/* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License (the "License"). * You may not use this file except in compliance with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or https://opensource.org/licenses/CDDL-1.0. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright (c) 2020, 2021, 2022 by Pawel Jakub Dawidek */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include /* * Block Cloning design. * * Block Cloning allows to manually clone a file (or a subset of its blocks) * into another (or the same) file by just creating additional references to * the data blocks without copying the data itself. Those references are kept * in the Block Reference Tables (BRTs). * * In many ways this is similar to the existing deduplication, but there are * some important differences: * * - Deduplication is automatic and Block Cloning is not - one has to use a * dedicated system call(s) to clone the given file/blocks. * - Deduplication keeps all data blocks in its table, even those referenced * just once. Block Cloning creates an entry in its tables only when there * are at least two references to the given data block. If the block was * never explicitly cloned or the second to last reference was dropped, * there will be neither space nor performance overhead. * - Deduplication needs data to work - one needs to pass real data to the * write(2) syscall, so hash can be calculated. Block Cloning doesn't require * data, just block pointers to the data, so it is extremely fast, as we pay * neither the cost of reading the data, nor the cost of writing the data - * we operate exclusively on metadata. * - If the D (dedup) bit is not set in the block pointer, it means that * the block is not in the dedup table (DDT) and we won't consult the DDT * when we need to free the block. Block Cloning must be consulted on every * free, because we cannot modify the source BP (eg. by setting something * similar to the D bit), thus we have no hint if the block is in the * Block Reference Table (BRT), so we need to look into the BRT. There is * an optimization in place that allows us to eliminate the majority of BRT * lookups which is described below in the "Minimizing free penalty" section. * - The BRT entry is much smaller than the DDT entry - for BRT we only store * 64bit offset and 64bit reference counter. * - Dedup keys are cryptographic hashes, so two blocks that are close to each * other on disk are most likely in totally different parts of the DDT. * The BRT entry keys are offsets into a single top-level VDEV, so data blocks * from one file should have BRT entries close to each other. * - Scrub will only do a single pass over a block that is referenced multiple * times in the DDT. Unfortunately it is not currently (if at all) possible * with Block Cloning and block referenced multiple times will be scrubbed * multiple times. The new, sorted scrub should be able to eliminate * duplicated reads given enough memory. * - Deduplication requires cryptographically strong hash as a checksum or * additional data verification. Block Cloning works with any checksum * algorithm or even with checksumming disabled. * * As mentioned above, the BRT entries are much smaller than the DDT entries. * To uniquely identify a block we just need its vdev id and offset. We also * need to maintain a reference counter. The vdev id will often repeat, as there * is a small number of top-level VDEVs and a large number of blocks stored in * each VDEV. We take advantage of that to reduce the BRT entry size further by * maintaining one BRT for each top-level VDEV, so we can then have only offset * and counter as the BRT entry. * * Minimizing free penalty. * * Block Cloning allows creating additional references to any existing block. * When we free a block there is no hint in the block pointer whether the block * was cloned or not, so on each free we have to check if there is a * corresponding entry in the BRT or not. If there is, we need to decrease * the reference counter. Doing BRT lookup on every free can potentially be * expensive by requiring additional I/Os if the BRT doesn't fit into memory. * This is the main problem with deduplication, so we've learned our lesson and * try not to repeat the same mistake here. How do we do that? We divide each * top-level VDEV into 16MB regions. For each region we maintain a counter that * is a sum of all the BRT entries that have offsets within the region. This * creates the entries count array of 16bit numbers for each top-level VDEV. * The entries count array is always kept in memory and updated on disk in the * same transaction group as the BRT updates to keep everything in-sync. We can * keep the array in memory, because it is very small. With 16MB regions and * 1TB VDEV the array requires only 128kB of memory (we may decide to decrease * the region size even further in the future). Now, when we want to free * a block, we first consult the array. If the counter for the whole region is * zero, there is no need to look for the BRT entry, as there isn't one for * sure. If the counter for the region is greater than zero, only then we will * do a BRT lookup and if an entry is found we will decrease the reference * counter in the BRT entry and in the entry counters array. * * The entry counters array is small, but can potentially be larger for very * large VDEVs or smaller regions. In this case we don't want to rewrite entire * array on every change. We then divide the array into 32kB block and keep * a bitmap of dirty blocks within a transaction group. When we sync the * transaction group we can only update the parts of the entry counters array * that were modified. Note: Keeping track of the dirty parts of the entry * counters array is implemented, but updating only parts of the array on disk * is not yet implemented - for now we will update entire array if there was * any change. * * The implementation tries to be economic: if BRT is not used, or no longer * used, there will be no entries in the MOS and no additional memory used (eg. * the entry counters array is only allocated if needed). * * Interaction between Deduplication and Block Cloning. * * If both functionalities are in use, we could end up with a block that is * referenced multiple times in both DDT and BRT. When we free one of the * references we couldn't tell where it belongs, so we would have to decide * what table takes the precedence: do we first clear DDT references or BRT * references? To avoid this dilemma BRT cooperates with DDT - if a given block * is being cloned using BRT and the BP has the D (dedup) bit set, BRT will * lookup DDT entry instead and increase the counter there. No BRT entry * will be created for a block which has the D (dedup) bit set. * BRT may be more efficient for manual deduplication, but if the block is * already in the DDT, then creating additional BRT entry would be less * efficient. This clever idea was proposed by Allan Jude. * * Block Cloning across datasets. * * Block Cloning is not limited to cloning blocks within the same dataset. * It is possible (and very useful) to clone blocks between different datasets. * One use case is recovering files from snapshots. By cloning the files into * dataset we need no additional storage. Without Block Cloning we would need * additional space for those files. * Another interesting use case is moving the files between datasets * (copying the file content to the new dataset and removing the source file). * In that case Block Cloning will only be used briefly, because the BRT entries * will be removed when the source is removed. * Block Cloning across encrypted datasets is supported as long as both * datasets share the same master key (e.g. snapshots and clones) * * Block Cloning flow through ZFS layers. * * Note: Block Cloning can be used both for cloning file system blocks and ZVOL * blocks. As of this writing no interface is implemented that allows for block * cloning within a ZVOL. * FreeBSD and Linux provides copy_file_range(2) system call and we will use it * for blocking cloning. * * ssize_t * copy_file_range(int infd, off_t *inoffp, int outfd, off_t *outoffp, * size_t len, unsigned int flags); * * Even though offsets and length represent bytes, they have to be * block-aligned or we will return an error so the upper layer can * fallback to the generic mechanism that will just copy the data. * Using copy_file_range(2) will call OS-independent zfs_clone_range() function. * This function was implemented based on zfs_write(), but instead of writing * the given data we first read block pointers using the new dmu_read_l0_bps() * function from the source file. Once we have BPs from the source file we call * the dmu_brt_clone() function on the destination file. This function * allocates BPs for us. We iterate over all source BPs. If the given BP is * a hole or an embedded block, we just copy BP as-is. If it points to a real * data we place this BP on a BRT pending list using the brt_pending_add() * function. * * We use this pending list to keep track of all BPs that got new references * within this transaction group. * * Some special cases to consider and how we address them: * - The block we want to clone may have been created within the same * transaction group that we are trying to clone. Such block has no BP * allocated yet, so cannot be immediately cloned. We return EAGAIN. * - The block we want to clone may have been modified within the same * transaction group. We return EAGAIN. * - A block may be cloned multiple times during one transaction group (that's * why pending list is actually a tree and not an append-only list - this * way we can figure out faster if this block is cloned for the first time * in this txg or consecutive time). * - A block may be cloned and freed within the same transaction group * (see dbuf_undirty()). * - A block may be cloned and within the same transaction group the clone * can be cloned again (see dmu_read_l0_bps()). * - A file might have been deleted, but the caller still has a file descriptor * open to this file and clones it. * * When we free a block we have an additional step in the ZIO pipeline where we * call the zio_brt_free() function. We then call the brt_entry_decref() * that loads the corresponding BRT entry (if one exists) and decreases * reference counter. If this is not the last reference we will stop ZIO * pipeline here. If this is the last reference or the block is not in the * BRT, we continue the pipeline and free the block as usual. * * At the beginning of spa_sync() where there can be no more block cloning, * but before issuing frees we call brt_pending_apply(). This function applies * all the new clones to the BRT table - we load BRT entries and update * reference counters. To sync new BRT entries to disk, we use brt_sync() * function. This function will sync all dirty per-top-level-vdev BRTs, * the entry counters arrays, etc. * * Block Cloning and ZIL. * * Every clone operation is divided into chunks (similar to write) and each * chunk is cloned in a separate transaction. The chunk size is determined by * how many BPs we can fit into a single ZIL entry. * Replaying clone operation is different from the regular clone operation, * as when we log clone operations we cannot use the source object - it may * reside on a different dataset, so we log BPs we want to clone. * The ZIL is replayed when we mount the given dataset, not when the pool is * imported. Taking this into account it is possible that the pool is imported * without mounting datasets and the source dataset is destroyed before the * destination dataset is mounted and its ZIL replayed. * To address this situation we leverage zil_claim() mechanism where ZFS will * parse all the ZILs on pool import. When we come across TX_CLONE_RANGE * entries, we will bump reference counters for their BPs in the BRT. Then * on mount and ZIL replay we bump the reference counters once more, while the * first references are dropped during ZIL destroy by zil_free_clone_range(). * It is possible that after zil_claim() we never mount the destination, so * we never replay its ZIL and just destroy it. In this case the only taken * references will be dropped by zil_free_clone_range(), since the cloning is * not going to ever take place. */ static kmem_cache_t *brt_entry_cache; /* * Enable/disable prefetching of BRT entries that we are going to modify. */ static int brt_zap_prefetch = 1; #ifdef ZFS_DEBUG #define BRT_DEBUG(...) do { \ if ((zfs_flags & ZFS_DEBUG_BRT) != 0) { \ __dprintf(B_TRUE, __FILE__, __func__, __LINE__, __VA_ARGS__); \ } \ } while (0) #else #define BRT_DEBUG(...) do { } while (0) #endif static int brt_zap_default_bs = 12; static int brt_zap_default_ibs = 12; static kstat_t *brt_ksp; typedef struct brt_stats { kstat_named_t brt_addref_entry_not_on_disk; kstat_named_t brt_addref_entry_on_disk; kstat_named_t brt_decref_entry_in_memory; kstat_named_t brt_decref_entry_loaded_from_disk; kstat_named_t brt_decref_entry_not_in_memory; kstat_named_t brt_decref_entry_read_lost_race; kstat_named_t brt_decref_entry_still_referenced; kstat_named_t brt_decref_free_data_later; kstat_named_t brt_decref_free_data_now; kstat_named_t brt_decref_no_entry; } brt_stats_t; static brt_stats_t brt_stats = { { "addref_entry_not_on_disk", KSTAT_DATA_UINT64 }, { "addref_entry_on_disk", KSTAT_DATA_UINT64 }, { "decref_entry_in_memory", KSTAT_DATA_UINT64 }, { "decref_entry_loaded_from_disk", KSTAT_DATA_UINT64 }, { "decref_entry_not_in_memory", KSTAT_DATA_UINT64 }, { "decref_entry_read_lost_race", KSTAT_DATA_UINT64 }, { "decref_entry_still_referenced", KSTAT_DATA_UINT64 }, { "decref_free_data_later", KSTAT_DATA_UINT64 }, { "decref_free_data_now", KSTAT_DATA_UINT64 }, { "decref_no_entry", KSTAT_DATA_UINT64 } }; struct { wmsum_t brt_addref_entry_not_on_disk; wmsum_t brt_addref_entry_on_disk; wmsum_t brt_decref_entry_in_memory; wmsum_t brt_decref_entry_loaded_from_disk; wmsum_t brt_decref_entry_not_in_memory; wmsum_t brt_decref_entry_read_lost_race; wmsum_t brt_decref_entry_still_referenced; wmsum_t brt_decref_free_data_later; wmsum_t brt_decref_free_data_now; wmsum_t brt_decref_no_entry; } brt_sums; #define BRTSTAT_BUMP(stat) wmsum_add(&brt_sums.stat, 1) static int brt_entry_compare(const void *x1, const void *x2); static void brt_vdevs_expand(spa_t *spa, uint64_t nvdevs); static void brt_rlock(spa_t *spa) { rw_enter(&spa->spa_brt_lock, RW_READER); } static void brt_wlock(spa_t *spa) { rw_enter(&spa->spa_brt_lock, RW_WRITER); } static void brt_unlock(spa_t *spa) { rw_exit(&spa->spa_brt_lock); } static uint16_t brt_vdev_entcount_get(const brt_vdev_t *brtvd, uint64_t idx) { ASSERT3U(idx, <, brtvd->bv_size); if (unlikely(brtvd->bv_need_byteswap)) { return (BSWAP_16(brtvd->bv_entcount[idx])); } else { return (brtvd->bv_entcount[idx]); } } static void brt_vdev_entcount_set(brt_vdev_t *brtvd, uint64_t idx, uint16_t entcnt) { ASSERT3U(idx, <, brtvd->bv_size); if (unlikely(brtvd->bv_need_byteswap)) { brtvd->bv_entcount[idx] = BSWAP_16(entcnt); } else { brtvd->bv_entcount[idx] = entcnt; } } static void brt_vdev_entcount_inc(brt_vdev_t *brtvd, uint64_t idx) { uint16_t entcnt; ASSERT3U(idx, <, brtvd->bv_size); entcnt = brt_vdev_entcount_get(brtvd, idx); ASSERT(entcnt < UINT16_MAX); brt_vdev_entcount_set(brtvd, idx, entcnt + 1); } static void brt_vdev_entcount_dec(brt_vdev_t *brtvd, uint64_t idx) { uint16_t entcnt; ASSERT3U(idx, <, brtvd->bv_size); entcnt = brt_vdev_entcount_get(brtvd, idx); ASSERT(entcnt > 0); brt_vdev_entcount_set(brtvd, idx, entcnt - 1); } #ifdef ZFS_DEBUG static void brt_vdev_dump(brt_vdev_t *brtvd) { uint64_t idx; uint64_t nblocks = BRT_RANGESIZE_TO_NBLOCKS(brtvd->bv_size); zfs_dbgmsg(" BRT vdevid=%llu meta_dirty=%d entcount_dirty=%d " "size=%llu totalcount=%llu nblocks=%llu bitmapsize=%zu", (u_longlong_t)brtvd->bv_vdevid, brtvd->bv_meta_dirty, brtvd->bv_entcount_dirty, (u_longlong_t)brtvd->bv_size, (u_longlong_t)brtvd->bv_totalcount, (u_longlong_t)nblocks, (size_t)BT_SIZEOFMAP(nblocks)); if (brtvd->bv_totalcount > 0) { zfs_dbgmsg(" entcounts:"); for (idx = 0; idx < brtvd->bv_size; idx++) { uint16_t entcnt = brt_vdev_entcount_get(brtvd, idx); if (entcnt > 0) { zfs_dbgmsg(" [%04llu] %hu", (u_longlong_t)idx, entcnt); } } } if (brtvd->bv_entcount_dirty) { char *bitmap; bitmap = kmem_alloc(nblocks + 1, KM_SLEEP); for (idx = 0; idx < nblocks; idx++) { bitmap[idx] = BT_TEST(brtvd->bv_bitmap, idx) ? 'x' : '.'; } bitmap[idx] = '\0'; zfs_dbgmsg(" dirty: %s", bitmap); kmem_free(bitmap, nblocks + 1); } } #endif static brt_vdev_t * brt_vdev(spa_t *spa, uint64_t vdevid, boolean_t alloc) { brt_vdev_t *brtvd = NULL; brt_rlock(spa); if (vdevid < spa->spa_brt_nvdevs) { brtvd = spa->spa_brt_vdevs[vdevid]; } else if (alloc) { /* New VDEV was added. */ brt_unlock(spa); brt_wlock(spa); if (vdevid >= spa->spa_brt_nvdevs) brt_vdevs_expand(spa, vdevid + 1); brtvd = spa->spa_brt_vdevs[vdevid]; } brt_unlock(spa); return (brtvd); } static void brt_vdev_create(spa_t *spa, brt_vdev_t *brtvd, dmu_tx_t *tx) { char name[64]; ASSERT(brtvd->bv_initiated); ASSERT0(brtvd->bv_mos_brtvdev); ASSERT0(brtvd->bv_mos_entries); uint64_t mos_entries = zap_create_flags(spa->spa_meta_objset, 0, ZAP_FLAG_HASH64 | ZAP_FLAG_UINT64_KEY, DMU_OTN_ZAP_METADATA, brt_zap_default_bs, brt_zap_default_ibs, DMU_OT_NONE, 0, tx); VERIFY(mos_entries != 0); VERIFY0(dnode_hold(spa->spa_meta_objset, mos_entries, brtvd, &brtvd->bv_mos_entries_dnode)); rw_enter(&brtvd->bv_mos_entries_lock, RW_WRITER); brtvd->bv_mos_entries = mos_entries; rw_exit(&brtvd->bv_mos_entries_lock); BRT_DEBUG("MOS entries created, object=%llu", (u_longlong_t)brtvd->bv_mos_entries); /* * We allocate DMU buffer to store the bv_entcount[] array. * We will keep array size (bv_size) and cummulative count for all * bv_entcount[]s (bv_totalcount) in the bonus buffer. */ brtvd->bv_mos_brtvdev = dmu_object_alloc(spa->spa_meta_objset, DMU_OTN_UINT64_METADATA, BRT_BLOCKSIZE, DMU_OTN_UINT64_METADATA, sizeof (brt_vdev_phys_t), tx); VERIFY(brtvd->bv_mos_brtvdev != 0); BRT_DEBUG("MOS BRT VDEV created, object=%llu", (u_longlong_t)brtvd->bv_mos_brtvdev); snprintf(name, sizeof (name), "%s%llu", BRT_OBJECT_VDEV_PREFIX, (u_longlong_t)brtvd->bv_vdevid); VERIFY0(zap_add(spa->spa_meta_objset, DMU_POOL_DIRECTORY_OBJECT, name, sizeof (uint64_t), 1, &brtvd->bv_mos_brtvdev, tx)); BRT_DEBUG("Pool directory object created, object=%s", name); spa_feature_incr(spa, SPA_FEATURE_BLOCK_CLONING, tx); } static void brt_vdev_realloc(spa_t *spa, brt_vdev_t *brtvd) { vdev_t *vd; uint16_t *entcount; ulong_t *bitmap; uint64_t nblocks, onblocks, size; ASSERT(RW_WRITE_HELD(&brtvd->bv_lock)); spa_config_enter(spa, SCL_VDEV, FTAG, RW_READER); vd = vdev_lookup_top(spa, brtvd->bv_vdevid); size = (vdev_get_min_asize(vd) - 1) / spa->spa_brt_rangesize + 1; spa_config_exit(spa, SCL_VDEV, FTAG); entcount = vmem_zalloc(sizeof (entcount[0]) * size, KM_SLEEP); nblocks = BRT_RANGESIZE_TO_NBLOCKS(size); bitmap = kmem_zalloc(BT_SIZEOFMAP(nblocks), KM_SLEEP); if (!brtvd->bv_initiated) { ASSERT0(brtvd->bv_size); ASSERT0P(brtvd->bv_entcount); ASSERT0P(brtvd->bv_bitmap); } else { ASSERT(brtvd->bv_size > 0); ASSERT(brtvd->bv_entcount != NULL); ASSERT(brtvd->bv_bitmap != NULL); /* * TODO: Allow vdev shrinking. We only need to implement * shrinking the on-disk BRT VDEV object. * dmu_free_range(spa->spa_meta_objset, brtvd->bv_mos_brtvdev, * offset, size, tx); */ ASSERT3U(brtvd->bv_size, <=, size); memcpy(entcount, brtvd->bv_entcount, sizeof (entcount[0]) * MIN(size, brtvd->bv_size)); vmem_free(brtvd->bv_entcount, sizeof (entcount[0]) * brtvd->bv_size); onblocks = BRT_RANGESIZE_TO_NBLOCKS(brtvd->bv_size); memcpy(bitmap, brtvd->bv_bitmap, MIN(BT_SIZEOFMAP(nblocks), BT_SIZEOFMAP(onblocks))); kmem_free(brtvd->bv_bitmap, BT_SIZEOFMAP(onblocks)); } brtvd->bv_size = size; brtvd->bv_entcount = entcount; brtvd->bv_bitmap = bitmap; if (!brtvd->bv_initiated) { brtvd->bv_need_byteswap = FALSE; brtvd->bv_initiated = TRUE; BRT_DEBUG("BRT VDEV %llu initiated.", (u_longlong_t)brtvd->bv_vdevid); } } static int brt_vdev_load(spa_t *spa, brt_vdev_t *brtvd) { dmu_buf_t *db; brt_vdev_phys_t *bvphys; int error; ASSERT(!brtvd->bv_initiated); ASSERT(brtvd->bv_mos_brtvdev != 0); error = dmu_bonus_hold(spa->spa_meta_objset, brtvd->bv_mos_brtvdev, FTAG, &db); if (error != 0) return (error); bvphys = db->db_data; if (spa->spa_brt_rangesize == 0) { spa->spa_brt_rangesize = bvphys->bvp_rangesize; } else { ASSERT3U(spa->spa_brt_rangesize, ==, bvphys->bvp_rangesize); } brt_vdev_realloc(spa, brtvd); /* TODO: We don't support VDEV shrinking. */ ASSERT3U(bvphys->bvp_size, <=, brtvd->bv_size); /* * If VDEV grew, we will leave new bv_entcount[] entries zeroed out. */ error = dmu_read(spa->spa_meta_objset, brtvd->bv_mos_brtvdev, 0, MIN(brtvd->bv_size, bvphys->bvp_size) * sizeof (uint16_t), brtvd->bv_entcount, DMU_READ_NO_PREFETCH); if (error != 0) return (error); ASSERT(bvphys->bvp_mos_entries != 0); VERIFY0(dnode_hold(spa->spa_meta_objset, bvphys->bvp_mos_entries, brtvd, &brtvd->bv_mos_entries_dnode)); rw_enter(&brtvd->bv_mos_entries_lock, RW_WRITER); brtvd->bv_mos_entries = bvphys->bvp_mos_entries; rw_exit(&brtvd->bv_mos_entries_lock); brtvd->bv_need_byteswap = (bvphys->bvp_byteorder != BRT_NATIVE_BYTEORDER); brtvd->bv_totalcount = bvphys->bvp_totalcount; brtvd->bv_usedspace = bvphys->bvp_usedspace; brtvd->bv_savedspace = bvphys->bvp_savedspace; dmu_buf_rele(db, FTAG); BRT_DEBUG("BRT VDEV %llu loaded: mos_brtvdev=%llu, mos_entries=%llu", (u_longlong_t)brtvd->bv_vdevid, (u_longlong_t)brtvd->bv_mos_brtvdev, (u_longlong_t)brtvd->bv_mos_entries); return (0); } static void brt_vdev_dealloc(brt_vdev_t *brtvd) { ASSERT(RW_WRITE_HELD(&brtvd->bv_lock)); ASSERT(brtvd->bv_initiated); ASSERT0(avl_numnodes(&brtvd->bv_tree)); vmem_free(brtvd->bv_entcount, sizeof (uint16_t) * brtvd->bv_size); brtvd->bv_entcount = NULL; uint64_t nblocks = BRT_RANGESIZE_TO_NBLOCKS(brtvd->bv_size); kmem_free(brtvd->bv_bitmap, BT_SIZEOFMAP(nblocks)); brtvd->bv_bitmap = NULL; brtvd->bv_size = 0; brtvd->bv_initiated = FALSE; BRT_DEBUG("BRT VDEV %llu deallocated.", (u_longlong_t)brtvd->bv_vdevid); } static void brt_vdev_destroy(spa_t *spa, brt_vdev_t *brtvd, dmu_tx_t *tx) { char name[64]; uint64_t count; ASSERT(brtvd->bv_initiated); ASSERT(brtvd->bv_mos_brtvdev != 0); ASSERT(brtvd->bv_mos_entries != 0); ASSERT0(brtvd->bv_totalcount); ASSERT0(brtvd->bv_usedspace); ASSERT0(brtvd->bv_savedspace); uint64_t mos_entries = brtvd->bv_mos_entries; rw_enter(&brtvd->bv_mos_entries_lock, RW_WRITER); brtvd->bv_mos_entries = 0; rw_exit(&brtvd->bv_mos_entries_lock); dnode_rele(brtvd->bv_mos_entries_dnode, brtvd); brtvd->bv_mos_entries_dnode = NULL; ASSERT0(zap_count(spa->spa_meta_objset, mos_entries, &count)); ASSERT0(count); VERIFY0(zap_destroy(spa->spa_meta_objset, mos_entries, tx)); BRT_DEBUG("MOS entries destroyed, object=%llu", (u_longlong_t)mos_entries); VERIFY0(dmu_object_free(spa->spa_meta_objset, brtvd->bv_mos_brtvdev, tx)); BRT_DEBUG("MOS BRT VDEV destroyed, object=%llu", (u_longlong_t)brtvd->bv_mos_brtvdev); brtvd->bv_mos_brtvdev = 0; brtvd->bv_entcount_dirty = FALSE; snprintf(name, sizeof (name), "%s%llu", BRT_OBJECT_VDEV_PREFIX, (u_longlong_t)brtvd->bv_vdevid); VERIFY0(zap_remove(spa->spa_meta_objset, DMU_POOL_DIRECTORY_OBJECT, name, tx)); BRT_DEBUG("Pool directory object removed, object=%s", name); brtvd->bv_meta_dirty = FALSE; rw_enter(&brtvd->bv_lock, RW_WRITER); brt_vdev_dealloc(brtvd); rw_exit(&brtvd->bv_lock); spa_feature_decr(spa, SPA_FEATURE_BLOCK_CLONING, tx); } static void brt_vdevs_expand(spa_t *spa, uint64_t nvdevs) { brt_vdev_t **vdevs; ASSERT(RW_WRITE_HELD(&spa->spa_brt_lock)); ASSERT3U(nvdevs, >=, spa->spa_brt_nvdevs); if (nvdevs == spa->spa_brt_nvdevs) return; vdevs = kmem_zalloc(sizeof (*spa->spa_brt_vdevs) * nvdevs, KM_SLEEP); if (spa->spa_brt_nvdevs > 0) { ASSERT(spa->spa_brt_vdevs != NULL); memcpy(vdevs, spa->spa_brt_vdevs, sizeof (*spa->spa_brt_vdevs) * spa->spa_brt_nvdevs); kmem_free(spa->spa_brt_vdevs, sizeof (*spa->spa_brt_vdevs) * spa->spa_brt_nvdevs); } spa->spa_brt_vdevs = vdevs; for (uint64_t vdevid = spa->spa_brt_nvdevs; vdevid < nvdevs; vdevid++) { brt_vdev_t *brtvd = kmem_zalloc(sizeof (*brtvd), KM_SLEEP); rw_init(&brtvd->bv_lock, NULL, RW_DEFAULT, NULL); brtvd->bv_vdevid = vdevid; brtvd->bv_initiated = FALSE; rw_init(&brtvd->bv_mos_entries_lock, NULL, RW_DEFAULT, NULL); avl_create(&brtvd->bv_tree, brt_entry_compare, sizeof (brt_entry_t), offsetof(brt_entry_t, bre_node)); for (int i = 0; i < TXG_SIZE; i++) { avl_create(&brtvd->bv_pending_tree[i], brt_entry_compare, sizeof (brt_entry_t), offsetof(brt_entry_t, bre_node)); } mutex_init(&brtvd->bv_pending_lock, NULL, MUTEX_DEFAULT, NULL); spa->spa_brt_vdevs[vdevid] = brtvd; } BRT_DEBUG("BRT VDEVs expanded from %llu to %llu.", (u_longlong_t)spa->spa_brt_nvdevs, (u_longlong_t)nvdevs); spa->spa_brt_nvdevs = nvdevs; } static boolean_t brt_vdev_lookup(spa_t *spa, brt_vdev_t *brtvd, uint64_t offset) { uint64_t idx = offset / spa->spa_brt_rangesize; if (idx < brtvd->bv_size) { /* VDEV wasn't expanded. */ return (brt_vdev_entcount_get(brtvd, idx) > 0); } return (FALSE); } static void brt_vdev_addref(spa_t *spa, brt_vdev_t *brtvd, const brt_entry_t *bre, uint64_t dsize, uint64_t count) { uint64_t idx; ASSERT(brtvd->bv_initiated); brtvd->bv_savedspace += dsize * count; brtvd->bv_meta_dirty = TRUE; if (bre->bre_count > 0) return; brtvd->bv_usedspace += dsize; idx = BRE_OFFSET(bre) / spa->spa_brt_rangesize; if (idx >= brtvd->bv_size) { /* VDEV has been expanded. */ rw_enter(&brtvd->bv_lock, RW_WRITER); brt_vdev_realloc(spa, brtvd); rw_exit(&brtvd->bv_lock); } ASSERT3U(idx, <, brtvd->bv_size); brtvd->bv_totalcount++; brt_vdev_entcount_inc(brtvd, idx); brtvd->bv_entcount_dirty = TRUE; idx = idx / BRT_BLOCKSIZE / 8; BT_SET(brtvd->bv_bitmap, idx); } static void brt_vdev_decref(spa_t *spa, brt_vdev_t *brtvd, const brt_entry_t *bre, uint64_t dsize) { uint64_t idx; ASSERT(RW_WRITE_HELD(&brtvd->bv_lock)); ASSERT(brtvd->bv_initiated); brtvd->bv_savedspace -= dsize; brtvd->bv_meta_dirty = TRUE; if (bre->bre_count > 0) return; brtvd->bv_usedspace -= dsize; idx = BRE_OFFSET(bre) / spa->spa_brt_rangesize; ASSERT3U(idx, <, brtvd->bv_size); ASSERT(brtvd->bv_totalcount > 0); brtvd->bv_totalcount--; brt_vdev_entcount_dec(brtvd, idx); brtvd->bv_entcount_dirty = TRUE; idx = idx / BRT_BLOCKSIZE / 8; BT_SET(brtvd->bv_bitmap, idx); } static void brt_vdev_sync(spa_t *spa, brt_vdev_t *brtvd, dmu_tx_t *tx) { dmu_buf_t *db; brt_vdev_phys_t *bvphys; ASSERT(brtvd->bv_meta_dirty); ASSERT(brtvd->bv_mos_brtvdev != 0); ASSERT(dmu_tx_is_syncing(tx)); VERIFY0(dmu_bonus_hold(spa->spa_meta_objset, brtvd->bv_mos_brtvdev, FTAG, &db)); if (brtvd->bv_entcount_dirty) { /* * TODO: Walk brtvd->bv_bitmap and write only the dirty blocks. */ dmu_write(spa->spa_meta_objset, brtvd->bv_mos_brtvdev, 0, brtvd->bv_size * sizeof (brtvd->bv_entcount[0]), brtvd->bv_entcount, tx); uint64_t nblocks = BRT_RANGESIZE_TO_NBLOCKS(brtvd->bv_size); memset(brtvd->bv_bitmap, 0, BT_SIZEOFMAP(nblocks)); brtvd->bv_entcount_dirty = FALSE; } dmu_buf_will_dirty(db, tx); bvphys = db->db_data; bvphys->bvp_mos_entries = brtvd->bv_mos_entries; bvphys->bvp_size = brtvd->bv_size; if (brtvd->bv_need_byteswap) { bvphys->bvp_byteorder = BRT_NON_NATIVE_BYTEORDER; } else { bvphys->bvp_byteorder = BRT_NATIVE_BYTEORDER; } bvphys->bvp_totalcount = brtvd->bv_totalcount; bvphys->bvp_rangesize = spa->spa_brt_rangesize; bvphys->bvp_usedspace = brtvd->bv_usedspace; bvphys->bvp_savedspace = brtvd->bv_savedspace; dmu_buf_rele(db, FTAG); brtvd->bv_meta_dirty = FALSE; } static void brt_vdevs_free(spa_t *spa) { if (spa->spa_brt_vdevs == 0) return; for (uint64_t vdevid = 0; vdevid < spa->spa_brt_nvdevs; vdevid++) { brt_vdev_t *brtvd = spa->spa_brt_vdevs[vdevid]; rw_enter(&brtvd->bv_lock, RW_WRITER); if (brtvd->bv_initiated) brt_vdev_dealloc(brtvd); rw_exit(&brtvd->bv_lock); rw_destroy(&brtvd->bv_lock); if (brtvd->bv_mos_entries != 0) dnode_rele(brtvd->bv_mos_entries_dnode, brtvd); rw_destroy(&brtvd->bv_mos_entries_lock); avl_destroy(&brtvd->bv_tree); for (int i = 0; i < TXG_SIZE; i++) avl_destroy(&brtvd->bv_pending_tree[i]); mutex_destroy(&brtvd->bv_pending_lock); kmem_free(brtvd, sizeof (*brtvd)); } kmem_free(spa->spa_brt_vdevs, sizeof (*spa->spa_brt_vdevs) * spa->spa_brt_nvdevs); } static void brt_entry_fill(const blkptr_t *bp, brt_entry_t *bre, uint64_t *vdevidp) { bre->bre_bp = *bp; bre->bre_count = 0; bre->bre_pcount = 0; *vdevidp = DVA_GET_VDEV(&bp->blk_dva[0]); } static int brt_entry_lookup(brt_vdev_t *brtvd, brt_entry_t *bre) { uint64_t off = BRE_OFFSET(bre); return (zap_lookup_uint64_by_dnode(brtvd->bv_mos_entries_dnode, &off, BRT_KEY_WORDS, 1, sizeof (bre->bre_count), &bre->bre_count)); } /* * Return TRUE if we _can_ have BRT entry for this bp. It might be false * positive, but gives us quick answer if we should look into BRT, which * may require reads and thus will be more expensive. */ boolean_t brt_maybe_exists(spa_t *spa, const blkptr_t *bp) { if (spa->spa_brt_nvdevs == 0) return (B_FALSE); uint64_t vdevid = DVA_GET_VDEV(&bp->blk_dva[0]); brt_vdev_t *brtvd = brt_vdev(spa, vdevid, B_FALSE); if (brtvd == NULL || !brtvd->bv_initiated) return (FALSE); /* * We don't need locks here, since bv_entcount pointer must be * stable at this point, and we don't care about false positive * races here, while false negative should be impossible, since * all brt_vdev_addref() have already completed by this point. */ uint64_t off = DVA_GET_OFFSET(&bp->blk_dva[0]); return (brt_vdev_lookup(spa, brtvd, off)); } uint64_t brt_get_dspace(spa_t *spa) { if (spa->spa_brt_nvdevs == 0) return (0); brt_rlock(spa); uint64_t s = 0; for (uint64_t vdevid = 0; vdevid < spa->spa_brt_nvdevs; vdevid++) s += spa->spa_brt_vdevs[vdevid]->bv_savedspace; brt_unlock(spa); return (s); } uint64_t brt_get_used(spa_t *spa) { if (spa->spa_brt_nvdevs == 0) return (0); brt_rlock(spa); uint64_t s = 0; for (uint64_t vdevid = 0; vdevid < spa->spa_brt_nvdevs; vdevid++) s += spa->spa_brt_vdevs[vdevid]->bv_usedspace; brt_unlock(spa); return (s); } uint64_t brt_get_saved(spa_t *spa) { return (brt_get_dspace(spa)); } uint64_t brt_get_ratio(spa_t *spa) { uint64_t used = brt_get_used(spa); if (used == 0) return (100); return ((used + brt_get_saved(spa)) * 100 / used); } static int brt_kstats_update(kstat_t *ksp, int rw) { brt_stats_t *bs = ksp->ks_data; if (rw == KSTAT_WRITE) return (EACCES); bs->brt_addref_entry_not_on_disk.value.ui64 = wmsum_value(&brt_sums.brt_addref_entry_not_on_disk); bs->brt_addref_entry_on_disk.value.ui64 = wmsum_value(&brt_sums.brt_addref_entry_on_disk); bs->brt_decref_entry_in_memory.value.ui64 = wmsum_value(&brt_sums.brt_decref_entry_in_memory); bs->brt_decref_entry_loaded_from_disk.value.ui64 = wmsum_value(&brt_sums.brt_decref_entry_loaded_from_disk); bs->brt_decref_entry_not_in_memory.value.ui64 = wmsum_value(&brt_sums.brt_decref_entry_not_in_memory); bs->brt_decref_entry_read_lost_race.value.ui64 = wmsum_value(&brt_sums.brt_decref_entry_read_lost_race); bs->brt_decref_entry_still_referenced.value.ui64 = wmsum_value(&brt_sums.brt_decref_entry_still_referenced); bs->brt_decref_free_data_later.value.ui64 = wmsum_value(&brt_sums.brt_decref_free_data_later); bs->brt_decref_free_data_now.value.ui64 = wmsum_value(&brt_sums.brt_decref_free_data_now); bs->brt_decref_no_entry.value.ui64 = wmsum_value(&brt_sums.brt_decref_no_entry); return (0); } static void brt_stat_init(void) { wmsum_init(&brt_sums.brt_addref_entry_not_on_disk, 0); wmsum_init(&brt_sums.brt_addref_entry_on_disk, 0); wmsum_init(&brt_sums.brt_decref_entry_in_memory, 0); wmsum_init(&brt_sums.brt_decref_entry_loaded_from_disk, 0); wmsum_init(&brt_sums.brt_decref_entry_not_in_memory, 0); wmsum_init(&brt_sums.brt_decref_entry_read_lost_race, 0); wmsum_init(&brt_sums.brt_decref_entry_still_referenced, 0); wmsum_init(&brt_sums.brt_decref_free_data_later, 0); wmsum_init(&brt_sums.brt_decref_free_data_now, 0); wmsum_init(&brt_sums.brt_decref_no_entry, 0); brt_ksp = kstat_create("zfs", 0, "brtstats", "misc", KSTAT_TYPE_NAMED, sizeof (brt_stats) / sizeof (kstat_named_t), KSTAT_FLAG_VIRTUAL); if (brt_ksp != NULL) { brt_ksp->ks_data = &brt_stats; brt_ksp->ks_update = brt_kstats_update; kstat_install(brt_ksp); } } static void brt_stat_fini(void) { if (brt_ksp != NULL) { kstat_delete(brt_ksp); brt_ksp = NULL; } wmsum_fini(&brt_sums.brt_addref_entry_not_on_disk); wmsum_fini(&brt_sums.brt_addref_entry_on_disk); wmsum_fini(&brt_sums.brt_decref_entry_in_memory); wmsum_fini(&brt_sums.brt_decref_entry_loaded_from_disk); wmsum_fini(&brt_sums.brt_decref_entry_not_in_memory); wmsum_fini(&brt_sums.brt_decref_entry_read_lost_race); wmsum_fini(&brt_sums.brt_decref_entry_still_referenced); wmsum_fini(&brt_sums.brt_decref_free_data_later); wmsum_fini(&brt_sums.brt_decref_free_data_now); wmsum_fini(&brt_sums.brt_decref_no_entry); } void brt_init(void) { brt_entry_cache = kmem_cache_create("brt_entry_cache", sizeof (brt_entry_t), 0, NULL, NULL, NULL, NULL, NULL, 0); brt_stat_init(); } void brt_fini(void) { brt_stat_fini(); kmem_cache_destroy(brt_entry_cache); } /* Return TRUE if block should be freed immediately. */ boolean_t brt_entry_decref(spa_t *spa, const blkptr_t *bp) { brt_entry_t *bre, *racebre; brt_entry_t bre_search; avl_index_t where; uint64_t vdevid; int error; brt_entry_fill(bp, &bre_search, &vdevid); brt_vdev_t *brtvd = brt_vdev(spa, vdevid, B_FALSE); ASSERT(brtvd != NULL); rw_enter(&brtvd->bv_lock, RW_WRITER); ASSERT(brtvd->bv_initiated); bre = avl_find(&brtvd->bv_tree, &bre_search, NULL); if (bre != NULL) { BRTSTAT_BUMP(brt_decref_entry_in_memory); goto out; } else { BRTSTAT_BUMP(brt_decref_entry_not_in_memory); } rw_exit(&brtvd->bv_lock); error = brt_entry_lookup(brtvd, &bre_search); /* bre_search now contains correct bre_count */ if (error == ENOENT) { BRTSTAT_BUMP(brt_decref_no_entry); return (B_TRUE); } ASSERT0(error); rw_enter(&brtvd->bv_lock, RW_WRITER); racebre = avl_find(&brtvd->bv_tree, &bre_search, &where); if (racebre != NULL) { /* The entry was added when the lock was dropped. */ BRTSTAT_BUMP(brt_decref_entry_read_lost_race); bre = racebre; goto out; } BRTSTAT_BUMP(brt_decref_entry_loaded_from_disk); bre = kmem_cache_alloc(brt_entry_cache, KM_SLEEP); bre->bre_bp = bre_search.bre_bp; bre->bre_count = bre_search.bre_count; bre->bre_pcount = 0; avl_insert(&brtvd->bv_tree, bre, where); out: if (bre->bre_count == 0) { rw_exit(&brtvd->bv_lock); BRTSTAT_BUMP(brt_decref_free_data_now); return (B_TRUE); } bre->bre_pcount--; ASSERT(bre->bre_count > 0); bre->bre_count--; if (bre->bre_count == 0) BRTSTAT_BUMP(brt_decref_free_data_later); else BRTSTAT_BUMP(brt_decref_entry_still_referenced); brt_vdev_decref(spa, brtvd, bre, bp_get_dsize_sync(spa, bp)); rw_exit(&brtvd->bv_lock); return (B_FALSE); } uint64_t brt_entry_get_refcount(spa_t *spa, const blkptr_t *bp) { brt_entry_t bre_search, *bre; uint64_t vdevid, refcnt; int error; brt_entry_fill(bp, &bre_search, &vdevid); brt_vdev_t *brtvd = brt_vdev(spa, vdevid, B_FALSE); ASSERT(brtvd != NULL); rw_enter(&brtvd->bv_lock, RW_READER); ASSERT(brtvd->bv_initiated); bre = avl_find(&brtvd->bv_tree, &bre_search, NULL); if (bre == NULL) { rw_exit(&brtvd->bv_lock); error = brt_entry_lookup(brtvd, &bre_search); if (error == ENOENT) { refcnt = 0; } else { ASSERT0(error); refcnt = bre_search.bre_count; } } else { refcnt = bre->bre_count; rw_exit(&brtvd->bv_lock); } return (refcnt); } static void brt_prefetch(brt_vdev_t *brtvd, const blkptr_t *bp) { if (!brt_zap_prefetch || brtvd->bv_mos_entries == 0) return; uint64_t off = DVA_GET_OFFSET(&bp->blk_dva[0]); rw_enter(&brtvd->bv_mos_entries_lock, RW_READER); if (brtvd->bv_mos_entries != 0) { (void) zap_prefetch_uint64_by_dnode(brtvd->bv_mos_entries_dnode, &off, BRT_KEY_WORDS); } rw_exit(&brtvd->bv_mos_entries_lock); } static int brt_entry_compare(const void *x1, const void *x2) { const brt_entry_t *bre1 = x1, *bre2 = x2; const blkptr_t *bp1 = &bre1->bre_bp, *bp2 = &bre2->bre_bp; return (TREE_CMP(DVA_GET_OFFSET(&bp1->blk_dva[0]), DVA_GET_OFFSET(&bp2->blk_dva[0]))); } void brt_pending_add(spa_t *spa, const blkptr_t *bp, dmu_tx_t *tx) { brt_entry_t *bre, *newbre; avl_index_t where; uint64_t txg; txg = dmu_tx_get_txg(tx); ASSERT3U(txg, !=, 0); uint64_t vdevid = DVA_GET_VDEV(&bp->blk_dva[0]); brt_vdev_t *brtvd = brt_vdev(spa, vdevid, B_TRUE); avl_tree_t *pending_tree = &brtvd->bv_pending_tree[txg & TXG_MASK]; newbre = kmem_cache_alloc(brt_entry_cache, KM_SLEEP); newbre->bre_bp = *bp; newbre->bre_count = 0; newbre->bre_pcount = 1; mutex_enter(&brtvd->bv_pending_lock); bre = avl_find(pending_tree, newbre, &where); if (bre == NULL) { avl_insert(pending_tree, newbre, where); newbre = NULL; } else { bre->bre_pcount++; } mutex_exit(&brtvd->bv_pending_lock); if (newbre != NULL) { ASSERT(bre != NULL); ASSERT(bre != newbre); kmem_cache_free(brt_entry_cache, newbre); } else { ASSERT0P(bre); /* Prefetch BRT entry for the syncing context. */ brt_prefetch(brtvd, bp); } } void brt_pending_remove(spa_t *spa, const blkptr_t *bp, dmu_tx_t *tx) { brt_entry_t *bre, bre_search; uint64_t txg; txg = dmu_tx_get_txg(tx); ASSERT3U(txg, !=, 0); uint64_t vdevid = DVA_GET_VDEV(&bp->blk_dva[0]); brt_vdev_t *brtvd = brt_vdev(spa, vdevid, B_FALSE); ASSERT(brtvd != NULL); avl_tree_t *pending_tree = &brtvd->bv_pending_tree[txg & TXG_MASK]; bre_search.bre_bp = *bp; mutex_enter(&brtvd->bv_pending_lock); bre = avl_find(pending_tree, &bre_search, NULL); ASSERT(bre != NULL); ASSERT(bre->bre_pcount > 0); bre->bre_pcount--; if (bre->bre_pcount == 0) avl_remove(pending_tree, bre); else bre = NULL; mutex_exit(&brtvd->bv_pending_lock); if (bre) kmem_cache_free(brt_entry_cache, bre); } static void brt_pending_apply_vdev(spa_t *spa, brt_vdev_t *brtvd, uint64_t txg) { brt_entry_t *bre, *nbre; /* * We are in syncing context, so no other bv_pending_tree accesses * are possible for the TXG. So we don't need bv_pending_lock. */ ASSERT(avl_is_empty(&brtvd->bv_tree)); avl_swap(&brtvd->bv_tree, &brtvd->bv_pending_tree[txg & TXG_MASK]); for (bre = avl_first(&brtvd->bv_tree); bre; bre = nbre) { nbre = AVL_NEXT(&brtvd->bv_tree, bre); /* * If the block has DEDUP bit set, it means that it * already exists in the DEDUP table, so we can just * use that instead of creating new entry in the BRT. */ if (BP_GET_DEDUP(&bre->bre_bp)) { while (bre->bre_pcount > 0) { if (!ddt_addref(spa, &bre->bre_bp)) break; bre->bre_pcount--; } if (bre->bre_pcount == 0) { avl_remove(&brtvd->bv_tree, bre); kmem_cache_free(brt_entry_cache, bre); continue; } } /* * Unless we know that the block is definitely not in ZAP, * try to get its reference count from there. */ uint64_t off = BRE_OFFSET(bre); if (brtvd->bv_mos_entries != 0 && brt_vdev_lookup(spa, brtvd, off)) { int error = zap_lookup_uint64_by_dnode( brtvd->bv_mos_entries_dnode, &off, BRT_KEY_WORDS, 1, sizeof (bre->bre_count), &bre->bre_count); if (error == 0) { BRTSTAT_BUMP(brt_addref_entry_on_disk); } else { ASSERT3U(error, ==, ENOENT); BRTSTAT_BUMP(brt_addref_entry_not_on_disk); } } } /* * If all the cloned blocks we had were handled by DDT, we don't need * to initiate the vdev. */ if (avl_is_empty(&brtvd->bv_tree)) return; if (!brtvd->bv_initiated) { rw_enter(&brtvd->bv_lock, RW_WRITER); brt_vdev_realloc(spa, brtvd); rw_exit(&brtvd->bv_lock); } /* * Convert pending references into proper ones. This has to be a * separate loop, since entcount modifications would cause false * positives for brt_vdev_lookup() on following iterations. */ for (bre = avl_first(&brtvd->bv_tree); bre; bre = AVL_NEXT(&brtvd->bv_tree, bre)) { brt_vdev_addref(spa, brtvd, bre, bp_get_dsize(spa, &bre->bre_bp), bre->bre_pcount); bre->bre_count += bre->bre_pcount; } } void brt_pending_apply(spa_t *spa, uint64_t txg) { brt_rlock(spa); for (uint64_t vdevid = 0; vdevid < spa->spa_brt_nvdevs; vdevid++) { brt_vdev_t *brtvd = spa->spa_brt_vdevs[vdevid]; brt_unlock(spa); brt_pending_apply_vdev(spa, brtvd, txg); brt_rlock(spa); } brt_unlock(spa); } static void brt_sync_entry(dnode_t *dn, brt_entry_t *bre, dmu_tx_t *tx) { uint64_t off = BRE_OFFSET(bre); if (bre->bre_pcount == 0) { /* The net change is zero, nothing to do in ZAP. */ } else if (bre->bre_count == 0) { int error = zap_remove_uint64_by_dnode(dn, &off, BRT_KEY_WORDS, tx); VERIFY(error == 0 || error == ENOENT); } else { VERIFY0(zap_update_uint64_by_dnode(dn, &off, BRT_KEY_WORDS, 1, sizeof (bre->bre_count), &bre->bre_count, tx)); } } static void brt_sync_table(spa_t *spa, dmu_tx_t *tx) { brt_entry_t *bre; brt_rlock(spa); for (uint64_t vdevid = 0; vdevid < spa->spa_brt_nvdevs; vdevid++) { brt_vdev_t *brtvd = spa->spa_brt_vdevs[vdevid]; brt_unlock(spa); if (!brtvd->bv_meta_dirty) { ASSERT(!brtvd->bv_entcount_dirty); ASSERT0(avl_numnodes(&brtvd->bv_tree)); brt_rlock(spa); continue; } ASSERT(!brtvd->bv_entcount_dirty || avl_numnodes(&brtvd->bv_tree) != 0); if (brtvd->bv_mos_brtvdev == 0) brt_vdev_create(spa, brtvd, tx); void *c = NULL; while ((bre = avl_destroy_nodes(&brtvd->bv_tree, &c)) != NULL) { brt_sync_entry(brtvd->bv_mos_entries_dnode, bre, tx); kmem_cache_free(brt_entry_cache, bre); } #ifdef ZFS_DEBUG if (zfs_flags & ZFS_DEBUG_BRT) brt_vdev_dump(brtvd); #endif if (brtvd->bv_totalcount == 0) brt_vdev_destroy(spa, brtvd, tx); else brt_vdev_sync(spa, brtvd, tx); brt_rlock(spa); } brt_unlock(spa); } void brt_sync(spa_t *spa, uint64_t txg) { dmu_tx_t *tx; uint64_t vdevid; ASSERT3U(spa_syncing_txg(spa), ==, txg); brt_rlock(spa); for (vdevid = 0; vdevid < spa->spa_brt_nvdevs; vdevid++) { if (spa->spa_brt_vdevs[vdevid]->bv_meta_dirty) break; } if (vdevid >= spa->spa_brt_nvdevs) { brt_unlock(spa); return; } brt_unlock(spa); tx = dmu_tx_create_assigned(spa->spa_dsl_pool, txg); brt_sync_table(spa, tx); dmu_tx_commit(tx); } static void brt_alloc(spa_t *spa) { rw_init(&spa->spa_brt_lock, NULL, RW_DEFAULT, NULL); spa->spa_brt_vdevs = NULL; spa->spa_brt_nvdevs = 0; spa->spa_brt_rangesize = 0; } void brt_create(spa_t *spa) { brt_alloc(spa); spa->spa_brt_rangesize = BRT_RANGESIZE; } int brt_load(spa_t *spa) { int error = 0; brt_alloc(spa); brt_wlock(spa); for (uint64_t vdevid = 0; vdevid < spa->spa_root_vdev->vdev_children; vdevid++) { char name[64]; uint64_t mos_brtvdev; /* Look if this vdev had active block cloning. */ snprintf(name, sizeof (name), "%s%llu", BRT_OBJECT_VDEV_PREFIX, (u_longlong_t)vdevid); error = zap_lookup(spa->spa_meta_objset, DMU_POOL_DIRECTORY_OBJECT, name, sizeof (uint64_t), 1, &mos_brtvdev); if (error == ENOENT) { error = 0; continue; } if (error != 0) break; /* If it did, then allocate them all and load this one. */ brt_vdevs_expand(spa, spa->spa_root_vdev->vdev_children); brt_vdev_t *brtvd = spa->spa_brt_vdevs[vdevid]; rw_enter(&brtvd->bv_lock, RW_WRITER); brtvd->bv_mos_brtvdev = mos_brtvdev; error = brt_vdev_load(spa, brtvd); rw_exit(&brtvd->bv_lock); if (error != 0) break; } if (spa->spa_brt_rangesize == 0) spa->spa_brt_rangesize = BRT_RANGESIZE; brt_unlock(spa); return (error); } void brt_unload(spa_t *spa) { if (spa->spa_brt_rangesize == 0) return; brt_vdevs_free(spa); rw_destroy(&spa->spa_brt_lock); spa->spa_brt_rangesize = 0; } ZFS_MODULE_PARAM(zfs_brt, , brt_zap_prefetch, INT, ZMOD_RW, "Enable prefetching of BRT ZAP entries"); ZFS_MODULE_PARAM(zfs_brt, , brt_zap_default_bs, UINT, ZMOD_RW, "BRT ZAP leaf blockshift"); ZFS_MODULE_PARAM(zfs_brt, , brt_zap_default_ibs, UINT, ZMOD_RW, "BRT ZAP indirect blockshift");