dm_list_init(&b->list); dm_list_init(&b->hash); b->flags = 0; b->index = index; b->ref_count = 0; b->error = 0; _hash_insert(b); } return b; } /*---------------------------------------------------------------- * Block reference counting *--------------------------------------------------------------*/ static void _zero_block(struct block *b) { b->cache->write_zeroes++; memset(b->data, 0, b->cache->block_sectors << SECTOR_SHIFT); _set_flags(b, BF_DIRTY); } static void _hit(struct block *b, unsigned flags) { struct bcache *cache = b->cache; if (flags & (GF_ZERO | GF_DIRTY)) cache->write_hits++; else cache->read_hits++; _relink(b); } static void _miss(struct bcache *cache, unsigned flags) { if (flags & (GF_ZERO | GF_DIRTY)) cache->write_misses++; else cache->read_misses++; } static struct block *_lookup_or_read_block(struct bcache *cache, int fd, block_address index, unsigned flags) { struct block *b = _hash_lookup(cache, fd, index); if (b) { // FIXME: this is insufficient. We need to also catch a read // lock of a write locked block. Ref count needs to distinguish. if (b->ref_count && (flags & (GF_DIRTY | GF_ZERO))) { log_err("concurrent write lock attempted"); return NULL; } if (_test_flags(b, BF_IO_PENDING)) { _miss(cache, flags); _wait_specific(b); } else _hit(b, flags); _unlink_block(b); if (flags & GF_ZERO) _zero_block(b); } else { _miss(cache, flags); b = _new_block(cache, index); if (b) { if (flags & GF_ZERO) _zero_block(b); else { _issue_read(b); _wait_specific(b); // we know the block is clean and unerrored. _unlink_block(b); } } } if (b && !b->error) { if (flags & (GF_DIRTY | GF_ZERO)) _set_flags(b, BF_DIRTY); _link_block(b); return b; } return NULL; } static void _preemptive_writeback(struct bcache *cache) { // FIXME: this ignores those blocks that are in the error state. Track // nr_clean instead? unsigned nr_available = cache->nr_cache_blocks - (cache->nr_dirty - cache->nr_io_pending); if (nr_available < (WRITEBACK_LOW_THRESHOLD_PERCENT * cache->nr_cache_blocks / 100)) _writeback(cache, (WRITEBACK_HIGH_THRESHOLD_PERCENT * cache->nr_cache_blocks / 100) - nr_available); } /*---------------------------------------------------------------- * Public interface *--------------------------------------------------------------*/ struct bcache *bcache_create(sector_t block_sectors, unsigned nr_cache_blocks) { int r; struct bcache *cache; cache = malloc(sizeof(*cache)); if (!cache) return NULL; cache->block_sectors = block_sectors; cache->nr_cache_blocks = nr_cache_blocks; cache->engine = _engine_create(nr_cache_blocks < 1024u ? nr_cache_blocks : 1024u); if (!cache->engine) { free(cache); return NULL; } cache->nr_locked = 0; cache->nr_dirty = 0; cache->nr_io_pending = 0; dm_list_init(&cache->free); dm_list_init(&cache->errored); dm_list_init(&cache->dirty); dm_list_init(&cache->clean); dm_list_init(&cache->io_pending); if (_hash_table_init(cache, nr_cache_blocks)) { _engine_destroy(cache->engine); free(cache); } cache->read_hits = 0; cache->read_misses = 0; cache->write_zeroes = 0; cache->write_hits = 0; cache->write_misses = 0; cache->prefetches = 0; r = _init_free_list(cache, nr_cache_blocks); if (r) { _engine_destroy(cache->engine); _hash_table_exit(cache); free(cache); } return cache; } void bcache_destroy(struct bcache *cache) { if (cache->nr_locked) log_warn("some blocks are still locked\n"); bcache_flush(cache); _wait_all(cache); _exit_free_list(cache); _hash_table_exit(cache); _engine_destroy(cache->engine); free(cache); } void bcache_prefetch(struct bcache *cache, int fd, block_address index) { struct block *b = _hash_lookup(cache, fd, index); if (!b) { cache->prefetches++; b = _new_block(cache, index); if (b) _issue_read(b); } } bool bcache_get(struct bcache *cache, int fd, block_address index, unsigned flags, struct block **result) { struct block *b = _lookup_or_read_block(cache, fd, index, flags); if (b) { if (!b->ref_count) cache->nr_locked++; b->ref_count++; *result = b; return true; } *result = NULL; log_err("couldn't get block"); return false; } void bcache_put(struct block *b) { if (!b->ref_count) { log_err("ref count on bcache block already zero"); return; } b->ref_count--; if (!b->ref_count) b->cache->nr_locked--; if (_test_flags(b, BF_DIRTY)) _preemptive_writeback(b->cache); } int bcache_flush(struct bcache *cache) { while (!dm_list_empty(&cache->dirty)) { struct block *b = dm_list_item(_list_pop(&cache->dirty), struct block); if (b->ref_count || _test_flags(b, BF_IO_PENDING)) // The superblock may well be still locked. continue; _issue_write(b); } _wait_all(cache); return dm_list_empty(&cache->errored) ? 0 : -EIO; } //----------------------------------------------------------------