diff --git a/cmd/zdb/zdb.c b/cmd/zdb/zdb.c index 92df3dd167bf..a3a363ca54f2 100644 --- a/cmd/zdb/zdb.c +++ b/cmd/zdb/zdb.c @@ -1,9013 +1,9013 @@ /* * 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) 2005, 2010, Oracle and/or its affiliates. All rights reserved. * Copyright (c) 2011, 2019 by Delphix. All rights reserved. * Copyright (c) 2014 Integros [integros.com] * Copyright 2016 Nexenta Systems, Inc. * Copyright (c) 2017, 2018 Lawrence Livermore National Security, LLC. * Copyright (c) 2015, 2017, Intel Corporation. * Copyright (c) 2020 Datto Inc. * Copyright (c) 2020, The FreeBSD Foundation [1] * * [1] Portions of this software were developed by Allan Jude * under sponsorship from the FreeBSD Foundation. * Copyright (c) 2021 Allan Jude * Copyright (c) 2021 Toomas Soome */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "zdb.h" #define ZDB_COMPRESS_NAME(idx) ((idx) < ZIO_COMPRESS_FUNCTIONS ? \ zio_compress_table[(idx)].ci_name : "UNKNOWN") #define ZDB_CHECKSUM_NAME(idx) ((idx) < ZIO_CHECKSUM_FUNCTIONS ? \ zio_checksum_table[(idx)].ci_name : "UNKNOWN") #define ZDB_OT_TYPE(idx) ((idx) < DMU_OT_NUMTYPES ? (idx) : \ (idx) == DMU_OTN_ZAP_DATA || (idx) == DMU_OTN_ZAP_METADATA ? \ DMU_OT_ZAP_OTHER : \ (idx) == DMU_OTN_UINT64_DATA || (idx) == DMU_OTN_UINT64_METADATA ? \ DMU_OT_UINT64_OTHER : DMU_OT_NUMTYPES) /* Some platforms require part of inode IDs to be remapped */ #ifdef __APPLE__ #define ZDB_MAP_OBJECT_ID(obj) INO_XNUTOZFS(obj, 2) #else #define ZDB_MAP_OBJECT_ID(obj) (obj) #endif static const char * zdb_ot_name(dmu_object_type_t type) { if (type < DMU_OT_NUMTYPES) return (dmu_ot[type].ot_name); else if ((type & DMU_OT_NEWTYPE) && ((type & DMU_OT_BYTESWAP_MASK) < DMU_BSWAP_NUMFUNCS)) return (dmu_ot_byteswap[type & DMU_OT_BYTESWAP_MASK].ob_name); else return ("UNKNOWN"); } extern int reference_tracking_enable; extern int zfs_recover; extern unsigned long zfs_arc_meta_min, zfs_arc_meta_limit; extern int zfs_vdev_async_read_max_active; extern boolean_t spa_load_verify_dryrun; extern boolean_t spa_mode_readable_spacemaps; extern int zfs_reconstruct_indirect_combinations_max; extern uint_t zfs_btree_verify_intensity; static const char cmdname[] = "zdb"; uint8_t dump_opt[256]; typedef void object_viewer_t(objset_t *, uint64_t, void *data, size_t size); uint64_t *zopt_metaslab = NULL; static unsigned zopt_metaslab_args = 0; typedef struct zopt_object_range { uint64_t zor_obj_start; uint64_t zor_obj_end; uint64_t zor_flags; } zopt_object_range_t; zopt_object_range_t *zopt_object_ranges = NULL; static unsigned zopt_object_args = 0; static int flagbits[256]; #define ZOR_FLAG_PLAIN_FILE 0x0001 #define ZOR_FLAG_DIRECTORY 0x0002 #define ZOR_FLAG_SPACE_MAP 0x0004 #define ZOR_FLAG_ZAP 0x0008 #define ZOR_FLAG_ALL_TYPES -1 #define ZOR_SUPPORTED_FLAGS (ZOR_FLAG_PLAIN_FILE | \ ZOR_FLAG_DIRECTORY | \ ZOR_FLAG_SPACE_MAP | \ ZOR_FLAG_ZAP) #define ZDB_FLAG_CHECKSUM 0x0001 #define ZDB_FLAG_DECOMPRESS 0x0002 #define ZDB_FLAG_BSWAP 0x0004 #define ZDB_FLAG_GBH 0x0008 #define ZDB_FLAG_INDIRECT 0x0010 #define ZDB_FLAG_RAW 0x0020 #define ZDB_FLAG_PRINT_BLKPTR 0x0040 #define ZDB_FLAG_VERBOSE 0x0080 uint64_t max_inflight_bytes = 256 * 1024 * 1024; /* 256MB */ static int leaked_objects = 0; static range_tree_t *mos_refd_objs; static void snprintf_blkptr_compact(char *, size_t, const blkptr_t *, boolean_t); static void mos_obj_refd(uint64_t); static void mos_obj_refd_multiple(uint64_t); static int dump_bpobj_cb(void *arg, const blkptr_t *bp, boolean_t free, dmu_tx_t *tx); typedef struct sublivelist_verify { /* FREE's that haven't yet matched to an ALLOC, in one sub-livelist */ zfs_btree_t sv_pair; /* ALLOC's without a matching FREE, accumulates across sub-livelists */ zfs_btree_t sv_leftover; } sublivelist_verify_t; static int livelist_compare(const void *larg, const void *rarg) { const blkptr_t *l = larg; const blkptr_t *r = rarg; /* Sort them according to dva[0] */ uint64_t l_dva0_vdev, r_dva0_vdev; l_dva0_vdev = DVA_GET_VDEV(&l->blk_dva[0]); r_dva0_vdev = DVA_GET_VDEV(&r->blk_dva[0]); if (l_dva0_vdev < r_dva0_vdev) return (-1); else if (l_dva0_vdev > r_dva0_vdev) return (+1); /* if vdevs are equal, sort by offsets. */ uint64_t l_dva0_offset; uint64_t r_dva0_offset; l_dva0_offset = DVA_GET_OFFSET(&l->blk_dva[0]); r_dva0_offset = DVA_GET_OFFSET(&r->blk_dva[0]); if (l_dva0_offset < r_dva0_offset) { return (-1); } else if (l_dva0_offset > r_dva0_offset) { return (+1); } /* * Since we're storing blkptrs without cancelling FREE/ALLOC pairs, * it's possible the offsets are equal. In that case, sort by txg */ if (l->blk_birth < r->blk_birth) { return (-1); } else if (l->blk_birth > r->blk_birth) { return (+1); } return (0); } typedef struct sublivelist_verify_block { dva_t svb_dva; /* * We need this to check if the block marked as allocated * in the livelist was freed (and potentially reallocated) * in the metaslab spacemaps at a later TXG. */ uint64_t svb_allocated_txg; } sublivelist_verify_block_t; static void zdb_print_blkptr(const blkptr_t *bp, int flags); typedef struct sublivelist_verify_block_refcnt { /* block pointer entry in livelist being verified */ blkptr_t svbr_blk; /* * Refcount gets incremented to 1 when we encounter the first * FREE entry for the svfbr block pointer and a node for it * is created in our ZDB verification/tracking metadata. * * As we encounter more FREE entries we increment this counter * and similarly decrement it whenever we find the respective * ALLOC entries for this block. * * When the refcount gets to 0 it means that all the FREE and * ALLOC entries of this block have paired up and we no longer * need to track it in our verification logic (e.g. the node * containing this struct in our verification data structure * should be freed). * * [refer to sublivelist_verify_blkptr() for the actual code] */ uint32_t svbr_refcnt; } sublivelist_verify_block_refcnt_t; static int sublivelist_block_refcnt_compare(const void *larg, const void *rarg) { const sublivelist_verify_block_refcnt_t *l = larg; const sublivelist_verify_block_refcnt_t *r = rarg; return (livelist_compare(&l->svbr_blk, &r->svbr_blk)); } static int sublivelist_verify_blkptr(void *arg, const blkptr_t *bp, boolean_t free, dmu_tx_t *tx) { ASSERT3P(tx, ==, NULL); struct sublivelist_verify *sv = arg; sublivelist_verify_block_refcnt_t current = { .svbr_blk = *bp, /* * Start with 1 in case this is the first free entry. * This field is not used for our B-Tree comparisons * anyway. */ .svbr_refcnt = 1, }; zfs_btree_index_t where; sublivelist_verify_block_refcnt_t *pair = zfs_btree_find(&sv->sv_pair, ¤t, &where); if (free) { if (pair == NULL) { /* first free entry for this block pointer */ zfs_btree_add(&sv->sv_pair, ¤t); } else { pair->svbr_refcnt++; } } else { if (pair == NULL) { /* block that is currently marked as allocated */ for (int i = 0; i < SPA_DVAS_PER_BP; i++) { if (DVA_IS_EMPTY(&bp->blk_dva[i])) break; sublivelist_verify_block_t svb = { .svb_dva = bp->blk_dva[i], .svb_allocated_txg = bp->blk_birth }; if (zfs_btree_find(&sv->sv_leftover, &svb, &where) == NULL) { zfs_btree_add_idx(&sv->sv_leftover, &svb, &where); } } } else { /* alloc matches a free entry */ pair->svbr_refcnt--; if (pair->svbr_refcnt == 0) { /* all allocs and frees have been matched */ zfs_btree_remove_idx(&sv->sv_pair, &where); } } } return (0); } static int sublivelist_verify_func(void *args, dsl_deadlist_entry_t *dle) { int err; struct sublivelist_verify *sv = args; zfs_btree_create(&sv->sv_pair, sublivelist_block_refcnt_compare, sizeof (sublivelist_verify_block_refcnt_t)); err = bpobj_iterate_nofree(&dle->dle_bpobj, sublivelist_verify_blkptr, sv, NULL); sublivelist_verify_block_refcnt_t *e; zfs_btree_index_t *cookie = NULL; while ((e = zfs_btree_destroy_nodes(&sv->sv_pair, &cookie)) != NULL) { char blkbuf[BP_SPRINTF_LEN]; snprintf_blkptr_compact(blkbuf, sizeof (blkbuf), &e->svbr_blk, B_TRUE); (void) printf("\tERROR: %d unmatched FREE(s): %s\n", e->svbr_refcnt, blkbuf); } zfs_btree_destroy(&sv->sv_pair); return (err); } static int livelist_block_compare(const void *larg, const void *rarg) { const sublivelist_verify_block_t *l = larg; const sublivelist_verify_block_t *r = rarg; if (DVA_GET_VDEV(&l->svb_dva) < DVA_GET_VDEV(&r->svb_dva)) return (-1); else if (DVA_GET_VDEV(&l->svb_dva) > DVA_GET_VDEV(&r->svb_dva)) return (+1); if (DVA_GET_OFFSET(&l->svb_dva) < DVA_GET_OFFSET(&r->svb_dva)) return (-1); else if (DVA_GET_OFFSET(&l->svb_dva) > DVA_GET_OFFSET(&r->svb_dva)) return (+1); if (DVA_GET_ASIZE(&l->svb_dva) < DVA_GET_ASIZE(&r->svb_dva)) return (-1); else if (DVA_GET_ASIZE(&l->svb_dva) > DVA_GET_ASIZE(&r->svb_dva)) return (+1); return (0); } /* * Check for errors in a livelist while tracking all unfreed ALLOCs in the * sublivelist_verify_t: sv->sv_leftover */ static void livelist_verify(dsl_deadlist_t *dl, void *arg) { sublivelist_verify_t *sv = arg; dsl_deadlist_iterate(dl, sublivelist_verify_func, sv); } /* * Check for errors in the livelist entry and discard the intermediary * data structures */ static int sublivelist_verify_lightweight(void *args, dsl_deadlist_entry_t *dle) { (void) args; sublivelist_verify_t sv; zfs_btree_create(&sv.sv_leftover, livelist_block_compare, sizeof (sublivelist_verify_block_t)); int err = sublivelist_verify_func(&sv, dle); zfs_btree_clear(&sv.sv_leftover); zfs_btree_destroy(&sv.sv_leftover); return (err); } typedef struct metaslab_verify { /* * Tree containing all the leftover ALLOCs from the livelists * that are part of this metaslab. */ zfs_btree_t mv_livelist_allocs; /* * Metaslab information. */ uint64_t mv_vdid; uint64_t mv_msid; uint64_t mv_start; uint64_t mv_end; /* * What's currently allocated for this metaslab. */ range_tree_t *mv_allocated; } metaslab_verify_t; typedef void ll_iter_t(dsl_deadlist_t *ll, void *arg); typedef int (*zdb_log_sm_cb_t)(spa_t *spa, space_map_entry_t *sme, uint64_t txg, void *arg); typedef struct unflushed_iter_cb_arg { spa_t *uic_spa; uint64_t uic_txg; void *uic_arg; zdb_log_sm_cb_t uic_cb; } unflushed_iter_cb_arg_t; static int iterate_through_spacemap_logs_cb(space_map_entry_t *sme, void *arg) { unflushed_iter_cb_arg_t *uic = arg; return (uic->uic_cb(uic->uic_spa, sme, uic->uic_txg, uic->uic_arg)); } static void iterate_through_spacemap_logs(spa_t *spa, zdb_log_sm_cb_t cb, void *arg) { if (!spa_feature_is_active(spa, SPA_FEATURE_LOG_SPACEMAP)) return; spa_config_enter(spa, SCL_CONFIG, FTAG, RW_READER); for (spa_log_sm_t *sls = avl_first(&spa->spa_sm_logs_by_txg); sls; sls = AVL_NEXT(&spa->spa_sm_logs_by_txg, sls)) { space_map_t *sm = NULL; VERIFY0(space_map_open(&sm, spa_meta_objset(spa), sls->sls_sm_obj, 0, UINT64_MAX, SPA_MINBLOCKSHIFT)); unflushed_iter_cb_arg_t uic = { .uic_spa = spa, .uic_txg = sls->sls_txg, .uic_arg = arg, .uic_cb = cb }; VERIFY0(space_map_iterate(sm, space_map_length(sm), iterate_through_spacemap_logs_cb, &uic)); space_map_close(sm); } spa_config_exit(spa, SCL_CONFIG, FTAG); } static void verify_livelist_allocs(metaslab_verify_t *mv, uint64_t txg, uint64_t offset, uint64_t size) { sublivelist_verify_block_t svb; DVA_SET_VDEV(&svb.svb_dva, mv->mv_vdid); DVA_SET_OFFSET(&svb.svb_dva, offset); DVA_SET_ASIZE(&svb.svb_dva, size); zfs_btree_index_t where; uint64_t end_offset = offset + size; /* * Look for an exact match for spacemap entry in the livelist entries. * Then, look for other livelist entries that fall within the range * of the spacemap entry as it may have been condensed */ sublivelist_verify_block_t *found = zfs_btree_find(&mv->mv_livelist_allocs, &svb, &where); if (found == NULL) { found = zfs_btree_next(&mv->mv_livelist_allocs, &where, &where); } for (; found != NULL && DVA_GET_VDEV(&found->svb_dva) == mv->mv_vdid && DVA_GET_OFFSET(&found->svb_dva) < end_offset; found = zfs_btree_next(&mv->mv_livelist_allocs, &where, &where)) { if (found->svb_allocated_txg <= txg) { (void) printf("ERROR: Livelist ALLOC [%llx:%llx] " "from TXG %llx FREED at TXG %llx\n", (u_longlong_t)DVA_GET_OFFSET(&found->svb_dva), (u_longlong_t)DVA_GET_ASIZE(&found->svb_dva), (u_longlong_t)found->svb_allocated_txg, (u_longlong_t)txg); } } } static int metaslab_spacemap_validation_cb(space_map_entry_t *sme, void *arg) { metaslab_verify_t *mv = arg; uint64_t offset = sme->sme_offset; uint64_t size = sme->sme_run; uint64_t txg = sme->sme_txg; if (sme->sme_type == SM_ALLOC) { if (range_tree_contains(mv->mv_allocated, offset, size)) { (void) printf("ERROR: DOUBLE ALLOC: " "%llu [%llx:%llx] " "%llu:%llu LOG_SM\n", (u_longlong_t)txg, (u_longlong_t)offset, (u_longlong_t)size, (u_longlong_t)mv->mv_vdid, (u_longlong_t)mv->mv_msid); } else { range_tree_add(mv->mv_allocated, offset, size); } } else { if (!range_tree_contains(mv->mv_allocated, offset, size)) { (void) printf("ERROR: DOUBLE FREE: " "%llu [%llx:%llx] " "%llu:%llu LOG_SM\n", (u_longlong_t)txg, (u_longlong_t)offset, (u_longlong_t)size, (u_longlong_t)mv->mv_vdid, (u_longlong_t)mv->mv_msid); } else { range_tree_remove(mv->mv_allocated, offset, size); } } if (sme->sme_type != SM_ALLOC) { /* * If something is freed in the spacemap, verify that * it is not listed as allocated in the livelist. */ verify_livelist_allocs(mv, txg, offset, size); } return (0); } static int spacemap_check_sm_log_cb(spa_t *spa, space_map_entry_t *sme, uint64_t txg, void *arg) { metaslab_verify_t *mv = arg; uint64_t offset = sme->sme_offset; uint64_t vdev_id = sme->sme_vdev; vdev_t *vd = vdev_lookup_top(spa, vdev_id); /* skip indirect vdevs */ if (!vdev_is_concrete(vd)) return (0); if (vdev_id != mv->mv_vdid) return (0); metaslab_t *ms = vd->vdev_ms[offset >> vd->vdev_ms_shift]; if (ms->ms_id != mv->mv_msid) return (0); if (txg < metaslab_unflushed_txg(ms)) return (0); ASSERT3U(txg, ==, sme->sme_txg); return (metaslab_spacemap_validation_cb(sme, mv)); } static void spacemap_check_sm_log(spa_t *spa, metaslab_verify_t *mv) { iterate_through_spacemap_logs(spa, spacemap_check_sm_log_cb, mv); } static void spacemap_check_ms_sm(space_map_t *sm, metaslab_verify_t *mv) { if (sm == NULL) return; VERIFY0(space_map_iterate(sm, space_map_length(sm), metaslab_spacemap_validation_cb, mv)); } static void iterate_deleted_livelists(spa_t *spa, ll_iter_t func, void *arg); /* * Transfer blocks from sv_leftover tree to the mv_livelist_allocs if * they are part of that metaslab (mv_msid). */ static void mv_populate_livelist_allocs(metaslab_verify_t *mv, sublivelist_verify_t *sv) { zfs_btree_index_t where; sublivelist_verify_block_t *svb; ASSERT3U(zfs_btree_numnodes(&mv->mv_livelist_allocs), ==, 0); for (svb = zfs_btree_first(&sv->sv_leftover, &where); svb != NULL; svb = zfs_btree_next(&sv->sv_leftover, &where, &where)) { if (DVA_GET_VDEV(&svb->svb_dva) != mv->mv_vdid) continue; if (DVA_GET_OFFSET(&svb->svb_dva) < mv->mv_start && (DVA_GET_OFFSET(&svb->svb_dva) + DVA_GET_ASIZE(&svb->svb_dva)) > mv->mv_start) { (void) printf("ERROR: Found block that crosses " "metaslab boundary: <%llu:%llx:%llx>\n", (u_longlong_t)DVA_GET_VDEV(&svb->svb_dva), (u_longlong_t)DVA_GET_OFFSET(&svb->svb_dva), (u_longlong_t)DVA_GET_ASIZE(&svb->svb_dva)); continue; } if (DVA_GET_OFFSET(&svb->svb_dva) < mv->mv_start) continue; if (DVA_GET_OFFSET(&svb->svb_dva) >= mv->mv_end) continue; if ((DVA_GET_OFFSET(&svb->svb_dva) + DVA_GET_ASIZE(&svb->svb_dva)) > mv->mv_end) { (void) printf("ERROR: Found block that crosses " "metaslab boundary: <%llu:%llx:%llx>\n", (u_longlong_t)DVA_GET_VDEV(&svb->svb_dva), (u_longlong_t)DVA_GET_OFFSET(&svb->svb_dva), (u_longlong_t)DVA_GET_ASIZE(&svb->svb_dva)); continue; } zfs_btree_add(&mv->mv_livelist_allocs, svb); } for (svb = zfs_btree_first(&mv->mv_livelist_allocs, &where); svb != NULL; svb = zfs_btree_next(&mv->mv_livelist_allocs, &where, &where)) { zfs_btree_remove(&sv->sv_leftover, svb); } } /* * [Livelist Check] * Iterate through all the sublivelists and: * - report leftover frees (**) * - record leftover ALLOCs together with their TXG [see Cross Check] * * (**) Note: Double ALLOCs are valid in datasets that have dedup * enabled. Similarly double FREEs are allowed as well but * only if they pair up with a corresponding ALLOC entry once * we our done with our sublivelist iteration. * * [Spacemap Check] * for each metaslab: * - iterate over spacemap and then the metaslab's entries in the * spacemap log, then report any double FREEs and ALLOCs (do not * blow up). * * [Cross Check] * After finishing the Livelist Check phase and while being in the * Spacemap Check phase, we find all the recorded leftover ALLOCs * of the livelist check that are part of the metaslab that we are * currently looking at in the Spacemap Check. We report any entries * that are marked as ALLOCs in the livelists but have been actually * freed (and potentially allocated again) after their TXG stamp in * the spacemaps. Also report any ALLOCs from the livelists that * belong to indirect vdevs (e.g. their vdev completed removal). * * Note that this will miss Log Spacemap entries that cancelled each other * out before being flushed to the metaslab, so we are not guaranteed * to match all erroneous ALLOCs. */ static void livelist_metaslab_validate(spa_t *spa) { (void) printf("Verifying deleted livelist entries\n"); sublivelist_verify_t sv; zfs_btree_create(&sv.sv_leftover, livelist_block_compare, sizeof (sublivelist_verify_block_t)); iterate_deleted_livelists(spa, livelist_verify, &sv); (void) printf("Verifying metaslab entries\n"); vdev_t *rvd = spa->spa_root_vdev; for (uint64_t c = 0; c < rvd->vdev_children; c++) { vdev_t *vd = rvd->vdev_child[c]; if (!vdev_is_concrete(vd)) continue; for (uint64_t mid = 0; mid < vd->vdev_ms_count; mid++) { metaslab_t *m = vd->vdev_ms[mid]; (void) fprintf(stderr, "\rverifying concrete vdev %llu, " "metaslab %llu of %llu ...", (longlong_t)vd->vdev_id, (longlong_t)mid, (longlong_t)vd->vdev_ms_count); uint64_t shift, start; range_seg_type_t type = metaslab_calculate_range_tree_type(vd, m, &start, &shift); metaslab_verify_t mv; mv.mv_allocated = range_tree_create(NULL, type, NULL, start, shift); mv.mv_vdid = vd->vdev_id; mv.mv_msid = m->ms_id; mv.mv_start = m->ms_start; mv.mv_end = m->ms_start + m->ms_size; zfs_btree_create(&mv.mv_livelist_allocs, livelist_block_compare, sizeof (sublivelist_verify_block_t)); mv_populate_livelist_allocs(&mv, &sv); spacemap_check_ms_sm(m->ms_sm, &mv); spacemap_check_sm_log(spa, &mv); range_tree_vacate(mv.mv_allocated, NULL, NULL); range_tree_destroy(mv.mv_allocated); zfs_btree_clear(&mv.mv_livelist_allocs); zfs_btree_destroy(&mv.mv_livelist_allocs); } } (void) fprintf(stderr, "\n"); /* * If there are any segments in the leftover tree after we walked * through all the metaslabs in the concrete vdevs then this means * that we have segments in the livelists that belong to indirect * vdevs and are marked as allocated. */ if (zfs_btree_numnodes(&sv.sv_leftover) == 0) { zfs_btree_destroy(&sv.sv_leftover); return; } (void) printf("ERROR: Found livelist blocks marked as allocated " "for indirect vdevs:\n"); zfs_btree_index_t *where = NULL; sublivelist_verify_block_t *svb; while ((svb = zfs_btree_destroy_nodes(&sv.sv_leftover, &where)) != NULL) { int vdev_id = DVA_GET_VDEV(&svb->svb_dva); ASSERT3U(vdev_id, <, rvd->vdev_children); vdev_t *vd = rvd->vdev_child[vdev_id]; ASSERT(!vdev_is_concrete(vd)); (void) printf("<%d:%llx:%llx> TXG %llx\n", vdev_id, (u_longlong_t)DVA_GET_OFFSET(&svb->svb_dva), (u_longlong_t)DVA_GET_ASIZE(&svb->svb_dva), (u_longlong_t)svb->svb_allocated_txg); } (void) printf("\n"); zfs_btree_destroy(&sv.sv_leftover); } /* * These libumem hooks provide a reasonable set of defaults for the allocator's * debugging facilities. */ const char * _umem_debug_init(void) { return ("default,verbose"); /* $UMEM_DEBUG setting */ } const char * _umem_logging_init(void) { return ("fail,contents"); /* $UMEM_LOGGING setting */ } static void usage(void) { (void) fprintf(stderr, "Usage:\t%s [-AbcdDFGhikLMPsvXy] [-e [-V] [-p ...]] " "[-I ]\n" "\t\t[-o =]... [-t ] [-U ] [-x ]\n" "\t\t[[/] [ ...]]\n" "\t%s [-AdiPv] [-e [-V] [-p ...]] [-U ]\n" "\t\t[[/] [ ...]\n" "\t%s [-v] \n" "\t%s -C [-A] [-U ]\n" "\t%s -l [-Aqu] \n" "\t%s -m [-AFLPX] [-e [-V] [-p ...]] [-t ] " "[-U ]\n\t\t [ [ ...]]\n" "\t%s -O \n" "\t%s -r \n" "\t%s -R [-A] [-e [-V] [-p ...]] [-U ]\n" "\t\t ::[:]\n" "\t%s -E [-A] word0:word1:...:word15\n" "\t%s -S [-AP] [-e [-V] [-p ...]] [-U ] " "\n\n", cmdname, cmdname, cmdname, cmdname, cmdname, cmdname, cmdname, cmdname, cmdname, cmdname, cmdname); (void) fprintf(stderr, " Dataset name must include at least one " "separator character '/' or '@'\n"); (void) fprintf(stderr, " If dataset name is specified, only that " "dataset is dumped\n"); (void) fprintf(stderr, " If object numbers or object number " "ranges are specified, only those\n" " objects or ranges are dumped.\n\n"); (void) fprintf(stderr, " Object ranges take the form :[:]\n" " start Starting object number\n" " end Ending object number, or -1 for no upper bound\n" " flags Optional flags to select object types:\n" " A All objects (this is the default)\n" " d ZFS directories\n" " f ZFS files \n" " m SPA space maps\n" " z ZAPs\n" " - Negate effect of next flag\n\n"); (void) fprintf(stderr, " Options to control amount of output:\n"); (void) fprintf(stderr, " -b --block-stats " "block statistics\n"); (void) fprintf(stderr, " -c --checksum " "checksum all metadata (twice for all data) blocks\n"); (void) fprintf(stderr, " -C --config " "config (or cachefile if alone)\n"); (void) fprintf(stderr, " -d --datasets " "dataset(s)\n"); (void) fprintf(stderr, " -D --dedup-stats " "dedup statistics\n"); (void) fprintf(stderr, " -E --embedded-block-pointer=INTEGER\n" " decode and display block " "from an embedded block pointer\n"); (void) fprintf(stderr, " -h --history " "pool history\n"); (void) fprintf(stderr, " -i --intent-logs " "intent logs\n"); (void) fprintf(stderr, " -l --label " "read label contents\n"); (void) fprintf(stderr, " -k --checkpointed-state " "examine the checkpointed state of the pool\n"); (void) fprintf(stderr, " -L --disable-leak-tracking " "disable leak tracking (do not load spacemaps)\n"); (void) fprintf(stderr, " -m --metaslabs " "metaslabs\n"); (void) fprintf(stderr, " -M --metaslab-groups " "metaslab groups\n"); (void) fprintf(stderr, " -O --object-lookups " "perform object lookups by path\n"); (void) fprintf(stderr, " -r --copy-object " "copy an object by path to file\n"); (void) fprintf(stderr, " -R --read-block " "read and display block from a device\n"); (void) fprintf(stderr, " -s --io-stats " "report stats on zdb's I/O\n"); (void) fprintf(stderr, " -S --simulate-dedup " "simulate dedup to measure effect\n"); (void) fprintf(stderr, " -v --verbose " "verbose (applies to all others)\n"); (void) fprintf(stderr, " -y --livelist " "perform livelist and metaslab validation on any livelists being " "deleted\n\n"); (void) fprintf(stderr, " Below options are intended for use " "with other options:\n"); (void) fprintf(stderr, " -A --ignore-assertions " "ignore assertions (-A), enable panic recovery (-AA) or both " "(-AAA)\n"); (void) fprintf(stderr, " -e --exported " "pool is exported/destroyed/has altroot/not in a cachefile\n"); (void) fprintf(stderr, " -F --automatic-rewind " "attempt automatic rewind within safe range of transaction " "groups\n"); (void) fprintf(stderr, " -G --dump-debug-msg " "dump zfs_dbgmsg buffer before exiting\n"); (void) fprintf(stderr, " -I --inflight=INTEGER " "specify the maximum number of checksumming I/Os " "[default is 200]\n"); (void) fprintf(stderr, " -o --option=\"OPTION=INTEGER\" " "set global variable to an unsigned 32-bit integer\n"); (void) fprintf(stderr, " -p --path==PATH " "use one or more with -e to specify path to vdev dir\n"); (void) fprintf(stderr, " -P --parseable " "print numbers in parseable form\n"); (void) fprintf(stderr, " -q --skip-label " "don't print label contents\n"); (void) fprintf(stderr, " -t --txg=INTEGER " "highest txg to use when searching for uberblocks\n"); (void) fprintf(stderr, " -u --uberblock " "uberblock\n"); (void) fprintf(stderr, " -U --cachefile=PATH " "use alternate cachefile\n"); (void) fprintf(stderr, " -V --verbatim " "do verbatim import\n"); (void) fprintf(stderr, " -x --dump-blocks=PATH " "dump all read blocks into specified directory\n"); (void) fprintf(stderr, " -X --extreme-rewind " "attempt extreme rewind (does not work with dataset)\n"); (void) fprintf(stderr, " -Y --all-reconstruction " "attempt all reconstruction combinations for split blocks\n"); (void) fprintf(stderr, " -Z --zstd-headers " "show ZSTD headers \n"); (void) fprintf(stderr, "Specify an option more than once (e.g. -bb) " "to make only that option verbose\n"); (void) fprintf(stderr, "Default is to dump everything non-verbosely\n"); exit(1); } static void dump_debug_buffer(void) { if (dump_opt['G']) { (void) printf("\n"); (void) fflush(stdout); zfs_dbgmsg_print("zdb"); } } /* * Called for usage errors that are discovered after a call to spa_open(), * dmu_bonus_hold(), or pool_match(). abort() is called for other errors. */ static void fatal(const char *fmt, ...) { va_list ap; va_start(ap, fmt); (void) fprintf(stderr, "%s: ", cmdname); (void) vfprintf(stderr, fmt, ap); va_end(ap); (void) fprintf(stderr, "\n"); dump_debug_buffer(); exit(1); } static void dump_packed_nvlist(objset_t *os, uint64_t object, void *data, size_t size) { (void) size; nvlist_t *nv; size_t nvsize = *(uint64_t *)data; char *packed = umem_alloc(nvsize, UMEM_NOFAIL); VERIFY(0 == dmu_read(os, object, 0, nvsize, packed, DMU_READ_PREFETCH)); VERIFY(nvlist_unpack(packed, nvsize, &nv, 0) == 0); umem_free(packed, nvsize); dump_nvlist(nv, 8); nvlist_free(nv); } static void dump_history_offsets(objset_t *os, uint64_t object, void *data, size_t size) { (void) os, (void) object, (void) size; spa_history_phys_t *shp = data; if (shp == NULL) return; (void) printf("\t\tpool_create_len = %llu\n", (u_longlong_t)shp->sh_pool_create_len); (void) printf("\t\tphys_max_off = %llu\n", (u_longlong_t)shp->sh_phys_max_off); (void) printf("\t\tbof = %llu\n", (u_longlong_t)shp->sh_bof); (void) printf("\t\teof = %llu\n", (u_longlong_t)shp->sh_eof); (void) printf("\t\trecords_lost = %llu\n", (u_longlong_t)shp->sh_records_lost); } static void zdb_nicenum(uint64_t num, char *buf, size_t buflen) { if (dump_opt['P']) (void) snprintf(buf, buflen, "%llu", (longlong_t)num); else nicenum(num, buf, sizeof (buf)); } static const char histo_stars[] = "****************************************"; static const uint64_t histo_width = sizeof (histo_stars) - 1; static void dump_histogram(const uint64_t *histo, int size, int offset) { int i; int minidx = size - 1; int maxidx = 0; uint64_t max = 0; for (i = 0; i < size; i++) { if (histo[i] > max) max = histo[i]; if (histo[i] > 0 && i > maxidx) maxidx = i; if (histo[i] > 0 && i < minidx) minidx = i; } if (max < histo_width) max = histo_width; for (i = minidx; i <= maxidx; i++) { (void) printf("\t\t\t%3u: %6llu %s\n", i + offset, (u_longlong_t)histo[i], &histo_stars[(max - histo[i]) * histo_width / max]); } } static void dump_zap_stats(objset_t *os, uint64_t object) { int error; zap_stats_t zs; error = zap_get_stats(os, object, &zs); if (error) return; if (zs.zs_ptrtbl_len == 0) { ASSERT(zs.zs_num_blocks == 1); (void) printf("\tmicrozap: %llu bytes, %llu entries\n", (u_longlong_t)zs.zs_blocksize, (u_longlong_t)zs.zs_num_entries); return; } (void) printf("\tFat ZAP stats:\n"); (void) printf("\t\tPointer table:\n"); (void) printf("\t\t\t%llu elements\n", (u_longlong_t)zs.zs_ptrtbl_len); (void) printf("\t\t\tzt_blk: %llu\n", (u_longlong_t)zs.zs_ptrtbl_zt_blk); (void) printf("\t\t\tzt_numblks: %llu\n", (u_longlong_t)zs.zs_ptrtbl_zt_numblks); (void) printf("\t\t\tzt_shift: %llu\n", (u_longlong_t)zs.zs_ptrtbl_zt_shift); (void) printf("\t\t\tzt_blks_copied: %llu\n", (u_longlong_t)zs.zs_ptrtbl_blks_copied); (void) printf("\t\t\tzt_nextblk: %llu\n", (u_longlong_t)zs.zs_ptrtbl_nextblk); (void) printf("\t\tZAP entries: %llu\n", (u_longlong_t)zs.zs_num_entries); (void) printf("\t\tLeaf blocks: %llu\n", (u_longlong_t)zs.zs_num_leafs); (void) printf("\t\tTotal blocks: %llu\n", (u_longlong_t)zs.zs_num_blocks); (void) printf("\t\tzap_block_type: 0x%llx\n", (u_longlong_t)zs.zs_block_type); (void) printf("\t\tzap_magic: 0x%llx\n", (u_longlong_t)zs.zs_magic); (void) printf("\t\tzap_salt: 0x%llx\n", (u_longlong_t)zs.zs_salt); (void) printf("\t\tLeafs with 2^n pointers:\n"); dump_histogram(zs.zs_leafs_with_2n_pointers, ZAP_HISTOGRAM_SIZE, 0); (void) printf("\t\tBlocks with n*5 entries:\n"); dump_histogram(zs.zs_blocks_with_n5_entries, ZAP_HISTOGRAM_SIZE, 0); (void) printf("\t\tBlocks n/10 full:\n"); dump_histogram(zs.zs_blocks_n_tenths_full, ZAP_HISTOGRAM_SIZE, 0); (void) printf("\t\tEntries with n chunks:\n"); dump_histogram(zs.zs_entries_using_n_chunks, ZAP_HISTOGRAM_SIZE, 0); (void) printf("\t\tBuckets with n entries:\n"); dump_histogram(zs.zs_buckets_with_n_entries, ZAP_HISTOGRAM_SIZE, 0); } static void dump_none(objset_t *os, uint64_t object, void *data, size_t size) { (void) os, (void) object, (void) data, (void) size; } static void dump_unknown(objset_t *os, uint64_t object, void *data, size_t size) { (void) os, (void) object, (void) data, (void) size; (void) printf("\tUNKNOWN OBJECT TYPE\n"); } static void dump_uint8(objset_t *os, uint64_t object, void *data, size_t size) { (void) os, (void) object, (void) data, (void) size; } static void dump_uint64(objset_t *os, uint64_t object, void *data, size_t size) { uint64_t *arr; uint64_t oursize; if (dump_opt['d'] < 6) return; if (data == NULL) { dmu_object_info_t doi; VERIFY0(dmu_object_info(os, object, &doi)); size = doi.doi_max_offset; /* * We cap the size at 1 mebibyte here to prevent * allocation failures and nigh-infinite printing if the * object is extremely large. */ oursize = MIN(size, 1 << 20); arr = kmem_alloc(oursize, KM_SLEEP); int err = dmu_read(os, object, 0, oursize, arr, 0); if (err != 0) { (void) printf("got error %u from dmu_read\n", err); kmem_free(arr, oursize); return; } } else { /* * Even though the allocation is already done in this code path, * we still cap the size to prevent excessive printing. */ oursize = MIN(size, 1 << 20); arr = data; } if (size == 0) { (void) printf("\t\t[]\n"); return; } (void) printf("\t\t[%0llx", (u_longlong_t)arr[0]); for (size_t i = 1; i * sizeof (uint64_t) < oursize; i++) { if (i % 4 != 0) (void) printf(", %0llx", (u_longlong_t)arr[i]); else (void) printf(",\n\t\t%0llx", (u_longlong_t)arr[i]); } if (oursize != size) (void) printf(", ... "); (void) printf("]\n"); if (data == NULL) kmem_free(arr, oursize); } static void dump_zap(objset_t *os, uint64_t object, void *data, size_t size) { (void) data, (void) size; zap_cursor_t zc; zap_attribute_t attr; void *prop; unsigned i; dump_zap_stats(os, object); (void) printf("\n"); for (zap_cursor_init(&zc, os, object); zap_cursor_retrieve(&zc, &attr) == 0; zap_cursor_advance(&zc)) { (void) printf("\t\t%s = ", attr.za_name); if (attr.za_num_integers == 0) { (void) printf("\n"); continue; } prop = umem_zalloc(attr.za_num_integers * attr.za_integer_length, UMEM_NOFAIL); (void) zap_lookup(os, object, attr.za_name, attr.za_integer_length, attr.za_num_integers, prop); if (attr.za_integer_length == 1) { if (strcmp(attr.za_name, DSL_CRYPTO_KEY_MASTER_KEY) == 0 || strcmp(attr.za_name, DSL_CRYPTO_KEY_HMAC_KEY) == 0 || strcmp(attr.za_name, DSL_CRYPTO_KEY_IV) == 0 || strcmp(attr.za_name, DSL_CRYPTO_KEY_MAC) == 0 || strcmp(attr.za_name, DMU_POOL_CHECKSUM_SALT) == 0) { uint8_t *u8 = prop; for (i = 0; i < attr.za_num_integers; i++) { (void) printf("%02x", u8[i]); } } else { (void) printf("%s", (char *)prop); } } else { for (i = 0; i < attr.za_num_integers; i++) { switch (attr.za_integer_length) { case 2: (void) printf("%u ", ((uint16_t *)prop)[i]); break; case 4: (void) printf("%u ", ((uint32_t *)prop)[i]); break; case 8: (void) printf("%lld ", (u_longlong_t)((int64_t *)prop)[i]); break; } } } (void) printf("\n"); umem_free(prop, attr.za_num_integers * attr.za_integer_length); } zap_cursor_fini(&zc); } static void dump_bpobj(objset_t *os, uint64_t object, void *data, size_t size) { bpobj_phys_t *bpop = data; uint64_t i; char bytes[32], comp[32], uncomp[32]; /* make sure the output won't get truncated */ _Static_assert(sizeof (bytes) >= NN_NUMBUF_SZ, "bytes truncated"); _Static_assert(sizeof (comp) >= NN_NUMBUF_SZ, "comp truncated"); _Static_assert(sizeof (uncomp) >= NN_NUMBUF_SZ, "uncomp truncated"); if (bpop == NULL) return; zdb_nicenum(bpop->bpo_bytes, bytes, sizeof (bytes)); zdb_nicenum(bpop->bpo_comp, comp, sizeof (comp)); zdb_nicenum(bpop->bpo_uncomp, uncomp, sizeof (uncomp)); (void) printf("\t\tnum_blkptrs = %llu\n", (u_longlong_t)bpop->bpo_num_blkptrs); (void) printf("\t\tbytes = %s\n", bytes); if (size >= BPOBJ_SIZE_V1) { (void) printf("\t\tcomp = %s\n", comp); (void) printf("\t\tuncomp = %s\n", uncomp); } if (size >= BPOBJ_SIZE_V2) { (void) printf("\t\tsubobjs = %llu\n", (u_longlong_t)bpop->bpo_subobjs); (void) printf("\t\tnum_subobjs = %llu\n", (u_longlong_t)bpop->bpo_num_subobjs); } if (size >= sizeof (*bpop)) { (void) printf("\t\tnum_freed = %llu\n", (u_longlong_t)bpop->bpo_num_freed); } if (dump_opt['d'] < 5) return; for (i = 0; i < bpop->bpo_num_blkptrs; i++) { char blkbuf[BP_SPRINTF_LEN]; blkptr_t bp; int err = dmu_read(os, object, i * sizeof (bp), sizeof (bp), &bp, 0); if (err != 0) { (void) printf("got error %u from dmu_read\n", err); break; } snprintf_blkptr_compact(blkbuf, sizeof (blkbuf), &bp, BP_GET_FREE(&bp)); (void) printf("\t%s\n", blkbuf); } } static void dump_bpobj_subobjs(objset_t *os, uint64_t object, void *data, size_t size) { (void) data, (void) size; dmu_object_info_t doi; int64_t i; VERIFY0(dmu_object_info(os, object, &doi)); uint64_t *subobjs = kmem_alloc(doi.doi_max_offset, KM_SLEEP); int err = dmu_read(os, object, 0, doi.doi_max_offset, subobjs, 0); if (err != 0) { (void) printf("got error %u from dmu_read\n", err); kmem_free(subobjs, doi.doi_max_offset); return; } int64_t last_nonzero = -1; for (i = 0; i < doi.doi_max_offset / 8; i++) { if (subobjs[i] != 0) last_nonzero = i; } for (i = 0; i <= last_nonzero; i++) { (void) printf("\t%llu\n", (u_longlong_t)subobjs[i]); } kmem_free(subobjs, doi.doi_max_offset); } static void dump_ddt_zap(objset_t *os, uint64_t object, void *data, size_t size) { (void) data, (void) size; dump_zap_stats(os, object); /* contents are printed elsewhere, properly decoded */ } static void dump_sa_attrs(objset_t *os, uint64_t object, void *data, size_t size) { (void) data, (void) size; zap_cursor_t zc; zap_attribute_t attr; dump_zap_stats(os, object); (void) printf("\n"); for (zap_cursor_init(&zc, os, object); zap_cursor_retrieve(&zc, &attr) == 0; zap_cursor_advance(&zc)) { (void) printf("\t\t%s = ", attr.za_name); if (attr.za_num_integers == 0) { (void) printf("\n"); continue; } (void) printf(" %llx : [%d:%d:%d]\n", (u_longlong_t)attr.za_first_integer, (int)ATTR_LENGTH(attr.za_first_integer), (int)ATTR_BSWAP(attr.za_first_integer), (int)ATTR_NUM(attr.za_first_integer)); } zap_cursor_fini(&zc); } static void dump_sa_layouts(objset_t *os, uint64_t object, void *data, size_t size) { (void) data, (void) size; zap_cursor_t zc; zap_attribute_t attr; uint16_t *layout_attrs; unsigned i; dump_zap_stats(os, object); (void) printf("\n"); for (zap_cursor_init(&zc, os, object); zap_cursor_retrieve(&zc, &attr) == 0; zap_cursor_advance(&zc)) { (void) printf("\t\t%s = [", attr.za_name); if (attr.za_num_integers == 0) { (void) printf("\n"); continue; } VERIFY(attr.za_integer_length == 2); layout_attrs = umem_zalloc(attr.za_num_integers * attr.za_integer_length, UMEM_NOFAIL); VERIFY(zap_lookup(os, object, attr.za_name, attr.za_integer_length, attr.za_num_integers, layout_attrs) == 0); for (i = 0; i != attr.za_num_integers; i++) (void) printf(" %d ", (int)layout_attrs[i]); (void) printf("]\n"); umem_free(layout_attrs, attr.za_num_integers * attr.za_integer_length); } zap_cursor_fini(&zc); } static void dump_zpldir(objset_t *os, uint64_t object, void *data, size_t size) { (void) data, (void) size; zap_cursor_t zc; zap_attribute_t attr; const char *typenames[] = { /* 0 */ "not specified", /* 1 */ "FIFO", /* 2 */ "Character Device", /* 3 */ "3 (invalid)", /* 4 */ "Directory", /* 5 */ "5 (invalid)", /* 6 */ "Block Device", /* 7 */ "7 (invalid)", /* 8 */ "Regular File", /* 9 */ "9 (invalid)", /* 10 */ "Symbolic Link", /* 11 */ "11 (invalid)", /* 12 */ "Socket", /* 13 */ "Door", /* 14 */ "Event Port", /* 15 */ "15 (invalid)", }; dump_zap_stats(os, object); (void) printf("\n"); for (zap_cursor_init(&zc, os, object); zap_cursor_retrieve(&zc, &attr) == 0; zap_cursor_advance(&zc)) { (void) printf("\t\t%s = %lld (type: %s)\n", attr.za_name, ZFS_DIRENT_OBJ(attr.za_first_integer), typenames[ZFS_DIRENT_TYPE(attr.za_first_integer)]); } zap_cursor_fini(&zc); } static int get_dtl_refcount(vdev_t *vd) { int refcount = 0; if (vd->vdev_ops->vdev_op_leaf) { space_map_t *sm = vd->vdev_dtl_sm; if (sm != NULL && sm->sm_dbuf->db_size == sizeof (space_map_phys_t)) return (1); return (0); } for (unsigned c = 0; c < vd->vdev_children; c++) refcount += get_dtl_refcount(vd->vdev_child[c]); return (refcount); } static int get_metaslab_refcount(vdev_t *vd) { int refcount = 0; if (vd->vdev_top == vd) { for (uint64_t m = 0; m < vd->vdev_ms_count; m++) { space_map_t *sm = vd->vdev_ms[m]->ms_sm; if (sm != NULL && sm->sm_dbuf->db_size == sizeof (space_map_phys_t)) refcount++; } } for (unsigned c = 0; c < vd->vdev_children; c++) refcount += get_metaslab_refcount(vd->vdev_child[c]); return (refcount); } static int get_obsolete_refcount(vdev_t *vd) { uint64_t obsolete_sm_object; int refcount = 0; VERIFY0(vdev_obsolete_sm_object(vd, &obsolete_sm_object)); if (vd->vdev_top == vd && obsolete_sm_object != 0) { dmu_object_info_t doi; VERIFY0(dmu_object_info(vd->vdev_spa->spa_meta_objset, obsolete_sm_object, &doi)); if (doi.doi_bonus_size == sizeof (space_map_phys_t)) { refcount++; } } else { ASSERT3P(vd->vdev_obsolete_sm, ==, NULL); ASSERT3U(obsolete_sm_object, ==, 0); } for (unsigned c = 0; c < vd->vdev_children; c++) { refcount += get_obsolete_refcount(vd->vdev_child[c]); } return (refcount); } static int get_prev_obsolete_spacemap_refcount(spa_t *spa) { uint64_t prev_obj = spa->spa_condensing_indirect_phys.scip_prev_obsolete_sm_object; if (prev_obj != 0) { dmu_object_info_t doi; VERIFY0(dmu_object_info(spa->spa_meta_objset, prev_obj, &doi)); if (doi.doi_bonus_size == sizeof (space_map_phys_t)) { return (1); } } return (0); } static int get_checkpoint_refcount(vdev_t *vd) { int refcount = 0; if (vd->vdev_top == vd && vd->vdev_top_zap != 0 && zap_contains(spa_meta_objset(vd->vdev_spa), vd->vdev_top_zap, VDEV_TOP_ZAP_POOL_CHECKPOINT_SM) == 0) refcount++; for (uint64_t c = 0; c < vd->vdev_children; c++) refcount += get_checkpoint_refcount(vd->vdev_child[c]); return (refcount); } static int get_log_spacemap_refcount(spa_t *spa) { return (avl_numnodes(&spa->spa_sm_logs_by_txg)); } static int verify_spacemap_refcounts(spa_t *spa) { uint64_t expected_refcount = 0; uint64_t actual_refcount; (void) feature_get_refcount(spa, &spa_feature_table[SPA_FEATURE_SPACEMAP_HISTOGRAM], &expected_refcount); actual_refcount = get_dtl_refcount(spa->spa_root_vdev); actual_refcount += get_metaslab_refcount(spa->spa_root_vdev); actual_refcount += get_obsolete_refcount(spa->spa_root_vdev); actual_refcount += get_prev_obsolete_spacemap_refcount(spa); actual_refcount += get_checkpoint_refcount(spa->spa_root_vdev); actual_refcount += get_log_spacemap_refcount(spa); if (expected_refcount != actual_refcount) { (void) printf("space map refcount mismatch: expected %lld != " "actual %lld\n", (longlong_t)expected_refcount, (longlong_t)actual_refcount); return (2); } return (0); } static void dump_spacemap(objset_t *os, space_map_t *sm) { const char *ddata[] = { "ALLOC", "FREE", "CONDENSE", "INVALID", "INVALID", "INVALID", "INVALID", "INVALID" }; if (sm == NULL) return; (void) printf("space map object %llu:\n", (longlong_t)sm->sm_object); (void) printf(" smp_length = 0x%llx\n", (longlong_t)sm->sm_phys->smp_length); (void) printf(" smp_alloc = 0x%llx\n", (longlong_t)sm->sm_phys->smp_alloc); if (dump_opt['d'] < 6 && dump_opt['m'] < 4) return; /* * Print out the freelist entries in both encoded and decoded form. */ uint8_t mapshift = sm->sm_shift; int64_t alloc = 0; uint64_t word, entry_id = 0; for (uint64_t offset = 0; offset < space_map_length(sm); offset += sizeof (word)) { VERIFY0(dmu_read(os, space_map_object(sm), offset, sizeof (word), &word, DMU_READ_PREFETCH)); if (sm_entry_is_debug(word)) { uint64_t de_txg = SM_DEBUG_TXG_DECODE(word); uint64_t de_sync_pass = SM_DEBUG_SYNCPASS_DECODE(word); if (de_txg == 0) { (void) printf( "\t [%6llu] PADDING\n", (u_longlong_t)entry_id); } else { (void) printf( "\t [%6llu] %s: txg %llu pass %llu\n", (u_longlong_t)entry_id, ddata[SM_DEBUG_ACTION_DECODE(word)], (u_longlong_t)de_txg, (u_longlong_t)de_sync_pass); } entry_id++; continue; } uint8_t words; char entry_type; uint64_t entry_off, entry_run, entry_vdev = SM_NO_VDEVID; if (sm_entry_is_single_word(word)) { entry_type = (SM_TYPE_DECODE(word) == SM_ALLOC) ? 'A' : 'F'; entry_off = (SM_OFFSET_DECODE(word) << mapshift) + sm->sm_start; entry_run = SM_RUN_DECODE(word) << mapshift; words = 1; } else { /* it is a two-word entry so we read another word */ ASSERT(sm_entry_is_double_word(word)); uint64_t extra_word; offset += sizeof (extra_word); VERIFY0(dmu_read(os, space_map_object(sm), offset, sizeof (extra_word), &extra_word, DMU_READ_PREFETCH)); ASSERT3U(offset, <=, space_map_length(sm)); entry_run = SM2_RUN_DECODE(word) << mapshift; entry_vdev = SM2_VDEV_DECODE(word); entry_type = (SM2_TYPE_DECODE(extra_word) == SM_ALLOC) ? 'A' : 'F'; entry_off = (SM2_OFFSET_DECODE(extra_word) << mapshift) + sm->sm_start; words = 2; } (void) printf("\t [%6llu] %c range:" " %010llx-%010llx size: %06llx vdev: %06llu words: %u\n", (u_longlong_t)entry_id, entry_type, (u_longlong_t)entry_off, (u_longlong_t)(entry_off + entry_run), (u_longlong_t)entry_run, (u_longlong_t)entry_vdev, words); if (entry_type == 'A') alloc += entry_run; else alloc -= entry_run; entry_id++; } if (alloc != space_map_allocated(sm)) { (void) printf("space_map_object alloc (%lld) INCONSISTENT " "with space map summary (%lld)\n", (longlong_t)space_map_allocated(sm), (longlong_t)alloc); } } static void dump_metaslab_stats(metaslab_t *msp) { char maxbuf[32]; range_tree_t *rt = msp->ms_allocatable; zfs_btree_t *t = &msp->ms_allocatable_by_size; int free_pct = range_tree_space(rt) * 100 / msp->ms_size; /* max sure nicenum has enough space */ _Static_assert(sizeof (maxbuf) >= NN_NUMBUF_SZ, "maxbuf truncated"); zdb_nicenum(metaslab_largest_allocatable(msp), maxbuf, sizeof (maxbuf)); (void) printf("\t %25s %10lu %7s %6s %4s %4d%%\n", "segments", zfs_btree_numnodes(t), "maxsize", maxbuf, "freepct", free_pct); (void) printf("\tIn-memory histogram:\n"); dump_histogram(rt->rt_histogram, RANGE_TREE_HISTOGRAM_SIZE, 0); } static void dump_metaslab(metaslab_t *msp) { vdev_t *vd = msp->ms_group->mg_vd; spa_t *spa = vd->vdev_spa; space_map_t *sm = msp->ms_sm; char freebuf[32]; zdb_nicenum(msp->ms_size - space_map_allocated(sm), freebuf, sizeof (freebuf)); (void) printf( "\tmetaslab %6llu offset %12llx spacemap %6llu free %5s\n", (u_longlong_t)msp->ms_id, (u_longlong_t)msp->ms_start, (u_longlong_t)space_map_object(sm), freebuf); if (dump_opt['m'] > 2 && !dump_opt['L']) { mutex_enter(&msp->ms_lock); VERIFY0(metaslab_load(msp)); range_tree_stat_verify(msp->ms_allocatable); dump_metaslab_stats(msp); metaslab_unload(msp); mutex_exit(&msp->ms_lock); } if (dump_opt['m'] > 1 && sm != NULL && spa_feature_is_active(spa, SPA_FEATURE_SPACEMAP_HISTOGRAM)) { /* * The space map histogram represents free space in chunks * of sm_shift (i.e. bucket 0 refers to 2^sm_shift). */ (void) printf("\tOn-disk histogram:\t\tfragmentation %llu\n", (u_longlong_t)msp->ms_fragmentation); dump_histogram(sm->sm_phys->smp_histogram, SPACE_MAP_HISTOGRAM_SIZE, sm->sm_shift); } if (vd->vdev_ops == &vdev_draid_ops) ASSERT3U(msp->ms_size, <=, 1ULL << vd->vdev_ms_shift); else ASSERT3U(msp->ms_size, ==, 1ULL << vd->vdev_ms_shift); dump_spacemap(spa->spa_meta_objset, msp->ms_sm); if (spa_feature_is_active(spa, SPA_FEATURE_LOG_SPACEMAP)) { (void) printf("\tFlush data:\n\tunflushed txg=%llu\n\n", (u_longlong_t)metaslab_unflushed_txg(msp)); } } static void print_vdev_metaslab_header(vdev_t *vd) { vdev_alloc_bias_t alloc_bias = vd->vdev_alloc_bias; const char *bias_str = ""; if (alloc_bias == VDEV_BIAS_LOG || vd->vdev_islog) { bias_str = VDEV_ALLOC_BIAS_LOG; } else if (alloc_bias == VDEV_BIAS_SPECIAL) { bias_str = VDEV_ALLOC_BIAS_SPECIAL; } else if (alloc_bias == VDEV_BIAS_DEDUP) { bias_str = VDEV_ALLOC_BIAS_DEDUP; } uint64_t ms_flush_data_obj = 0; if (vd->vdev_top_zap != 0) { int error = zap_lookup(spa_meta_objset(vd->vdev_spa), vd->vdev_top_zap, VDEV_TOP_ZAP_MS_UNFLUSHED_PHYS_TXGS, sizeof (uint64_t), 1, &ms_flush_data_obj); if (error != ENOENT) { ASSERT0(error); } } (void) printf("\tvdev %10llu %s", (u_longlong_t)vd->vdev_id, bias_str); if (ms_flush_data_obj != 0) { (void) printf(" ms_unflushed_phys object %llu", (u_longlong_t)ms_flush_data_obj); } (void) printf("\n\t%-10s%5llu %-19s %-15s %-12s\n", "metaslabs", (u_longlong_t)vd->vdev_ms_count, "offset", "spacemap", "free"); (void) printf("\t%15s %19s %15s %12s\n", "---------------", "-------------------", "---------------", "------------"); } static void dump_metaslab_groups(spa_t *spa, boolean_t show_special) { vdev_t *rvd = spa->spa_root_vdev; metaslab_class_t *mc = spa_normal_class(spa); metaslab_class_t *smc = spa_special_class(spa); uint64_t fragmentation; metaslab_class_histogram_verify(mc); for (unsigned c = 0; c < rvd->vdev_children; c++) { vdev_t *tvd = rvd->vdev_child[c]; metaslab_group_t *mg = tvd->vdev_mg; if (mg == NULL || (mg->mg_class != mc && (!show_special || mg->mg_class != smc))) continue; metaslab_group_histogram_verify(mg); mg->mg_fragmentation = metaslab_group_fragmentation(mg); (void) printf("\tvdev %10llu\t\tmetaslabs%5llu\t\t" "fragmentation", (u_longlong_t)tvd->vdev_id, (u_longlong_t)tvd->vdev_ms_count); if (mg->mg_fragmentation == ZFS_FRAG_INVALID) { (void) printf("%3s\n", "-"); } else { (void) printf("%3llu%%\n", (u_longlong_t)mg->mg_fragmentation); } dump_histogram(mg->mg_histogram, RANGE_TREE_HISTOGRAM_SIZE, 0); } (void) printf("\tpool %s\tfragmentation", spa_name(spa)); fragmentation = metaslab_class_fragmentation(mc); if (fragmentation == ZFS_FRAG_INVALID) (void) printf("\t%3s\n", "-"); else (void) printf("\t%3llu%%\n", (u_longlong_t)fragmentation); dump_histogram(mc->mc_histogram, RANGE_TREE_HISTOGRAM_SIZE, 0); } static void print_vdev_indirect(vdev_t *vd) { vdev_indirect_config_t *vic = &vd->vdev_indirect_config; vdev_indirect_mapping_t *vim = vd->vdev_indirect_mapping; vdev_indirect_births_t *vib = vd->vdev_indirect_births; if (vim == NULL) { ASSERT3P(vib, ==, NULL); return; } ASSERT3U(vdev_indirect_mapping_object(vim), ==, vic->vic_mapping_object); ASSERT3U(vdev_indirect_births_object(vib), ==, vic->vic_births_object); (void) printf("indirect births obj %llu:\n", (longlong_t)vic->vic_births_object); (void) printf(" vib_count = %llu\n", (longlong_t)vdev_indirect_births_count(vib)); for (uint64_t i = 0; i < vdev_indirect_births_count(vib); i++) { vdev_indirect_birth_entry_phys_t *cur_vibe = &vib->vib_entries[i]; (void) printf("\toffset %llx -> txg %llu\n", (longlong_t)cur_vibe->vibe_offset, (longlong_t)cur_vibe->vibe_phys_birth_txg); } (void) printf("\n"); (void) printf("indirect mapping obj %llu:\n", (longlong_t)vic->vic_mapping_object); (void) printf(" vim_max_offset = 0x%llx\n", (longlong_t)vdev_indirect_mapping_max_offset(vim)); (void) printf(" vim_bytes_mapped = 0x%llx\n", (longlong_t)vdev_indirect_mapping_bytes_mapped(vim)); (void) printf(" vim_count = %llu\n", (longlong_t)vdev_indirect_mapping_num_entries(vim)); if (dump_opt['d'] <= 5 && dump_opt['m'] <= 3) return; uint32_t *counts = vdev_indirect_mapping_load_obsolete_counts(vim); for (uint64_t i = 0; i < vdev_indirect_mapping_num_entries(vim); i++) { vdev_indirect_mapping_entry_phys_t *vimep = &vim->vim_entries[i]; (void) printf("\t<%llx:%llx:%llx> -> " "<%llx:%llx:%llx> (%x obsolete)\n", (longlong_t)vd->vdev_id, (longlong_t)DVA_MAPPING_GET_SRC_OFFSET(vimep), (longlong_t)DVA_GET_ASIZE(&vimep->vimep_dst), (longlong_t)DVA_GET_VDEV(&vimep->vimep_dst), (longlong_t)DVA_GET_OFFSET(&vimep->vimep_dst), (longlong_t)DVA_GET_ASIZE(&vimep->vimep_dst), counts[i]); } (void) printf("\n"); uint64_t obsolete_sm_object; VERIFY0(vdev_obsolete_sm_object(vd, &obsolete_sm_object)); if (obsolete_sm_object != 0) { objset_t *mos = vd->vdev_spa->spa_meta_objset; (void) printf("obsolete space map object %llu:\n", (u_longlong_t)obsolete_sm_object); ASSERT(vd->vdev_obsolete_sm != NULL); ASSERT3U(space_map_object(vd->vdev_obsolete_sm), ==, obsolete_sm_object); dump_spacemap(mos, vd->vdev_obsolete_sm); (void) printf("\n"); } } static void dump_metaslabs(spa_t *spa) { vdev_t *vd, *rvd = spa->spa_root_vdev; uint64_t m, c = 0, children = rvd->vdev_children; (void) printf("\nMetaslabs:\n"); if (!dump_opt['d'] && zopt_metaslab_args > 0) { c = zopt_metaslab[0]; if (c >= children) (void) fatal("bad vdev id: %llu", (u_longlong_t)c); if (zopt_metaslab_args > 1) { vd = rvd->vdev_child[c]; print_vdev_metaslab_header(vd); for (m = 1; m < zopt_metaslab_args; m++) { if (zopt_metaslab[m] < vd->vdev_ms_count) dump_metaslab( vd->vdev_ms[zopt_metaslab[m]]); else (void) fprintf(stderr, "bad metaslab " "number %llu\n", (u_longlong_t)zopt_metaslab[m]); } (void) printf("\n"); return; } children = c + 1; } for (; c < children; c++) { vd = rvd->vdev_child[c]; print_vdev_metaslab_header(vd); print_vdev_indirect(vd); for (m = 0; m < vd->vdev_ms_count; m++) dump_metaslab(vd->vdev_ms[m]); (void) printf("\n"); } } static void dump_log_spacemaps(spa_t *spa) { if (!spa_feature_is_active(spa, SPA_FEATURE_LOG_SPACEMAP)) return; (void) printf("\nLog Space Maps in Pool:\n"); for (spa_log_sm_t *sls = avl_first(&spa->spa_sm_logs_by_txg); sls; sls = AVL_NEXT(&spa->spa_sm_logs_by_txg, sls)) { space_map_t *sm = NULL; VERIFY0(space_map_open(&sm, spa_meta_objset(spa), sls->sls_sm_obj, 0, UINT64_MAX, SPA_MINBLOCKSHIFT)); (void) printf("Log Spacemap object %llu txg %llu\n", (u_longlong_t)sls->sls_sm_obj, (u_longlong_t)sls->sls_txg); dump_spacemap(spa->spa_meta_objset, sm); space_map_close(sm); } (void) printf("\n"); } static void dump_dde(const ddt_t *ddt, const ddt_entry_t *dde, uint64_t index) { const ddt_phys_t *ddp = dde->dde_phys; const ddt_key_t *ddk = &dde->dde_key; const char *types[4] = { "ditto", "single", "double", "triple" }; char blkbuf[BP_SPRINTF_LEN]; blkptr_t blk; int p; for (p = 0; p < DDT_PHYS_TYPES; p++, ddp++) { if (ddp->ddp_phys_birth == 0) continue; ddt_bp_create(ddt->ddt_checksum, ddk, ddp, &blk); snprintf_blkptr(blkbuf, sizeof (blkbuf), &blk); (void) printf("index %llx refcnt %llu %s %s\n", (u_longlong_t)index, (u_longlong_t)ddp->ddp_refcnt, types[p], blkbuf); } } static void dump_dedup_ratio(const ddt_stat_t *dds) { double rL, rP, rD, D, dedup, compress, copies; if (dds->dds_blocks == 0) return; rL = (double)dds->dds_ref_lsize; rP = (double)dds->dds_ref_psize; rD = (double)dds->dds_ref_dsize; D = (double)dds->dds_dsize; dedup = rD / D; compress = rL / rP; copies = rD / rP; (void) printf("dedup = %.2f, compress = %.2f, copies = %.2f, " "dedup * compress / copies = %.2f\n\n", dedup, compress, copies, dedup * compress / copies); } static void dump_ddt(ddt_t *ddt, enum ddt_type type, enum ddt_class class) { char name[DDT_NAMELEN]; ddt_entry_t dde; uint64_t walk = 0; dmu_object_info_t doi; uint64_t count, dspace, mspace; int error; error = ddt_object_info(ddt, type, class, &doi); if (error == ENOENT) return; ASSERT(error == 0); error = ddt_object_count(ddt, type, class, &count); ASSERT(error == 0); if (count == 0) return; dspace = doi.doi_physical_blocks_512 << 9; mspace = doi.doi_fill_count * doi.doi_data_block_size; ddt_object_name(ddt, type, class, name); (void) printf("%s: %llu entries, size %llu on disk, %llu in core\n", name, (u_longlong_t)count, (u_longlong_t)(dspace / count), (u_longlong_t)(mspace / count)); if (dump_opt['D'] < 3) return; zpool_dump_ddt(NULL, &ddt->ddt_histogram[type][class]); if (dump_opt['D'] < 4) return; if (dump_opt['D'] < 5 && class == DDT_CLASS_UNIQUE) return; (void) printf("%s contents:\n\n", name); while ((error = ddt_object_walk(ddt, type, class, &walk, &dde)) == 0) dump_dde(ddt, &dde, walk); ASSERT3U(error, ==, ENOENT); (void) printf("\n"); } static void dump_all_ddts(spa_t *spa) { ddt_histogram_t ddh_total = {{{0}}}; ddt_stat_t dds_total = {0}; for (enum zio_checksum c = 0; c < ZIO_CHECKSUM_FUNCTIONS; c++) { ddt_t *ddt = spa->spa_ddt[c]; for (enum ddt_type type = 0; type < DDT_TYPES; type++) { for (enum ddt_class class = 0; class < DDT_CLASSES; class++) { dump_ddt(ddt, type, class); } } } ddt_get_dedup_stats(spa, &dds_total); if (dds_total.dds_blocks == 0) { (void) printf("All DDTs are empty\n"); return; } (void) printf("\n"); if (dump_opt['D'] > 1) { (void) printf("DDT histogram (aggregated over all DDTs):\n"); ddt_get_dedup_histogram(spa, &ddh_total); zpool_dump_ddt(&dds_total, &ddh_total); } dump_dedup_ratio(&dds_total); } static void dump_dtl_seg(void *arg, uint64_t start, uint64_t size) { char *prefix = arg; (void) printf("%s [%llu,%llu) length %llu\n", prefix, (u_longlong_t)start, (u_longlong_t)(start + size), (u_longlong_t)(size)); } static void dump_dtl(vdev_t *vd, int indent) { spa_t *spa = vd->vdev_spa; boolean_t required; const char *name[DTL_TYPES] = { "missing", "partial", "scrub", "outage" }; char prefix[256]; spa_vdev_state_enter(spa, SCL_NONE); required = vdev_dtl_required(vd); (void) spa_vdev_state_exit(spa, NULL, 0); if (indent == 0) (void) printf("\nDirty time logs:\n\n"); (void) printf("\t%*s%s [%s]\n", indent, "", vd->vdev_path ? vd->vdev_path : vd->vdev_parent ? vd->vdev_ops->vdev_op_type : spa_name(spa), required ? "DTL-required" : "DTL-expendable"); for (int t = 0; t < DTL_TYPES; t++) { range_tree_t *rt = vd->vdev_dtl[t]; if (range_tree_space(rt) == 0) continue; (void) snprintf(prefix, sizeof (prefix), "\t%*s%s", indent + 2, "", name[t]); range_tree_walk(rt, dump_dtl_seg, prefix); if (dump_opt['d'] > 5 && vd->vdev_children == 0) dump_spacemap(spa->spa_meta_objset, vd->vdev_dtl_sm); } for (unsigned c = 0; c < vd->vdev_children; c++) dump_dtl(vd->vdev_child[c], indent + 4); } static void dump_history(spa_t *spa) { nvlist_t **events = NULL; char *buf; uint64_t resid, len, off = 0; uint_t num = 0; int error; char tbuf[30]; if ((buf = malloc(SPA_OLD_MAXBLOCKSIZE)) == NULL) { (void) fprintf(stderr, "%s: unable to allocate I/O buffer\n", __func__); return; } do { len = SPA_OLD_MAXBLOCKSIZE; if ((error = spa_history_get(spa, &off, &len, buf)) != 0) { (void) fprintf(stderr, "Unable to read history: " "error %d\n", error); free(buf); return; } if (zpool_history_unpack(buf, len, &resid, &events, &num) != 0) break; off -= resid; } while (len != 0); (void) printf("\nHistory:\n"); for (unsigned i = 0; i < num; i++) { boolean_t printed = B_FALSE; if (nvlist_exists(events[i], ZPOOL_HIST_TIME)) { time_t tsec; struct tm t; tsec = fnvlist_lookup_uint64(events[i], ZPOOL_HIST_TIME); (void) localtime_r(&tsec, &t); (void) strftime(tbuf, sizeof (tbuf), "%F.%T", &t); } else { tbuf[0] = '\0'; } if (nvlist_exists(events[i], ZPOOL_HIST_CMD)) { (void) printf("%s %s\n", tbuf, fnvlist_lookup_string(events[i], ZPOOL_HIST_CMD)); } else if (nvlist_exists(events[i], ZPOOL_HIST_INT_EVENT)) { uint64_t ievent; ievent = fnvlist_lookup_uint64(events[i], ZPOOL_HIST_INT_EVENT); if (ievent >= ZFS_NUM_LEGACY_HISTORY_EVENTS) goto next; (void) printf(" %s [internal %s txg:%ju] %s\n", tbuf, zfs_history_event_names[ievent], fnvlist_lookup_uint64(events[i], ZPOOL_HIST_TXG), fnvlist_lookup_string(events[i], ZPOOL_HIST_INT_STR)); } else if (nvlist_exists(events[i], ZPOOL_HIST_INT_NAME)) { (void) printf("%s [txg:%ju] %s", tbuf, fnvlist_lookup_uint64(events[i], ZPOOL_HIST_TXG), fnvlist_lookup_string(events[i], ZPOOL_HIST_INT_NAME)); if (nvlist_exists(events[i], ZPOOL_HIST_DSNAME)) { (void) printf(" %s (%llu)", fnvlist_lookup_string(events[i], ZPOOL_HIST_DSNAME), (u_longlong_t)fnvlist_lookup_uint64( events[i], ZPOOL_HIST_DSID)); } (void) printf(" %s\n", fnvlist_lookup_string(events[i], ZPOOL_HIST_INT_STR)); } else if (nvlist_exists(events[i], ZPOOL_HIST_IOCTL)) { (void) printf("%s ioctl %s\n", tbuf, fnvlist_lookup_string(events[i], ZPOOL_HIST_IOCTL)); if (nvlist_exists(events[i], ZPOOL_HIST_INPUT_NVL)) { (void) printf(" input:\n"); dump_nvlist(fnvlist_lookup_nvlist(events[i], ZPOOL_HIST_INPUT_NVL), 8); } if (nvlist_exists(events[i], ZPOOL_HIST_OUTPUT_NVL)) { (void) printf(" output:\n"); dump_nvlist(fnvlist_lookup_nvlist(events[i], ZPOOL_HIST_OUTPUT_NVL), 8); } if (nvlist_exists(events[i], ZPOOL_HIST_ERRNO)) { (void) printf(" errno: %lld\n", (longlong_t)fnvlist_lookup_int64(events[i], ZPOOL_HIST_ERRNO)); } } else { goto next; } printed = B_TRUE; next: if (dump_opt['h'] > 1) { if (!printed) (void) printf("unrecognized record:\n"); dump_nvlist(events[i], 2); } } free(buf); } static void dump_dnode(objset_t *os, uint64_t object, void *data, size_t size) { (void) os, (void) object, (void) data, (void) size; } static uint64_t blkid2offset(const dnode_phys_t *dnp, const blkptr_t *bp, const zbookmark_phys_t *zb) { if (dnp == NULL) { ASSERT(zb->zb_level < 0); if (zb->zb_object == 0) return (zb->zb_blkid); return (zb->zb_blkid * BP_GET_LSIZE(bp)); } ASSERT(zb->zb_level >= 0); return ((zb->zb_blkid << (zb->zb_level * (dnp->dn_indblkshift - SPA_BLKPTRSHIFT))) * dnp->dn_datablkszsec << SPA_MINBLOCKSHIFT); } static void snprintf_zstd_header(spa_t *spa, char *blkbuf, size_t buflen, const blkptr_t *bp) { abd_t *pabd; void *buf; zio_t *zio; zfs_zstdhdr_t zstd_hdr; int error; if (BP_GET_COMPRESS(bp) != ZIO_COMPRESS_ZSTD) return; if (BP_IS_HOLE(bp)) return; if (BP_IS_EMBEDDED(bp)) { buf = malloc(SPA_MAXBLOCKSIZE); if (buf == NULL) { (void) fprintf(stderr, "out of memory\n"); exit(1); } decode_embedded_bp_compressed(bp, buf); memcpy(&zstd_hdr, buf, sizeof (zstd_hdr)); free(buf); zstd_hdr.c_len = BE_32(zstd_hdr.c_len); zstd_hdr.raw_version_level = BE_32(zstd_hdr.raw_version_level); (void) snprintf(blkbuf + strlen(blkbuf), buflen - strlen(blkbuf), " ZSTD:size=%u:version=%u:level=%u:EMBEDDED", zstd_hdr.c_len, zfs_get_hdrversion(&zstd_hdr), zfs_get_hdrlevel(&zstd_hdr)); return; } pabd = abd_alloc_for_io(SPA_MAXBLOCKSIZE, B_FALSE); zio = zio_root(spa, NULL, NULL, 0); /* Decrypt but don't decompress so we can read the compression header */ zio_nowait(zio_read(zio, spa, bp, pabd, BP_GET_PSIZE(bp), NULL, NULL, ZIO_PRIORITY_SYNC_READ, ZIO_FLAG_CANFAIL | ZIO_FLAG_RAW_COMPRESS, NULL)); error = zio_wait(zio); if (error) { (void) fprintf(stderr, "read failed: %d\n", error); return; } buf = abd_borrow_buf_copy(pabd, BP_GET_LSIZE(bp)); memcpy(&zstd_hdr, buf, sizeof (zstd_hdr)); zstd_hdr.c_len = BE_32(zstd_hdr.c_len); zstd_hdr.raw_version_level = BE_32(zstd_hdr.raw_version_level); (void) snprintf(blkbuf + strlen(blkbuf), buflen - strlen(blkbuf), " ZSTD:size=%u:version=%u:level=%u:NORMAL", zstd_hdr.c_len, zfs_get_hdrversion(&zstd_hdr), zfs_get_hdrlevel(&zstd_hdr)); abd_return_buf_copy(pabd, buf, BP_GET_LSIZE(bp)); } static void snprintf_blkptr_compact(char *blkbuf, size_t buflen, const blkptr_t *bp, boolean_t bp_freed) { const dva_t *dva = bp->blk_dva; int ndvas = dump_opt['d'] > 5 ? BP_GET_NDVAS(bp) : 1; int i; if (dump_opt['b'] >= 6) { snprintf_blkptr(blkbuf, buflen, bp); if (bp_freed) { (void) snprintf(blkbuf + strlen(blkbuf), buflen - strlen(blkbuf), " %s", "FREE"); } return; } if (BP_IS_EMBEDDED(bp)) { (void) sprintf(blkbuf, "EMBEDDED et=%u %llxL/%llxP B=%llu", (int)BPE_GET_ETYPE(bp), (u_longlong_t)BPE_GET_LSIZE(bp), (u_longlong_t)BPE_GET_PSIZE(bp), (u_longlong_t)bp->blk_birth); return; } blkbuf[0] = '\0'; for (i = 0; i < ndvas; i++) (void) snprintf(blkbuf + strlen(blkbuf), buflen - strlen(blkbuf), "%llu:%llx:%llx ", (u_longlong_t)DVA_GET_VDEV(&dva[i]), (u_longlong_t)DVA_GET_OFFSET(&dva[i]), (u_longlong_t)DVA_GET_ASIZE(&dva[i])); if (BP_IS_HOLE(bp)) { (void) snprintf(blkbuf + strlen(blkbuf), buflen - strlen(blkbuf), "%llxL B=%llu", (u_longlong_t)BP_GET_LSIZE(bp), (u_longlong_t)bp->blk_birth); } else { (void) snprintf(blkbuf + strlen(blkbuf), buflen - strlen(blkbuf), "%llxL/%llxP F=%llu B=%llu/%llu", (u_longlong_t)BP_GET_LSIZE(bp), (u_longlong_t)BP_GET_PSIZE(bp), (u_longlong_t)BP_GET_FILL(bp), (u_longlong_t)bp->blk_birth, (u_longlong_t)BP_PHYSICAL_BIRTH(bp)); if (bp_freed) (void) snprintf(blkbuf + strlen(blkbuf), buflen - strlen(blkbuf), " %s", "FREE"); (void) snprintf(blkbuf + strlen(blkbuf), buflen - strlen(blkbuf), " cksum=%llx:%llx:%llx:%llx", (u_longlong_t)bp->blk_cksum.zc_word[0], (u_longlong_t)bp->blk_cksum.zc_word[1], (u_longlong_t)bp->blk_cksum.zc_word[2], (u_longlong_t)bp->blk_cksum.zc_word[3]); } } static void print_indirect(spa_t *spa, blkptr_t *bp, const zbookmark_phys_t *zb, const dnode_phys_t *dnp) { char blkbuf[BP_SPRINTF_LEN]; int l; if (!BP_IS_EMBEDDED(bp)) { ASSERT3U(BP_GET_TYPE(bp), ==, dnp->dn_type); ASSERT3U(BP_GET_LEVEL(bp), ==, zb->zb_level); } (void) printf("%16llx ", (u_longlong_t)blkid2offset(dnp, bp, zb)); ASSERT(zb->zb_level >= 0); for (l = dnp->dn_nlevels - 1; l >= -1; l--) { if (l == zb->zb_level) { (void) printf("L%llx", (u_longlong_t)zb->zb_level); } else { (void) printf(" "); } } snprintf_blkptr_compact(blkbuf, sizeof (blkbuf), bp, B_FALSE); if (dump_opt['Z'] && BP_GET_COMPRESS(bp) == ZIO_COMPRESS_ZSTD) snprintf_zstd_header(spa, blkbuf, sizeof (blkbuf), bp); (void) printf("%s\n", blkbuf); } static int visit_indirect(spa_t *spa, const dnode_phys_t *dnp, blkptr_t *bp, const zbookmark_phys_t *zb) { int err = 0; if (bp->blk_birth == 0) return (0); print_indirect(spa, bp, zb, dnp); if (BP_GET_LEVEL(bp) > 0 && !BP_IS_HOLE(bp)) { arc_flags_t flags = ARC_FLAG_WAIT; int i; blkptr_t *cbp; int epb = BP_GET_LSIZE(bp) >> SPA_BLKPTRSHIFT; arc_buf_t *buf; uint64_t fill = 0; ASSERT(!BP_IS_REDACTED(bp)); err = arc_read(NULL, spa, bp, arc_getbuf_func, &buf, ZIO_PRIORITY_ASYNC_READ, ZIO_FLAG_CANFAIL, &flags, zb); if (err) return (err); ASSERT(buf->b_data); /* recursively visit blocks below this */ cbp = buf->b_data; for (i = 0; i < epb; i++, cbp++) { zbookmark_phys_t czb; SET_BOOKMARK(&czb, zb->zb_objset, zb->zb_object, zb->zb_level - 1, zb->zb_blkid * epb + i); err = visit_indirect(spa, dnp, cbp, &czb); if (err) break; fill += BP_GET_FILL(cbp); } if (!err) ASSERT3U(fill, ==, BP_GET_FILL(bp)); arc_buf_destroy(buf, &buf); } return (err); } static void dump_indirect(dnode_t *dn) { dnode_phys_t *dnp = dn->dn_phys; zbookmark_phys_t czb; (void) printf("Indirect blocks:\n"); SET_BOOKMARK(&czb, dmu_objset_id(dn->dn_objset), dn->dn_object, dnp->dn_nlevels - 1, 0); for (int j = 0; j < dnp->dn_nblkptr; j++) { czb.zb_blkid = j; (void) visit_indirect(dmu_objset_spa(dn->dn_objset), dnp, &dnp->dn_blkptr[j], &czb); } (void) printf("\n"); } static void dump_dsl_dir(objset_t *os, uint64_t object, void *data, size_t size) { (void) os, (void) object; dsl_dir_phys_t *dd = data; time_t crtime; char nice[32]; /* make sure nicenum has enough space */ _Static_assert(sizeof (nice) >= NN_NUMBUF_SZ, "nice truncated"); if (dd == NULL) return; ASSERT3U(size, >=, sizeof (dsl_dir_phys_t)); crtime = dd->dd_creation_time; (void) printf("\t\tcreation_time = %s", ctime(&crtime)); (void) printf("\t\thead_dataset_obj = %llu\n", (u_longlong_t)dd->dd_head_dataset_obj); (void) printf("\t\tparent_dir_obj = %llu\n", (u_longlong_t)dd->dd_parent_obj); (void) printf("\t\torigin_obj = %llu\n", (u_longlong_t)dd->dd_origin_obj); (void) printf("\t\tchild_dir_zapobj = %llu\n", (u_longlong_t)dd->dd_child_dir_zapobj); zdb_nicenum(dd->dd_used_bytes, nice, sizeof (nice)); (void) printf("\t\tused_bytes = %s\n", nice); zdb_nicenum(dd->dd_compressed_bytes, nice, sizeof (nice)); (void) printf("\t\tcompressed_bytes = %s\n", nice); zdb_nicenum(dd->dd_uncompressed_bytes, nice, sizeof (nice)); (void) printf("\t\tuncompressed_bytes = %s\n", nice); zdb_nicenum(dd->dd_quota, nice, sizeof (nice)); (void) printf("\t\tquota = %s\n", nice); zdb_nicenum(dd->dd_reserved, nice, sizeof (nice)); (void) printf("\t\treserved = %s\n", nice); (void) printf("\t\tprops_zapobj = %llu\n", (u_longlong_t)dd->dd_props_zapobj); (void) printf("\t\tdeleg_zapobj = %llu\n", (u_longlong_t)dd->dd_deleg_zapobj); (void) printf("\t\tflags = %llx\n", (u_longlong_t)dd->dd_flags); #define DO(which) \ zdb_nicenum(dd->dd_used_breakdown[DD_USED_ ## which], nice, \ sizeof (nice)); \ (void) printf("\t\tused_breakdown[" #which "] = %s\n", nice) DO(HEAD); DO(SNAP); DO(CHILD); DO(CHILD_RSRV); DO(REFRSRV); #undef DO (void) printf("\t\tclones = %llu\n", (u_longlong_t)dd->dd_clones); } static void dump_dsl_dataset(objset_t *os, uint64_t object, void *data, size_t size) { (void) os, (void) object; dsl_dataset_phys_t *ds = data; time_t crtime; char used[32], compressed[32], uncompressed[32], unique[32]; char blkbuf[BP_SPRINTF_LEN]; /* make sure nicenum has enough space */ _Static_assert(sizeof (used) >= NN_NUMBUF_SZ, "used truncated"); _Static_assert(sizeof (compressed) >= NN_NUMBUF_SZ, "compressed truncated"); _Static_assert(sizeof (uncompressed) >= NN_NUMBUF_SZ, "uncompressed truncated"); _Static_assert(sizeof (unique) >= NN_NUMBUF_SZ, "unique truncated"); if (ds == NULL) return; ASSERT(size == sizeof (*ds)); crtime = ds->ds_creation_time; zdb_nicenum(ds->ds_referenced_bytes, used, sizeof (used)); zdb_nicenum(ds->ds_compressed_bytes, compressed, sizeof (compressed)); zdb_nicenum(ds->ds_uncompressed_bytes, uncompressed, sizeof (uncompressed)); zdb_nicenum(ds->ds_unique_bytes, unique, sizeof (unique)); snprintf_blkptr(blkbuf, sizeof (blkbuf), &ds->ds_bp); (void) printf("\t\tdir_obj = %llu\n", (u_longlong_t)ds->ds_dir_obj); (void) printf("\t\tprev_snap_obj = %llu\n", (u_longlong_t)ds->ds_prev_snap_obj); (void) printf("\t\tprev_snap_txg = %llu\n", (u_longlong_t)ds->ds_prev_snap_txg); (void) printf("\t\tnext_snap_obj = %llu\n", (u_longlong_t)ds->ds_next_snap_obj); (void) printf("\t\tsnapnames_zapobj = %llu\n", (u_longlong_t)ds->ds_snapnames_zapobj); (void) printf("\t\tnum_children = %llu\n", (u_longlong_t)ds->ds_num_children); (void) printf("\t\tuserrefs_obj = %llu\n", (u_longlong_t)ds->ds_userrefs_obj); (void) printf("\t\tcreation_time = %s", ctime(&crtime)); (void) printf("\t\tcreation_txg = %llu\n", (u_longlong_t)ds->ds_creation_txg); (void) printf("\t\tdeadlist_obj = %llu\n", (u_longlong_t)ds->ds_deadlist_obj); (void) printf("\t\tused_bytes = %s\n", used); (void) printf("\t\tcompressed_bytes = %s\n", compressed); (void) printf("\t\tuncompressed_bytes = %s\n", uncompressed); (void) printf("\t\tunique = %s\n", unique); (void) printf("\t\tfsid_guid = %llu\n", (u_longlong_t)ds->ds_fsid_guid); (void) printf("\t\tguid = %llu\n", (u_longlong_t)ds->ds_guid); (void) printf("\t\tflags = %llx\n", (u_longlong_t)ds->ds_flags); (void) printf("\t\tnext_clones_obj = %llu\n", (u_longlong_t)ds->ds_next_clones_obj); (void) printf("\t\tprops_obj = %llu\n", (u_longlong_t)ds->ds_props_obj); (void) printf("\t\tbp = %s\n", blkbuf); } static int dump_bptree_cb(void *arg, const blkptr_t *bp, dmu_tx_t *tx) { (void) arg, (void) tx; char blkbuf[BP_SPRINTF_LEN]; if (bp->blk_birth != 0) { snprintf_blkptr(blkbuf, sizeof (blkbuf), bp); (void) printf("\t%s\n", blkbuf); } return (0); } static void dump_bptree(objset_t *os, uint64_t obj, const char *name) { char bytes[32]; bptree_phys_t *bt; dmu_buf_t *db; /* make sure nicenum has enough space */ _Static_assert(sizeof (bytes) >= NN_NUMBUF_SZ, "bytes truncated"); if (dump_opt['d'] < 3) return; VERIFY3U(0, ==, dmu_bonus_hold(os, obj, FTAG, &db)); bt = db->db_data; zdb_nicenum(bt->bt_bytes, bytes, sizeof (bytes)); (void) printf("\n %s: %llu datasets, %s\n", name, (unsigned long long)(bt->bt_end - bt->bt_begin), bytes); dmu_buf_rele(db, FTAG); if (dump_opt['d'] < 5) return; (void) printf("\n"); (void) bptree_iterate(os, obj, B_FALSE, dump_bptree_cb, NULL, NULL); } static int dump_bpobj_cb(void *arg, const blkptr_t *bp, boolean_t bp_freed, dmu_tx_t *tx) { (void) arg, (void) tx; char blkbuf[BP_SPRINTF_LEN]; ASSERT(bp->blk_birth != 0); snprintf_blkptr_compact(blkbuf, sizeof (blkbuf), bp, bp_freed); (void) printf("\t%s\n", blkbuf); return (0); } static void dump_full_bpobj(bpobj_t *bpo, const char *name, int indent) { char bytes[32]; char comp[32]; char uncomp[32]; uint64_t i; /* make sure nicenum has enough space */ _Static_assert(sizeof (bytes) >= NN_NUMBUF_SZ, "bytes truncated"); _Static_assert(sizeof (comp) >= NN_NUMBUF_SZ, "comp truncated"); _Static_assert(sizeof (uncomp) >= NN_NUMBUF_SZ, "uncomp truncated"); if (dump_opt['d'] < 3) return; zdb_nicenum(bpo->bpo_phys->bpo_bytes, bytes, sizeof (bytes)); if (bpo->bpo_havesubobj && bpo->bpo_phys->bpo_subobjs != 0) { zdb_nicenum(bpo->bpo_phys->bpo_comp, comp, sizeof (comp)); zdb_nicenum(bpo->bpo_phys->bpo_uncomp, uncomp, sizeof (uncomp)); if (bpo->bpo_havefreed) { (void) printf(" %*s: object %llu, %llu local " "blkptrs, %llu freed, %llu subobjs in object %llu, " "%s (%s/%s comp)\n", indent * 8, name, (u_longlong_t)bpo->bpo_object, (u_longlong_t)bpo->bpo_phys->bpo_num_blkptrs, (u_longlong_t)bpo->bpo_phys->bpo_num_freed, (u_longlong_t)bpo->bpo_phys->bpo_num_subobjs, (u_longlong_t)bpo->bpo_phys->bpo_subobjs, bytes, comp, uncomp); } else { (void) printf(" %*s: object %llu, %llu local " "blkptrs, %llu subobjs in object %llu, " "%s (%s/%s comp)\n", indent * 8, name, (u_longlong_t)bpo->bpo_object, (u_longlong_t)bpo->bpo_phys->bpo_num_blkptrs, (u_longlong_t)bpo->bpo_phys->bpo_num_subobjs, (u_longlong_t)bpo->bpo_phys->bpo_subobjs, bytes, comp, uncomp); } for (i = 0; i < bpo->bpo_phys->bpo_num_subobjs; i++) { uint64_t subobj; bpobj_t subbpo; int error; VERIFY0(dmu_read(bpo->bpo_os, bpo->bpo_phys->bpo_subobjs, i * sizeof (subobj), sizeof (subobj), &subobj, 0)); error = bpobj_open(&subbpo, bpo->bpo_os, subobj); if (error != 0) { (void) printf("ERROR %u while trying to open " "subobj id %llu\n", error, (u_longlong_t)subobj); continue; } dump_full_bpobj(&subbpo, "subobj", indent + 1); bpobj_close(&subbpo); } } else { if (bpo->bpo_havefreed) { (void) printf(" %*s: object %llu, %llu blkptrs, " "%llu freed, %s\n", indent * 8, name, (u_longlong_t)bpo->bpo_object, (u_longlong_t)bpo->bpo_phys->bpo_num_blkptrs, (u_longlong_t)bpo->bpo_phys->bpo_num_freed, bytes); } else { (void) printf(" %*s: object %llu, %llu blkptrs, " "%s\n", indent * 8, name, (u_longlong_t)bpo->bpo_object, (u_longlong_t)bpo->bpo_phys->bpo_num_blkptrs, bytes); } } if (dump_opt['d'] < 5) return; if (indent == 0) { (void) bpobj_iterate_nofree(bpo, dump_bpobj_cb, NULL, NULL); (void) printf("\n"); } } static int dump_bookmark(dsl_pool_t *dp, char *name, boolean_t print_redact, boolean_t print_list) { int err = 0; zfs_bookmark_phys_t prop; objset_t *mos = dp->dp_spa->spa_meta_objset; err = dsl_bookmark_lookup(dp, name, NULL, &prop); if (err != 0) { return (err); } (void) printf("\t#%s: ", strchr(name, '#') + 1); (void) printf("{guid: %llx creation_txg: %llu creation_time: " "%llu redaction_obj: %llu}\n", (u_longlong_t)prop.zbm_guid, (u_longlong_t)prop.zbm_creation_txg, (u_longlong_t)prop.zbm_creation_time, (u_longlong_t)prop.zbm_redaction_obj); IMPLY(print_list, print_redact); if (!print_redact || prop.zbm_redaction_obj == 0) return (0); redaction_list_t *rl; VERIFY0(dsl_redaction_list_hold_obj(dp, prop.zbm_redaction_obj, FTAG, &rl)); redaction_list_phys_t *rlp = rl->rl_phys; (void) printf("\tRedacted:\n\t\tProgress: "); if (rlp->rlp_last_object != UINT64_MAX || rlp->rlp_last_blkid != UINT64_MAX) { (void) printf("%llu %llu (incomplete)\n", (u_longlong_t)rlp->rlp_last_object, (u_longlong_t)rlp->rlp_last_blkid); } else { (void) printf("complete\n"); } (void) printf("\t\tSnapshots: ["); for (unsigned int i = 0; i < rlp->rlp_num_snaps; i++) { if (i > 0) (void) printf(", "); (void) printf("%0llu", (u_longlong_t)rlp->rlp_snaps[i]); } (void) printf("]\n\t\tLength: %llu\n", (u_longlong_t)rlp->rlp_num_entries); if (!print_list) { dsl_redaction_list_rele(rl, FTAG); return (0); } if (rlp->rlp_num_entries == 0) { dsl_redaction_list_rele(rl, FTAG); (void) printf("\t\tRedaction List: []\n\n"); return (0); } redact_block_phys_t *rbp_buf; uint64_t size; dmu_object_info_t doi; VERIFY0(dmu_object_info(mos, prop.zbm_redaction_obj, &doi)); size = doi.doi_max_offset; rbp_buf = kmem_alloc(size, KM_SLEEP); err = dmu_read(mos, prop.zbm_redaction_obj, 0, size, rbp_buf, 0); if (err != 0) { dsl_redaction_list_rele(rl, FTAG); kmem_free(rbp_buf, size); return (err); } (void) printf("\t\tRedaction List: [{object: %llx, offset: " "%llx, blksz: %x, count: %llx}", (u_longlong_t)rbp_buf[0].rbp_object, (u_longlong_t)rbp_buf[0].rbp_blkid, (uint_t)(redact_block_get_size(&rbp_buf[0])), (u_longlong_t)redact_block_get_count(&rbp_buf[0])); for (size_t i = 1; i < rlp->rlp_num_entries; i++) { (void) printf(",\n\t\t{object: %llx, offset: %llx, " "blksz: %x, count: %llx}", (u_longlong_t)rbp_buf[i].rbp_object, (u_longlong_t)rbp_buf[i].rbp_blkid, (uint_t)(redact_block_get_size(&rbp_buf[i])), (u_longlong_t)redact_block_get_count(&rbp_buf[i])); } dsl_redaction_list_rele(rl, FTAG); kmem_free(rbp_buf, size); (void) printf("]\n\n"); return (0); } static void dump_bookmarks(objset_t *os, int verbosity) { zap_cursor_t zc; zap_attribute_t attr; dsl_dataset_t *ds = dmu_objset_ds(os); dsl_pool_t *dp = spa_get_dsl(os->os_spa); objset_t *mos = os->os_spa->spa_meta_objset; if (verbosity < 4) return; dsl_pool_config_enter(dp, FTAG); for (zap_cursor_init(&zc, mos, ds->ds_bookmarks_obj); zap_cursor_retrieve(&zc, &attr) == 0; zap_cursor_advance(&zc)) { char osname[ZFS_MAX_DATASET_NAME_LEN]; char buf[ZFS_MAX_DATASET_NAME_LEN]; dmu_objset_name(os, osname); VERIFY3S(0, <=, snprintf(buf, sizeof (buf), "%s#%s", osname, attr.za_name)); (void) dump_bookmark(dp, buf, verbosity >= 5, verbosity >= 6); } zap_cursor_fini(&zc); dsl_pool_config_exit(dp, FTAG); } static void bpobj_count_refd(bpobj_t *bpo) { mos_obj_refd(bpo->bpo_object); if (bpo->bpo_havesubobj && bpo->bpo_phys->bpo_subobjs != 0) { mos_obj_refd(bpo->bpo_phys->bpo_subobjs); for (uint64_t i = 0; i < bpo->bpo_phys->bpo_num_subobjs; i++) { uint64_t subobj; bpobj_t subbpo; int error; VERIFY0(dmu_read(bpo->bpo_os, bpo->bpo_phys->bpo_subobjs, i * sizeof (subobj), sizeof (subobj), &subobj, 0)); error = bpobj_open(&subbpo, bpo->bpo_os, subobj); if (error != 0) { (void) printf("ERROR %u while trying to open " "subobj id %llu\n", error, (u_longlong_t)subobj); continue; } bpobj_count_refd(&subbpo); bpobj_close(&subbpo); } } } static int dsl_deadlist_entry_count_refd(void *arg, dsl_deadlist_entry_t *dle) { spa_t *spa = arg; uint64_t empty_bpobj = spa->spa_dsl_pool->dp_empty_bpobj; if (dle->dle_bpobj.bpo_object != empty_bpobj) bpobj_count_refd(&dle->dle_bpobj); return (0); } static int dsl_deadlist_entry_dump(void *arg, dsl_deadlist_entry_t *dle) { ASSERT(arg == NULL); if (dump_opt['d'] >= 5) { char buf[128]; (void) snprintf(buf, sizeof (buf), "mintxg %llu -> obj %llu", (longlong_t)dle->dle_mintxg, (longlong_t)dle->dle_bpobj.bpo_object); dump_full_bpobj(&dle->dle_bpobj, buf, 0); } else { (void) printf("mintxg %llu -> obj %llu\n", (longlong_t)dle->dle_mintxg, (longlong_t)dle->dle_bpobj.bpo_object); } return (0); } static void dump_blkptr_list(dsl_deadlist_t *dl, const char *name) { char bytes[32]; char comp[32]; char uncomp[32]; char entries[32]; spa_t *spa = dmu_objset_spa(dl->dl_os); uint64_t empty_bpobj = spa->spa_dsl_pool->dp_empty_bpobj; if (dl->dl_oldfmt) { if (dl->dl_bpobj.bpo_object != empty_bpobj) bpobj_count_refd(&dl->dl_bpobj); } else { mos_obj_refd(dl->dl_object); dsl_deadlist_iterate(dl, dsl_deadlist_entry_count_refd, spa); } /* make sure nicenum has enough space */ _Static_assert(sizeof (bytes) >= NN_NUMBUF_SZ, "bytes truncated"); _Static_assert(sizeof (comp) >= NN_NUMBUF_SZ, "comp truncated"); _Static_assert(sizeof (uncomp) >= NN_NUMBUF_SZ, "uncomp truncated"); _Static_assert(sizeof (entries) >= NN_NUMBUF_SZ, "entries truncated"); if (dump_opt['d'] < 3) return; if (dl->dl_oldfmt) { dump_full_bpobj(&dl->dl_bpobj, "old-format deadlist", 0); return; } zdb_nicenum(dl->dl_phys->dl_used, bytes, sizeof (bytes)); zdb_nicenum(dl->dl_phys->dl_comp, comp, sizeof (comp)); zdb_nicenum(dl->dl_phys->dl_uncomp, uncomp, sizeof (uncomp)); zdb_nicenum(avl_numnodes(&dl->dl_tree), entries, sizeof (entries)); (void) printf("\n %s: %s (%s/%s comp), %s entries\n", name, bytes, comp, uncomp, entries); if (dump_opt['d'] < 4) return; (void) putchar('\n'); dsl_deadlist_iterate(dl, dsl_deadlist_entry_dump, NULL); } static int verify_dd_livelist(objset_t *os) { uint64_t ll_used, used, ll_comp, comp, ll_uncomp, uncomp; dsl_pool_t *dp = spa_get_dsl(os->os_spa); dsl_dir_t *dd = os->os_dsl_dataset->ds_dir; ASSERT(!dmu_objset_is_snapshot(os)); if (!dsl_deadlist_is_open(&dd->dd_livelist)) return (0); /* Iterate through the livelist to check for duplicates */ dsl_deadlist_iterate(&dd->dd_livelist, sublivelist_verify_lightweight, NULL); dsl_pool_config_enter(dp, FTAG); dsl_deadlist_space(&dd->dd_livelist, &ll_used, &ll_comp, &ll_uncomp); dsl_dataset_t *origin_ds; ASSERT(dsl_pool_config_held(dp)); VERIFY0(dsl_dataset_hold_obj(dp, dsl_dir_phys(dd)->dd_origin_obj, FTAG, &origin_ds)); VERIFY0(dsl_dataset_space_written(origin_ds, os->os_dsl_dataset, &used, &comp, &uncomp)); dsl_dataset_rele(origin_ds, FTAG); dsl_pool_config_exit(dp, FTAG); /* * It's possible that the dataset's uncomp space is larger than the * livelist's because livelists do not track embedded block pointers */ if (used != ll_used || comp != ll_comp || uncomp < ll_uncomp) { char nice_used[32], nice_comp[32], nice_uncomp[32]; (void) printf("Discrepancy in space accounting:\n"); zdb_nicenum(used, nice_used, sizeof (nice_used)); zdb_nicenum(comp, nice_comp, sizeof (nice_comp)); zdb_nicenum(uncomp, nice_uncomp, sizeof (nice_uncomp)); (void) printf("dir: used %s, comp %s, uncomp %s\n", nice_used, nice_comp, nice_uncomp); zdb_nicenum(ll_used, nice_used, sizeof (nice_used)); zdb_nicenum(ll_comp, nice_comp, sizeof (nice_comp)); zdb_nicenum(ll_uncomp, nice_uncomp, sizeof (nice_uncomp)); (void) printf("livelist: used %s, comp %s, uncomp %s\n", nice_used, nice_comp, nice_uncomp); return (1); } return (0); } static avl_tree_t idx_tree; static avl_tree_t domain_tree; static boolean_t fuid_table_loaded; static objset_t *sa_os = NULL; static sa_attr_type_t *sa_attr_table = NULL; static int open_objset(const char *path, const void *tag, objset_t **osp) { int err; uint64_t sa_attrs = 0; uint64_t version = 0; VERIFY3P(sa_os, ==, NULL); /* * We can't own an objset if it's redacted. Therefore, we do this * dance: hold the objset, then acquire a long hold on its dataset, then * release the pool (which is held as part of holding the objset). */ err = dmu_objset_hold(path, tag, osp); if (err != 0) { (void) fprintf(stderr, "failed to hold dataset '%s': %s\n", path, strerror(err)); return (err); } dsl_dataset_long_hold(dmu_objset_ds(*osp), tag); dsl_pool_rele(dmu_objset_pool(*osp), tag); if (dmu_objset_type(*osp) == DMU_OST_ZFS && !(*osp)->os_encrypted) { (void) zap_lookup(*osp, MASTER_NODE_OBJ, ZPL_VERSION_STR, 8, 1, &version); if (version >= ZPL_VERSION_SA) { (void) zap_lookup(*osp, MASTER_NODE_OBJ, ZFS_SA_ATTRS, 8, 1, &sa_attrs); } err = sa_setup(*osp, sa_attrs, zfs_attr_table, ZPL_END, &sa_attr_table); if (err != 0) { (void) fprintf(stderr, "sa_setup failed: %s\n", strerror(err)); dsl_dataset_long_rele(dmu_objset_ds(*osp), tag); dsl_dataset_rele(dmu_objset_ds(*osp), tag); *osp = NULL; } } sa_os = *osp; return (0); } static void close_objset(objset_t *os, const void *tag) { VERIFY3P(os, ==, sa_os); if (os->os_sa != NULL) sa_tear_down(os); dsl_dataset_long_rele(dmu_objset_ds(os), tag); dsl_dataset_rele(dmu_objset_ds(os), tag); sa_attr_table = NULL; sa_os = NULL; } static void fuid_table_destroy(void) { if (fuid_table_loaded) { zfs_fuid_table_destroy(&idx_tree, &domain_tree); fuid_table_loaded = B_FALSE; } } /* * print uid or gid information. * For normal POSIX id just the id is printed in decimal format. * For CIFS files with FUID the fuid is printed in hex followed by * the domain-rid string. */ static void print_idstr(uint64_t id, const char *id_type) { if (FUID_INDEX(id)) { const char *domain = zfs_fuid_idx_domain(&idx_tree, FUID_INDEX(id)); (void) printf("\t%s %llx [%s-%d]\n", id_type, (u_longlong_t)id, domain, (int)FUID_RID(id)); } else { (void) printf("\t%s %llu\n", id_type, (u_longlong_t)id); } } static void dump_uidgid(objset_t *os, uint64_t uid, uint64_t gid) { uint32_t uid_idx, gid_idx; uid_idx = FUID_INDEX(uid); gid_idx = FUID_INDEX(gid); /* Load domain table, if not already loaded */ if (!fuid_table_loaded && (uid_idx || gid_idx)) { uint64_t fuid_obj; /* first find the fuid object. It lives in the master node */ VERIFY(zap_lookup(os, MASTER_NODE_OBJ, ZFS_FUID_TABLES, 8, 1, &fuid_obj) == 0); zfs_fuid_avl_tree_create(&idx_tree, &domain_tree); (void) zfs_fuid_table_load(os, fuid_obj, &idx_tree, &domain_tree); fuid_table_loaded = B_TRUE; } print_idstr(uid, "uid"); print_idstr(gid, "gid"); } static void dump_znode_sa_xattr(sa_handle_t *hdl) { nvlist_t *sa_xattr; nvpair_t *elem = NULL; int sa_xattr_size = 0; int sa_xattr_entries = 0; int error; char *sa_xattr_packed; error = sa_size(hdl, sa_attr_table[ZPL_DXATTR], &sa_xattr_size); if (error || sa_xattr_size == 0) return; sa_xattr_packed = malloc(sa_xattr_size); if (sa_xattr_packed == NULL) return; error = sa_lookup(hdl, sa_attr_table[ZPL_DXATTR], sa_xattr_packed, sa_xattr_size); if (error) { free(sa_xattr_packed); return; } error = nvlist_unpack(sa_xattr_packed, sa_xattr_size, &sa_xattr, 0); if (error) { free(sa_xattr_packed); return; } while ((elem = nvlist_next_nvpair(sa_xattr, elem)) != NULL) sa_xattr_entries++; (void) printf("\tSA xattrs: %d bytes, %d entries\n\n", sa_xattr_size, sa_xattr_entries); while ((elem = nvlist_next_nvpair(sa_xattr, elem)) != NULL) { uchar_t *value; uint_t cnt, idx; (void) printf("\t\t%s = ", nvpair_name(elem)); nvpair_value_byte_array(elem, &value, &cnt); for (idx = 0; idx < cnt; ++idx) { if (isprint(value[idx])) (void) putchar(value[idx]); else (void) printf("\\%3.3o", value[idx]); } (void) putchar('\n'); } nvlist_free(sa_xattr); free(sa_xattr_packed); } static void dump_znode_symlink(sa_handle_t *hdl) { int sa_symlink_size = 0; char linktarget[MAXPATHLEN]; int error; error = sa_size(hdl, sa_attr_table[ZPL_SYMLINK], &sa_symlink_size); if (error || sa_symlink_size == 0) { return; } if (sa_symlink_size >= sizeof (linktarget)) { (void) printf("symlink size %d is too large\n", sa_symlink_size); return; } linktarget[sa_symlink_size] = '\0'; if (sa_lookup(hdl, sa_attr_table[ZPL_SYMLINK], &linktarget, sa_symlink_size) == 0) (void) printf("\ttarget %s\n", linktarget); } static void dump_znode(objset_t *os, uint64_t object, void *data, size_t size) { (void) data, (void) size; char path[MAXPATHLEN * 2]; /* allow for xattr and failure prefix */ sa_handle_t *hdl; uint64_t xattr, rdev, gen; uint64_t uid, gid, mode, fsize, parent, links; uint64_t pflags; uint64_t acctm[2], modtm[2], chgtm[2], crtm[2]; time_t z_crtime, z_atime, z_mtime, z_ctime; sa_bulk_attr_t bulk[12]; int idx = 0; int error; VERIFY3P(os, ==, sa_os); if (sa_handle_get(os, object, NULL, SA_HDL_PRIVATE, &hdl)) { (void) printf("Failed to get handle for SA znode\n"); return; } SA_ADD_BULK_ATTR(bulk, idx, sa_attr_table[ZPL_UID], NULL, &uid, 8); SA_ADD_BULK_ATTR(bulk, idx, sa_attr_table[ZPL_GID], NULL, &gid, 8); SA_ADD_BULK_ATTR(bulk, idx, sa_attr_table[ZPL_LINKS], NULL, &links, 8); SA_ADD_BULK_ATTR(bulk, idx, sa_attr_table[ZPL_GEN], NULL, &gen, 8); SA_ADD_BULK_ATTR(bulk, idx, sa_attr_table[ZPL_MODE], NULL, &mode, 8); SA_ADD_BULK_ATTR(bulk, idx, sa_attr_table[ZPL_PARENT], NULL, &parent, 8); SA_ADD_BULK_ATTR(bulk, idx, sa_attr_table[ZPL_SIZE], NULL, &fsize, 8); SA_ADD_BULK_ATTR(bulk, idx, sa_attr_table[ZPL_ATIME], NULL, acctm, 16); SA_ADD_BULK_ATTR(bulk, idx, sa_attr_table[ZPL_MTIME], NULL, modtm, 16); SA_ADD_BULK_ATTR(bulk, idx, sa_attr_table[ZPL_CRTIME], NULL, crtm, 16); SA_ADD_BULK_ATTR(bulk, idx, sa_attr_table[ZPL_CTIME], NULL, chgtm, 16); SA_ADD_BULK_ATTR(bulk, idx, sa_attr_table[ZPL_FLAGS], NULL, &pflags, 8); if (sa_bulk_lookup(hdl, bulk, idx)) { (void) sa_handle_destroy(hdl); return; } z_crtime = (time_t)crtm[0]; z_atime = (time_t)acctm[0]; z_mtime = (time_t)modtm[0]; z_ctime = (time_t)chgtm[0]; if (dump_opt['d'] > 4) { error = zfs_obj_to_path(os, object, path, sizeof (path)); if (error == ESTALE) { (void) snprintf(path, sizeof (path), "on delete queue"); } else if (error != 0) { leaked_objects++; (void) snprintf(path, sizeof (path), "path not found, possibly leaked"); } (void) printf("\tpath %s\n", path); } if (S_ISLNK(mode)) dump_znode_symlink(hdl); dump_uidgid(os, uid, gid); (void) printf("\tatime %s", ctime(&z_atime)); (void) printf("\tmtime %s", ctime(&z_mtime)); (void) printf("\tctime %s", ctime(&z_ctime)); (void) printf("\tcrtime %s", ctime(&z_crtime)); (void) printf("\tgen %llu\n", (u_longlong_t)gen); (void) printf("\tmode %llo\n", (u_longlong_t)mode); (void) printf("\tsize %llu\n", (u_longlong_t)fsize); (void) printf("\tparent %llu\n", (u_longlong_t)parent); (void) printf("\tlinks %llu\n", (u_longlong_t)links); (void) printf("\tpflags %llx\n", (u_longlong_t)pflags); if (dmu_objset_projectquota_enabled(os) && (pflags & ZFS_PROJID)) { uint64_t projid; if (sa_lookup(hdl, sa_attr_table[ZPL_PROJID], &projid, sizeof (uint64_t)) == 0) (void) printf("\tprojid %llu\n", (u_longlong_t)projid); } if (sa_lookup(hdl, sa_attr_table[ZPL_XATTR], &xattr, sizeof (uint64_t)) == 0) (void) printf("\txattr %llu\n", (u_longlong_t)xattr); if (sa_lookup(hdl, sa_attr_table[ZPL_RDEV], &rdev, sizeof (uint64_t)) == 0) (void) printf("\trdev 0x%016llx\n", (u_longlong_t)rdev); dump_znode_sa_xattr(hdl); sa_handle_destroy(hdl); } static void dump_acl(objset_t *os, uint64_t object, void *data, size_t size) { (void) os, (void) object, (void) data, (void) size; } static void dump_dmu_objset(objset_t *os, uint64_t object, void *data, size_t size) { (void) os, (void) object, (void) data, (void) size; } static object_viewer_t *object_viewer[DMU_OT_NUMTYPES + 1] = { dump_none, /* unallocated */ dump_zap, /* object directory */ dump_uint64, /* object array */ dump_none, /* packed nvlist */ dump_packed_nvlist, /* packed nvlist size */ dump_none, /* bpobj */ dump_bpobj, /* bpobj header */ dump_none, /* SPA space map header */ dump_none, /* SPA space map */ dump_none, /* ZIL intent log */ dump_dnode, /* DMU dnode */ dump_dmu_objset, /* DMU objset */ dump_dsl_dir, /* DSL directory */ dump_zap, /* DSL directory child map */ dump_zap, /* DSL dataset snap map */ dump_zap, /* DSL props */ dump_dsl_dataset, /* DSL dataset */ dump_znode, /* ZFS znode */ dump_acl, /* ZFS V0 ACL */ dump_uint8, /* ZFS plain file */ dump_zpldir, /* ZFS directory */ dump_zap, /* ZFS master node */ dump_zap, /* ZFS delete queue */ dump_uint8, /* zvol object */ dump_zap, /* zvol prop */ dump_uint8, /* other uint8[] */ dump_uint64, /* other uint64[] */ dump_zap, /* other ZAP */ dump_zap, /* persistent error log */ dump_uint8, /* SPA history */ dump_history_offsets, /* SPA history offsets */ dump_zap, /* Pool properties */ dump_zap, /* DSL permissions */ dump_acl, /* ZFS ACL */ dump_uint8, /* ZFS SYSACL */ dump_none, /* FUID nvlist */ dump_packed_nvlist, /* FUID nvlist size */ dump_zap, /* DSL dataset next clones */ dump_zap, /* DSL scrub queue */ dump_zap, /* ZFS user/group/project used */ dump_zap, /* ZFS user/group/project quota */ dump_zap, /* snapshot refcount tags */ dump_ddt_zap, /* DDT ZAP object */ dump_zap, /* DDT statistics */ dump_znode, /* SA object */ dump_zap, /* SA Master Node */ dump_sa_attrs, /* SA attribute registration */ dump_sa_layouts, /* SA attribute layouts */ dump_zap, /* DSL scrub translations */ dump_none, /* fake dedup BP */ dump_zap, /* deadlist */ dump_none, /* deadlist hdr */ dump_zap, /* dsl clones */ dump_bpobj_subobjs, /* bpobj subobjs */ dump_unknown, /* Unknown type, must be last */ }; static boolean_t match_object_type(dmu_object_type_t obj_type, uint64_t flags) { boolean_t match = B_TRUE; switch (obj_type) { case DMU_OT_DIRECTORY_CONTENTS: if (!(flags & ZOR_FLAG_DIRECTORY)) match = B_FALSE; break; case DMU_OT_PLAIN_FILE_CONTENTS: if (!(flags & ZOR_FLAG_PLAIN_FILE)) match = B_FALSE; break; case DMU_OT_SPACE_MAP: if (!(flags & ZOR_FLAG_SPACE_MAP)) match = B_FALSE; break; default: if (strcmp(zdb_ot_name(obj_type), "zap") == 0) { if (!(flags & ZOR_FLAG_ZAP)) match = B_FALSE; break; } /* * If all bits except some of the supported flags are * set, the user combined the all-types flag (A) with * a negated flag to exclude some types (e.g. A-f to * show all object types except plain files). */ if ((flags | ZOR_SUPPORTED_FLAGS) != ZOR_FLAG_ALL_TYPES) match = B_FALSE; break; } return (match); } static void dump_object(objset_t *os, uint64_t object, int verbosity, boolean_t *print_header, uint64_t *dnode_slots_used, uint64_t flags) { dmu_buf_t *db = NULL; dmu_object_info_t doi; dnode_t *dn; boolean_t dnode_held = B_FALSE; void *bonus = NULL; size_t bsize = 0; char iblk[32], dblk[32], lsize[32], asize[32], fill[32], dnsize[32]; char bonus_size[32]; char aux[50]; int error; /* make sure nicenum has enough space */ _Static_assert(sizeof (iblk) >= NN_NUMBUF_SZ, "iblk truncated"); _Static_assert(sizeof (dblk) >= NN_NUMBUF_SZ, "dblk truncated"); _Static_assert(sizeof (lsize) >= NN_NUMBUF_SZ, "lsize truncated"); _Static_assert(sizeof (asize) >= NN_NUMBUF_SZ, "asize truncated"); _Static_assert(sizeof (bonus_size) >= NN_NUMBUF_SZ, "bonus_size truncated"); if (*print_header) { (void) printf("\n%10s %3s %5s %5s %5s %6s %5s %6s %s\n", "Object", "lvl", "iblk", "dblk", "dsize", "dnsize", "lsize", "%full", "type"); *print_header = 0; } if (object == 0) { dn = DMU_META_DNODE(os); dmu_object_info_from_dnode(dn, &doi); } else { /* * Encrypted datasets will have sensitive bonus buffers * encrypted. Therefore we cannot hold the bonus buffer and * must hold the dnode itself instead. */ error = dmu_object_info(os, object, &doi); if (error) fatal("dmu_object_info() failed, errno %u", error); if (os->os_encrypted && DMU_OT_IS_ENCRYPTED(doi.doi_bonus_type)) { error = dnode_hold(os, object, FTAG, &dn); if (error) fatal("dnode_hold() failed, errno %u", error); dnode_held = B_TRUE; } else { error = dmu_bonus_hold(os, object, FTAG, &db); if (error) fatal("dmu_bonus_hold(%llu) failed, errno %u", object, error); bonus = db->db_data; bsize = db->db_size; dn = DB_DNODE((dmu_buf_impl_t *)db); } } /* * Default to showing all object types if no flags were specified. */ if (flags != 0 && flags != ZOR_FLAG_ALL_TYPES && !match_object_type(doi.doi_type, flags)) goto out; if (dnode_slots_used) *dnode_slots_used = doi.doi_dnodesize / DNODE_MIN_SIZE; zdb_nicenum(doi.doi_metadata_block_size, iblk, sizeof (iblk)); zdb_nicenum(doi.doi_data_block_size, dblk, sizeof (dblk)); zdb_nicenum(doi.doi_max_offset, lsize, sizeof (lsize)); zdb_nicenum(doi.doi_physical_blocks_512 << 9, asize, sizeof (asize)); zdb_nicenum(doi.doi_bonus_size, bonus_size, sizeof (bonus_size)); zdb_nicenum(doi.doi_dnodesize, dnsize, sizeof (dnsize)); (void) sprintf(fill, "%6.2f", 100.0 * doi.doi_fill_count * doi.doi_data_block_size / (object == 0 ? DNODES_PER_BLOCK : 1) / doi.doi_max_offset); aux[0] = '\0'; if (doi.doi_checksum != ZIO_CHECKSUM_INHERIT || verbosity >= 6) { (void) snprintf(aux + strlen(aux), sizeof (aux) - strlen(aux), " (K=%s)", ZDB_CHECKSUM_NAME(doi.doi_checksum)); } if (doi.doi_compress == ZIO_COMPRESS_INHERIT && ZIO_COMPRESS_HASLEVEL(os->os_compress) && verbosity >= 6) { const char *compname = NULL; if (zfs_prop_index_to_string(ZFS_PROP_COMPRESSION, ZIO_COMPRESS_RAW(os->os_compress, os->os_complevel), &compname) == 0) { (void) snprintf(aux + strlen(aux), sizeof (aux) - strlen(aux), " (Z=inherit=%s)", compname); } else { (void) snprintf(aux + strlen(aux), sizeof (aux) - strlen(aux), " (Z=inherit=%s-unknown)", ZDB_COMPRESS_NAME(os->os_compress)); } } else if (doi.doi_compress == ZIO_COMPRESS_INHERIT && verbosity >= 6) { (void) snprintf(aux + strlen(aux), sizeof (aux) - strlen(aux), " (Z=inherit=%s)", ZDB_COMPRESS_NAME(os->os_compress)); } else if (doi.doi_compress != ZIO_COMPRESS_INHERIT || verbosity >= 6) { (void) snprintf(aux + strlen(aux), sizeof (aux) - strlen(aux), " (Z=%s)", ZDB_COMPRESS_NAME(doi.doi_compress)); } (void) printf("%10lld %3u %5s %5s %5s %6s %5s %6s %s%s\n", (u_longlong_t)object, doi.doi_indirection, iblk, dblk, asize, dnsize, lsize, fill, zdb_ot_name(doi.doi_type), aux); if (doi.doi_bonus_type != DMU_OT_NONE && verbosity > 3) { (void) printf("%10s %3s %5s %5s %5s %5s %5s %6s %s\n", "", "", "", "", "", "", bonus_size, "bonus", zdb_ot_name(doi.doi_bonus_type)); } if (verbosity >= 4) { (void) printf("\tdnode flags: %s%s%s%s\n", (dn->dn_phys->dn_flags & DNODE_FLAG_USED_BYTES) ? "USED_BYTES " : "", (dn->dn_phys->dn_flags & DNODE_FLAG_USERUSED_ACCOUNTED) ? "USERUSED_ACCOUNTED " : "", (dn->dn_phys->dn_flags & DNODE_FLAG_USEROBJUSED_ACCOUNTED) ? "USEROBJUSED_ACCOUNTED " : "", (dn->dn_phys->dn_flags & DNODE_FLAG_SPILL_BLKPTR) ? "SPILL_BLKPTR" : ""); (void) printf("\tdnode maxblkid: %llu\n", (longlong_t)dn->dn_phys->dn_maxblkid); if (!dnode_held) { object_viewer[ZDB_OT_TYPE(doi.doi_bonus_type)](os, object, bonus, bsize); } else { (void) printf("\t\t(bonus encrypted)\n"); } if (!os->os_encrypted || !DMU_OT_IS_ENCRYPTED(doi.doi_type)) { object_viewer[ZDB_OT_TYPE(doi.doi_type)](os, object, NULL, 0); } else { (void) printf("\t\t(object encrypted)\n"); } *print_header = B_TRUE; } if (verbosity >= 5) { if (dn->dn_phys->dn_flags & DNODE_FLAG_SPILL_BLKPTR) { char blkbuf[BP_SPRINTF_LEN]; snprintf_blkptr_compact(blkbuf, sizeof (blkbuf), DN_SPILL_BLKPTR(dn->dn_phys), B_FALSE); (void) printf("\nSpill block: %s\n", blkbuf); } dump_indirect(dn); } if (verbosity >= 5) { /* * Report the list of segments that comprise the object. */ uint64_t start = 0; uint64_t end; uint64_t blkfill = 1; int minlvl = 1; if (dn->dn_type == DMU_OT_DNODE) { minlvl = 0; blkfill = DNODES_PER_BLOCK; } for (;;) { char segsize[32]; /* make sure nicenum has enough space */ _Static_assert(sizeof (segsize) >= NN_NUMBUF_SZ, "segsize truncated"); error = dnode_next_offset(dn, 0, &start, minlvl, blkfill, 0); if (error) break; end = start; error = dnode_next_offset(dn, DNODE_FIND_HOLE, &end, minlvl, blkfill, 0); zdb_nicenum(end - start, segsize, sizeof (segsize)); (void) printf("\t\tsegment [%016llx, %016llx)" " size %5s\n", (u_longlong_t)start, (u_longlong_t)end, segsize); if (error) break; start = end; } } out: if (db != NULL) dmu_buf_rele(db, FTAG); if (dnode_held) dnode_rele(dn, FTAG); } static void count_dir_mos_objects(dsl_dir_t *dd) { mos_obj_refd(dd->dd_object); mos_obj_refd(dsl_dir_phys(dd)->dd_child_dir_zapobj); mos_obj_refd(dsl_dir_phys(dd)->dd_deleg_zapobj); mos_obj_refd(dsl_dir_phys(dd)->dd_props_zapobj); mos_obj_refd(dsl_dir_phys(dd)->dd_clones); /* * The dd_crypto_obj can be referenced by multiple dsl_dir's. * Ignore the references after the first one. */ mos_obj_refd_multiple(dd->dd_crypto_obj); } static void count_ds_mos_objects(dsl_dataset_t *ds) { mos_obj_refd(ds->ds_object); mos_obj_refd(dsl_dataset_phys(ds)->ds_next_clones_obj); mos_obj_refd(dsl_dataset_phys(ds)->ds_props_obj); mos_obj_refd(dsl_dataset_phys(ds)->ds_userrefs_obj); mos_obj_refd(dsl_dataset_phys(ds)->ds_snapnames_zapobj); mos_obj_refd(ds->ds_bookmarks_obj); if (!dsl_dataset_is_snapshot(ds)) { count_dir_mos_objects(ds->ds_dir); } } static const char *const objset_types[DMU_OST_NUMTYPES] = { "NONE", "META", "ZPL", "ZVOL", "OTHER", "ANY" }; /* * Parse a string denoting a range of object IDs of the form * [:[:flags]], and store the results in zor. * Return 0 on success. On error, return 1 and update the msg * pointer to point to a descriptive error message. */ static int parse_object_range(char *range, zopt_object_range_t *zor, const char **msg) { uint64_t flags = 0; char *p, *s, *dup, *flagstr, *tmp = NULL; size_t len; int i; int rc = 0; if (strchr(range, ':') == NULL) { zor->zor_obj_start = strtoull(range, &p, 0); if (*p != '\0') { *msg = "Invalid characters in object ID"; rc = 1; } zor->zor_obj_start = ZDB_MAP_OBJECT_ID(zor->zor_obj_start); zor->zor_obj_end = zor->zor_obj_start; return (rc); } if (strchr(range, ':') == range) { *msg = "Invalid leading colon"; rc = 1; return (rc); } len = strlen(range); if (range[len - 1] == ':') { *msg = "Invalid trailing colon"; rc = 1; return (rc); } dup = strdup(range); s = strtok_r(dup, ":", &tmp); zor->zor_obj_start = strtoull(s, &p, 0); if (*p != '\0') { *msg = "Invalid characters in start object ID"; rc = 1; goto out; } s = strtok_r(NULL, ":", &tmp); zor->zor_obj_end = strtoull(s, &p, 0); if (*p != '\0') { *msg = "Invalid characters in end object ID"; rc = 1; goto out; } if (zor->zor_obj_start > zor->zor_obj_end) { *msg = "Start object ID may not exceed end object ID"; rc = 1; goto out; } s = strtok_r(NULL, ":", &tmp); if (s == NULL) { zor->zor_flags = ZOR_FLAG_ALL_TYPES; goto out; } else if (strtok_r(NULL, ":", &tmp) != NULL) { *msg = "Invalid colon-delimited field after flags"; rc = 1; goto out; } flagstr = s; for (i = 0; flagstr[i]; i++) { int bit; boolean_t negation = (flagstr[i] == '-'); if (negation) { i++; if (flagstr[i] == '\0') { *msg = "Invalid trailing negation operator"; rc = 1; goto out; } } bit = flagbits[(uchar_t)flagstr[i]]; if (bit == 0) { *msg = "Invalid flag"; rc = 1; goto out; } if (negation) flags &= ~bit; else flags |= bit; } zor->zor_flags = flags; zor->zor_obj_start = ZDB_MAP_OBJECT_ID(zor->zor_obj_start); zor->zor_obj_end = ZDB_MAP_OBJECT_ID(zor->zor_obj_end); out: free(dup); return (rc); } static void dump_objset(objset_t *os) { dmu_objset_stats_t dds = { 0 }; uint64_t object, object_count; uint64_t refdbytes, usedobjs, scratch; char numbuf[32]; char blkbuf[BP_SPRINTF_LEN + 20]; char osname[ZFS_MAX_DATASET_NAME_LEN]; const char *type = "UNKNOWN"; int verbosity = dump_opt['d']; boolean_t print_header; unsigned i; int error; uint64_t total_slots_used = 0; uint64_t max_slot_used = 0; uint64_t dnode_slots; uint64_t obj_start; uint64_t obj_end; uint64_t flags; /* make sure nicenum has enough space */ _Static_assert(sizeof (numbuf) >= NN_NUMBUF_SZ, "numbuf truncated"); dsl_pool_config_enter(dmu_objset_pool(os), FTAG); dmu_objset_fast_stat(os, &dds); dsl_pool_config_exit(dmu_objset_pool(os), FTAG); print_header = B_TRUE; if (dds.dds_type < DMU_OST_NUMTYPES) type = objset_types[dds.dds_type]; if (dds.dds_type == DMU_OST_META) { dds.dds_creation_txg = TXG_INITIAL; usedobjs = BP_GET_FILL(os->os_rootbp); refdbytes = dsl_dir_phys(os->os_spa->spa_dsl_pool->dp_mos_dir)-> dd_used_bytes; } else { dmu_objset_space(os, &refdbytes, &scratch, &usedobjs, &scratch); } ASSERT3U(usedobjs, ==, BP_GET_FILL(os->os_rootbp)); zdb_nicenum(refdbytes, numbuf, sizeof (numbuf)); if (verbosity >= 4) { (void) snprintf(blkbuf, sizeof (blkbuf), ", rootbp "); (void) snprintf_blkptr(blkbuf + strlen(blkbuf), sizeof (blkbuf) - strlen(blkbuf), os->os_rootbp); } else { blkbuf[0] = '\0'; } dmu_objset_name(os, osname); (void) printf("Dataset %s [%s], ID %llu, cr_txg %llu, " "%s, %llu objects%s%s\n", osname, type, (u_longlong_t)dmu_objset_id(os), (u_longlong_t)dds.dds_creation_txg, numbuf, (u_longlong_t)usedobjs, blkbuf, (dds.dds_inconsistent) ? " (inconsistent)" : ""); for (i = 0; i < zopt_object_args; i++) { obj_start = zopt_object_ranges[i].zor_obj_start; obj_end = zopt_object_ranges[i].zor_obj_end; flags = zopt_object_ranges[i].zor_flags; object = obj_start; if (object == 0 || obj_start == obj_end) dump_object(os, object, verbosity, &print_header, NULL, flags); else object--; while ((dmu_object_next(os, &object, B_FALSE, 0) == 0) && object <= obj_end) { dump_object(os, object, verbosity, &print_header, NULL, flags); } } if (zopt_object_args > 0) { (void) printf("\n"); return; } if (dump_opt['i'] != 0 || verbosity >= 2) dump_intent_log(dmu_objset_zil(os)); if (dmu_objset_ds(os) != NULL) { dsl_dataset_t *ds = dmu_objset_ds(os); dump_blkptr_list(&ds->ds_deadlist, "Deadlist"); if (dsl_deadlist_is_open(&ds->ds_dir->dd_livelist) && !dmu_objset_is_snapshot(os)) { dump_blkptr_list(&ds->ds_dir->dd_livelist, "Livelist"); if (verify_dd_livelist(os) != 0) fatal("livelist is incorrect"); } if (dsl_dataset_remap_deadlist_exists(ds)) { (void) printf("ds_remap_deadlist:\n"); dump_blkptr_list(&ds->ds_remap_deadlist, "Deadlist"); } count_ds_mos_objects(ds); } if (dmu_objset_ds(os) != NULL) dump_bookmarks(os, verbosity); if (verbosity < 2) return; if (BP_IS_HOLE(os->os_rootbp)) return; dump_object(os, 0, verbosity, &print_header, NULL, 0); object_count = 0; if (DMU_USERUSED_DNODE(os) != NULL && DMU_USERUSED_DNODE(os)->dn_type != 0) { dump_object(os, DMU_USERUSED_OBJECT, verbosity, &print_header, NULL, 0); dump_object(os, DMU_GROUPUSED_OBJECT, verbosity, &print_header, NULL, 0); } if (DMU_PROJECTUSED_DNODE(os) != NULL && DMU_PROJECTUSED_DNODE(os)->dn_type != 0) dump_object(os, DMU_PROJECTUSED_OBJECT, verbosity, &print_header, NULL, 0); object = 0; while ((error = dmu_object_next(os, &object, B_FALSE, 0)) == 0) { dump_object(os, object, verbosity, &print_header, &dnode_slots, 0); object_count++; total_slots_used += dnode_slots; max_slot_used = object + dnode_slots - 1; } (void) printf("\n"); (void) printf(" Dnode slots:\n"); (void) printf("\tTotal used: %10llu\n", (u_longlong_t)total_slots_used); (void) printf("\tMax used: %10llu\n", (u_longlong_t)max_slot_used); (void) printf("\tPercent empty: %10lf\n", (double)(max_slot_used - total_slots_used)*100 / (double)max_slot_used); (void) printf("\n"); if (error != ESRCH) { (void) fprintf(stderr, "dmu_object_next() = %d\n", error); abort(); } ASSERT3U(object_count, ==, usedobjs); if (leaked_objects != 0) { (void) printf("%d potentially leaked objects detected\n", leaked_objects); leaked_objects = 0; } } static void dump_uberblock(uberblock_t *ub, const char *header, const char *footer) { time_t timestamp = ub->ub_timestamp; (void) printf("%s", header ? header : ""); (void) printf("\tmagic = %016llx\n", (u_longlong_t)ub->ub_magic); (void) printf("\tversion = %llu\n", (u_longlong_t)ub->ub_version); (void) printf("\ttxg = %llu\n", (u_longlong_t)ub->ub_txg); (void) printf("\tguid_sum = %llu\n", (u_longlong_t)ub->ub_guid_sum); (void) printf("\ttimestamp = %llu UTC = %s", (u_longlong_t)ub->ub_timestamp, ctime(×tamp)); (void) printf("\tmmp_magic = %016llx\n", (u_longlong_t)ub->ub_mmp_magic); if (MMP_VALID(ub)) { (void) printf("\tmmp_delay = %0llu\n", (u_longlong_t)ub->ub_mmp_delay); if (MMP_SEQ_VALID(ub)) (void) printf("\tmmp_seq = %u\n", (unsigned int) MMP_SEQ(ub)); if (MMP_FAIL_INT_VALID(ub)) (void) printf("\tmmp_fail = %u\n", (unsigned int) MMP_FAIL_INT(ub)); if (MMP_INTERVAL_VALID(ub)) (void) printf("\tmmp_write = %u\n", (unsigned int) MMP_INTERVAL(ub)); /* After MMP_* to make summarize_uberblock_mmp cleaner */ (void) printf("\tmmp_valid = %x\n", (unsigned int) ub->ub_mmp_config & 0xFF); } if (dump_opt['u'] >= 4) { char blkbuf[BP_SPRINTF_LEN]; snprintf_blkptr(blkbuf, sizeof (blkbuf), &ub->ub_rootbp); (void) printf("\trootbp = %s\n", blkbuf); } (void) printf("\tcheckpoint_txg = %llu\n", (u_longlong_t)ub->ub_checkpoint_txg); (void) printf("%s", footer ? footer : ""); } static void dump_config(spa_t *spa) { dmu_buf_t *db; size_t nvsize = 0; int error = 0; error = dmu_bonus_hold(spa->spa_meta_objset, spa->spa_config_object, FTAG, &db); if (error == 0) { nvsize = *(uint64_t *)db->db_data; dmu_buf_rele(db, FTAG); (void) printf("\nMOS Configuration:\n"); dump_packed_nvlist(spa->spa_meta_objset, spa->spa_config_object, (void *)&nvsize, 1); } else { (void) fprintf(stderr, "dmu_bonus_hold(%llu) failed, errno %d", (u_longlong_t)spa->spa_config_object, error); } } static void dump_cachefile(const char *cachefile) { int fd; struct stat64 statbuf; char *buf; nvlist_t *config; if ((fd = open64(cachefile, O_RDONLY)) < 0) { (void) printf("cannot open '%s': %s\n", cachefile, strerror(errno)); exit(1); } if (fstat64(fd, &statbuf) != 0) { (void) printf("failed to stat '%s': %s\n", cachefile, strerror(errno)); exit(1); } if ((buf = malloc(statbuf.st_size)) == NULL) { (void) fprintf(stderr, "failed to allocate %llu bytes\n", (u_longlong_t)statbuf.st_size); exit(1); } if (read(fd, buf, statbuf.st_size) != statbuf.st_size) { (void) fprintf(stderr, "failed to read %llu bytes\n", (u_longlong_t)statbuf.st_size); exit(1); } (void) close(fd); if (nvlist_unpack(buf, statbuf.st_size, &config, 0) != 0) { (void) fprintf(stderr, "failed to unpack nvlist\n"); exit(1); } free(buf); dump_nvlist(config, 0); nvlist_free(config); } /* * ZFS label nvlist stats */ typedef struct zdb_nvl_stats { int zns_list_count; int zns_leaf_count; size_t zns_leaf_largest; size_t zns_leaf_total; nvlist_t *zns_string; nvlist_t *zns_uint64; nvlist_t *zns_boolean; } zdb_nvl_stats_t; static void collect_nvlist_stats(nvlist_t *nvl, zdb_nvl_stats_t *stats) { nvlist_t *list, **array; nvpair_t *nvp = NULL; char *name; uint_t i, items; stats->zns_list_count++; while ((nvp = nvlist_next_nvpair(nvl, nvp)) != NULL) { name = nvpair_name(nvp); switch (nvpair_type(nvp)) { case DATA_TYPE_STRING: fnvlist_add_string(stats->zns_string, name, fnvpair_value_string(nvp)); break; case DATA_TYPE_UINT64: fnvlist_add_uint64(stats->zns_uint64, name, fnvpair_value_uint64(nvp)); break; case DATA_TYPE_BOOLEAN: fnvlist_add_boolean(stats->zns_boolean, name); break; case DATA_TYPE_NVLIST: if (nvpair_value_nvlist(nvp, &list) == 0) collect_nvlist_stats(list, stats); break; case DATA_TYPE_NVLIST_ARRAY: if (nvpair_value_nvlist_array(nvp, &array, &items) != 0) break; for (i = 0; i < items; i++) { collect_nvlist_stats(array[i], stats); /* collect stats on leaf vdev */ if (strcmp(name, "children") == 0) { size_t size; (void) nvlist_size(array[i], &size, NV_ENCODE_XDR); stats->zns_leaf_total += size; if (size > stats->zns_leaf_largest) stats->zns_leaf_largest = size; stats->zns_leaf_count++; } } break; default: (void) printf("skip type %d!\n", (int)nvpair_type(nvp)); } } } static void dump_nvlist_stats(nvlist_t *nvl, size_t cap) { zdb_nvl_stats_t stats = { 0 }; size_t size, sum = 0, total; size_t noise; /* requires nvlist with non-unique names for stat collection */ VERIFY0(nvlist_alloc(&stats.zns_string, 0, 0)); VERIFY0(nvlist_alloc(&stats.zns_uint64, 0, 0)); VERIFY0(nvlist_alloc(&stats.zns_boolean, 0, 0)); VERIFY0(nvlist_size(stats.zns_boolean, &noise, NV_ENCODE_XDR)); (void) printf("\n\nZFS Label NVList Config Stats:\n"); VERIFY0(nvlist_size(nvl, &total, NV_ENCODE_XDR)); (void) printf(" %d bytes used, %d bytes free (using %4.1f%%)\n\n", (int)total, (int)(cap - total), 100.0 * total / cap); collect_nvlist_stats(nvl, &stats); VERIFY0(nvlist_size(stats.zns_uint64, &size, NV_ENCODE_XDR)); size -= noise; sum += size; (void) printf("%12s %4d %6d bytes (%5.2f%%)\n", "integers:", (int)fnvlist_num_pairs(stats.zns_uint64), (int)size, 100.0 * size / total); VERIFY0(nvlist_size(stats.zns_string, &size, NV_ENCODE_XDR)); size -= noise; sum += size; (void) printf("%12s %4d %6d bytes (%5.2f%%)\n", "strings:", (int)fnvlist_num_pairs(stats.zns_string), (int)size, 100.0 * size / total); VERIFY0(nvlist_size(stats.zns_boolean, &size, NV_ENCODE_XDR)); size -= noise; sum += size; (void) printf("%12s %4d %6d bytes (%5.2f%%)\n", "booleans:", (int)fnvlist_num_pairs(stats.zns_boolean), (int)size, 100.0 * size / total); size = total - sum; /* treat remainder as nvlist overhead */ (void) printf("%12s %4d %6d bytes (%5.2f%%)\n\n", "nvlists:", stats.zns_list_count, (int)size, 100.0 * size / total); if (stats.zns_leaf_count > 0) { size_t average = stats.zns_leaf_total / stats.zns_leaf_count; (void) printf("%12s %4d %6d bytes average\n", "leaf vdevs:", stats.zns_leaf_count, (int)average); (void) printf("%24d bytes largest\n", (int)stats.zns_leaf_largest); if (dump_opt['l'] >= 3 && average > 0) (void) printf(" space for %d additional leaf vdevs\n", (int)((cap - total) / average)); } (void) printf("\n"); nvlist_free(stats.zns_string); nvlist_free(stats.zns_uint64); nvlist_free(stats.zns_boolean); } typedef struct cksum_record { zio_cksum_t cksum; boolean_t labels[VDEV_LABELS]; avl_node_t link; } cksum_record_t; static int cksum_record_compare(const void *x1, const void *x2) { const cksum_record_t *l = (cksum_record_t *)x1; const cksum_record_t *r = (cksum_record_t *)x2; int arraysize = ARRAY_SIZE(l->cksum.zc_word); int difference = 0; for (int i = 0; i < arraysize; i++) { difference = TREE_CMP(l->cksum.zc_word[i], r->cksum.zc_word[i]); if (difference) break; } return (difference); } static cksum_record_t * cksum_record_alloc(zio_cksum_t *cksum, int l) { cksum_record_t *rec; rec = umem_zalloc(sizeof (*rec), UMEM_NOFAIL); rec->cksum = *cksum; rec->labels[l] = B_TRUE; return (rec); } static cksum_record_t * cksum_record_lookup(avl_tree_t *tree, zio_cksum_t *cksum) { cksum_record_t lookup = { .cksum = *cksum }; avl_index_t where; return (avl_find(tree, &lookup, &where)); } static cksum_record_t * cksum_record_insert(avl_tree_t *tree, zio_cksum_t *cksum, int l) { cksum_record_t *rec; rec = cksum_record_lookup(tree, cksum); if (rec) { rec->labels[l] = B_TRUE; } else { rec = cksum_record_alloc(cksum, l); avl_add(tree, rec); } return (rec); } static int first_label(cksum_record_t *rec) { for (int i = 0; i < VDEV_LABELS; i++) if (rec->labels[i]) return (i); return (-1); } static void print_label_numbers(const char *prefix, const cksum_record_t *rec) { fputs(prefix, stdout); for (int i = 0; i < VDEV_LABELS; i++) if (rec->labels[i] == B_TRUE) printf("%d ", i); putchar('\n'); } #define MAX_UBERBLOCK_COUNT (VDEV_UBERBLOCK_RING >> UBERBLOCK_SHIFT) typedef struct zdb_label { vdev_label_t label; uint64_t label_offset; nvlist_t *config_nv; cksum_record_t *config; cksum_record_t *uberblocks[MAX_UBERBLOCK_COUNT]; boolean_t header_printed; boolean_t read_failed; boolean_t cksum_valid; } zdb_label_t; static void print_label_header(zdb_label_t *label, int l) { if (dump_opt['q']) return; if (label->header_printed == B_TRUE) return; (void) printf("------------------------------------\n"); (void) printf("LABEL %d %s\n", l, label->cksum_valid ? "" : "(Bad label cksum)"); (void) printf("------------------------------------\n"); label->header_printed = B_TRUE; } static void print_l2arc_header(void) { (void) printf("------------------------------------\n"); (void) printf("L2ARC device header\n"); (void) printf("------------------------------------\n"); } static void print_l2arc_log_blocks(void) { (void) printf("------------------------------------\n"); (void) printf("L2ARC device log blocks\n"); (void) printf("------------------------------------\n"); } static void dump_l2arc_log_entries(uint64_t log_entries, l2arc_log_ent_phys_t *le, uint64_t i) { for (int j = 0; j < log_entries; j++) { dva_t dva = le[j].le_dva; (void) printf("lb[%4llu]\tle[%4d]\tDVA asize: %llu, " "vdev: %llu, offset: %llu\n", (u_longlong_t)i, j + 1, (u_longlong_t)DVA_GET_ASIZE(&dva), (u_longlong_t)DVA_GET_VDEV(&dva), (u_longlong_t)DVA_GET_OFFSET(&dva)); (void) printf("|\t\t\t\tbirth: %llu\n", (u_longlong_t)le[j].le_birth); (void) printf("|\t\t\t\tlsize: %llu\n", (u_longlong_t)L2BLK_GET_LSIZE((&le[j])->le_prop)); (void) printf("|\t\t\t\tpsize: %llu\n", (u_longlong_t)L2BLK_GET_PSIZE((&le[j])->le_prop)); (void) printf("|\t\t\t\tcompr: %llu\n", (u_longlong_t)L2BLK_GET_COMPRESS((&le[j])->le_prop)); (void) printf("|\t\t\t\tcomplevel: %llu\n", (u_longlong_t)(&le[j])->le_complevel); (void) printf("|\t\t\t\ttype: %llu\n", (u_longlong_t)L2BLK_GET_TYPE((&le[j])->le_prop)); (void) printf("|\t\t\t\tprotected: %llu\n", (u_longlong_t)L2BLK_GET_PROTECTED((&le[j])->le_prop)); (void) printf("|\t\t\t\tprefetch: %llu\n", (u_longlong_t)L2BLK_GET_PREFETCH((&le[j])->le_prop)); (void) printf("|\t\t\t\taddress: %llu\n", (u_longlong_t)le[j].le_daddr); (void) printf("|\t\t\t\tARC state: %llu\n", (u_longlong_t)L2BLK_GET_STATE((&le[j])->le_prop)); (void) printf("|\n"); } (void) printf("\n"); } static void dump_l2arc_log_blkptr(l2arc_log_blkptr_t lbps) { (void) printf("|\t\tdaddr: %llu\n", (u_longlong_t)lbps.lbp_daddr); (void) printf("|\t\tpayload_asize: %llu\n", (u_longlong_t)lbps.lbp_payload_asize); (void) printf("|\t\tpayload_start: %llu\n", (u_longlong_t)lbps.lbp_payload_start); (void) printf("|\t\tlsize: %llu\n", (u_longlong_t)L2BLK_GET_LSIZE((&lbps)->lbp_prop)); (void) printf("|\t\tasize: %llu\n", (u_longlong_t)L2BLK_GET_PSIZE((&lbps)->lbp_prop)); (void) printf("|\t\tcompralgo: %llu\n", (u_longlong_t)L2BLK_GET_COMPRESS((&lbps)->lbp_prop)); (void) printf("|\t\tcksumalgo: %llu\n", (u_longlong_t)L2BLK_GET_CHECKSUM((&lbps)->lbp_prop)); (void) printf("|\n\n"); } static void dump_l2arc_log_blocks(int fd, l2arc_dev_hdr_phys_t l2dhdr, l2arc_dev_hdr_phys_t *rebuild) { l2arc_log_blk_phys_t this_lb; uint64_t asize; l2arc_log_blkptr_t lbps[2]; abd_t *abd; zio_cksum_t cksum; int failed = 0; l2arc_dev_t dev; if (!dump_opt['q']) print_l2arc_log_blocks(); memcpy(lbps, l2dhdr.dh_start_lbps, sizeof (lbps)); dev.l2ad_evict = l2dhdr.dh_evict; dev.l2ad_start = l2dhdr.dh_start; dev.l2ad_end = l2dhdr.dh_end; if (l2dhdr.dh_start_lbps[0].lbp_daddr == 0) { /* no log blocks to read */ if (!dump_opt['q']) { (void) printf("No log blocks to read\n"); (void) printf("\n"); } return; } else { dev.l2ad_hand = lbps[0].lbp_daddr + L2BLK_GET_PSIZE((&lbps[0])->lbp_prop); } dev.l2ad_first = !!(l2dhdr.dh_flags & L2ARC_DEV_HDR_EVICT_FIRST); for (;;) { if (!l2arc_log_blkptr_valid(&dev, &lbps[0])) break; /* L2BLK_GET_PSIZE returns aligned size for log blocks */ asize = L2BLK_GET_PSIZE((&lbps[0])->lbp_prop); if (pread64(fd, &this_lb, asize, lbps[0].lbp_daddr) != asize) { if (!dump_opt['q']) { (void) printf("Error while reading next log " "block\n\n"); } break; } fletcher_4_native_varsize(&this_lb, asize, &cksum); if (!ZIO_CHECKSUM_EQUAL(cksum, lbps[0].lbp_cksum)) { failed++; if (!dump_opt['q']) { (void) printf("Invalid cksum\n"); dump_l2arc_log_blkptr(lbps[0]); } break; } switch (L2BLK_GET_COMPRESS((&lbps[0])->lbp_prop)) { case ZIO_COMPRESS_OFF: break; default: abd = abd_alloc_for_io(asize, B_TRUE); abd_copy_from_buf_off(abd, &this_lb, 0, asize); zio_decompress_data(L2BLK_GET_COMPRESS( (&lbps[0])->lbp_prop), abd, &this_lb, asize, sizeof (this_lb), NULL); abd_free(abd); break; } if (this_lb.lb_magic == BSWAP_64(L2ARC_LOG_BLK_MAGIC)) byteswap_uint64_array(&this_lb, sizeof (this_lb)); if (this_lb.lb_magic != L2ARC_LOG_BLK_MAGIC) { if (!dump_opt['q']) (void) printf("Invalid log block magic\n\n"); break; } rebuild->dh_lb_count++; rebuild->dh_lb_asize += asize; if (dump_opt['l'] > 1 && !dump_opt['q']) { (void) printf("lb[%4llu]\tmagic: %llu\n", (u_longlong_t)rebuild->dh_lb_count, (u_longlong_t)this_lb.lb_magic); dump_l2arc_log_blkptr(lbps[0]); } if (dump_opt['l'] > 2 && !dump_opt['q']) dump_l2arc_log_entries(l2dhdr.dh_log_entries, this_lb.lb_entries, rebuild->dh_lb_count); if (l2arc_range_check_overlap(lbps[1].lbp_payload_start, lbps[0].lbp_payload_start, dev.l2ad_evict) && !dev.l2ad_first) break; lbps[0] = lbps[1]; lbps[1] = this_lb.lb_prev_lbp; } if (!dump_opt['q']) { (void) printf("log_blk_count:\t %llu with valid cksum\n", (u_longlong_t)rebuild->dh_lb_count); (void) printf("\t\t %d with invalid cksum\n", failed); (void) printf("log_blk_asize:\t %llu\n\n", (u_longlong_t)rebuild->dh_lb_asize); } } static int dump_l2arc_header(int fd) { l2arc_dev_hdr_phys_t l2dhdr = {0}, rebuild = {0}; int error = B_FALSE; if (pread64(fd, &l2dhdr, sizeof (l2dhdr), VDEV_LABEL_START_SIZE) != sizeof (l2dhdr)) { error = B_TRUE; } else { if (l2dhdr.dh_magic == BSWAP_64(L2ARC_DEV_HDR_MAGIC)) byteswap_uint64_array(&l2dhdr, sizeof (l2dhdr)); if (l2dhdr.dh_magic != L2ARC_DEV_HDR_MAGIC) error = B_TRUE; } if (error) { (void) printf("L2ARC device header not found\n\n"); /* Do not return an error here for backward compatibility */ return (0); } else if (!dump_opt['q']) { print_l2arc_header(); (void) printf(" magic: %llu\n", (u_longlong_t)l2dhdr.dh_magic); (void) printf(" version: %llu\n", (u_longlong_t)l2dhdr.dh_version); (void) printf(" pool_guid: %llu\n", (u_longlong_t)l2dhdr.dh_spa_guid); (void) printf(" flags: %llu\n", (u_longlong_t)l2dhdr.dh_flags); (void) printf(" start_lbps[0]: %llu\n", (u_longlong_t) l2dhdr.dh_start_lbps[0].lbp_daddr); (void) printf(" start_lbps[1]: %llu\n", (u_longlong_t) l2dhdr.dh_start_lbps[1].lbp_daddr); (void) printf(" log_blk_ent: %llu\n", (u_longlong_t)l2dhdr.dh_log_entries); (void) printf(" start: %llu\n", (u_longlong_t)l2dhdr.dh_start); (void) printf(" end: %llu\n", (u_longlong_t)l2dhdr.dh_end); (void) printf(" evict: %llu\n", (u_longlong_t)l2dhdr.dh_evict); (void) printf(" lb_asize_refcount: %llu\n", (u_longlong_t)l2dhdr.dh_lb_asize); (void) printf(" lb_count_refcount: %llu\n", (u_longlong_t)l2dhdr.dh_lb_count); (void) printf(" trim_action_time: %llu\n", (u_longlong_t)l2dhdr.dh_trim_action_time); (void) printf(" trim_state: %llu\n\n", (u_longlong_t)l2dhdr.dh_trim_state); } dump_l2arc_log_blocks(fd, l2dhdr, &rebuild); /* * The total aligned size of log blocks and the number of log blocks * reported in the header of the device may be less than what zdb * reports by dump_l2arc_log_blocks() which emulates l2arc_rebuild(). * This happens because dump_l2arc_log_blocks() lacks the memory * pressure valve that l2arc_rebuild() has. Thus, if we are on a system * with low memory, l2arc_rebuild will exit prematurely and dh_lb_asize * and dh_lb_count will be lower to begin with than what exists on the * device. This is normal and zdb should not exit with an error. The * opposite case should never happen though, the values reported in the * header should never be higher than what dump_l2arc_log_blocks() and * l2arc_rebuild() report. If this happens there is a leak in the * accounting of log blocks. */ if (l2dhdr.dh_lb_asize > rebuild.dh_lb_asize || l2dhdr.dh_lb_count > rebuild.dh_lb_count) return (1); return (0); } static void dump_config_from_label(zdb_label_t *label, size_t buflen, int l) { if (dump_opt['q']) return; if ((dump_opt['l'] < 3) && (first_label(label->config) != l)) return; print_label_header(label, l); dump_nvlist(label->config_nv, 4); print_label_numbers(" labels = ", label->config); if (dump_opt['l'] >= 2) dump_nvlist_stats(label->config_nv, buflen); } #define ZDB_MAX_UB_HEADER_SIZE 32 static void dump_label_uberblocks(zdb_label_t *label, uint64_t ashift, int label_num) { vdev_t vd; char header[ZDB_MAX_UB_HEADER_SIZE]; vd.vdev_ashift = ashift; vd.vdev_top = &vd; for (int i = 0; i < VDEV_UBERBLOCK_COUNT(&vd); i++) { uint64_t uoff = VDEV_UBERBLOCK_OFFSET(&vd, i); uberblock_t *ub = (void *)((char *)&label->label + uoff); cksum_record_t *rec = label->uberblocks[i]; if (rec == NULL) { if (dump_opt['u'] >= 2) { print_label_header(label, label_num); (void) printf(" Uberblock[%d] invalid\n", i); } continue; } if ((dump_opt['u'] < 3) && (first_label(rec) != label_num)) continue; if ((dump_opt['u'] < 4) && (ub->ub_mmp_magic == MMP_MAGIC) && ub->ub_mmp_delay && (i >= VDEV_UBERBLOCK_COUNT(&vd) - MMP_BLOCKS_PER_LABEL)) continue; print_label_header(label, label_num); (void) snprintf(header, ZDB_MAX_UB_HEADER_SIZE, " Uberblock[%d]\n", i); dump_uberblock(ub, header, ""); print_label_numbers(" labels = ", rec); } } static char curpath[PATH_MAX]; /* * Iterate through the path components, recursively passing * current one's obj and remaining path until we find the obj * for the last one. */ static int dump_path_impl(objset_t *os, uint64_t obj, char *name, uint64_t *retobj) { int err; boolean_t header = B_TRUE; uint64_t child_obj; char *s; dmu_buf_t *db; dmu_object_info_t doi; if ((s = strchr(name, '/')) != NULL) *s = '\0'; err = zap_lookup(os, obj, name, 8, 1, &child_obj); (void) strlcat(curpath, name, sizeof (curpath)); if (err != 0) { (void) fprintf(stderr, "failed to lookup %s: %s\n", curpath, strerror(err)); return (err); } child_obj = ZFS_DIRENT_OBJ(child_obj); err = sa_buf_hold(os, child_obj, FTAG, &db); if (err != 0) { (void) fprintf(stderr, "failed to get SA dbuf for obj %llu: %s\n", (u_longlong_t)child_obj, strerror(err)); return (EINVAL); } dmu_object_info_from_db(db, &doi); sa_buf_rele(db, FTAG); if (doi.doi_bonus_type != DMU_OT_SA && doi.doi_bonus_type != DMU_OT_ZNODE) { (void) fprintf(stderr, "invalid bonus type %d for obj %llu\n", doi.doi_bonus_type, (u_longlong_t)child_obj); return (EINVAL); } if (dump_opt['v'] > 6) { (void) printf("obj=%llu %s type=%d bonustype=%d\n", (u_longlong_t)child_obj, curpath, doi.doi_type, doi.doi_bonus_type); } (void) strlcat(curpath, "/", sizeof (curpath)); switch (doi.doi_type) { case DMU_OT_DIRECTORY_CONTENTS: if (s != NULL && *(s + 1) != '\0') return (dump_path_impl(os, child_obj, s + 1, retobj)); zfs_fallthrough; case DMU_OT_PLAIN_FILE_CONTENTS: if (retobj != NULL) { *retobj = child_obj; } else { dump_object(os, child_obj, dump_opt['v'], &header, NULL, 0); } return (0); default: (void) fprintf(stderr, "object %llu has non-file/directory " "type %d\n", (u_longlong_t)obj, doi.doi_type); break; } return (EINVAL); } /* * Dump the blocks for the object specified by path inside the dataset. */ static int dump_path(char *ds, char *path, uint64_t *retobj) { int err; objset_t *os; uint64_t root_obj; err = open_objset(ds, FTAG, &os); if (err != 0) return (err); err = zap_lookup(os, MASTER_NODE_OBJ, ZFS_ROOT_OBJ, 8, 1, &root_obj); if (err != 0) { (void) fprintf(stderr, "can't lookup root znode: %s\n", strerror(err)); close_objset(os, FTAG); return (EINVAL); } (void) snprintf(curpath, sizeof (curpath), "dataset=%s path=/", ds); err = dump_path_impl(os, root_obj, path, retobj); close_objset(os, FTAG); return (err); } static int zdb_copy_object(objset_t *os, uint64_t srcobj, char *destfile) { int err = 0; uint64_t size, readsize, oursize, offset; ssize_t writesize; sa_handle_t *hdl; (void) printf("Copying object %" PRIu64 " to file %s\n", srcobj, destfile); VERIFY3P(os, ==, sa_os); if ((err = sa_handle_get(os, srcobj, NULL, SA_HDL_PRIVATE, &hdl))) { (void) printf("Failed to get handle for SA znode\n"); return (err); } if ((err = sa_lookup(hdl, sa_attr_table[ZPL_SIZE], &size, 8))) { (void) sa_handle_destroy(hdl); return (err); } (void) sa_handle_destroy(hdl); (void) printf("Object %" PRIu64 " is %" PRIu64 " bytes\n", srcobj, size); if (size == 0) { return (EINVAL); } int fd = open(destfile, O_WRONLY | O_CREAT | O_TRUNC, 0644); if (fd == -1) return (errno); /* * We cap the size at 1 mebibyte here to prevent * allocation failures and nigh-infinite printing if the * object is extremely large. */ oursize = MIN(size, 1 << 20); offset = 0; char *buf = kmem_alloc(oursize, KM_NOSLEEP); if (buf == NULL) { (void) close(fd); return (ENOMEM); } while (offset < size) { readsize = MIN(size - offset, 1 << 20); err = dmu_read(os, srcobj, offset, readsize, buf, 0); if (err != 0) { (void) printf("got error %u from dmu_read\n", err); kmem_free(buf, oursize); (void) close(fd); return (err); } if (dump_opt['v'] > 3) { (void) printf("Read offset=%" PRIu64 " size=%" PRIu64 " error=%d\n", offset, readsize, err); } writesize = write(fd, buf, readsize); if (writesize < 0) { err = errno; break; } else if (writesize != readsize) { /* Incomplete write */ (void) fprintf(stderr, "Short write, only wrote %llu of" " %" PRIu64 " bytes, exiting...\n", (u_longlong_t)writesize, readsize); break; } offset += readsize; } (void) close(fd); if (buf != NULL) kmem_free(buf, oursize); return (err); } static boolean_t label_cksum_valid(vdev_label_t *label, uint64_t offset) { zio_checksum_info_t *ci = &zio_checksum_table[ZIO_CHECKSUM_LABEL]; zio_cksum_t expected_cksum; zio_cksum_t actual_cksum; zio_cksum_t verifier; zio_eck_t *eck; int byteswap; void *data = (char *)label + offsetof(vdev_label_t, vl_vdev_phys); eck = (zio_eck_t *)((char *)(data) + VDEV_PHYS_SIZE) - 1; offset += offsetof(vdev_label_t, vl_vdev_phys); ZIO_SET_CHECKSUM(&verifier, offset, 0, 0, 0); byteswap = (eck->zec_magic == BSWAP_64(ZEC_MAGIC)); if (byteswap) byteswap_uint64_array(&verifier, sizeof (zio_cksum_t)); expected_cksum = eck->zec_cksum; eck->zec_cksum = verifier; abd_t *abd = abd_get_from_buf(data, VDEV_PHYS_SIZE); ci->ci_func[byteswap](abd, VDEV_PHYS_SIZE, NULL, &actual_cksum); abd_free(abd); if (byteswap) byteswap_uint64_array(&expected_cksum, sizeof (zio_cksum_t)); if (ZIO_CHECKSUM_EQUAL(actual_cksum, expected_cksum)) return (B_TRUE); return (B_FALSE); } static int dump_label(const char *dev) { char path[MAXPATHLEN]; zdb_label_t labels[VDEV_LABELS] = {{{{0}}}}; uint64_t psize, ashift, l2cache; struct stat64 statbuf; boolean_t config_found = B_FALSE; boolean_t error = B_FALSE; boolean_t read_l2arc_header = B_FALSE; avl_tree_t config_tree; avl_tree_t uberblock_tree; void *node, *cookie; int fd; /* * Check if we were given absolute path and use it as is. * Otherwise if the provided vdev name doesn't point to a file, * try prepending expected disk paths and partition numbers. */ (void) strlcpy(path, dev, sizeof (path)); if (dev[0] != '/' && stat64(path, &statbuf) != 0) { int error; error = zfs_resolve_shortname(dev, path, MAXPATHLEN); if (error == 0 && zfs_dev_is_whole_disk(path)) { if (zfs_append_partition(path, MAXPATHLEN) == -1) error = ENOENT; } if (error || (stat64(path, &statbuf) != 0)) { (void) printf("failed to find device %s, try " "specifying absolute path instead\n", dev); return (1); } } if ((fd = open64(path, O_RDONLY)) < 0) { (void) printf("cannot open '%s': %s\n", path, strerror(errno)); exit(1); } if (fstat64_blk(fd, &statbuf) != 0) { (void) printf("failed to stat '%s': %s\n", path, strerror(errno)); (void) close(fd); exit(1); } if (S_ISBLK(statbuf.st_mode) && zfs_dev_flush(fd) != 0) (void) printf("failed to invalidate cache '%s' : %s\n", path, strerror(errno)); avl_create(&config_tree, cksum_record_compare, sizeof (cksum_record_t), offsetof(cksum_record_t, link)); avl_create(&uberblock_tree, cksum_record_compare, sizeof (cksum_record_t), offsetof(cksum_record_t, link)); psize = statbuf.st_size; psize = P2ALIGN(psize, (uint64_t)sizeof (vdev_label_t)); ashift = SPA_MINBLOCKSHIFT; /* * 1. Read the label from disk * 2. Verify label cksum * 3. Unpack the configuration and insert in config tree. * 4. Traverse all uberblocks and insert in uberblock tree. */ for (int l = 0; l < VDEV_LABELS; l++) { zdb_label_t *label = &labels[l]; char *buf = label->label.vl_vdev_phys.vp_nvlist; size_t buflen = sizeof (label->label.vl_vdev_phys.vp_nvlist); nvlist_t *config; cksum_record_t *rec; zio_cksum_t cksum; vdev_t vd; label->label_offset = vdev_label_offset(psize, l, 0); if (pread64(fd, &label->label, sizeof (label->label), label->label_offset) != sizeof (label->label)) { if (!dump_opt['q']) (void) printf("failed to read label %d\n", l); label->read_failed = B_TRUE; error = B_TRUE; continue; } label->read_failed = B_FALSE; label->cksum_valid = label_cksum_valid(&label->label, label->label_offset); if (nvlist_unpack(buf, buflen, &config, 0) == 0) { nvlist_t *vdev_tree = NULL; size_t size; if ((nvlist_lookup_nvlist(config, ZPOOL_CONFIG_VDEV_TREE, &vdev_tree) != 0) || (nvlist_lookup_uint64(vdev_tree, ZPOOL_CONFIG_ASHIFT, &ashift) != 0)) ashift = SPA_MINBLOCKSHIFT; if (nvlist_size(config, &size, NV_ENCODE_XDR) != 0) size = buflen; /* If the device is a cache device clear the header. */ if (!read_l2arc_header) { if (nvlist_lookup_uint64(config, ZPOOL_CONFIG_POOL_STATE, &l2cache) == 0 && l2cache == POOL_STATE_L2CACHE) { read_l2arc_header = B_TRUE; } } fletcher_4_native_varsize(buf, size, &cksum); rec = cksum_record_insert(&config_tree, &cksum, l); label->config = rec; label->config_nv = config; config_found = B_TRUE; } else { error = B_TRUE; } vd.vdev_ashift = ashift; vd.vdev_top = &vd; for (int i = 0; i < VDEV_UBERBLOCK_COUNT(&vd); i++) { uint64_t uoff = VDEV_UBERBLOCK_OFFSET(&vd, i); uberblock_t *ub = (void *)((char *)label + uoff); if (uberblock_verify(ub)) continue; fletcher_4_native_varsize(ub, sizeof (*ub), &cksum); rec = cksum_record_insert(&uberblock_tree, &cksum, l); label->uberblocks[i] = rec; } } /* * Dump the label and uberblocks. */ for (int l = 0; l < VDEV_LABELS; l++) { zdb_label_t *label = &labels[l]; size_t buflen = sizeof (label->label.vl_vdev_phys.vp_nvlist); if (label->read_failed == B_TRUE) continue; if (label->config_nv) { dump_config_from_label(label, buflen, l); } else { if (!dump_opt['q']) (void) printf("failed to unpack label %d\n", l); } if (dump_opt['u']) dump_label_uberblocks(label, ashift, l); nvlist_free(label->config_nv); } /* * Dump the L2ARC header, if existent. */ if (read_l2arc_header) error |= dump_l2arc_header(fd); cookie = NULL; while ((node = avl_destroy_nodes(&config_tree, &cookie)) != NULL) umem_free(node, sizeof (cksum_record_t)); cookie = NULL; while ((node = avl_destroy_nodes(&uberblock_tree, &cookie)) != NULL) umem_free(node, sizeof (cksum_record_t)); avl_destroy(&config_tree); avl_destroy(&uberblock_tree); (void) close(fd); return (config_found == B_FALSE ? 2 : (error == B_TRUE ? 1 : 0)); } static uint64_t dataset_feature_count[SPA_FEATURES]; static uint64_t global_feature_count[SPA_FEATURES]; static uint64_t remap_deadlist_count = 0; static int dump_one_objset(const char *dsname, void *arg) { (void) arg; int error; objset_t *os; spa_feature_t f; error = open_objset(dsname, FTAG, &os); if (error != 0) return (0); for (f = 0; f < SPA_FEATURES; f++) { if (!dsl_dataset_feature_is_active(dmu_objset_ds(os), f)) continue; ASSERT(spa_feature_table[f].fi_flags & ZFEATURE_FLAG_PER_DATASET); dataset_feature_count[f]++; } if (dsl_dataset_remap_deadlist_exists(dmu_objset_ds(os))) { remap_deadlist_count++; } for (dsl_bookmark_node_t *dbn = avl_first(&dmu_objset_ds(os)->ds_bookmarks); dbn != NULL; dbn = AVL_NEXT(&dmu_objset_ds(os)->ds_bookmarks, dbn)) { mos_obj_refd(dbn->dbn_phys.zbm_redaction_obj); if (dbn->dbn_phys.zbm_redaction_obj != 0) global_feature_count[SPA_FEATURE_REDACTION_BOOKMARKS]++; if (dbn->dbn_phys.zbm_flags & ZBM_FLAG_HAS_FBN) global_feature_count[SPA_FEATURE_BOOKMARK_WRITTEN]++; } if (dsl_deadlist_is_open(&dmu_objset_ds(os)->ds_dir->dd_livelist) && !dmu_objset_is_snapshot(os)) { global_feature_count[SPA_FEATURE_LIVELIST]++; } dump_objset(os); close_objset(os, FTAG); fuid_table_destroy(); return (0); } /* * Block statistics. */ #define PSIZE_HISTO_SIZE (SPA_OLD_MAXBLOCKSIZE / SPA_MINBLOCKSIZE + 2) typedef struct zdb_blkstats { uint64_t zb_asize; uint64_t zb_lsize; uint64_t zb_psize; uint64_t zb_count; uint64_t zb_gangs; uint64_t zb_ditto_samevdev; uint64_t zb_ditto_same_ms; uint64_t zb_psize_histogram[PSIZE_HISTO_SIZE]; } zdb_blkstats_t; /* * Extended object types to report deferred frees and dedup auto-ditto blocks. */ #define ZDB_OT_DEFERRED (DMU_OT_NUMTYPES + 0) #define ZDB_OT_DITTO (DMU_OT_NUMTYPES + 1) #define ZDB_OT_OTHER (DMU_OT_NUMTYPES + 2) #define ZDB_OT_TOTAL (DMU_OT_NUMTYPES + 3) static const char *zdb_ot_extname[] = { "deferred free", "dedup ditto", "other", "Total", }; #define ZB_TOTAL DN_MAX_LEVELS #define SPA_MAX_FOR_16M (SPA_MAXBLOCKSHIFT+1) typedef struct zdb_cb { zdb_blkstats_t zcb_type[ZB_TOTAL + 1][ZDB_OT_TOTAL + 1]; uint64_t zcb_removing_size; uint64_t zcb_checkpoint_size; uint64_t zcb_dedup_asize; uint64_t zcb_dedup_blocks; uint64_t zcb_psize_count[SPA_MAX_FOR_16M]; uint64_t zcb_lsize_count[SPA_MAX_FOR_16M]; uint64_t zcb_asize_count[SPA_MAX_FOR_16M]; uint64_t zcb_psize_len[SPA_MAX_FOR_16M]; uint64_t zcb_lsize_len[SPA_MAX_FOR_16M]; uint64_t zcb_asize_len[SPA_MAX_FOR_16M]; uint64_t zcb_psize_total; uint64_t zcb_lsize_total; uint64_t zcb_asize_total; uint64_t zcb_embedded_blocks[NUM_BP_EMBEDDED_TYPES]; uint64_t zcb_embedded_histogram[NUM_BP_EMBEDDED_TYPES] [BPE_PAYLOAD_SIZE + 1]; uint64_t zcb_start; hrtime_t zcb_lastprint; uint64_t zcb_totalasize; uint64_t zcb_errors[256]; int zcb_readfails; int zcb_haderrors; spa_t *zcb_spa; uint32_t **zcb_vd_obsolete_counts; } zdb_cb_t; /* test if two DVA offsets from same vdev are within the same metaslab */ static boolean_t same_metaslab(spa_t *spa, uint64_t vdev, uint64_t off1, uint64_t off2) { vdev_t *vd = vdev_lookup_top(spa, vdev); uint64_t ms_shift = vd->vdev_ms_shift; return ((off1 >> ms_shift) == (off2 >> ms_shift)); } /* * Used to simplify reporting of the histogram data. */ typedef struct one_histo { const char *name; uint64_t *count; uint64_t *len; uint64_t cumulative; } one_histo_t; /* * The number of separate histograms processed for psize, lsize and asize. */ #define NUM_HISTO 3 /* * This routine will create a fixed column size output of three different * histograms showing by blocksize of 512 - 2^ SPA_MAX_FOR_16M * the count, length and cumulative length of the psize, lsize and * asize blocks. * * All three types of blocks are listed on a single line * * By default the table is printed in nicenumber format (e.g. 123K) but * if the '-P' parameter is specified then the full raw number (parseable) * is printed out. */ static void dump_size_histograms(zdb_cb_t *zcb) { /* * A temporary buffer that allows us to convert a number into * a string using zdb_nicenumber to allow either raw or human * readable numbers to be output. */ char numbuf[32]; /* * Define titles which are used in the headers of the tables * printed by this routine. */ const char blocksize_title1[] = "block"; const char blocksize_title2[] = "size"; const char count_title[] = "Count"; const char length_title[] = "Size"; const char cumulative_title[] = "Cum."; /* * Setup the histogram arrays (psize, lsize, and asize). */ one_histo_t parm_histo[NUM_HISTO]; parm_histo[0].name = "psize"; parm_histo[0].count = zcb->zcb_psize_count; parm_histo[0].len = zcb->zcb_psize_len; parm_histo[0].cumulative = 0; parm_histo[1].name = "lsize"; parm_histo[1].count = zcb->zcb_lsize_count; parm_histo[1].len = zcb->zcb_lsize_len; parm_histo[1].cumulative = 0; parm_histo[2].name = "asize"; parm_histo[2].count = zcb->zcb_asize_count; parm_histo[2].len = zcb->zcb_asize_len; parm_histo[2].cumulative = 0; (void) printf("\nBlock Size Histogram\n"); /* * Print the first line titles */ if (dump_opt['P']) (void) printf("\n%s\t", blocksize_title1); else (void) printf("\n%7s ", blocksize_title1); for (int j = 0; j < NUM_HISTO; j++) { if (dump_opt['P']) { if (j < NUM_HISTO - 1) { (void) printf("%s\t\t\t", parm_histo[j].name); } else { /* Don't print trailing spaces */ (void) printf(" %s", parm_histo[j].name); } } else { if (j < NUM_HISTO - 1) { /* Left aligned strings in the output */ (void) printf("%-7s ", parm_histo[j].name); } else { /* Don't print trailing spaces */ (void) printf("%s", parm_histo[j].name); } } } (void) printf("\n"); /* * Print the second line titles */ if (dump_opt['P']) { (void) printf("%s\t", blocksize_title2); } else { (void) printf("%7s ", blocksize_title2); } for (int i = 0; i < NUM_HISTO; i++) { if (dump_opt['P']) { (void) printf("%s\t%s\t%s\t", count_title, length_title, cumulative_title); } else { (void) printf("%7s%7s%7s", count_title, length_title, cumulative_title); } } (void) printf("\n"); /* * Print the rows */ for (int i = SPA_MINBLOCKSHIFT; i < SPA_MAX_FOR_16M; i++) { /* * Print the first column showing the blocksize */ zdb_nicenum((1ULL << i), numbuf, sizeof (numbuf)); if (dump_opt['P']) { printf("%s", numbuf); } else { printf("%7s:", numbuf); } /* * Print the remaining set of 3 columns per size: * for psize, lsize and asize */ for (int j = 0; j < NUM_HISTO; j++) { parm_histo[j].cumulative += parm_histo[j].len[i]; zdb_nicenum(parm_histo[j].count[i], numbuf, sizeof (numbuf)); if (dump_opt['P']) (void) printf("\t%s", numbuf); else (void) printf("%7s", numbuf); zdb_nicenum(parm_histo[j].len[i], numbuf, sizeof (numbuf)); if (dump_opt['P']) (void) printf("\t%s", numbuf); else (void) printf("%7s", numbuf); zdb_nicenum(parm_histo[j].cumulative, numbuf, sizeof (numbuf)); if (dump_opt['P']) (void) printf("\t%s", numbuf); else (void) printf("%7s", numbuf); } (void) printf("\n"); } } static void zdb_count_block(zdb_cb_t *zcb, zilog_t *zilog, const blkptr_t *bp, dmu_object_type_t type) { uint64_t refcnt = 0; int i; ASSERT(type < ZDB_OT_TOTAL); if (zilog && zil_bp_tree_add(zilog, bp) != 0) return; spa_config_enter(zcb->zcb_spa, SCL_CONFIG, FTAG, RW_READER); for (i = 0; i < 4; i++) { int l = (i < 2) ? BP_GET_LEVEL(bp) : ZB_TOTAL; int t = (i & 1) ? type : ZDB_OT_TOTAL; int equal; zdb_blkstats_t *zb = &zcb->zcb_type[l][t]; zb->zb_asize += BP_GET_ASIZE(bp); zb->zb_lsize += BP_GET_LSIZE(bp); zb->zb_psize += BP_GET_PSIZE(bp); zb->zb_count++; /* * The histogram is only big enough to record blocks up to * SPA_OLD_MAXBLOCKSIZE; larger blocks go into the last, * "other", bucket. */ unsigned idx = BP_GET_PSIZE(bp) >> SPA_MINBLOCKSHIFT; idx = MIN(idx, SPA_OLD_MAXBLOCKSIZE / SPA_MINBLOCKSIZE + 1); zb->zb_psize_histogram[idx]++; zb->zb_gangs += BP_COUNT_GANG(bp); switch (BP_GET_NDVAS(bp)) { case 2: if (DVA_GET_VDEV(&bp->blk_dva[0]) == DVA_GET_VDEV(&bp->blk_dva[1])) { zb->zb_ditto_samevdev++; if (same_metaslab(zcb->zcb_spa, DVA_GET_VDEV(&bp->blk_dva[0]), DVA_GET_OFFSET(&bp->blk_dva[0]), DVA_GET_OFFSET(&bp->blk_dva[1]))) zb->zb_ditto_same_ms++; } break; case 3: equal = (DVA_GET_VDEV(&bp->blk_dva[0]) == DVA_GET_VDEV(&bp->blk_dva[1])) + (DVA_GET_VDEV(&bp->blk_dva[0]) == DVA_GET_VDEV(&bp->blk_dva[2])) + (DVA_GET_VDEV(&bp->blk_dva[1]) == DVA_GET_VDEV(&bp->blk_dva[2])); if (equal != 0) { zb->zb_ditto_samevdev++; if (DVA_GET_VDEV(&bp->blk_dva[0]) == DVA_GET_VDEV(&bp->blk_dva[1]) && same_metaslab(zcb->zcb_spa, DVA_GET_VDEV(&bp->blk_dva[0]), DVA_GET_OFFSET(&bp->blk_dva[0]), DVA_GET_OFFSET(&bp->blk_dva[1]))) zb->zb_ditto_same_ms++; else if (DVA_GET_VDEV(&bp->blk_dva[0]) == DVA_GET_VDEV(&bp->blk_dva[2]) && same_metaslab(zcb->zcb_spa, DVA_GET_VDEV(&bp->blk_dva[0]), DVA_GET_OFFSET(&bp->blk_dva[0]), DVA_GET_OFFSET(&bp->blk_dva[2]))) zb->zb_ditto_same_ms++; else if (DVA_GET_VDEV(&bp->blk_dva[1]) == DVA_GET_VDEV(&bp->blk_dva[2]) && same_metaslab(zcb->zcb_spa, DVA_GET_VDEV(&bp->blk_dva[1]), DVA_GET_OFFSET(&bp->blk_dva[1]), DVA_GET_OFFSET(&bp->blk_dva[2]))) zb->zb_ditto_same_ms++; } break; } } spa_config_exit(zcb->zcb_spa, SCL_CONFIG, FTAG); if (BP_IS_EMBEDDED(bp)) { zcb->zcb_embedded_blocks[BPE_GET_ETYPE(bp)]++; zcb->zcb_embedded_histogram[BPE_GET_ETYPE(bp)] [BPE_GET_PSIZE(bp)]++; return; } /* * The binning histogram bins by powers of two up to * SPA_MAXBLOCKSIZE rather than creating bins for * every possible blocksize found in the pool. */ int bin = highbit64(BP_GET_PSIZE(bp)) - 1; zcb->zcb_psize_count[bin]++; zcb->zcb_psize_len[bin] += BP_GET_PSIZE(bp); zcb->zcb_psize_total += BP_GET_PSIZE(bp); bin = highbit64(BP_GET_LSIZE(bp)) - 1; zcb->zcb_lsize_count[bin]++; zcb->zcb_lsize_len[bin] += BP_GET_LSIZE(bp); zcb->zcb_lsize_total += BP_GET_LSIZE(bp); bin = highbit64(BP_GET_ASIZE(bp)) - 1; zcb->zcb_asize_count[bin]++; zcb->zcb_asize_len[bin] += BP_GET_ASIZE(bp); zcb->zcb_asize_total += BP_GET_ASIZE(bp); if (dump_opt['L']) return; if (BP_GET_DEDUP(bp)) { ddt_t *ddt; ddt_entry_t *dde; ddt = ddt_select(zcb->zcb_spa, bp); ddt_enter(ddt); dde = ddt_lookup(ddt, bp, B_FALSE); if (dde == NULL) { refcnt = 0; } else { ddt_phys_t *ddp = ddt_phys_select(dde, bp); ddt_phys_decref(ddp); refcnt = ddp->ddp_refcnt; if (ddt_phys_total_refcnt(dde) == 0) ddt_remove(ddt, dde); } ddt_exit(ddt); } VERIFY3U(zio_wait(zio_claim(NULL, zcb->zcb_spa, refcnt ? 0 : spa_min_claim_txg(zcb->zcb_spa), bp, NULL, NULL, ZIO_FLAG_CANFAIL)), ==, 0); } static void zdb_blkptr_done(zio_t *zio) { spa_t *spa = zio->io_spa; blkptr_t *bp = zio->io_bp; int ioerr = zio->io_error; zdb_cb_t *zcb = zio->io_private; zbookmark_phys_t *zb = &zio->io_bookmark; mutex_enter(&spa->spa_scrub_lock); spa->spa_load_verify_bytes -= BP_GET_PSIZE(bp); cv_broadcast(&spa->spa_scrub_io_cv); if (ioerr && !(zio->io_flags & ZIO_FLAG_SPECULATIVE)) { char blkbuf[BP_SPRINTF_LEN]; zcb->zcb_haderrors = 1; zcb->zcb_errors[ioerr]++; if (dump_opt['b'] >= 2) snprintf_blkptr(blkbuf, sizeof (blkbuf), bp); else blkbuf[0] = '\0'; (void) printf("zdb_blkptr_cb: " "Got error %d reading " "<%llu, %llu, %lld, %llx> %s -- skipping\n", ioerr, (u_longlong_t)zb->zb_objset, (u_longlong_t)zb->zb_object, (u_longlong_t)zb->zb_level, (u_longlong_t)zb->zb_blkid, blkbuf); } mutex_exit(&spa->spa_scrub_lock); abd_free(zio->io_abd); } static int zdb_blkptr_cb(spa_t *spa, zilog_t *zilog, const blkptr_t *bp, const zbookmark_phys_t *zb, const dnode_phys_t *dnp, void *arg) { zdb_cb_t *zcb = arg; dmu_object_type_t type; boolean_t is_metadata; if (zb->zb_level == ZB_DNODE_LEVEL) return (0); if (dump_opt['b'] >= 5 && bp->blk_birth > 0) { char blkbuf[BP_SPRINTF_LEN]; snprintf_blkptr(blkbuf, sizeof (blkbuf), bp); (void) printf("objset %llu object %llu " "level %lld offset 0x%llx %s\n", (u_longlong_t)zb->zb_objset, (u_longlong_t)zb->zb_object, (longlong_t)zb->zb_level, (u_longlong_t)blkid2offset(dnp, bp, zb), blkbuf); } if (BP_IS_HOLE(bp) || BP_IS_REDACTED(bp)) return (0); type = BP_GET_TYPE(bp); zdb_count_block(zcb, zilog, bp, (type & DMU_OT_NEWTYPE) ? ZDB_OT_OTHER : type); is_metadata = (BP_GET_LEVEL(bp) != 0 || DMU_OT_IS_METADATA(type)); if (!BP_IS_EMBEDDED(bp) && (dump_opt['c'] > 1 || (dump_opt['c'] && is_metadata))) { size_t size = BP_GET_PSIZE(bp); abd_t *abd = abd_alloc(size, B_FALSE); int flags = ZIO_FLAG_CANFAIL | ZIO_FLAG_SCRUB | ZIO_FLAG_RAW; /* If it's an intent log block, failure is expected. */ if (zb->zb_level == ZB_ZIL_LEVEL) flags |= ZIO_FLAG_SPECULATIVE; mutex_enter(&spa->spa_scrub_lock); while (spa->spa_load_verify_bytes > max_inflight_bytes) cv_wait(&spa->spa_scrub_io_cv, &spa->spa_scrub_lock); spa->spa_load_verify_bytes += size; mutex_exit(&spa->spa_scrub_lock); zio_nowait(zio_read(NULL, spa, bp, abd, size, zdb_blkptr_done, zcb, ZIO_PRIORITY_ASYNC_READ, flags, zb)); } zcb->zcb_readfails = 0; /* only call gethrtime() every 100 blocks */ static int iters; if (++iters > 100) iters = 0; else return (0); if (dump_opt['b'] < 5 && gethrtime() > zcb->zcb_lastprint + NANOSEC) { uint64_t now = gethrtime(); char buf[10]; uint64_t bytes = zcb->zcb_type[ZB_TOTAL][ZDB_OT_TOTAL].zb_asize; uint64_t kb_per_sec = 1 + bytes / (1 + ((now - zcb->zcb_start) / 1000 / 1000)); uint64_t sec_remaining = (zcb->zcb_totalasize - bytes) / 1024 / kb_per_sec; /* make sure nicenum has enough space */ _Static_assert(sizeof (buf) >= NN_NUMBUF_SZ, "buf truncated"); zfs_nicebytes(bytes, buf, sizeof (buf)); (void) fprintf(stderr, "\r%5s completed (%4"PRIu64"MB/s) " "estimated time remaining: " "%"PRIu64"hr %02"PRIu64"min %02"PRIu64"sec ", buf, kb_per_sec / 1024, sec_remaining / 60 / 60, sec_remaining / 60 % 60, sec_remaining % 60); zcb->zcb_lastprint = now; } return (0); } static void zdb_leak(void *arg, uint64_t start, uint64_t size) { vdev_t *vd = arg; (void) printf("leaked space: vdev %llu, offset 0x%llx, size %llu\n", (u_longlong_t)vd->vdev_id, (u_longlong_t)start, (u_longlong_t)size); } static metaslab_ops_t zdb_metaslab_ops = { NULL /* alloc */ }; static int load_unflushed_svr_segs_cb(spa_t *spa, space_map_entry_t *sme, uint64_t txg, void *arg) { spa_vdev_removal_t *svr = arg; uint64_t offset = sme->sme_offset; uint64_t size = sme->sme_run; /* skip vdevs we don't care about */ if (sme->sme_vdev != svr->svr_vdev_id) return (0); vdev_t *vd = vdev_lookup_top(spa, sme->sme_vdev); metaslab_t *ms = vd->vdev_ms[offset >> vd->vdev_ms_shift]; ASSERT(sme->sme_type == SM_ALLOC || sme->sme_type == SM_FREE); if (txg < metaslab_unflushed_txg(ms)) return (0); if (sme->sme_type == SM_ALLOC) range_tree_add(svr->svr_allocd_segs, offset, size); else range_tree_remove(svr->svr_allocd_segs, offset, size); return (0); } static void claim_segment_impl_cb(uint64_t inner_offset, vdev_t *vd, uint64_t offset, uint64_t size, void *arg) { (void) inner_offset, (void) arg; /* * This callback was called through a remap from * a device being removed. Therefore, the vdev that * this callback is applied to is a concrete * vdev. */ ASSERT(vdev_is_concrete(vd)); VERIFY0(metaslab_claim_impl(vd, offset, size, spa_min_claim_txg(vd->vdev_spa))); } static void claim_segment_cb(void *arg, uint64_t offset, uint64_t size) { vdev_t *vd = arg; vdev_indirect_ops.vdev_op_remap(vd, offset, size, claim_segment_impl_cb, NULL); } /* * After accounting for all allocated blocks that are directly referenced, * we might have missed a reference to a block from a partially complete * (and thus unused) indirect mapping object. We perform a secondary pass * through the metaslabs we have already mapped and claim the destination * blocks. */ static void zdb_claim_removing(spa_t *spa, zdb_cb_t *zcb) { if (dump_opt['L']) return; if (spa->spa_vdev_removal == NULL) return; spa_config_enter(spa, SCL_CONFIG, FTAG, RW_READER); spa_vdev_removal_t *svr = spa->spa_vdev_removal; vdev_t *vd = vdev_lookup_top(spa, svr->svr_vdev_id); vdev_indirect_mapping_t *vim = vd->vdev_indirect_mapping; ASSERT0(range_tree_space(svr->svr_allocd_segs)); range_tree_t *allocs = range_tree_create(NULL, RANGE_SEG64, NULL, 0, 0); for (uint64_t msi = 0; msi < vd->vdev_ms_count; msi++) { metaslab_t *msp = vd->vdev_ms[msi]; ASSERT0(range_tree_space(allocs)); if (msp->ms_sm != NULL) VERIFY0(space_map_load(msp->ms_sm, allocs, SM_ALLOC)); range_tree_vacate(allocs, range_tree_add, svr->svr_allocd_segs); } range_tree_destroy(allocs); iterate_through_spacemap_logs(spa, load_unflushed_svr_segs_cb, svr); /* * Clear everything past what has been synced, * because we have not allocated mappings for * it yet. */ range_tree_clear(svr->svr_allocd_segs, vdev_indirect_mapping_max_offset(vim), vd->vdev_asize - vdev_indirect_mapping_max_offset(vim)); zcb->zcb_removing_size += range_tree_space(svr->svr_allocd_segs); range_tree_vacate(svr->svr_allocd_segs, claim_segment_cb, vd); spa_config_exit(spa, SCL_CONFIG, FTAG); } static int increment_indirect_mapping_cb(void *arg, const blkptr_t *bp, boolean_t bp_freed, dmu_tx_t *tx) { (void) tx; zdb_cb_t *zcb = arg; spa_t *spa = zcb->zcb_spa; vdev_t *vd; const dva_t *dva = &bp->blk_dva[0]; ASSERT(!bp_freed); ASSERT(!dump_opt['L']); ASSERT3U(BP_GET_NDVAS(bp), ==, 1); spa_config_enter(spa, SCL_VDEV, FTAG, RW_READER); vd = vdev_lookup_top(zcb->zcb_spa, DVA_GET_VDEV(dva)); ASSERT3P(vd, !=, NULL); spa_config_exit(spa, SCL_VDEV, FTAG); ASSERT(vd->vdev_indirect_config.vic_mapping_object != 0); ASSERT3P(zcb->zcb_vd_obsolete_counts[vd->vdev_id], !=, NULL); vdev_indirect_mapping_increment_obsolete_count( vd->vdev_indirect_mapping, DVA_GET_OFFSET(dva), DVA_GET_ASIZE(dva), zcb->zcb_vd_obsolete_counts[vd->vdev_id]); return (0); } static uint32_t * zdb_load_obsolete_counts(vdev_t *vd) { vdev_indirect_mapping_t *vim = vd->vdev_indirect_mapping; spa_t *spa = vd->vdev_spa; spa_condensing_indirect_phys_t *scip = &spa->spa_condensing_indirect_phys; uint64_t obsolete_sm_object; uint32_t *counts; VERIFY0(vdev_obsolete_sm_object(vd, &obsolete_sm_object)); EQUIV(obsolete_sm_object != 0, vd->vdev_obsolete_sm != NULL); counts = vdev_indirect_mapping_load_obsolete_counts(vim); if (vd->vdev_obsolete_sm != NULL) { vdev_indirect_mapping_load_obsolete_spacemap(vim, counts, vd->vdev_obsolete_sm); } if (scip->scip_vdev == vd->vdev_id && scip->scip_prev_obsolete_sm_object != 0) { space_map_t *prev_obsolete_sm = NULL; VERIFY0(space_map_open(&prev_obsolete_sm, spa->spa_meta_objset, scip->scip_prev_obsolete_sm_object, 0, vd->vdev_asize, 0)); vdev_indirect_mapping_load_obsolete_spacemap(vim, counts, prev_obsolete_sm); space_map_close(prev_obsolete_sm); } return (counts); } static void zdb_ddt_leak_init(spa_t *spa, zdb_cb_t *zcb) { ddt_bookmark_t ddb = {0}; ddt_entry_t dde; int error; int p; ASSERT(!dump_opt['L']); while ((error = ddt_walk(spa, &ddb, &dde)) == 0) { blkptr_t blk; ddt_phys_t *ddp = dde.dde_phys; if (ddb.ddb_class == DDT_CLASS_UNIQUE) return; ASSERT(ddt_phys_total_refcnt(&dde) > 1); for (p = 0; p < DDT_PHYS_TYPES; p++, ddp++) { if (ddp->ddp_phys_birth == 0) continue; ddt_bp_create(ddb.ddb_checksum, &dde.dde_key, ddp, &blk); if (p == DDT_PHYS_DITTO) { zdb_count_block(zcb, NULL, &blk, ZDB_OT_DITTO); } else { zcb->zcb_dedup_asize += BP_GET_ASIZE(&blk) * (ddp->ddp_refcnt - 1); zcb->zcb_dedup_blocks++; } } ddt_t *ddt = spa->spa_ddt[ddb.ddb_checksum]; ddt_enter(ddt); VERIFY(ddt_lookup(ddt, &blk, B_TRUE) != NULL); ddt_exit(ddt); } ASSERT(error == ENOENT); } typedef struct checkpoint_sm_exclude_entry_arg { vdev_t *cseea_vd; uint64_t cseea_checkpoint_size; } checkpoint_sm_exclude_entry_arg_t; static int checkpoint_sm_exclude_entry_cb(space_map_entry_t *sme, void *arg) { checkpoint_sm_exclude_entry_arg_t *cseea = arg; vdev_t *vd = cseea->cseea_vd; metaslab_t *ms = vd->vdev_ms[sme->sme_offset >> vd->vdev_ms_shift]; uint64_t end = sme->sme_offset + sme->sme_run; ASSERT(sme->sme_type == SM_FREE); /* * Since the vdev_checkpoint_sm exists in the vdev level * and the ms_sm space maps exist in the metaslab level, * an entry in the checkpoint space map could theoretically * cross the boundaries of the metaslab that it belongs. * * In reality, because of the way that we populate and * manipulate the checkpoint's space maps currently, * there shouldn't be any entries that cross metaslabs. * Hence the assertion below. * * That said, there is no fundamental requirement that * the checkpoint's space map entries should not cross * metaslab boundaries. So if needed we could add code * that handles metaslab-crossing segments in the future. */ VERIFY3U(sme->sme_offset, >=, ms->ms_start); VERIFY3U(end, <=, ms->ms_start + ms->ms_size); /* * By removing the entry from the allocated segments we * also verify that the entry is there to begin with. */ mutex_enter(&ms->ms_lock); range_tree_remove(ms->ms_allocatable, sme->sme_offset, sme->sme_run); mutex_exit(&ms->ms_lock); cseea->cseea_checkpoint_size += sme->sme_run; return (0); } static void zdb_leak_init_vdev_exclude_checkpoint(vdev_t *vd, zdb_cb_t *zcb) { spa_t *spa = vd->vdev_spa; space_map_t *checkpoint_sm = NULL; uint64_t checkpoint_sm_obj; /* * If there is no vdev_top_zap, we are in a pool whose * version predates the pool checkpoint feature. */ if (vd->vdev_top_zap == 0) return; /* * If there is no reference of the vdev_checkpoint_sm in * the vdev_top_zap, then one of the following scenarios * is true: * * 1] There is no checkpoint * 2] There is a checkpoint, but no checkpointed blocks * have been freed yet * 3] The current vdev is indirect * * In these cases we return immediately. */ if (zap_contains(spa_meta_objset(spa), vd->vdev_top_zap, VDEV_TOP_ZAP_POOL_CHECKPOINT_SM) != 0) return; VERIFY0(zap_lookup(spa_meta_objset(spa), vd->vdev_top_zap, VDEV_TOP_ZAP_POOL_CHECKPOINT_SM, sizeof (uint64_t), 1, &checkpoint_sm_obj)); checkpoint_sm_exclude_entry_arg_t cseea; cseea.cseea_vd = vd; cseea.cseea_checkpoint_size = 0; VERIFY0(space_map_open(&checkpoint_sm, spa_meta_objset(spa), checkpoint_sm_obj, 0, vd->vdev_asize, vd->vdev_ashift)); VERIFY0(space_map_iterate(checkpoint_sm, space_map_length(checkpoint_sm), checkpoint_sm_exclude_entry_cb, &cseea)); space_map_close(checkpoint_sm); zcb->zcb_checkpoint_size += cseea.cseea_checkpoint_size; } static void zdb_leak_init_exclude_checkpoint(spa_t *spa, zdb_cb_t *zcb) { ASSERT(!dump_opt['L']); vdev_t *rvd = spa->spa_root_vdev; for (uint64_t c = 0; c < rvd->vdev_children; c++) { ASSERT3U(c, ==, rvd->vdev_child[c]->vdev_id); zdb_leak_init_vdev_exclude_checkpoint(rvd->vdev_child[c], zcb); } } static int count_unflushed_space_cb(spa_t *spa, space_map_entry_t *sme, uint64_t txg, void *arg) { int64_t *ualloc_space = arg; uint64_t offset = sme->sme_offset; uint64_t vdev_id = sme->sme_vdev; vdev_t *vd = vdev_lookup_top(spa, vdev_id); if (!vdev_is_concrete(vd)) return (0); metaslab_t *ms = vd->vdev_ms[offset >> vd->vdev_ms_shift]; ASSERT(sme->sme_type == SM_ALLOC || sme->sme_type == SM_FREE); if (txg < metaslab_unflushed_txg(ms)) return (0); if (sme->sme_type == SM_ALLOC) *ualloc_space += sme->sme_run; else *ualloc_space -= sme->sme_run; return (0); } static int64_t get_unflushed_alloc_space(spa_t *spa) { if (dump_opt['L']) return (0); int64_t ualloc_space = 0; iterate_through_spacemap_logs(spa, count_unflushed_space_cb, &ualloc_space); return (ualloc_space); } static int load_unflushed_cb(spa_t *spa, space_map_entry_t *sme, uint64_t txg, void *arg) { maptype_t *uic_maptype = arg; uint64_t offset = sme->sme_offset; uint64_t size = sme->sme_run; uint64_t vdev_id = sme->sme_vdev; vdev_t *vd = vdev_lookup_top(spa, vdev_id); /* skip indirect vdevs */ if (!vdev_is_concrete(vd)) return (0); metaslab_t *ms = vd->vdev_ms[offset >> vd->vdev_ms_shift]; ASSERT(sme->sme_type == SM_ALLOC || sme->sme_type == SM_FREE); ASSERT(*uic_maptype == SM_ALLOC || *uic_maptype == SM_FREE); if (txg < metaslab_unflushed_txg(ms)) return (0); if (*uic_maptype == sme->sme_type) range_tree_add(ms->ms_allocatable, offset, size); else range_tree_remove(ms->ms_allocatable, offset, size); return (0); } static void load_unflushed_to_ms_allocatables(spa_t *spa, maptype_t maptype) { iterate_through_spacemap_logs(spa, load_unflushed_cb, &maptype); } static void load_concrete_ms_allocatable_trees(spa_t *spa, maptype_t maptype) { vdev_t *rvd = spa->spa_root_vdev; for (uint64_t i = 0; i < rvd->vdev_children; i++) { vdev_t *vd = rvd->vdev_child[i]; ASSERT3U(i, ==, vd->vdev_id); if (vd->vdev_ops == &vdev_indirect_ops) continue; for (uint64_t m = 0; m < vd->vdev_ms_count; m++) { metaslab_t *msp = vd->vdev_ms[m]; (void) fprintf(stderr, "\rloading concrete vdev %llu, " "metaslab %llu of %llu ...", (longlong_t)vd->vdev_id, (longlong_t)msp->ms_id, (longlong_t)vd->vdev_ms_count); mutex_enter(&msp->ms_lock); range_tree_vacate(msp->ms_allocatable, NULL, NULL); /* * We don't want to spend the CPU manipulating the * size-ordered tree, so clear the range_tree ops. */ msp->ms_allocatable->rt_ops = NULL; if (msp->ms_sm != NULL) { VERIFY0(space_map_load(msp->ms_sm, msp->ms_allocatable, maptype)); } if (!msp->ms_loaded) msp->ms_loaded = B_TRUE; mutex_exit(&msp->ms_lock); } } load_unflushed_to_ms_allocatables(spa, maptype); } /* * vm_idxp is an in-out parameter which (for indirect vdevs) is the * index in vim_entries that has the first entry in this metaslab. * On return, it will be set to the first entry after this metaslab. */ static void load_indirect_ms_allocatable_tree(vdev_t *vd, metaslab_t *msp, uint64_t *vim_idxp) { vdev_indirect_mapping_t *vim = vd->vdev_indirect_mapping; mutex_enter(&msp->ms_lock); range_tree_vacate(msp->ms_allocatable, NULL, NULL); /* * We don't want to spend the CPU manipulating the * size-ordered tree, so clear the range_tree ops. */ msp->ms_allocatable->rt_ops = NULL; for (; *vim_idxp < vdev_indirect_mapping_num_entries(vim); (*vim_idxp)++) { vdev_indirect_mapping_entry_phys_t *vimep = &vim->vim_entries[*vim_idxp]; uint64_t ent_offset = DVA_MAPPING_GET_SRC_OFFSET(vimep); uint64_t ent_len = DVA_GET_ASIZE(&vimep->vimep_dst); ASSERT3U(ent_offset, >=, msp->ms_start); if (ent_offset >= msp->ms_start + msp->ms_size) break; /* * Mappings do not cross metaslab boundaries, * because we create them by walking the metaslabs. */ ASSERT3U(ent_offset + ent_len, <=, msp->ms_start + msp->ms_size); range_tree_add(msp->ms_allocatable, ent_offset, ent_len); } if (!msp->ms_loaded) msp->ms_loaded = B_TRUE; mutex_exit(&msp->ms_lock); } static void zdb_leak_init_prepare_indirect_vdevs(spa_t *spa, zdb_cb_t *zcb) { ASSERT(!dump_opt['L']); vdev_t *rvd = spa->spa_root_vdev; for (uint64_t c = 0; c < rvd->vdev_children; c++) { vdev_t *vd = rvd->vdev_child[c]; ASSERT3U(c, ==, vd->vdev_id); if (vd->vdev_ops != &vdev_indirect_ops) continue; /* * Note: we don't check for mapping leaks on * removing vdevs because their ms_allocatable's * are used to look for leaks in allocated space. */ zcb->zcb_vd_obsolete_counts[c] = zdb_load_obsolete_counts(vd); /* * Normally, indirect vdevs don't have any * metaslabs. We want to set them up for * zio_claim(). */ vdev_metaslab_group_create(vd); VERIFY0(vdev_metaslab_init(vd, 0)); vdev_indirect_mapping_t *vim __maybe_unused = vd->vdev_indirect_mapping; uint64_t vim_idx = 0; for (uint64_t m = 0; m < vd->vdev_ms_count; m++) { (void) fprintf(stderr, "\rloading indirect vdev %llu, " "metaslab %llu of %llu ...", (longlong_t)vd->vdev_id, (longlong_t)vd->vdev_ms[m]->ms_id, (longlong_t)vd->vdev_ms_count); load_indirect_ms_allocatable_tree(vd, vd->vdev_ms[m], &vim_idx); } ASSERT3U(vim_idx, ==, vdev_indirect_mapping_num_entries(vim)); } } static void zdb_leak_init(spa_t *spa, zdb_cb_t *zcb) { zcb->zcb_spa = spa; if (dump_opt['L']) return; dsl_pool_t *dp = spa->spa_dsl_pool; vdev_t *rvd = spa->spa_root_vdev; /* * We are going to be changing the meaning of the metaslab's * ms_allocatable. Ensure that the allocator doesn't try to * use the tree. */ spa->spa_normal_class->mc_ops = &zdb_metaslab_ops; spa->spa_log_class->mc_ops = &zdb_metaslab_ops; spa->spa_embedded_log_class->mc_ops = &zdb_metaslab_ops; zcb->zcb_vd_obsolete_counts = umem_zalloc(rvd->vdev_children * sizeof (uint32_t *), UMEM_NOFAIL); /* * For leak detection, we overload the ms_allocatable trees * to contain allocated segments instead of free segments. * As a result, we can't use the normal metaslab_load/unload * interfaces. */ zdb_leak_init_prepare_indirect_vdevs(spa, zcb); load_concrete_ms_allocatable_trees(spa, SM_ALLOC); /* * On load_concrete_ms_allocatable_trees() we loaded all the * allocated entries from the ms_sm to the ms_allocatable for * each metaslab. If the pool has a checkpoint or is in the * middle of discarding a checkpoint, some of these blocks * may have been freed but their ms_sm may not have been * updated because they are referenced by the checkpoint. In * order to avoid false-positives during leak-detection, we * go through the vdev's checkpoint space map and exclude all * its entries from their relevant ms_allocatable. * * We also aggregate the space held by the checkpoint and add * it to zcb_checkpoint_size. * * Note that at this point we are also verifying that all the * entries on the checkpoint_sm are marked as allocated in * the ms_sm of their relevant metaslab. * [see comment in checkpoint_sm_exclude_entry_cb()] */ zdb_leak_init_exclude_checkpoint(spa, zcb); ASSERT3U(zcb->zcb_checkpoint_size, ==, spa_get_checkpoint_space(spa)); /* for cleaner progress output */ (void) fprintf(stderr, "\n"); if (bpobj_is_open(&dp->dp_obsolete_bpobj)) { ASSERT(spa_feature_is_enabled(spa, SPA_FEATURE_DEVICE_REMOVAL)); (void) bpobj_iterate_nofree(&dp->dp_obsolete_bpobj, increment_indirect_mapping_cb, zcb, NULL); } spa_config_enter(spa, SCL_CONFIG, FTAG, RW_READER); zdb_ddt_leak_init(spa, zcb); spa_config_exit(spa, SCL_CONFIG, FTAG); } static boolean_t zdb_check_for_obsolete_leaks(vdev_t *vd, zdb_cb_t *zcb) { boolean_t leaks = B_FALSE; vdev_indirect_mapping_t *vim = vd->vdev_indirect_mapping; uint64_t total_leaked = 0; boolean_t are_precise = B_FALSE; ASSERT(vim != NULL); for (uint64_t i = 0; i < vdev_indirect_mapping_num_entries(vim); i++) { vdev_indirect_mapping_entry_phys_t *vimep = &vim->vim_entries[i]; uint64_t obsolete_bytes = 0; uint64_t offset = DVA_MAPPING_GET_SRC_OFFSET(vimep); metaslab_t *msp = vd->vdev_ms[offset >> vd->vdev_ms_shift]; /* * This is not very efficient but it's easy to * verify correctness. */ for (uint64_t inner_offset = 0; inner_offset < DVA_GET_ASIZE(&vimep->vimep_dst); - inner_offset += 1 << vd->vdev_ashift) { + inner_offset += 1ULL << vd->vdev_ashift) { if (range_tree_contains(msp->ms_allocatable, - offset + inner_offset, 1 << vd->vdev_ashift)) { - obsolete_bytes += 1 << vd->vdev_ashift; + offset + inner_offset, 1ULL << vd->vdev_ashift)) { + obsolete_bytes += 1ULL << vd->vdev_ashift; } } int64_t bytes_leaked = obsolete_bytes - zcb->zcb_vd_obsolete_counts[vd->vdev_id][i]; ASSERT3U(DVA_GET_ASIZE(&vimep->vimep_dst), >=, zcb->zcb_vd_obsolete_counts[vd->vdev_id][i]); VERIFY0(vdev_obsolete_counts_are_precise(vd, &are_precise)); if (bytes_leaked != 0 && (are_precise || dump_opt['d'] >= 5)) { (void) printf("obsolete indirect mapping count " "mismatch on %llu:%llx:%llx : %llx bytes leaked\n", (u_longlong_t)vd->vdev_id, (u_longlong_t)DVA_MAPPING_GET_SRC_OFFSET(vimep), (u_longlong_t)DVA_GET_ASIZE(&vimep->vimep_dst), (u_longlong_t)bytes_leaked); } total_leaked += ABS(bytes_leaked); } VERIFY0(vdev_obsolete_counts_are_precise(vd, &are_precise)); if (!are_precise && total_leaked > 0) { int pct_leaked = total_leaked * 100 / vdev_indirect_mapping_bytes_mapped(vim); (void) printf("cannot verify obsolete indirect mapping " "counts of vdev %llu because precise feature was not " "enabled when it was removed: %d%% (%llx bytes) of mapping" "unreferenced\n", (u_longlong_t)vd->vdev_id, pct_leaked, (u_longlong_t)total_leaked); } else if (total_leaked > 0) { (void) printf("obsolete indirect mapping count mismatch " "for vdev %llu -- %llx total bytes mismatched\n", (u_longlong_t)vd->vdev_id, (u_longlong_t)total_leaked); leaks |= B_TRUE; } vdev_indirect_mapping_free_obsolete_counts(vim, zcb->zcb_vd_obsolete_counts[vd->vdev_id]); zcb->zcb_vd_obsolete_counts[vd->vdev_id] = NULL; return (leaks); } static boolean_t zdb_leak_fini(spa_t *spa, zdb_cb_t *zcb) { if (dump_opt['L']) return (B_FALSE); boolean_t leaks = B_FALSE; vdev_t *rvd = spa->spa_root_vdev; for (unsigned c = 0; c < rvd->vdev_children; c++) { vdev_t *vd = rvd->vdev_child[c]; if (zcb->zcb_vd_obsolete_counts[c] != NULL) { leaks |= zdb_check_for_obsolete_leaks(vd, zcb); } for (uint64_t m = 0; m < vd->vdev_ms_count; m++) { metaslab_t *msp = vd->vdev_ms[m]; ASSERT3P(msp->ms_group, ==, (msp->ms_group->mg_class == spa_embedded_log_class(spa)) ? vd->vdev_log_mg : vd->vdev_mg); /* * ms_allocatable has been overloaded * to contain allocated segments. Now that * we finished traversing all blocks, any * block that remains in the ms_allocatable * represents an allocated block that we * did not claim during the traversal. * Claimed blocks would have been removed * from the ms_allocatable. For indirect * vdevs, space remaining in the tree * represents parts of the mapping that are * not referenced, which is not a bug. */ if (vd->vdev_ops == &vdev_indirect_ops) { range_tree_vacate(msp->ms_allocatable, NULL, NULL); } else { range_tree_vacate(msp->ms_allocatable, zdb_leak, vd); } if (msp->ms_loaded) { msp->ms_loaded = B_FALSE; } } } umem_free(zcb->zcb_vd_obsolete_counts, rvd->vdev_children * sizeof (uint32_t *)); zcb->zcb_vd_obsolete_counts = NULL; return (leaks); } static int count_block_cb(void *arg, const blkptr_t *bp, dmu_tx_t *tx) { (void) tx; zdb_cb_t *zcb = arg; if (dump_opt['b'] >= 5) { char blkbuf[BP_SPRINTF_LEN]; snprintf_blkptr(blkbuf, sizeof (blkbuf), bp); (void) printf("[%s] %s\n", "deferred free", blkbuf); } zdb_count_block(zcb, NULL, bp, ZDB_OT_DEFERRED); return (0); } /* * Iterate over livelists which have been destroyed by the user but * are still present in the MOS, waiting to be freed */ static void iterate_deleted_livelists(spa_t *spa, ll_iter_t func, void *arg) { objset_t *mos = spa->spa_meta_objset; uint64_t zap_obj; int err = zap_lookup(mos, DMU_POOL_DIRECTORY_OBJECT, DMU_POOL_DELETED_CLONES, sizeof (uint64_t), 1, &zap_obj); if (err == ENOENT) return; ASSERT0(err); zap_cursor_t zc; zap_attribute_t attr; dsl_deadlist_t ll; /* NULL out os prior to dsl_deadlist_open in case it's garbage */ ll.dl_os = NULL; for (zap_cursor_init(&zc, mos, zap_obj); zap_cursor_retrieve(&zc, &attr) == 0; (void) zap_cursor_advance(&zc)) { dsl_deadlist_open(&ll, mos, attr.za_first_integer); func(&ll, arg); dsl_deadlist_close(&ll); } zap_cursor_fini(&zc); } static int bpobj_count_block_cb(void *arg, const blkptr_t *bp, boolean_t bp_freed, dmu_tx_t *tx) { ASSERT(!bp_freed); return (count_block_cb(arg, bp, tx)); } static int livelist_entry_count_blocks_cb(void *args, dsl_deadlist_entry_t *dle) { zdb_cb_t *zbc = args; bplist_t blks; bplist_create(&blks); /* determine which blocks have been alloc'd but not freed */ VERIFY0(dsl_process_sub_livelist(&dle->dle_bpobj, &blks, NULL, NULL)); /* count those blocks */ (void) bplist_iterate(&blks, count_block_cb, zbc, NULL); bplist_destroy(&blks); return (0); } static void livelist_count_blocks(dsl_deadlist_t *ll, void *arg) { dsl_deadlist_iterate(ll, livelist_entry_count_blocks_cb, arg); } /* * Count the blocks in the livelists that have been destroyed by the user * but haven't yet been freed. */ static void deleted_livelists_count_blocks(spa_t *spa, zdb_cb_t *zbc) { iterate_deleted_livelists(spa, livelist_count_blocks, zbc); } static void dump_livelist_cb(dsl_deadlist_t *ll, void *arg) { ASSERT3P(arg, ==, NULL); global_feature_count[SPA_FEATURE_LIVELIST]++; dump_blkptr_list(ll, "Deleted Livelist"); dsl_deadlist_iterate(ll, sublivelist_verify_lightweight, NULL); } /* * Print out, register object references to, and increment feature counts for * livelists that have been destroyed by the user but haven't yet been freed. */ static void deleted_livelists_dump_mos(spa_t *spa) { uint64_t zap_obj; objset_t *mos = spa->spa_meta_objset; int err = zap_lookup(mos, DMU_POOL_DIRECTORY_OBJECT, DMU_POOL_DELETED_CLONES, sizeof (uint64_t), 1, &zap_obj); if (err == ENOENT) return; mos_obj_refd(zap_obj); iterate_deleted_livelists(spa, dump_livelist_cb, NULL); } static int dump_block_stats(spa_t *spa) { zdb_cb_t *zcb; zdb_blkstats_t *zb, *tzb; uint64_t norm_alloc, norm_space, total_alloc, total_found; int flags = TRAVERSE_PRE | TRAVERSE_PREFETCH_METADATA | TRAVERSE_NO_DECRYPT | TRAVERSE_HARD; boolean_t leaks = B_FALSE; int e, c, err; bp_embedded_type_t i; zcb = umem_zalloc(sizeof (zdb_cb_t), UMEM_NOFAIL); (void) printf("\nTraversing all blocks %s%s%s%s%s...\n\n", (dump_opt['c'] || !dump_opt['L']) ? "to verify " : "", (dump_opt['c'] == 1) ? "metadata " : "", dump_opt['c'] ? "checksums " : "", (dump_opt['c'] && !dump_opt['L']) ? "and verify " : "", !dump_opt['L'] ? "nothing leaked " : ""); /* * When leak detection is enabled we load all space maps as SM_ALLOC * maps, then traverse the pool claiming each block we discover. If * the pool is perfectly consistent, the segment trees will be empty * when we're done. Anything left over is a leak; any block we can't * claim (because it's not part of any space map) is a double * allocation, reference to a freed block, or an unclaimed log block. * * When leak detection is disabled (-L option) we still traverse the * pool claiming each block we discover, but we skip opening any space * maps. */ zdb_leak_init(spa, zcb); /* * If there's a deferred-free bplist, process that first. */ (void) bpobj_iterate_nofree(&spa->spa_deferred_bpobj, bpobj_count_block_cb, zcb, NULL); if (spa_version(spa) >= SPA_VERSION_DEADLISTS) { (void) bpobj_iterate_nofree(&spa->spa_dsl_pool->dp_free_bpobj, bpobj_count_block_cb, zcb, NULL); } zdb_claim_removing(spa, zcb); if (spa_feature_is_active(spa, SPA_FEATURE_ASYNC_DESTROY)) { VERIFY3U(0, ==, bptree_iterate(spa->spa_meta_objset, spa->spa_dsl_pool->dp_bptree_obj, B_FALSE, count_block_cb, zcb, NULL)); } deleted_livelists_count_blocks(spa, zcb); if (dump_opt['c'] > 1) flags |= TRAVERSE_PREFETCH_DATA; zcb->zcb_totalasize = metaslab_class_get_alloc(spa_normal_class(spa)); zcb->zcb_totalasize += metaslab_class_get_alloc(spa_special_class(spa)); zcb->zcb_totalasize += metaslab_class_get_alloc(spa_dedup_class(spa)); zcb->zcb_totalasize += metaslab_class_get_alloc(spa_embedded_log_class(spa)); zcb->zcb_start = zcb->zcb_lastprint = gethrtime(); err = traverse_pool(spa, 0, flags, zdb_blkptr_cb, zcb); /* * If we've traversed the data blocks then we need to wait for those * I/Os to complete. We leverage "The Godfather" zio to wait on * all async I/Os to complete. */ if (dump_opt['c']) { for (c = 0; c < max_ncpus; c++) { (void) zio_wait(spa->spa_async_zio_root[c]); spa->spa_async_zio_root[c] = zio_root(spa, NULL, NULL, ZIO_FLAG_CANFAIL | ZIO_FLAG_SPECULATIVE | ZIO_FLAG_GODFATHER); } } ASSERT0(spa->spa_load_verify_bytes); /* * Done after zio_wait() since zcb_haderrors is modified in * zdb_blkptr_done() */ zcb->zcb_haderrors |= err; if (zcb->zcb_haderrors) { (void) printf("\nError counts:\n\n"); (void) printf("\t%5s %s\n", "errno", "count"); for (e = 0; e < 256; e++) { if (zcb->zcb_errors[e] != 0) { (void) printf("\t%5d %llu\n", e, (u_longlong_t)zcb->zcb_errors[e]); } } } /* * Report any leaked segments. */ leaks |= zdb_leak_fini(spa, zcb); tzb = &zcb->zcb_type[ZB_TOTAL][ZDB_OT_TOTAL]; norm_alloc = metaslab_class_get_alloc(spa_normal_class(spa)); norm_space = metaslab_class_get_space(spa_normal_class(spa)); total_alloc = norm_alloc + metaslab_class_get_alloc(spa_log_class(spa)) + metaslab_class_get_alloc(spa_embedded_log_class(spa)) + metaslab_class_get_alloc(spa_special_class(spa)) + metaslab_class_get_alloc(spa_dedup_class(spa)) + get_unflushed_alloc_space(spa); total_found = tzb->zb_asize - zcb->zcb_dedup_asize + zcb->zcb_removing_size + zcb->zcb_checkpoint_size; if (total_found == total_alloc && !dump_opt['L']) { (void) printf("\n\tNo leaks (block sum matches space" " maps exactly)\n"); } else if (!dump_opt['L']) { (void) printf("block traversal size %llu != alloc %llu " "(%s %lld)\n", (u_longlong_t)total_found, (u_longlong_t)total_alloc, (dump_opt['L']) ? "unreachable" : "leaked", (longlong_t)(total_alloc - total_found)); leaks = B_TRUE; } if (tzb->zb_count == 0) { umem_free(zcb, sizeof (zdb_cb_t)); return (2); } (void) printf("\n"); (void) printf("\t%-16s %14llu\n", "bp count:", (u_longlong_t)tzb->zb_count); (void) printf("\t%-16s %14llu\n", "ganged count:", (longlong_t)tzb->zb_gangs); (void) printf("\t%-16s %14llu avg: %6llu\n", "bp logical:", (u_longlong_t)tzb->zb_lsize, (u_longlong_t)(tzb->zb_lsize / tzb->zb_count)); (void) printf("\t%-16s %14llu avg: %6llu compression: %6.2f\n", "bp physical:", (u_longlong_t)tzb->zb_psize, (u_longlong_t)(tzb->zb_psize / tzb->zb_count), (double)tzb->zb_lsize / tzb->zb_psize); (void) printf("\t%-16s %14llu avg: %6llu compression: %6.2f\n", "bp allocated:", (u_longlong_t)tzb->zb_asize, (u_longlong_t)(tzb->zb_asize / tzb->zb_count), (double)tzb->zb_lsize / tzb->zb_asize); (void) printf("\t%-16s %14llu ref>1: %6llu deduplication: %6.2f\n", "bp deduped:", (u_longlong_t)zcb->zcb_dedup_asize, (u_longlong_t)zcb->zcb_dedup_blocks, (double)zcb->zcb_dedup_asize / tzb->zb_asize + 1.0); (void) printf("\t%-16s %14llu used: %5.2f%%\n", "Normal class:", (u_longlong_t)norm_alloc, 100.0 * norm_alloc / norm_space); if (spa_special_class(spa)->mc_allocator[0].mca_rotor != NULL) { uint64_t alloc = metaslab_class_get_alloc( spa_special_class(spa)); uint64_t space = metaslab_class_get_space( spa_special_class(spa)); (void) printf("\t%-16s %14llu used: %5.2f%%\n", "Special class", (u_longlong_t)alloc, 100.0 * alloc / space); } if (spa_dedup_class(spa)->mc_allocator[0].mca_rotor != NULL) { uint64_t alloc = metaslab_class_get_alloc( spa_dedup_class(spa)); uint64_t space = metaslab_class_get_space( spa_dedup_class(spa)); (void) printf("\t%-16s %14llu used: %5.2f%%\n", "Dedup class", (u_longlong_t)alloc, 100.0 * alloc / space); } if (spa_embedded_log_class(spa)->mc_allocator[0].mca_rotor != NULL) { uint64_t alloc = metaslab_class_get_alloc( spa_embedded_log_class(spa)); uint64_t space = metaslab_class_get_space( spa_embedded_log_class(spa)); (void) printf("\t%-16s %14llu used: %5.2f%%\n", "Embedded log class", (u_longlong_t)alloc, 100.0 * alloc / space); } for (i = 0; i < NUM_BP_EMBEDDED_TYPES; i++) { if (zcb->zcb_embedded_blocks[i] == 0) continue; (void) printf("\n"); (void) printf("\tadditional, non-pointer bps of type %u: " "%10llu\n", i, (u_longlong_t)zcb->zcb_embedded_blocks[i]); if (dump_opt['b'] >= 3) { (void) printf("\t number of (compressed) bytes: " "number of bps\n"); dump_histogram(zcb->zcb_embedded_histogram[i], sizeof (zcb->zcb_embedded_histogram[i]) / sizeof (zcb->zcb_embedded_histogram[i][0]), 0); } } if (tzb->zb_ditto_samevdev != 0) { (void) printf("\tDittoed blocks on same vdev: %llu\n", (longlong_t)tzb->zb_ditto_samevdev); } if (tzb->zb_ditto_same_ms != 0) { (void) printf("\tDittoed blocks in same metaslab: %llu\n", (longlong_t)tzb->zb_ditto_same_ms); } for (uint64_t v = 0; v < spa->spa_root_vdev->vdev_children; v++) { vdev_t *vd = spa->spa_root_vdev->vdev_child[v]; vdev_indirect_mapping_t *vim = vd->vdev_indirect_mapping; if (vim == NULL) { continue; } char mem[32]; zdb_nicenum(vdev_indirect_mapping_num_entries(vim), mem, vdev_indirect_mapping_size(vim)); (void) printf("\tindirect vdev id %llu has %llu segments " "(%s in memory)\n", (longlong_t)vd->vdev_id, (longlong_t)vdev_indirect_mapping_num_entries(vim), mem); } if (dump_opt['b'] >= 2) { int l, t, level; (void) printf("\nBlocks\tLSIZE\tPSIZE\tASIZE" "\t avg\t comp\t%%Total\tType\n"); for (t = 0; t <= ZDB_OT_TOTAL; t++) { char csize[32], lsize[32], psize[32], asize[32]; char avg[32], gang[32]; const char *typename; /* make sure nicenum has enough space */ _Static_assert(sizeof (csize) >= NN_NUMBUF_SZ, "csize truncated"); _Static_assert(sizeof (lsize) >= NN_NUMBUF_SZ, "lsize truncated"); _Static_assert(sizeof (psize) >= NN_NUMBUF_SZ, "psize truncated"); _Static_assert(sizeof (asize) >= NN_NUMBUF_SZ, "asize truncated"); _Static_assert(sizeof (avg) >= NN_NUMBUF_SZ, "avg truncated"); _Static_assert(sizeof (gang) >= NN_NUMBUF_SZ, "gang truncated"); if (t < DMU_OT_NUMTYPES) typename = dmu_ot[t].ot_name; else typename = zdb_ot_extname[t - DMU_OT_NUMTYPES]; if (zcb->zcb_type[ZB_TOTAL][t].zb_asize == 0) { (void) printf("%6s\t%5s\t%5s\t%5s" "\t%5s\t%5s\t%6s\t%s\n", "-", "-", "-", "-", "-", "-", "-", typename); continue; } for (l = ZB_TOTAL - 1; l >= -1; l--) { level = (l == -1 ? ZB_TOTAL : l); zb = &zcb->zcb_type[level][t]; if (zb->zb_asize == 0) continue; if (dump_opt['b'] < 3 && level != ZB_TOTAL) continue; if (level == 0 && zb->zb_asize == zcb->zcb_type[ZB_TOTAL][t].zb_asize) continue; zdb_nicenum(zb->zb_count, csize, sizeof (csize)); zdb_nicenum(zb->zb_lsize, lsize, sizeof (lsize)); zdb_nicenum(zb->zb_psize, psize, sizeof (psize)); zdb_nicenum(zb->zb_asize, asize, sizeof (asize)); zdb_nicenum(zb->zb_asize / zb->zb_count, avg, sizeof (avg)); zdb_nicenum(zb->zb_gangs, gang, sizeof (gang)); (void) printf("%6s\t%5s\t%5s\t%5s\t%5s" "\t%5.2f\t%6.2f\t", csize, lsize, psize, asize, avg, (double)zb->zb_lsize / zb->zb_psize, 100.0 * zb->zb_asize / tzb->zb_asize); if (level == ZB_TOTAL) (void) printf("%s\n", typename); else (void) printf(" L%d %s\n", level, typename); if (dump_opt['b'] >= 3 && zb->zb_gangs > 0) { (void) printf("\t number of ganged " "blocks: %s\n", gang); } if (dump_opt['b'] >= 4) { (void) printf("psize " "(in 512-byte sectors): " "number of blocks\n"); dump_histogram(zb->zb_psize_histogram, PSIZE_HISTO_SIZE, 0); } } } /* Output a table summarizing block sizes in the pool */ if (dump_opt['b'] >= 2) { dump_size_histograms(zcb); } } (void) printf("\n"); if (leaks) { umem_free(zcb, sizeof (zdb_cb_t)); return (2); } if (zcb->zcb_haderrors) { umem_free(zcb, sizeof (zdb_cb_t)); return (3); } umem_free(zcb, sizeof (zdb_cb_t)); return (0); } typedef struct zdb_ddt_entry { ddt_key_t zdde_key; uint64_t zdde_ref_blocks; uint64_t zdde_ref_lsize; uint64_t zdde_ref_psize; uint64_t zdde_ref_dsize; avl_node_t zdde_node; } zdb_ddt_entry_t; static int zdb_ddt_add_cb(spa_t *spa, zilog_t *zilog, const blkptr_t *bp, const zbookmark_phys_t *zb, const dnode_phys_t *dnp, void *arg) { (void) zilog, (void) dnp; avl_tree_t *t = arg; avl_index_t where; zdb_ddt_entry_t *zdde, zdde_search; if (zb->zb_level == ZB_DNODE_LEVEL || BP_IS_HOLE(bp) || BP_IS_EMBEDDED(bp)) return (0); if (dump_opt['S'] > 1 && zb->zb_level == ZB_ROOT_LEVEL) { (void) printf("traversing objset %llu, %llu objects, " "%lu blocks so far\n", (u_longlong_t)zb->zb_objset, (u_longlong_t)BP_GET_FILL(bp), avl_numnodes(t)); } if (BP_IS_HOLE(bp) || BP_GET_CHECKSUM(bp) == ZIO_CHECKSUM_OFF || BP_GET_LEVEL(bp) > 0 || DMU_OT_IS_METADATA(BP_GET_TYPE(bp))) return (0); ddt_key_fill(&zdde_search.zdde_key, bp); zdde = avl_find(t, &zdde_search, &where); if (zdde == NULL) { zdde = umem_zalloc(sizeof (*zdde), UMEM_NOFAIL); zdde->zdde_key = zdde_search.zdde_key; avl_insert(t, zdde, where); } zdde->zdde_ref_blocks += 1; zdde->zdde_ref_lsize += BP_GET_LSIZE(bp); zdde->zdde_ref_psize += BP_GET_PSIZE(bp); zdde->zdde_ref_dsize += bp_get_dsize_sync(spa, bp); return (0); } static void dump_simulated_ddt(spa_t *spa) { avl_tree_t t; void *cookie = NULL; zdb_ddt_entry_t *zdde; ddt_histogram_t ddh_total = {{{0}}}; ddt_stat_t dds_total = {0}; avl_create(&t, ddt_entry_compare, sizeof (zdb_ddt_entry_t), offsetof(zdb_ddt_entry_t, zdde_node)); spa_config_enter(spa, SCL_CONFIG, FTAG, RW_READER); (void) traverse_pool(spa, 0, TRAVERSE_PRE | TRAVERSE_PREFETCH_METADATA | TRAVERSE_NO_DECRYPT, zdb_ddt_add_cb, &t); spa_config_exit(spa, SCL_CONFIG, FTAG); while ((zdde = avl_destroy_nodes(&t, &cookie)) != NULL) { ddt_stat_t dds; uint64_t refcnt = zdde->zdde_ref_blocks; ASSERT(refcnt != 0); dds.dds_blocks = zdde->zdde_ref_blocks / refcnt; dds.dds_lsize = zdde->zdde_ref_lsize / refcnt; dds.dds_psize = zdde->zdde_ref_psize / refcnt; dds.dds_dsize = zdde->zdde_ref_dsize / refcnt; dds.dds_ref_blocks = zdde->zdde_ref_blocks; dds.dds_ref_lsize = zdde->zdde_ref_lsize; dds.dds_ref_psize = zdde->zdde_ref_psize; dds.dds_ref_dsize = zdde->zdde_ref_dsize; ddt_stat_add(&ddh_total.ddh_stat[highbit64(refcnt) - 1], &dds, 0); umem_free(zdde, sizeof (*zdde)); } avl_destroy(&t); ddt_histogram_stat(&dds_total, &ddh_total); (void) printf("Simulated DDT histogram:\n"); zpool_dump_ddt(&dds_total, &ddh_total); dump_dedup_ratio(&dds_total); } static int verify_device_removal_feature_counts(spa_t *spa) { uint64_t dr_feature_refcount = 0; uint64_t oc_feature_refcount = 0; uint64_t indirect_vdev_count = 0; uint64_t precise_vdev_count = 0; uint64_t obsolete_counts_object_count = 0; uint64_t obsolete_sm_count = 0; uint64_t obsolete_counts_count = 0; uint64_t scip_count = 0; uint64_t obsolete_bpobj_count = 0; int ret = 0; spa_condensing_indirect_phys_t *scip = &spa->spa_condensing_indirect_phys; if (scip->scip_next_mapping_object != 0) { vdev_t *vd = spa->spa_root_vdev->vdev_child[scip->scip_vdev]; ASSERT(scip->scip_prev_obsolete_sm_object != 0); ASSERT3P(vd->vdev_ops, ==, &vdev_indirect_ops); (void) printf("Condensing indirect vdev %llu: new mapping " "object %llu, prev obsolete sm %llu\n", (u_longlong_t)scip->scip_vdev, (u_longlong_t)scip->scip_next_mapping_object, (u_longlong_t)scip->scip_prev_obsolete_sm_object); if (scip->scip_prev_obsolete_sm_object != 0) { space_map_t *prev_obsolete_sm = NULL; VERIFY0(space_map_open(&prev_obsolete_sm, spa->spa_meta_objset, scip->scip_prev_obsolete_sm_object, 0, vd->vdev_asize, 0)); dump_spacemap(spa->spa_meta_objset, prev_obsolete_sm); (void) printf("\n"); space_map_close(prev_obsolete_sm); } scip_count += 2; } for (uint64_t i = 0; i < spa->spa_root_vdev->vdev_children; i++) { vdev_t *vd = spa->spa_root_vdev->vdev_child[i]; vdev_indirect_config_t *vic = &vd->vdev_indirect_config; if (vic->vic_mapping_object != 0) { ASSERT(vd->vdev_ops == &vdev_indirect_ops || vd->vdev_removing); indirect_vdev_count++; if (vd->vdev_indirect_mapping->vim_havecounts) { obsolete_counts_count++; } } boolean_t are_precise; VERIFY0(vdev_obsolete_counts_are_precise(vd, &are_precise)); if (are_precise) { ASSERT(vic->vic_mapping_object != 0); precise_vdev_count++; } uint64_t obsolete_sm_object; VERIFY0(vdev_obsolete_sm_object(vd, &obsolete_sm_object)); if (obsolete_sm_object != 0) { ASSERT(vic->vic_mapping_object != 0); obsolete_sm_count++; } } (void) feature_get_refcount(spa, &spa_feature_table[SPA_FEATURE_DEVICE_REMOVAL], &dr_feature_refcount); (void) feature_get_refcount(spa, &spa_feature_table[SPA_FEATURE_OBSOLETE_COUNTS], &oc_feature_refcount); if (dr_feature_refcount != indirect_vdev_count) { ret = 1; (void) printf("Number of indirect vdevs (%llu) " \ "does not match feature count (%llu)\n", (u_longlong_t)indirect_vdev_count, (u_longlong_t)dr_feature_refcount); } else { (void) printf("Verified device_removal feature refcount " \ "of %llu is correct\n", (u_longlong_t)dr_feature_refcount); } if (zap_contains(spa_meta_objset(spa), DMU_POOL_DIRECTORY_OBJECT, DMU_POOL_OBSOLETE_BPOBJ) == 0) { obsolete_bpobj_count++; } obsolete_counts_object_count = precise_vdev_count; obsolete_counts_object_count += obsolete_sm_count; obsolete_counts_object_count += obsolete_counts_count; obsolete_counts_object_count += scip_count; obsolete_counts_object_count += obsolete_bpobj_count; obsolete_counts_object_count += remap_deadlist_count; if (oc_feature_refcount != obsolete_counts_object_count) { ret = 1; (void) printf("Number of obsolete counts objects (%llu) " \ "does not match feature count (%llu)\n", (u_longlong_t)obsolete_counts_object_count, (u_longlong_t)oc_feature_refcount); (void) printf("pv:%llu os:%llu oc:%llu sc:%llu " "ob:%llu rd:%llu\n", (u_longlong_t)precise_vdev_count, (u_longlong_t)obsolete_sm_count, (u_longlong_t)obsolete_counts_count, (u_longlong_t)scip_count, (u_longlong_t)obsolete_bpobj_count, (u_longlong_t)remap_deadlist_count); } else { (void) printf("Verified indirect_refcount feature refcount " \ "of %llu is correct\n", (u_longlong_t)oc_feature_refcount); } return (ret); } static void zdb_set_skip_mmp(char *target) { spa_t *spa; /* * Disable the activity check to allow examination of * active pools. */ mutex_enter(&spa_namespace_lock); if ((spa = spa_lookup(target)) != NULL) { spa->spa_import_flags |= ZFS_IMPORT_SKIP_MMP; } mutex_exit(&spa_namespace_lock); } #define BOGUS_SUFFIX "_CHECKPOINTED_UNIVERSE" /* * Import the checkpointed state of the pool specified by the target * parameter as readonly. The function also accepts a pool config * as an optional parameter, else it attempts to infer the config by * the name of the target pool. * * Note that the checkpointed state's pool name will be the name of * the original pool with the above suffix appended to it. In addition, * if the target is not a pool name (e.g. a path to a dataset) then * the new_path parameter is populated with the updated path to * reflect the fact that we are looking into the checkpointed state. * * The function returns a newly-allocated copy of the name of the * pool containing the checkpointed state. When this copy is no * longer needed it should be freed with free(3C). Same thing * applies to the new_path parameter if allocated. */ static char * import_checkpointed_state(char *target, nvlist_t *cfg, char **new_path) { int error = 0; char *poolname, *bogus_name = NULL; boolean_t freecfg = B_FALSE; /* If the target is not a pool, the extract the pool name */ char *path_start = strchr(target, '/'); if (path_start != NULL) { size_t poolname_len = path_start - target; poolname = strndup(target, poolname_len); } else { poolname = target; } if (cfg == NULL) { zdb_set_skip_mmp(poolname); error = spa_get_stats(poolname, &cfg, NULL, 0); if (error != 0) { fatal("Tried to read config of pool \"%s\" but " "spa_get_stats() failed with error %d\n", poolname, error); } freecfg = B_TRUE; } if (asprintf(&bogus_name, "%s%s", poolname, BOGUS_SUFFIX) == -1) return (NULL); fnvlist_add_string(cfg, ZPOOL_CONFIG_POOL_NAME, bogus_name); error = spa_import(bogus_name, cfg, NULL, ZFS_IMPORT_MISSING_LOG | ZFS_IMPORT_CHECKPOINT | ZFS_IMPORT_SKIP_MMP); if (freecfg) nvlist_free(cfg); if (error != 0) { fatal("Tried to import pool \"%s\" but spa_import() failed " "with error %d\n", bogus_name, error); } if (new_path != NULL && path_start != NULL) { if (asprintf(new_path, "%s%s", bogus_name, path_start) == -1) { if (path_start != NULL) free(poolname); return (NULL); } } if (target != poolname) free(poolname); return (bogus_name); } typedef struct verify_checkpoint_sm_entry_cb_arg { vdev_t *vcsec_vd; /* the following fields are only used for printing progress */ uint64_t vcsec_entryid; uint64_t vcsec_num_entries; } verify_checkpoint_sm_entry_cb_arg_t; #define ENTRIES_PER_PROGRESS_UPDATE 10000 static int verify_checkpoint_sm_entry_cb(space_map_entry_t *sme, void *arg) { verify_checkpoint_sm_entry_cb_arg_t *vcsec = arg; vdev_t *vd = vcsec->vcsec_vd; metaslab_t *ms = vd->vdev_ms[sme->sme_offset >> vd->vdev_ms_shift]; uint64_t end = sme->sme_offset + sme->sme_run; ASSERT(sme->sme_type == SM_FREE); if ((vcsec->vcsec_entryid % ENTRIES_PER_PROGRESS_UPDATE) == 0) { (void) fprintf(stderr, "\rverifying vdev %llu, space map entry %llu of %llu ...", (longlong_t)vd->vdev_id, (longlong_t)vcsec->vcsec_entryid, (longlong_t)vcsec->vcsec_num_entries); } vcsec->vcsec_entryid++; /* * See comment in checkpoint_sm_exclude_entry_cb() */ VERIFY3U(sme->sme_offset, >=, ms->ms_start); VERIFY3U(end, <=, ms->ms_start + ms->ms_size); /* * The entries in the vdev_checkpoint_sm should be marked as * allocated in the checkpointed state of the pool, therefore * their respective ms_allocateable trees should not contain them. */ mutex_enter(&ms->ms_lock); range_tree_verify_not_present(ms->ms_allocatable, sme->sme_offset, sme->sme_run); mutex_exit(&ms->ms_lock); return (0); } /* * Verify that all segments in the vdev_checkpoint_sm are allocated * according to the checkpoint's ms_sm (i.e. are not in the checkpoint's * ms_allocatable). * * Do so by comparing the checkpoint space maps (vdev_checkpoint_sm) of * each vdev in the current state of the pool to the metaslab space maps * (ms_sm) of the checkpointed state of the pool. * * Note that the function changes the state of the ms_allocatable * trees of the current spa_t. The entries of these ms_allocatable * trees are cleared out and then repopulated from with the free * entries of their respective ms_sm space maps. */ static void verify_checkpoint_vdev_spacemaps(spa_t *checkpoint, spa_t *current) { vdev_t *ckpoint_rvd = checkpoint->spa_root_vdev; vdev_t *current_rvd = current->spa_root_vdev; load_concrete_ms_allocatable_trees(checkpoint, SM_FREE); for (uint64_t c = 0; c < ckpoint_rvd->vdev_children; c++) { vdev_t *ckpoint_vd = ckpoint_rvd->vdev_child[c]; vdev_t *current_vd = current_rvd->vdev_child[c]; space_map_t *checkpoint_sm = NULL; uint64_t checkpoint_sm_obj; if (ckpoint_vd->vdev_ops == &vdev_indirect_ops) { /* * Since we don't allow device removal in a pool * that has a checkpoint, we expect that all removed * vdevs were removed from the pool before the * checkpoint. */ ASSERT3P(current_vd->vdev_ops, ==, &vdev_indirect_ops); continue; } /* * If the checkpoint space map doesn't exist, then nothing * here is checkpointed so there's nothing to verify. */ if (current_vd->vdev_top_zap == 0 || zap_contains(spa_meta_objset(current), current_vd->vdev_top_zap, VDEV_TOP_ZAP_POOL_CHECKPOINT_SM) != 0) continue; VERIFY0(zap_lookup(spa_meta_objset(current), current_vd->vdev_top_zap, VDEV_TOP_ZAP_POOL_CHECKPOINT_SM, sizeof (uint64_t), 1, &checkpoint_sm_obj)); VERIFY0(space_map_open(&checkpoint_sm, spa_meta_objset(current), checkpoint_sm_obj, 0, current_vd->vdev_asize, current_vd->vdev_ashift)); verify_checkpoint_sm_entry_cb_arg_t vcsec; vcsec.vcsec_vd = ckpoint_vd; vcsec.vcsec_entryid = 0; vcsec.vcsec_num_entries = space_map_length(checkpoint_sm) / sizeof (uint64_t); VERIFY0(space_map_iterate(checkpoint_sm, space_map_length(checkpoint_sm), verify_checkpoint_sm_entry_cb, &vcsec)); if (dump_opt['m'] > 3) dump_spacemap(current->spa_meta_objset, checkpoint_sm); space_map_close(checkpoint_sm); } /* * If we've added vdevs since we took the checkpoint, ensure * that their checkpoint space maps are empty. */ if (ckpoint_rvd->vdev_children < current_rvd->vdev_children) { for (uint64_t c = ckpoint_rvd->vdev_children; c < current_rvd->vdev_children; c++) { vdev_t *current_vd = current_rvd->vdev_child[c]; VERIFY3P(current_vd->vdev_checkpoint_sm, ==, NULL); } } /* for cleaner progress output */ (void) fprintf(stderr, "\n"); } /* * Verifies that all space that's allocated in the checkpoint is * still allocated in the current version, by checking that everything * in checkpoint's ms_allocatable (which is actually allocated, not * allocatable/free) is not present in current's ms_allocatable. * * Note that the function changes the state of the ms_allocatable * trees of both spas when called. The entries of all ms_allocatable * trees are cleared out and then repopulated from their respective * ms_sm space maps. In the checkpointed state we load the allocated * entries, and in the current state we load the free entries. */ static void verify_checkpoint_ms_spacemaps(spa_t *checkpoint, spa_t *current) { vdev_t *ckpoint_rvd = checkpoint->spa_root_vdev; vdev_t *current_rvd = current->spa_root_vdev; load_concrete_ms_allocatable_trees(checkpoint, SM_ALLOC); load_concrete_ms_allocatable_trees(current, SM_FREE); for (uint64_t i = 0; i < ckpoint_rvd->vdev_children; i++) { vdev_t *ckpoint_vd = ckpoint_rvd->vdev_child[i]; vdev_t *current_vd = current_rvd->vdev_child[i]; if (ckpoint_vd->vdev_ops == &vdev_indirect_ops) { /* * See comment in verify_checkpoint_vdev_spacemaps() */ ASSERT3P(current_vd->vdev_ops, ==, &vdev_indirect_ops); continue; } for (uint64_t m = 0; m < ckpoint_vd->vdev_ms_count; m++) { metaslab_t *ckpoint_msp = ckpoint_vd->vdev_ms[m]; metaslab_t *current_msp = current_vd->vdev_ms[m]; (void) fprintf(stderr, "\rverifying vdev %llu of %llu, " "metaslab %llu of %llu ...", (longlong_t)current_vd->vdev_id, (longlong_t)current_rvd->vdev_children, (longlong_t)current_vd->vdev_ms[m]->ms_id, (longlong_t)current_vd->vdev_ms_count); /* * We walk through the ms_allocatable trees that * are loaded with the allocated blocks from the * ms_sm spacemaps of the checkpoint. For each * one of these ranges we ensure that none of them * exists in the ms_allocatable trees of the * current state which are loaded with the ranges * that are currently free. * * This way we ensure that none of the blocks that * are part of the checkpoint were freed by mistake. */ range_tree_walk(ckpoint_msp->ms_allocatable, (range_tree_func_t *)range_tree_verify_not_present, current_msp->ms_allocatable); } } /* for cleaner progress output */ (void) fprintf(stderr, "\n"); } static void verify_checkpoint_blocks(spa_t *spa) { ASSERT(!dump_opt['L']); spa_t *checkpoint_spa; char *checkpoint_pool; int error = 0; /* * We import the checkpointed state of the pool (under a different * name) so we can do verification on it against the current state * of the pool. */ checkpoint_pool = import_checkpointed_state(spa->spa_name, NULL, NULL); ASSERT(strcmp(spa->spa_name, checkpoint_pool) != 0); error = spa_open(checkpoint_pool, &checkpoint_spa, FTAG); if (error != 0) { fatal("Tried to open pool \"%s\" but spa_open() failed with " "error %d\n", checkpoint_pool, error); } /* * Ensure that ranges in the checkpoint space maps of each vdev * are allocated according to the checkpointed state's metaslab * space maps. */ verify_checkpoint_vdev_spacemaps(checkpoint_spa, spa); /* * Ensure that allocated ranges in the checkpoint's metaslab * space maps remain allocated in the metaslab space maps of * the current state. */ verify_checkpoint_ms_spacemaps(checkpoint_spa, spa); /* * Once we are done, we get rid of the checkpointed state. */ spa_close(checkpoint_spa, FTAG); free(checkpoint_pool); } static void dump_leftover_checkpoint_blocks(spa_t *spa) { vdev_t *rvd = spa->spa_root_vdev; for (uint64_t i = 0; i < rvd->vdev_children; i++) { vdev_t *vd = rvd->vdev_child[i]; space_map_t *checkpoint_sm = NULL; uint64_t checkpoint_sm_obj; if (vd->vdev_top_zap == 0) continue; if (zap_contains(spa_meta_objset(spa), vd->vdev_top_zap, VDEV_TOP_ZAP_POOL_CHECKPOINT_SM) != 0) continue; VERIFY0(zap_lookup(spa_meta_objset(spa), vd->vdev_top_zap, VDEV_TOP_ZAP_POOL_CHECKPOINT_SM, sizeof (uint64_t), 1, &checkpoint_sm_obj)); VERIFY0(space_map_open(&checkpoint_sm, spa_meta_objset(spa), checkpoint_sm_obj, 0, vd->vdev_asize, vd->vdev_ashift)); dump_spacemap(spa->spa_meta_objset, checkpoint_sm); space_map_close(checkpoint_sm); } } static int verify_checkpoint(spa_t *spa) { uberblock_t checkpoint; int error; if (!spa_feature_is_active(spa, SPA_FEATURE_POOL_CHECKPOINT)) return (0); error = zap_lookup(spa->spa_meta_objset, DMU_POOL_DIRECTORY_OBJECT, DMU_POOL_ZPOOL_CHECKPOINT, sizeof (uint64_t), sizeof (uberblock_t) / sizeof (uint64_t), &checkpoint); if (error == ENOENT && !dump_opt['L']) { /* * If the feature is active but the uberblock is missing * then we must be in the middle of discarding the * checkpoint. */ (void) printf("\nPartially discarded checkpoint " "state found:\n"); if (dump_opt['m'] > 3) dump_leftover_checkpoint_blocks(spa); return (0); } else if (error != 0) { (void) printf("lookup error %d when looking for " "checkpointed uberblock in MOS\n", error); return (error); } dump_uberblock(&checkpoint, "\nCheckpointed uberblock found:\n", "\n"); if (checkpoint.ub_checkpoint_txg == 0) { (void) printf("\nub_checkpoint_txg not set in checkpointed " "uberblock\n"); error = 3; } if (error == 0 && !dump_opt['L']) verify_checkpoint_blocks(spa); return (error); } static void mos_leaks_cb(void *arg, uint64_t start, uint64_t size) { (void) arg; for (uint64_t i = start; i < size; i++) { (void) printf("MOS object %llu referenced but not allocated\n", (u_longlong_t)i); } } static void mos_obj_refd(uint64_t obj) { if (obj != 0 && mos_refd_objs != NULL) range_tree_add(mos_refd_objs, obj, 1); } /* * Call on a MOS object that may already have been referenced. */ static void mos_obj_refd_multiple(uint64_t obj) { if (obj != 0 && mos_refd_objs != NULL && !range_tree_contains(mos_refd_objs, obj, 1)) range_tree_add(mos_refd_objs, obj, 1); } static void mos_leak_vdev_top_zap(vdev_t *vd) { uint64_t ms_flush_data_obj; int error = zap_lookup(spa_meta_objset(vd->vdev_spa), vd->vdev_top_zap, VDEV_TOP_ZAP_MS_UNFLUSHED_PHYS_TXGS, sizeof (ms_flush_data_obj), 1, &ms_flush_data_obj); if (error == ENOENT) return; ASSERT0(error); mos_obj_refd(ms_flush_data_obj); } static void mos_leak_vdev(vdev_t *vd) { mos_obj_refd(vd->vdev_dtl_object); mos_obj_refd(vd->vdev_ms_array); mos_obj_refd(vd->vdev_indirect_config.vic_births_object); mos_obj_refd(vd->vdev_indirect_config.vic_mapping_object); mos_obj_refd(vd->vdev_leaf_zap); if (vd->vdev_checkpoint_sm != NULL) mos_obj_refd(vd->vdev_checkpoint_sm->sm_object); if (vd->vdev_indirect_mapping != NULL) { mos_obj_refd(vd->vdev_indirect_mapping-> vim_phys->vimp_counts_object); } if (vd->vdev_obsolete_sm != NULL) mos_obj_refd(vd->vdev_obsolete_sm->sm_object); for (uint64_t m = 0; m < vd->vdev_ms_count; m++) { metaslab_t *ms = vd->vdev_ms[m]; mos_obj_refd(space_map_object(ms->ms_sm)); } if (vd->vdev_top_zap != 0) { mos_obj_refd(vd->vdev_top_zap); mos_leak_vdev_top_zap(vd); } for (uint64_t c = 0; c < vd->vdev_children; c++) { mos_leak_vdev(vd->vdev_child[c]); } } static void mos_leak_log_spacemaps(spa_t *spa) { uint64_t spacemap_zap; int error = zap_lookup(spa_meta_objset(spa), DMU_POOL_DIRECTORY_OBJECT, DMU_POOL_LOG_SPACEMAP_ZAP, sizeof (spacemap_zap), 1, &spacemap_zap); if (error == ENOENT) return; ASSERT0(error); mos_obj_refd(spacemap_zap); for (spa_log_sm_t *sls = avl_first(&spa->spa_sm_logs_by_txg); sls; sls = AVL_NEXT(&spa->spa_sm_logs_by_txg, sls)) mos_obj_refd(sls->sls_sm_obj); } static int dump_mos_leaks(spa_t *spa) { int rv = 0; objset_t *mos = spa->spa_meta_objset; dsl_pool_t *dp = spa->spa_dsl_pool; /* Visit and mark all referenced objects in the MOS */ mos_obj_refd(DMU_POOL_DIRECTORY_OBJECT); mos_obj_refd(spa->spa_pool_props_object); mos_obj_refd(spa->spa_config_object); mos_obj_refd(spa->spa_ddt_stat_object); mos_obj_refd(spa->spa_feat_desc_obj); mos_obj_refd(spa->spa_feat_enabled_txg_obj); mos_obj_refd(spa->spa_feat_for_read_obj); mos_obj_refd(spa->spa_feat_for_write_obj); mos_obj_refd(spa->spa_history); mos_obj_refd(spa->spa_errlog_last); mos_obj_refd(spa->spa_errlog_scrub); mos_obj_refd(spa->spa_all_vdev_zaps); mos_obj_refd(spa->spa_dsl_pool->dp_bptree_obj); mos_obj_refd(spa->spa_dsl_pool->dp_tmp_userrefs_obj); mos_obj_refd(spa->spa_dsl_pool->dp_scan->scn_phys.scn_queue_obj); bpobj_count_refd(&spa->spa_deferred_bpobj); mos_obj_refd(dp->dp_empty_bpobj); bpobj_count_refd(&dp->dp_obsolete_bpobj); bpobj_count_refd(&dp->dp_free_bpobj); mos_obj_refd(spa->spa_l2cache.sav_object); mos_obj_refd(spa->spa_spares.sav_object); if (spa->spa_syncing_log_sm != NULL) mos_obj_refd(spa->spa_syncing_log_sm->sm_object); mos_leak_log_spacemaps(spa); mos_obj_refd(spa->spa_condensing_indirect_phys. scip_next_mapping_object); mos_obj_refd(spa->spa_condensing_indirect_phys. scip_prev_obsolete_sm_object); if (spa->spa_condensing_indirect_phys.scip_next_mapping_object != 0) { vdev_indirect_mapping_t *vim = vdev_indirect_mapping_open(mos, spa->spa_condensing_indirect_phys.scip_next_mapping_object); mos_obj_refd(vim->vim_phys->vimp_counts_object); vdev_indirect_mapping_close(vim); } deleted_livelists_dump_mos(spa); if (dp->dp_origin_snap != NULL) { dsl_dataset_t *ds; dsl_pool_config_enter(dp, FTAG); VERIFY0(dsl_dataset_hold_obj(dp, dsl_dataset_phys(dp->dp_origin_snap)->ds_next_snap_obj, FTAG, &ds)); count_ds_mos_objects(ds); dump_blkptr_list(&ds->ds_deadlist, "Deadlist"); dsl_dataset_rele(ds, FTAG); dsl_pool_config_exit(dp, FTAG); count_ds_mos_objects(dp->dp_origin_snap); dump_blkptr_list(&dp->dp_origin_snap->ds_deadlist, "Deadlist"); } count_dir_mos_objects(dp->dp_mos_dir); if (dp->dp_free_dir != NULL) count_dir_mos_objects(dp->dp_free_dir); if (dp->dp_leak_dir != NULL) count_dir_mos_objects(dp->dp_leak_dir); mos_leak_vdev(spa->spa_root_vdev); for (uint64_t class = 0; class < DDT_CLASSES; class++) { for (uint64_t type = 0; type < DDT_TYPES; type++) { for (uint64_t cksum = 0; cksum < ZIO_CHECKSUM_FUNCTIONS; cksum++) { ddt_t *ddt = spa->spa_ddt[cksum]; mos_obj_refd(ddt->ddt_object[type][class]); } } } /* * Visit all allocated objects and make sure they are referenced. */ uint64_t object = 0; while (dmu_object_next(mos, &object, B_FALSE, 0) == 0) { if (range_tree_contains(mos_refd_objs, object, 1)) { range_tree_remove(mos_refd_objs, object, 1); } else { dmu_object_info_t doi; const char *name; dmu_object_info(mos, object, &doi); if (doi.doi_type & DMU_OT_NEWTYPE) { dmu_object_byteswap_t bswap = DMU_OT_BYTESWAP(doi.doi_type); name = dmu_ot_byteswap[bswap].ob_name; } else { name = dmu_ot[doi.doi_type].ot_name; } (void) printf("MOS object %llu (%s) leaked\n", (u_longlong_t)object, name); rv = 2; } } (void) range_tree_walk(mos_refd_objs, mos_leaks_cb, NULL); if (!range_tree_is_empty(mos_refd_objs)) rv = 2; range_tree_vacate(mos_refd_objs, NULL, NULL); range_tree_destroy(mos_refd_objs); return (rv); } typedef struct log_sm_obsolete_stats_arg { uint64_t lsos_current_txg; uint64_t lsos_total_entries; uint64_t lsos_valid_entries; uint64_t lsos_sm_entries; uint64_t lsos_valid_sm_entries; } log_sm_obsolete_stats_arg_t; static int log_spacemap_obsolete_stats_cb(spa_t *spa, space_map_entry_t *sme, uint64_t txg, void *arg) { log_sm_obsolete_stats_arg_t *lsos = arg; uint64_t offset = sme->sme_offset; uint64_t vdev_id = sme->sme_vdev; if (lsos->lsos_current_txg == 0) { /* this is the first log */ lsos->lsos_current_txg = txg; } else if (lsos->lsos_current_txg < txg) { /* we just changed log - print stats and reset */ (void) printf("%-8llu valid entries out of %-8llu - txg %llu\n", (u_longlong_t)lsos->lsos_valid_sm_entries, (u_longlong_t)lsos->lsos_sm_entries, (u_longlong_t)lsos->lsos_current_txg); lsos->lsos_valid_sm_entries = 0; lsos->lsos_sm_entries = 0; lsos->lsos_current_txg = txg; } ASSERT3U(lsos->lsos_current_txg, ==, txg); lsos->lsos_sm_entries++; lsos->lsos_total_entries++; vdev_t *vd = vdev_lookup_top(spa, vdev_id); if (!vdev_is_concrete(vd)) return (0); metaslab_t *ms = vd->vdev_ms[offset >> vd->vdev_ms_shift]; ASSERT(sme->sme_type == SM_ALLOC || sme->sme_type == SM_FREE); if (txg < metaslab_unflushed_txg(ms)) return (0); lsos->lsos_valid_sm_entries++; lsos->lsos_valid_entries++; return (0); } static void dump_log_spacemap_obsolete_stats(spa_t *spa) { if (!spa_feature_is_active(spa, SPA_FEATURE_LOG_SPACEMAP)) return; log_sm_obsolete_stats_arg_t lsos = {0}; (void) printf("Log Space Map Obsolete Entry Statistics:\n"); iterate_through_spacemap_logs(spa, log_spacemap_obsolete_stats_cb, &lsos); /* print stats for latest log */ (void) printf("%-8llu valid entries out of %-8llu - txg %llu\n", (u_longlong_t)lsos.lsos_valid_sm_entries, (u_longlong_t)lsos.lsos_sm_entries, (u_longlong_t)lsos.lsos_current_txg); (void) printf("%-8llu valid entries out of %-8llu - total\n\n", (u_longlong_t)lsos.lsos_valid_entries, (u_longlong_t)lsos.lsos_total_entries); } static void dump_zpool(spa_t *spa) { dsl_pool_t *dp = spa_get_dsl(spa); int rc = 0; if (dump_opt['y']) { livelist_metaslab_validate(spa); } if (dump_opt['S']) { dump_simulated_ddt(spa); return; } if (!dump_opt['e'] && dump_opt['C'] > 1) { (void) printf("\nCached configuration:\n"); dump_nvlist(spa->spa_config, 8); } if (dump_opt['C']) dump_config(spa); if (dump_opt['u']) dump_uberblock(&spa->spa_uberblock, "\nUberblock:\n", "\n"); if (dump_opt['D']) dump_all_ddts(spa); if (dump_opt['d'] > 2 || dump_opt['m']) dump_metaslabs(spa); if (dump_opt['M']) dump_metaslab_groups(spa, dump_opt['M'] > 1); if (dump_opt['d'] > 2 || dump_opt['m']) { dump_log_spacemaps(spa); dump_log_spacemap_obsolete_stats(spa); } if (dump_opt['d'] || dump_opt['i']) { spa_feature_t f; mos_refd_objs = range_tree_create(NULL, RANGE_SEG64, NULL, 0, 0); dump_objset(dp->dp_meta_objset); if (dump_opt['d'] >= 3) { dsl_pool_t *dp = spa->spa_dsl_pool; dump_full_bpobj(&spa->spa_deferred_bpobj, "Deferred frees", 0); if (spa_version(spa) >= SPA_VERSION_DEADLISTS) { dump_full_bpobj(&dp->dp_free_bpobj, "Pool snapshot frees", 0); } if (bpobj_is_open(&dp->dp_obsolete_bpobj)) { ASSERT(spa_feature_is_enabled(spa, SPA_FEATURE_DEVICE_REMOVAL)); dump_full_bpobj(&dp->dp_obsolete_bpobj, "Pool obsolete blocks", 0); } if (spa_feature_is_active(spa, SPA_FEATURE_ASYNC_DESTROY)) { dump_bptree(spa->spa_meta_objset, dp->dp_bptree_obj, "Pool dataset frees"); } dump_dtl(spa->spa_root_vdev, 0); } for (spa_feature_t f = 0; f < SPA_FEATURES; f++) global_feature_count[f] = UINT64_MAX; global_feature_count[SPA_FEATURE_REDACTION_BOOKMARKS] = 0; global_feature_count[SPA_FEATURE_BOOKMARK_WRITTEN] = 0; global_feature_count[SPA_FEATURE_LIVELIST] = 0; (void) dmu_objset_find(spa_name(spa), dump_one_objset, NULL, DS_FIND_SNAPSHOTS | DS_FIND_CHILDREN); if (rc == 0 && !dump_opt['L']) rc = dump_mos_leaks(spa); for (f = 0; f < SPA_FEATURES; f++) { uint64_t refcount; uint64_t *arr; if (!(spa_feature_table[f].fi_flags & ZFEATURE_FLAG_PER_DATASET)) { if (global_feature_count[f] == UINT64_MAX) continue; if (!spa_feature_is_enabled(spa, f)) { ASSERT0(global_feature_count[f]); continue; } arr = global_feature_count; } else { if (!spa_feature_is_enabled(spa, f)) { ASSERT0(dataset_feature_count[f]); continue; } arr = dataset_feature_count; } if (feature_get_refcount(spa, &spa_feature_table[f], &refcount) == ENOTSUP) continue; if (arr[f] != refcount) { (void) printf("%s feature refcount mismatch: " "%lld consumers != %lld refcount\n", spa_feature_table[f].fi_uname, (longlong_t)arr[f], (longlong_t)refcount); rc = 2; } else { (void) printf("Verified %s feature refcount " "of %llu is correct\n", spa_feature_table[f].fi_uname, (longlong_t)refcount); } } if (rc == 0) rc = verify_device_removal_feature_counts(spa); } if (rc == 0 && (dump_opt['b'] || dump_opt['c'])) rc = dump_block_stats(spa); if (rc == 0) rc = verify_spacemap_refcounts(spa); if (dump_opt['s']) show_pool_stats(spa); if (dump_opt['h']) dump_history(spa); if (rc == 0) rc = verify_checkpoint(spa); if (rc != 0) { dump_debug_buffer(); exit(rc); } } #define ZDB_FLAG_CHECKSUM 0x0001 #define ZDB_FLAG_DECOMPRESS 0x0002 #define ZDB_FLAG_BSWAP 0x0004 #define ZDB_FLAG_GBH 0x0008 #define ZDB_FLAG_INDIRECT 0x0010 #define ZDB_FLAG_RAW 0x0020 #define ZDB_FLAG_PRINT_BLKPTR 0x0040 #define ZDB_FLAG_VERBOSE 0x0080 static int flagbits[256]; static char flagbitstr[16]; static void zdb_print_blkptr(const blkptr_t *bp, int flags) { char blkbuf[BP_SPRINTF_LEN]; if (flags & ZDB_FLAG_BSWAP) byteswap_uint64_array((void *)bp, sizeof (blkptr_t)); snprintf_blkptr(blkbuf, sizeof (blkbuf), bp); (void) printf("%s\n", blkbuf); } static void zdb_dump_indirect(blkptr_t *bp, int nbps, int flags) { int i; for (i = 0; i < nbps; i++) zdb_print_blkptr(&bp[i], flags); } static void zdb_dump_gbh(void *buf, int flags) { zdb_dump_indirect((blkptr_t *)buf, SPA_GBH_NBLKPTRS, flags); } static void zdb_dump_block_raw(void *buf, uint64_t size, int flags) { if (flags & ZDB_FLAG_BSWAP) byteswap_uint64_array(buf, size); VERIFY(write(fileno(stdout), buf, size) == size); } static void zdb_dump_block(char *label, void *buf, uint64_t size, int flags) { uint64_t *d = (uint64_t *)buf; unsigned nwords = size / sizeof (uint64_t); int do_bswap = !!(flags & ZDB_FLAG_BSWAP); unsigned i, j; const char *hdr; char *c; if (do_bswap) hdr = " 7 6 5 4 3 2 1 0 f e d c b a 9 8"; else hdr = " 0 1 2 3 4 5 6 7 8 9 a b c d e f"; (void) printf("\n%s\n%6s %s 0123456789abcdef\n", label, "", hdr); #ifdef _LITTLE_ENDIAN /* correct the endianness */ do_bswap = !do_bswap; #endif for (i = 0; i < nwords; i += 2) { (void) printf("%06llx: %016llx %016llx ", (u_longlong_t)(i * sizeof (uint64_t)), (u_longlong_t)(do_bswap ? BSWAP_64(d[i]) : d[i]), (u_longlong_t)(do_bswap ? BSWAP_64(d[i + 1]) : d[i + 1])); c = (char *)&d[i]; for (j = 0; j < 2 * sizeof (uint64_t); j++) (void) printf("%c", isprint(c[j]) ? c[j] : '.'); (void) printf("\n"); } } /* * There are two acceptable formats: * leaf_name - For example: c1t0d0 or /tmp/ztest.0a * child[.child]* - For example: 0.1.1 * * The second form can be used to specify arbitrary vdevs anywhere * in the hierarchy. For example, in a pool with a mirror of * RAID-Zs, you can specify either RAID-Z vdev with 0.0 or 0.1 . */ static vdev_t * zdb_vdev_lookup(vdev_t *vdev, const char *path) { char *s, *p, *q; unsigned i; if (vdev == NULL) return (NULL); /* First, assume the x.x.x.x format */ i = strtoul(path, &s, 10); if (s == path || (s && *s != '.' && *s != '\0')) goto name; if (i >= vdev->vdev_children) return (NULL); vdev = vdev->vdev_child[i]; if (s && *s == '\0') return (vdev); return (zdb_vdev_lookup(vdev, s+1)); name: for (i = 0; i < vdev->vdev_children; i++) { vdev_t *vc = vdev->vdev_child[i]; if (vc->vdev_path == NULL) { vc = zdb_vdev_lookup(vc, path); if (vc == NULL) continue; else return (vc); } p = strrchr(vc->vdev_path, '/'); p = p ? p + 1 : vc->vdev_path; q = &vc->vdev_path[strlen(vc->vdev_path) - 2]; if (strcmp(vc->vdev_path, path) == 0) return (vc); if (strcmp(p, path) == 0) return (vc); if (strcmp(q, "s0") == 0 && strncmp(p, path, q - p) == 0) return (vc); } return (NULL); } static int name_from_objset_id(spa_t *spa, uint64_t objset_id, char *outstr) { dsl_dataset_t *ds; dsl_pool_config_enter(spa->spa_dsl_pool, FTAG); int error = dsl_dataset_hold_obj(spa->spa_dsl_pool, objset_id, NULL, &ds); if (error != 0) { (void) fprintf(stderr, "failed to hold objset %llu: %s\n", (u_longlong_t)objset_id, strerror(error)); dsl_pool_config_exit(spa->spa_dsl_pool, FTAG); return (error); } dsl_dataset_name(ds, outstr); dsl_dataset_rele(ds, NULL); dsl_pool_config_exit(spa->spa_dsl_pool, FTAG); return (0); } static boolean_t zdb_parse_block_sizes(char *sizes, uint64_t *lsize, uint64_t *psize) { char *s0, *s1, *tmp = NULL; if (sizes == NULL) return (B_FALSE); s0 = strtok_r(sizes, "/", &tmp); if (s0 == NULL) return (B_FALSE); s1 = strtok_r(NULL, "/", &tmp); *lsize = strtoull(s0, NULL, 16); *psize = s1 ? strtoull(s1, NULL, 16) : *lsize; return (*lsize >= *psize && *psize > 0); } #define ZIO_COMPRESS_MASK(alg) (1ULL << (ZIO_COMPRESS_##alg)) static boolean_t zdb_decompress_block(abd_t *pabd, void *buf, void *lbuf, uint64_t lsize, uint64_t psize, int flags) { (void) buf; boolean_t exceeded = B_FALSE; /* * We don't know how the data was compressed, so just try * every decompress function at every inflated blocksize. */ void *lbuf2 = umem_alloc(SPA_MAXBLOCKSIZE, UMEM_NOFAIL); int cfuncs[ZIO_COMPRESS_FUNCTIONS] = { 0 }; int *cfuncp = cfuncs; uint64_t maxlsize = SPA_MAXBLOCKSIZE; uint64_t mask = ZIO_COMPRESS_MASK(ON) | ZIO_COMPRESS_MASK(OFF) | ZIO_COMPRESS_MASK(INHERIT) | ZIO_COMPRESS_MASK(EMPTY) | (getenv("ZDB_NO_ZLE") ? ZIO_COMPRESS_MASK(ZLE) : 0); *cfuncp++ = ZIO_COMPRESS_LZ4; *cfuncp++ = ZIO_COMPRESS_LZJB; mask |= ZIO_COMPRESS_MASK(LZ4) | ZIO_COMPRESS_MASK(LZJB); for (int c = 0; c < ZIO_COMPRESS_FUNCTIONS; c++) if (((1ULL << c) & mask) == 0) *cfuncp++ = c; /* * On the one hand, with SPA_MAXBLOCKSIZE at 16MB, this * could take a while and we should let the user know * we are not stuck. On the other hand, printing progress * info gets old after a while. User can specify 'v' flag * to see the progression. */ if (lsize == psize) lsize += SPA_MINBLOCKSIZE; else maxlsize = lsize; for (; lsize <= maxlsize; lsize += SPA_MINBLOCKSIZE) { for (cfuncp = cfuncs; *cfuncp; cfuncp++) { if (flags & ZDB_FLAG_VERBOSE) { (void) fprintf(stderr, "Trying %05llx -> %05llx (%s)\n", (u_longlong_t)psize, (u_longlong_t)lsize, zio_compress_table[*cfuncp].\ ci_name); } /* * We randomize lbuf2, and decompress to both * lbuf and lbuf2. This way, we will know if * decompression fill exactly to lsize. */ VERIFY0(random_get_pseudo_bytes(lbuf2, lsize)); if (zio_decompress_data(*cfuncp, pabd, lbuf, psize, lsize, NULL) == 0 && zio_decompress_data(*cfuncp, pabd, lbuf2, psize, lsize, NULL) == 0 && memcmp(lbuf, lbuf2, lsize) == 0) break; } if (*cfuncp != 0) break; } umem_free(lbuf2, SPA_MAXBLOCKSIZE); if (lsize > maxlsize) { exceeded = B_TRUE; } if (*cfuncp == ZIO_COMPRESS_ZLE) { printf("\nZLE decompression was selected. If you " "suspect the results are wrong,\ntry avoiding ZLE " "by setting and exporting ZDB_NO_ZLE=\"true\"\n"); } return (exceeded); } /* * Read a block from a pool and print it out. The syntax of the * block descriptor is: * * pool:vdev_specifier:offset:[lsize/]psize[:flags] * * pool - The name of the pool you wish to read from * vdev_specifier - Which vdev (see comment for zdb_vdev_lookup) * offset - offset, in hex, in bytes * size - Amount of data to read, in hex, in bytes * flags - A string of characters specifying options * b: Decode a blkptr at given offset within block * c: Calculate and display checksums * d: Decompress data before dumping * e: Byteswap data before dumping * g: Display data as a gang block header * i: Display as an indirect block * r: Dump raw data to stdout * v: Verbose * */ static void zdb_read_block(char *thing, spa_t *spa) { blkptr_t blk, *bp = &blk; dva_t *dva = bp->blk_dva; int flags = 0; uint64_t offset = 0, psize = 0, lsize = 0, blkptr_offset = 0; zio_t *zio; vdev_t *vd; abd_t *pabd; void *lbuf, *buf; char *s, *p, *dup, *flagstr, *sizes, *tmp = NULL; const char *vdev, *errmsg = NULL; int i, error; boolean_t borrowed = B_FALSE, found = B_FALSE; dup = strdup(thing); s = strtok_r(dup, ":", &tmp); vdev = s ?: ""; s = strtok_r(NULL, ":", &tmp); offset = strtoull(s ? s : "", NULL, 16); sizes = strtok_r(NULL, ":", &tmp); s = strtok_r(NULL, ":", &tmp); flagstr = strdup(s ?: ""); if (!zdb_parse_block_sizes(sizes, &lsize, &psize)) errmsg = "invalid size(s)"; if (!IS_P2ALIGNED(psize, DEV_BSIZE) || !IS_P2ALIGNED(lsize, DEV_BSIZE)) errmsg = "size must be a multiple of sector size"; if (!IS_P2ALIGNED(offset, DEV_BSIZE)) errmsg = "offset must be a multiple of sector size"; if (errmsg) { (void) printf("Invalid block specifier: %s - %s\n", thing, errmsg); goto done; } tmp = NULL; for (s = strtok_r(flagstr, ":", &tmp); s != NULL; s = strtok_r(NULL, ":", &tmp)) { for (i = 0; i < strlen(flagstr); i++) { int bit = flagbits[(uchar_t)flagstr[i]]; if (bit == 0) { (void) printf("***Ignoring flag: %c\n", (uchar_t)flagstr[i]); continue; } found = B_TRUE; flags |= bit; p = &flagstr[i + 1]; if (*p != ':' && *p != '\0') { int j = 0, nextbit = flagbits[(uchar_t)*p]; char *end, offstr[8] = { 0 }; if ((bit == ZDB_FLAG_PRINT_BLKPTR) && (nextbit == 0)) { /* look ahead to isolate the offset */ while (nextbit == 0 && strchr(flagbitstr, *p) == NULL) { offstr[j] = *p; j++; if (i + j > strlen(flagstr)) break; p++; nextbit = flagbits[(uchar_t)*p]; } blkptr_offset = strtoull(offstr, &end, 16); i += j; } else if (nextbit == 0) { (void) printf("***Ignoring flag arg:" " '%c'\n", (uchar_t)*p); } } } } if (blkptr_offset % sizeof (blkptr_t)) { printf("Block pointer offset 0x%llx " "must be divisible by 0x%x\n", (longlong_t)blkptr_offset, (int)sizeof (blkptr_t)); goto done; } if (found == B_FALSE && strlen(flagstr) > 0) { printf("Invalid flag arg: '%s'\n", flagstr); goto done; } vd = zdb_vdev_lookup(spa->spa_root_vdev, vdev); if (vd == NULL) { (void) printf("***Invalid vdev: %s\n", vdev); free(dup); return; } else { if (vd->vdev_path) (void) fprintf(stderr, "Found vdev: %s\n", vd->vdev_path); else (void) fprintf(stderr, "Found vdev type: %s\n", vd->vdev_ops->vdev_op_type); } pabd = abd_alloc_for_io(SPA_MAXBLOCKSIZE, B_FALSE); lbuf = umem_alloc(SPA_MAXBLOCKSIZE, UMEM_NOFAIL); BP_ZERO(bp); DVA_SET_VDEV(&dva[0], vd->vdev_id); DVA_SET_OFFSET(&dva[0], offset); DVA_SET_GANG(&dva[0], !!(flags & ZDB_FLAG_GBH)); DVA_SET_ASIZE(&dva[0], vdev_psize_to_asize(vd, psize)); BP_SET_BIRTH(bp, TXG_INITIAL, TXG_INITIAL); BP_SET_LSIZE(bp, lsize); BP_SET_PSIZE(bp, psize); BP_SET_COMPRESS(bp, ZIO_COMPRESS_OFF); BP_SET_CHECKSUM(bp, ZIO_CHECKSUM_OFF); BP_SET_TYPE(bp, DMU_OT_NONE); BP_SET_LEVEL(bp, 0); BP_SET_DEDUP(bp, 0); BP_SET_BYTEORDER(bp, ZFS_HOST_BYTEORDER); spa_config_enter(spa, SCL_STATE, FTAG, RW_READER); zio = zio_root(spa, NULL, NULL, 0); if (vd == vd->vdev_top) { /* * Treat this as a normal block read. */ zio_nowait(zio_read(zio, spa, bp, pabd, psize, NULL, NULL, ZIO_PRIORITY_SYNC_READ, ZIO_FLAG_CANFAIL | ZIO_FLAG_RAW, NULL)); } else { /* * Treat this as a vdev child I/O. */ zio_nowait(zio_vdev_child_io(zio, bp, vd, offset, pabd, psize, ZIO_TYPE_READ, ZIO_PRIORITY_SYNC_READ, ZIO_FLAG_DONT_CACHE | ZIO_FLAG_DONT_PROPAGATE | ZIO_FLAG_DONT_RETRY | ZIO_FLAG_CANFAIL | ZIO_FLAG_RAW | ZIO_FLAG_OPTIONAL, NULL, NULL)); } error = zio_wait(zio); spa_config_exit(spa, SCL_STATE, FTAG); if (error) { (void) printf("Read of %s failed, error: %d\n", thing, error); goto out; } uint64_t orig_lsize = lsize; buf = lbuf; if (flags & ZDB_FLAG_DECOMPRESS) { boolean_t failed = zdb_decompress_block(pabd, buf, lbuf, lsize, psize, flags); if (failed) { (void) printf("Decompress of %s failed\n", thing); goto out; } } else { buf = abd_borrow_buf_copy(pabd, lsize); borrowed = B_TRUE; } /* * Try to detect invalid block pointer. If invalid, try * decompressing. */ if ((flags & ZDB_FLAG_PRINT_BLKPTR || flags & ZDB_FLAG_INDIRECT) && !(flags & ZDB_FLAG_DECOMPRESS)) { const blkptr_t *b = (const blkptr_t *)(void *) ((uintptr_t)buf + (uintptr_t)blkptr_offset); if (zfs_blkptr_verify(spa, b, B_FALSE, BLK_VERIFY_ONLY) == B_FALSE) { abd_return_buf_copy(pabd, buf, lsize); borrowed = B_FALSE; buf = lbuf; boolean_t failed = zdb_decompress_block(pabd, buf, lbuf, lsize, psize, flags); b = (const blkptr_t *)(void *) ((uintptr_t)buf + (uintptr_t)blkptr_offset); if (failed || zfs_blkptr_verify(spa, b, B_FALSE, BLK_VERIFY_LOG) == B_FALSE) { printf("invalid block pointer at this DVA\n"); goto out; } } } if (flags & ZDB_FLAG_PRINT_BLKPTR) zdb_print_blkptr((blkptr_t *)(void *) ((uintptr_t)buf + (uintptr_t)blkptr_offset), flags); else if (flags & ZDB_FLAG_RAW) zdb_dump_block_raw(buf, lsize, flags); else if (flags & ZDB_FLAG_INDIRECT) zdb_dump_indirect((blkptr_t *)buf, orig_lsize / sizeof (blkptr_t), flags); else if (flags & ZDB_FLAG_GBH) zdb_dump_gbh(buf, flags); else zdb_dump_block(thing, buf, lsize, flags); /* * If :c was specified, iterate through the checksum table to * calculate and display each checksum for our specified * DVA and length. */ if ((flags & ZDB_FLAG_CHECKSUM) && !(flags & ZDB_FLAG_RAW) && !(flags & ZDB_FLAG_GBH)) { zio_t *czio; (void) printf("\n"); for (enum zio_checksum ck = ZIO_CHECKSUM_LABEL; ck < ZIO_CHECKSUM_FUNCTIONS; ck++) { if ((zio_checksum_table[ck].ci_flags & ZCHECKSUM_FLAG_EMBEDDED) || ck == ZIO_CHECKSUM_NOPARITY) { continue; } BP_SET_CHECKSUM(bp, ck); spa_config_enter(spa, SCL_STATE, FTAG, RW_READER); czio = zio_root(spa, NULL, NULL, ZIO_FLAG_CANFAIL); czio->io_bp = bp; if (vd == vd->vdev_top) { zio_nowait(zio_read(czio, spa, bp, pabd, psize, NULL, NULL, ZIO_PRIORITY_SYNC_READ, ZIO_FLAG_CANFAIL | ZIO_FLAG_RAW | ZIO_FLAG_DONT_RETRY, NULL)); } else { zio_nowait(zio_vdev_child_io(czio, bp, vd, offset, pabd, psize, ZIO_TYPE_READ, ZIO_PRIORITY_SYNC_READ, ZIO_FLAG_DONT_CACHE | ZIO_FLAG_DONT_PROPAGATE | ZIO_FLAG_DONT_RETRY | ZIO_FLAG_CANFAIL | ZIO_FLAG_RAW | ZIO_FLAG_SPECULATIVE | ZIO_FLAG_OPTIONAL, NULL, NULL)); } error = zio_wait(czio); if (error == 0 || error == ECKSUM) { zio_t *ck_zio = zio_root(spa, NULL, NULL, 0); ck_zio->io_offset = DVA_GET_OFFSET(&bp->blk_dva[0]); ck_zio->io_bp = bp; zio_checksum_compute(ck_zio, ck, pabd, lsize); printf("%12s\tcksum=%llx:%llx:%llx:%llx\n", zio_checksum_table[ck].ci_name, (u_longlong_t)bp->blk_cksum.zc_word[0], (u_longlong_t)bp->blk_cksum.zc_word[1], (u_longlong_t)bp->blk_cksum.zc_word[2], (u_longlong_t)bp->blk_cksum.zc_word[3]); zio_wait(ck_zio); } else { printf("error %d reading block\n", error); } spa_config_exit(spa, SCL_STATE, FTAG); } } if (borrowed) abd_return_buf_copy(pabd, buf, lsize); out: abd_free(pabd); umem_free(lbuf, SPA_MAXBLOCKSIZE); done: free(flagstr); free(dup); } static void zdb_embedded_block(char *thing) { blkptr_t bp = {{{{0}}}}; unsigned long long *words = (void *)&bp; char *buf; int err; err = sscanf(thing, "%llx:%llx:%llx:%llx:%llx:%llx:%llx:%llx:" "%llx:%llx:%llx:%llx:%llx:%llx:%llx:%llx", words + 0, words + 1, words + 2, words + 3, words + 4, words + 5, words + 6, words + 7, words + 8, words + 9, words + 10, words + 11, words + 12, words + 13, words + 14, words + 15); if (err != 16) { (void) fprintf(stderr, "invalid input format\n"); exit(1); } ASSERT3U(BPE_GET_LSIZE(&bp), <=, SPA_MAXBLOCKSIZE); buf = malloc(SPA_MAXBLOCKSIZE); if (buf == NULL) { (void) fprintf(stderr, "out of memory\n"); exit(1); } err = decode_embedded_bp(&bp, buf, BPE_GET_LSIZE(&bp)); if (err != 0) { (void) fprintf(stderr, "decode failed: %u\n", err); exit(1); } zdb_dump_block_raw(buf, BPE_GET_LSIZE(&bp), 0); free(buf); } /* check for valid hex or decimal numeric string */ static boolean_t zdb_numeric(char *str) { int i = 0; if (strlen(str) == 0) return (B_FALSE); if (strncmp(str, "0x", 2) == 0 || strncmp(str, "0X", 2) == 0) i = 2; for (; i < strlen(str); i++) { if (!isxdigit(str[i])) return (B_FALSE); } return (B_TRUE); } int main(int argc, char **argv) { int c; spa_t *spa = NULL; objset_t *os = NULL; int dump_all = 1; int verbose = 0; int error = 0; char **searchdirs = NULL; int nsearch = 0; char *target, *target_pool, dsname[ZFS_MAX_DATASET_NAME_LEN]; nvlist_t *policy = NULL; uint64_t max_txg = UINT64_MAX; int64_t objset_id = -1; uint64_t object; int flags = ZFS_IMPORT_MISSING_LOG; int rewind = ZPOOL_NEVER_REWIND; char *spa_config_path_env, *objset_str; boolean_t target_is_spa = B_TRUE, dataset_lookup = B_FALSE; nvlist_t *cfg = NULL; dprintf_setup(&argc, argv); /* * If there is an environment variable SPA_CONFIG_PATH it overrides * default spa_config_path setting. If -U flag is specified it will * override this environment variable settings once again. */ spa_config_path_env = getenv("SPA_CONFIG_PATH"); if (spa_config_path_env != NULL) spa_config_path = spa_config_path_env; /* * For performance reasons, we set this tunable down. We do so before * the arg parsing section so that the user can override this value if * they choose. */ zfs_btree_verify_intensity = 3; struct option long_options[] = { {"ignore-assertions", no_argument, NULL, 'A'}, {"block-stats", no_argument, NULL, 'b'}, {"checksum", no_argument, NULL, 'c'}, {"config", no_argument, NULL, 'C'}, {"datasets", no_argument, NULL, 'd'}, {"dedup-stats", no_argument, NULL, 'D'}, {"exported", no_argument, NULL, 'e'}, {"embedded-block-pointer", no_argument, NULL, 'E'}, {"automatic-rewind", no_argument, NULL, 'F'}, {"dump-debug-msg", no_argument, NULL, 'G'}, {"history", no_argument, NULL, 'h'}, {"intent-logs", no_argument, NULL, 'i'}, {"inflight", required_argument, NULL, 'I'}, {"checkpointed-state", no_argument, NULL, 'k'}, {"label", no_argument, NULL, 'l'}, {"disable-leak-tracking", no_argument, NULL, 'L'}, {"metaslabs", no_argument, NULL, 'm'}, {"metaslab-groups", no_argument, NULL, 'M'}, {"numeric", no_argument, NULL, 'N'}, {"option", required_argument, NULL, 'o'}, {"object-lookups", no_argument, NULL, 'O'}, {"path", required_argument, NULL, 'p'}, {"parseable", no_argument, NULL, 'P'}, {"skip-label", no_argument, NULL, 'q'}, {"copy-object", no_argument, NULL, 'r'}, {"read-block", no_argument, NULL, 'R'}, {"io-stats", no_argument, NULL, 's'}, {"simulate-dedup", no_argument, NULL, 'S'}, {"txg", required_argument, NULL, 't'}, {"uberblock", no_argument, NULL, 'u'}, {"cachefile", required_argument, NULL, 'U'}, {"verbose", no_argument, NULL, 'v'}, {"verbatim", no_argument, NULL, 'V'}, {"dump-blocks", required_argument, NULL, 'x'}, {"extreme-rewind", no_argument, NULL, 'X'}, {"all-reconstruction", no_argument, NULL, 'Y'}, {"livelist", no_argument, NULL, 'y'}, {"zstd-headers", no_argument, NULL, 'Z'}, {0, 0, 0, 0} }; while ((c = getopt_long(argc, argv, "AbcCdDeEFGhiI:klLmMNo:Op:PqrRsSt:uU:vVx:XYyZ", long_options, NULL)) != -1) { switch (c) { case 'b': case 'c': case 'C': case 'd': case 'D': case 'E': case 'G': case 'h': case 'i': case 'l': case 'm': case 'M': case 'N': case 'O': case 'r': case 'R': case 's': case 'S': case 'u': case 'y': case 'Z': dump_opt[c]++; dump_all = 0; break; case 'A': case 'e': case 'F': case 'k': case 'L': case 'P': case 'q': case 'X': dump_opt[c]++; break; case 'Y': zfs_reconstruct_indirect_combinations_max = INT_MAX; zfs_deadman_enabled = 0; break; /* NB: Sort single match options below. */ case 'I': max_inflight_bytes = strtoull(optarg, NULL, 0); if (max_inflight_bytes == 0) { (void) fprintf(stderr, "maximum number " "of inflight bytes must be greater " "than 0\n"); usage(); } break; case 'o': error = set_global_var(optarg); if (error != 0) usage(); break; case 'p': if (searchdirs == NULL) { searchdirs = umem_alloc(sizeof (char *), UMEM_NOFAIL); } else { char **tmp = umem_alloc((nsearch + 1) * sizeof (char *), UMEM_NOFAIL); memcpy(tmp, searchdirs, nsearch * sizeof (char *)); umem_free(searchdirs, nsearch * sizeof (char *)); searchdirs = tmp; } searchdirs[nsearch++] = optarg; break; case 't': max_txg = strtoull(optarg, NULL, 0); if (max_txg < TXG_INITIAL) { (void) fprintf(stderr, "incorrect txg " "specified: %s\n", optarg); usage(); } break; case 'U': spa_config_path = optarg; if (spa_config_path[0] != '/') { (void) fprintf(stderr, "cachefile must be an absolute path " "(i.e. start with a slash)\n"); usage(); } break; case 'v': verbose++; break; case 'V': flags = ZFS_IMPORT_VERBATIM; break; case 'x': vn_dumpdir = optarg; break; default: usage(); break; } } if (!dump_opt['e'] && searchdirs != NULL) { (void) fprintf(stderr, "-p option requires use of -e\n"); usage(); } #if defined(_LP64) /* * ZDB does not typically re-read blocks; therefore limit the ARC * to 256 MB, which can be used entirely for metadata. */ zfs_arc_min = zfs_arc_meta_min = 2ULL << SPA_MAXBLOCKSHIFT; zfs_arc_max = zfs_arc_meta_limit = 256 * 1024 * 1024; #endif /* * "zdb -c" uses checksum-verifying scrub i/os which are async reads. * "zdb -b" uses traversal prefetch which uses async reads. * For good performance, let several of them be active at once. */ zfs_vdev_async_read_max_active = 10; /* * Disable reference tracking for better performance. */ reference_tracking_enable = B_FALSE; /* * Do not fail spa_load when spa_load_verify fails. This is needed * to load non-idle pools. */ spa_load_verify_dryrun = B_TRUE; /* * ZDB should have ability to read spacemaps. */ spa_mode_readable_spacemaps = B_TRUE; kernel_init(SPA_MODE_READ); if (dump_all) verbose = MAX(verbose, 1); for (c = 0; c < 256; c++) { if (dump_all && strchr("AeEFklLNOPrRSXy", c) == NULL) dump_opt[c] = 1; if (dump_opt[c]) dump_opt[c] += verbose; } libspl_set_assert_ok((dump_opt['A'] == 1) || (dump_opt['A'] > 2)); zfs_recover = (dump_opt['A'] > 1); argc -= optind; argv += optind; if (argc < 2 && dump_opt['R']) usage(); if (dump_opt['E']) { if (argc != 1) usage(); zdb_embedded_block(argv[0]); return (0); } if (argc < 1) { if (!dump_opt['e'] && dump_opt['C']) { dump_cachefile(spa_config_path); return (0); } usage(); } if (dump_opt['l']) return (dump_label(argv[0])); if (dump_opt['O']) { if (argc != 2) usage(); dump_opt['v'] = verbose + 3; return (dump_path(argv[0], argv[1], NULL)); } if (dump_opt['r']) { target_is_spa = B_FALSE; if (argc != 3) usage(); dump_opt['v'] = verbose; error = dump_path(argv[0], argv[1], &object); } if (dump_opt['X'] || dump_opt['F']) rewind = ZPOOL_DO_REWIND | (dump_opt['X'] ? ZPOOL_EXTREME_REWIND : 0); /* -N implies -d */ if (dump_opt['N'] && dump_opt['d'] == 0) dump_opt['d'] = dump_opt['N']; if (nvlist_alloc(&policy, NV_UNIQUE_NAME_TYPE, 0) != 0 || nvlist_add_uint64(policy, ZPOOL_LOAD_REQUEST_TXG, max_txg) != 0 || nvlist_add_uint32(policy, ZPOOL_LOAD_REWIND_POLICY, rewind) != 0) fatal("internal error: %s", strerror(ENOMEM)); error = 0; target = argv[0]; if (strpbrk(target, "/@") != NULL) { size_t targetlen; target_pool = strdup(target); *strpbrk(target_pool, "/@") = '\0'; target_is_spa = B_FALSE; targetlen = strlen(target); if (targetlen && target[targetlen - 1] == '/') target[targetlen - 1] = '\0'; /* * See if an objset ID was supplied (-d /). * To disambiguate tank/100, consider the 100 as objsetID * if -N was given, otherwise 100 is an objsetID iff * tank/100 as a named dataset fails on lookup. */ objset_str = strchr(target, '/'); if (objset_str && strlen(objset_str) > 1 && zdb_numeric(objset_str + 1)) { char *endptr; errno = 0; objset_str++; objset_id = strtoull(objset_str, &endptr, 0); /* dataset 0 is the same as opening the pool */ if (errno == 0 && endptr != objset_str && objset_id != 0) { if (dump_opt['N']) dataset_lookup = B_TRUE; } /* normal dataset name not an objset ID */ if (endptr == objset_str) { objset_id = -1; } } else if (objset_str && !zdb_numeric(objset_str + 1) && dump_opt['N']) { printf("Supply a numeric objset ID with -N\n"); exit(1); } } else { target_pool = target; } if (dump_opt['e']) { importargs_t args = { 0 }; args.paths = nsearch; args.path = searchdirs; args.can_be_active = B_TRUE; error = zpool_find_config(NULL, target_pool, &cfg, &args, &libzpool_config_ops); if (error == 0) { if (nvlist_add_nvlist(cfg, ZPOOL_LOAD_POLICY, policy) != 0) { fatal("can't open '%s': %s", target, strerror(ENOMEM)); } if (dump_opt['C'] > 1) { (void) printf("\nConfiguration for import:\n"); dump_nvlist(cfg, 8); } /* * Disable the activity check to allow examination of * active pools. */ error = spa_import(target_pool, cfg, NULL, flags | ZFS_IMPORT_SKIP_MMP); } } if (searchdirs != NULL) { umem_free(searchdirs, nsearch * sizeof (char *)); searchdirs = NULL; } /* * import_checkpointed_state makes the assumption that the * target pool that we pass it is already part of the spa * namespace. Because of that we need to make sure to call * it always after the -e option has been processed, which * imports the pool to the namespace if it's not in the * cachefile. */ char *checkpoint_pool = NULL; char *checkpoint_target = NULL; if (dump_opt['k']) { checkpoint_pool = import_checkpointed_state(target, cfg, &checkpoint_target); if (checkpoint_target != NULL) target = checkpoint_target; } if (cfg != NULL) { nvlist_free(cfg); cfg = NULL; } if (target_pool != target) free(target_pool); if (error == 0) { if (dump_opt['k'] && (target_is_spa || dump_opt['R'])) { ASSERT(checkpoint_pool != NULL); ASSERT(checkpoint_target == NULL); error = spa_open(checkpoint_pool, &spa, FTAG); if (error != 0) { fatal("Tried to open pool \"%s\" but " "spa_open() failed with error %d\n", checkpoint_pool, error); } } else if (target_is_spa || dump_opt['R'] || objset_id == 0) { zdb_set_skip_mmp(target); error = spa_open_rewind(target, &spa, FTAG, policy, NULL); if (error) { /* * If we're missing the log device then * try opening the pool after clearing the * log state. */ mutex_enter(&spa_namespace_lock); if ((spa = spa_lookup(target)) != NULL && spa->spa_log_state == SPA_LOG_MISSING) { spa->spa_log_state = SPA_LOG_CLEAR; error = 0; } mutex_exit(&spa_namespace_lock); if (!error) { error = spa_open_rewind(target, &spa, FTAG, policy, NULL); } } } else if (strpbrk(target, "#") != NULL) { dsl_pool_t *dp; error = dsl_pool_hold(target, FTAG, &dp); if (error != 0) { fatal("can't dump '%s': %s", target, strerror(error)); } error = dump_bookmark(dp, target, B_TRUE, verbose > 1); dsl_pool_rele(dp, FTAG); if (error != 0) { fatal("can't dump '%s': %s", target, strerror(error)); } return (error); } else { target_pool = strdup(target); if (strpbrk(target, "/@") != NULL) *strpbrk(target_pool, "/@") = '\0'; zdb_set_skip_mmp(target); /* * If -N was supplied, the user has indicated that * zdb -d / is in effect. Otherwise * we first assume that the dataset string is the * dataset name. If dmu_objset_hold fails with the * dataset string, and we have an objset_id, retry the * lookup with the objsetID. */ boolean_t retry = B_TRUE; retry_lookup: if (dataset_lookup == B_TRUE) { /* * Use the supplied id to get the name * for open_objset. */ error = spa_open(target_pool, &spa, FTAG); if (error == 0) { error = name_from_objset_id(spa, objset_id, dsname); spa_close(spa, FTAG); if (error == 0) target = dsname; } } if (error == 0) { if (objset_id > 0 && retry) { int err = dmu_objset_hold(target, FTAG, &os); if (err) { dataset_lookup = B_TRUE; retry = B_FALSE; goto retry_lookup; } else { dmu_objset_rele(os, FTAG); } } error = open_objset(target, FTAG, &os); } if (error == 0) spa = dmu_objset_spa(os); free(target_pool); } } nvlist_free(policy); if (error) fatal("can't open '%s': %s", target, strerror(error)); /* * Set the pool failure mode to panic in order to prevent the pool * from suspending. A suspended I/O will have no way to resume and * can prevent the zdb(8) command from terminating as expected. */ if (spa != NULL) spa->spa_failmode = ZIO_FAILURE_MODE_PANIC; argv++; argc--; if (dump_opt['r']) { error = zdb_copy_object(os, object, argv[1]); } else if (!dump_opt['R']) { flagbits['d'] = ZOR_FLAG_DIRECTORY; flagbits['f'] = ZOR_FLAG_PLAIN_FILE; flagbits['m'] = ZOR_FLAG_SPACE_MAP; flagbits['z'] = ZOR_FLAG_ZAP; flagbits['A'] = ZOR_FLAG_ALL_TYPES; if (argc > 0 && dump_opt['d']) { zopt_object_args = argc; zopt_object_ranges = calloc(zopt_object_args, sizeof (zopt_object_range_t)); for (unsigned i = 0; i < zopt_object_args; i++) { int err; const char *msg = NULL; err = parse_object_range(argv[i], &zopt_object_ranges[i], &msg); if (err != 0) fatal("Bad object or range: '%s': %s\n", argv[i], msg ?: ""); } } else if (argc > 0 && dump_opt['m']) { zopt_metaslab_args = argc; zopt_metaslab = calloc(zopt_metaslab_args, sizeof (uint64_t)); for (unsigned i = 0; i < zopt_metaslab_args; i++) { errno = 0; zopt_metaslab[i] = strtoull(argv[i], NULL, 0); if (zopt_metaslab[i] == 0 && errno != 0) fatal("bad number %s: %s", argv[i], strerror(errno)); } } if (os != NULL) { dump_objset(os); } else if (zopt_object_args > 0 && !dump_opt['m']) { dump_objset(spa->spa_meta_objset); } else { dump_zpool(spa); } } else { flagbits['b'] = ZDB_FLAG_PRINT_BLKPTR; flagbits['c'] = ZDB_FLAG_CHECKSUM; flagbits['d'] = ZDB_FLAG_DECOMPRESS; flagbits['e'] = ZDB_FLAG_BSWAP; flagbits['g'] = ZDB_FLAG_GBH; flagbits['i'] = ZDB_FLAG_INDIRECT; flagbits['r'] = ZDB_FLAG_RAW; flagbits['v'] = ZDB_FLAG_VERBOSE; for (int i = 0; i < argc; i++) zdb_read_block(argv[i], spa); } if (dump_opt['k']) { free(checkpoint_pool); if (!target_is_spa) free(checkpoint_target); } if (os != NULL) { close_objset(os, FTAG); } else { spa_close(spa, FTAG); } fuid_table_destroy(); dump_debug_buffer(); kernel_fini(); return (error); } diff --git a/module/zfs/dsl_scan.c b/module/zfs/dsl_scan.c index 28afc3dead7e..5ad8ff1f34a2 100644 --- a/module/zfs/dsl_scan.c +++ b/module/zfs/dsl_scan.c @@ -1,4494 +1,4494 @@ /* * 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) 2008, 2010, Oracle and/or its affiliates. All rights reserved. * Copyright (c) 2011, 2021 by Delphix. All rights reserved. * Copyright 2016 Gary Mills * Copyright (c) 2017, 2019, Datto Inc. All rights reserved. * Copyright (c) 2015, Nexenta Systems, Inc. All rights reserved. * Copyright 2019 Joyent, Inc. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #ifdef _KERNEL #include #endif /* * Grand theory statement on scan queue sorting * * Scanning is implemented by recursively traversing all indirection levels * in an object and reading all blocks referenced from said objects. This * results in us approximately traversing the object from lowest logical * offset to the highest. For best performance, we would want the logical * blocks to be physically contiguous. However, this is frequently not the * case with pools given the allocation patterns of copy-on-write filesystems. * So instead, we put the I/Os into a reordering queue and issue them in a * way that will most benefit physical disks (LBA-order). * * Queue management: * * Ideally, we would want to scan all metadata and queue up all block I/O * prior to starting to issue it, because that allows us to do an optimal * sorting job. This can however consume large amounts of memory. Therefore * we continuously monitor the size of the queues and constrain them to 5% * (zfs_scan_mem_lim_fact) of physmem. If the queues grow larger than this * limit, we clear out a few of the largest extents at the head of the queues * to make room for more scanning. Hopefully, these extents will be fairly * large and contiguous, allowing us to approach sequential I/O throughput * even without a fully sorted tree. * * Metadata scanning takes place in dsl_scan_visit(), which is called from * dsl_scan_sync() every spa_sync(). If we have either fully scanned all * metadata on the pool, or we need to make room in memory because our * queues are too large, dsl_scan_visit() is postponed and * scan_io_queues_run() is called from dsl_scan_sync() instead. This implies * that metadata scanning and queued I/O issuing are mutually exclusive. This * allows us to provide maximum sequential I/O throughput for the majority of * I/O's issued since sequential I/O performance is significantly negatively * impacted if it is interleaved with random I/O. * * Implementation Notes * * One side effect of the queued scanning algorithm is that the scanning code * needs to be notified whenever a block is freed. This is needed to allow * the scanning code to remove these I/Os from the issuing queue. Additionally, * we do not attempt to queue gang blocks to be issued sequentially since this * is very hard to do and would have an extremely limited performance benefit. * Instead, we simply issue gang I/Os as soon as we find them using the legacy * algorithm. * * Backwards compatibility * * This new algorithm is backwards compatible with the legacy on-disk data * structures (and therefore does not require a new feature flag). * Periodically during scanning (see zfs_scan_checkpoint_intval), the scan * will stop scanning metadata (in logical order) and wait for all outstanding * sorted I/O to complete. Once this is done, we write out a checkpoint * bookmark, indicating that we have scanned everything logically before it. * If the pool is imported on a machine without the new sorting algorithm, * the scan simply resumes from the last checkpoint using the legacy algorithm. */ typedef int (scan_cb_t)(dsl_pool_t *, const blkptr_t *, const zbookmark_phys_t *); static scan_cb_t dsl_scan_scrub_cb; static int scan_ds_queue_compare(const void *a, const void *b); static int scan_prefetch_queue_compare(const void *a, const void *b); static void scan_ds_queue_clear(dsl_scan_t *scn); static void scan_ds_prefetch_queue_clear(dsl_scan_t *scn); static boolean_t scan_ds_queue_contains(dsl_scan_t *scn, uint64_t dsobj, uint64_t *txg); static void scan_ds_queue_insert(dsl_scan_t *scn, uint64_t dsobj, uint64_t txg); static void scan_ds_queue_remove(dsl_scan_t *scn, uint64_t dsobj); static void scan_ds_queue_sync(dsl_scan_t *scn, dmu_tx_t *tx); static uint64_t dsl_scan_count_data_disks(vdev_t *vd); extern int zfs_vdev_async_write_active_min_dirty_percent; static int zfs_scan_blkstats = 0; /* * By default zfs will check to ensure it is not over the hard memory * limit before each txg. If finer-grained control of this is needed * this value can be set to 1 to enable checking before scanning each * block. */ static int zfs_scan_strict_mem_lim = B_FALSE; /* * Maximum number of parallelly executed bytes per leaf vdev. We attempt * to strike a balance here between keeping the vdev queues full of I/Os * at all times and not overflowing the queues to cause long latency, * which would cause long txg sync times. No matter what, we will not * overload the drives with I/O, since that is protected by * zfs_vdev_scrub_max_active. */ static unsigned long zfs_scan_vdev_limit = 4 << 20; static int zfs_scan_issue_strategy = 0; static int zfs_scan_legacy = B_FALSE; /* don't queue & sort zios, go direct */ static unsigned long zfs_scan_max_ext_gap = 2 << 20; /* in bytes */ /* * fill_weight is non-tunable at runtime, so we copy it at module init from * zfs_scan_fill_weight. Runtime adjustments to zfs_scan_fill_weight would * break queue sorting. */ static int zfs_scan_fill_weight = 3; static uint64_t fill_weight; /* See dsl_scan_should_clear() for details on the memory limit tunables */ static const uint64_t zfs_scan_mem_lim_min = 16 << 20; /* bytes */ static const uint64_t zfs_scan_mem_lim_soft_max = 128 << 20; /* bytes */ static int zfs_scan_mem_lim_fact = 20; /* fraction of physmem */ static int zfs_scan_mem_lim_soft_fact = 20; /* fraction of mem lim above */ static int zfs_scrub_min_time_ms = 1000; /* min millis to scrub per txg */ static int zfs_obsolete_min_time_ms = 500; /* min millis to obsolete per txg */ static int zfs_free_min_time_ms = 1000; /* min millis to free per txg */ static int zfs_resilver_min_time_ms = 3000; /* min millis to resilver per txg */ static int zfs_scan_checkpoint_intval = 7200; /* in seconds */ int zfs_scan_suspend_progress = 0; /* set to prevent scans from progressing */ static int zfs_no_scrub_io = B_FALSE; /* set to disable scrub i/o */ static int zfs_no_scrub_prefetch = B_FALSE; /* set to disable scrub prefetch */ static const enum ddt_class zfs_scrub_ddt_class_max = DDT_CLASS_DUPLICATE; /* max number of blocks to free in a single TXG */ static unsigned long zfs_async_block_max_blocks = ULONG_MAX; /* max number of dedup blocks to free in a single TXG */ static unsigned long zfs_max_async_dedup_frees = 100000; /* set to disable resilver deferring */ static int zfs_resilver_disable_defer = B_FALSE; /* * We wait a few txgs after importing a pool to begin scanning so that * the import / mounting code isn't held up by scrub / resilver IO. * Unfortunately, it is a bit difficult to determine exactly how long * this will take since userspace will trigger fs mounts asynchronously * and the kernel will create zvol minors asynchronously. As a result, * the value provided here is a bit arbitrary, but represents a * reasonable estimate of how many txgs it will take to finish fully * importing a pool */ #define SCAN_IMPORT_WAIT_TXGS 5 #define DSL_SCAN_IS_SCRUB_RESILVER(scn) \ ((scn)->scn_phys.scn_func == POOL_SCAN_SCRUB || \ (scn)->scn_phys.scn_func == POOL_SCAN_RESILVER) /* * Enable/disable the processing of the free_bpobj object. */ static int zfs_free_bpobj_enabled = 1; /* the order has to match pool_scan_type */ static scan_cb_t *scan_funcs[POOL_SCAN_FUNCS] = { NULL, dsl_scan_scrub_cb, /* POOL_SCAN_SCRUB */ dsl_scan_scrub_cb, /* POOL_SCAN_RESILVER */ }; /* In core node for the scn->scn_queue. Represents a dataset to be scanned */ typedef struct { uint64_t sds_dsobj; uint64_t sds_txg; avl_node_t sds_node; } scan_ds_t; /* * This controls what conditions are placed on dsl_scan_sync_state(): * SYNC_OPTIONAL) write out scn_phys iff scn_queues_pending == 0 * SYNC_MANDATORY) write out scn_phys always. scn_queues_pending must be 0. * SYNC_CACHED) if scn_queues_pending == 0, write out scn_phys. Otherwise * write out the scn_phys_cached version. * See dsl_scan_sync_state for details. */ typedef enum { SYNC_OPTIONAL, SYNC_MANDATORY, SYNC_CACHED } state_sync_type_t; /* * This struct represents the minimum information needed to reconstruct a * zio for sequential scanning. This is useful because many of these will * accumulate in the sequential IO queues before being issued, so saving * memory matters here. */ typedef struct scan_io { /* fields from blkptr_t */ uint64_t sio_blk_prop; uint64_t sio_phys_birth; uint64_t sio_birth; zio_cksum_t sio_cksum; uint32_t sio_nr_dvas; /* fields from zio_t */ uint32_t sio_flags; zbookmark_phys_t sio_zb; /* members for queue sorting */ union { avl_node_t sio_addr_node; /* link into issuing queue */ list_node_t sio_list_node; /* link for issuing to disk */ } sio_nodes; /* * There may be up to SPA_DVAS_PER_BP DVAs here from the bp, * depending on how many were in the original bp. Only the * first DVA is really used for sorting and issuing purposes. * The other DVAs (if provided) simply exist so that the zio * layer can find additional copies to repair from in the * event of an error. This array must go at the end of the * struct to allow this for the variable number of elements. */ dva_t sio_dva[0]; } scan_io_t; #define SIO_SET_OFFSET(sio, x) DVA_SET_OFFSET(&(sio)->sio_dva[0], x) #define SIO_SET_ASIZE(sio, x) DVA_SET_ASIZE(&(sio)->sio_dva[0], x) #define SIO_GET_OFFSET(sio) DVA_GET_OFFSET(&(sio)->sio_dva[0]) #define SIO_GET_ASIZE(sio) DVA_GET_ASIZE(&(sio)->sio_dva[0]) #define SIO_GET_END_OFFSET(sio) \ (SIO_GET_OFFSET(sio) + SIO_GET_ASIZE(sio)) #define SIO_GET_MUSED(sio) \ (sizeof (scan_io_t) + ((sio)->sio_nr_dvas * sizeof (dva_t))) struct dsl_scan_io_queue { dsl_scan_t *q_scn; /* associated dsl_scan_t */ vdev_t *q_vd; /* top-level vdev that this queue represents */ zio_t *q_zio; /* scn_zio_root child for waiting on IO */ /* trees used for sorting I/Os and extents of I/Os */ range_tree_t *q_exts_by_addr; zfs_btree_t q_exts_by_size; avl_tree_t q_sios_by_addr; uint64_t q_sio_memused; uint64_t q_last_ext_addr; /* members for zio rate limiting */ uint64_t q_maxinflight_bytes; uint64_t q_inflight_bytes; kcondvar_t q_zio_cv; /* used under vd->vdev_scan_io_queue_lock */ /* per txg statistics */ uint64_t q_total_seg_size_this_txg; uint64_t q_segs_this_txg; uint64_t q_total_zio_size_this_txg; uint64_t q_zios_this_txg; }; /* private data for dsl_scan_prefetch_cb() */ typedef struct scan_prefetch_ctx { zfs_refcount_t spc_refcnt; /* refcount for memory management */ dsl_scan_t *spc_scn; /* dsl_scan_t for the pool */ boolean_t spc_root; /* is this prefetch for an objset? */ uint8_t spc_indblkshift; /* dn_indblkshift of current dnode */ uint16_t spc_datablkszsec; /* dn_idatablkszsec of current dnode */ } scan_prefetch_ctx_t; /* private data for dsl_scan_prefetch() */ typedef struct scan_prefetch_issue_ctx { avl_node_t spic_avl_node; /* link into scn->scn_prefetch_queue */ scan_prefetch_ctx_t *spic_spc; /* spc for the callback */ blkptr_t spic_bp; /* bp to prefetch */ zbookmark_phys_t spic_zb; /* bookmark to prefetch */ } scan_prefetch_issue_ctx_t; static void scan_exec_io(dsl_pool_t *dp, const blkptr_t *bp, int zio_flags, const zbookmark_phys_t *zb, dsl_scan_io_queue_t *queue); static void scan_io_queue_insert_impl(dsl_scan_io_queue_t *queue, scan_io_t *sio); static dsl_scan_io_queue_t *scan_io_queue_create(vdev_t *vd); static void scan_io_queues_destroy(dsl_scan_t *scn); static kmem_cache_t *sio_cache[SPA_DVAS_PER_BP]; /* sio->sio_nr_dvas must be set so we know which cache to free from */ static void sio_free(scan_io_t *sio) { ASSERT3U(sio->sio_nr_dvas, >, 0); ASSERT3U(sio->sio_nr_dvas, <=, SPA_DVAS_PER_BP); kmem_cache_free(sio_cache[sio->sio_nr_dvas - 1], sio); } /* It is up to the caller to set sio->sio_nr_dvas for freeing */ static scan_io_t * sio_alloc(unsigned short nr_dvas) { ASSERT3U(nr_dvas, >, 0); ASSERT3U(nr_dvas, <=, SPA_DVAS_PER_BP); return (kmem_cache_alloc(sio_cache[nr_dvas - 1], KM_SLEEP)); } void scan_init(void) { /* * This is used in ext_size_compare() to weight segments * based on how sparse they are. This cannot be changed * mid-scan and the tree comparison functions don't currently * have a mechanism for passing additional context to the * compare functions. Thus we store this value globally and * we only allow it to be set at module initialization time */ fill_weight = zfs_scan_fill_weight; for (int i = 0; i < SPA_DVAS_PER_BP; i++) { char name[36]; (void) snprintf(name, sizeof (name), "sio_cache_%d", i); sio_cache[i] = kmem_cache_create(name, (sizeof (scan_io_t) + ((i + 1) * sizeof (dva_t))), 0, NULL, NULL, NULL, NULL, NULL, 0); } } void scan_fini(void) { for (int i = 0; i < SPA_DVAS_PER_BP; i++) { kmem_cache_destroy(sio_cache[i]); } } static inline boolean_t dsl_scan_is_running(const dsl_scan_t *scn) { return (scn->scn_phys.scn_state == DSS_SCANNING); } boolean_t dsl_scan_resilvering(dsl_pool_t *dp) { return (dsl_scan_is_running(dp->dp_scan) && dp->dp_scan->scn_phys.scn_func == POOL_SCAN_RESILVER); } static inline void sio2bp(const scan_io_t *sio, blkptr_t *bp) { memset(bp, 0, sizeof (*bp)); bp->blk_prop = sio->sio_blk_prop; bp->blk_phys_birth = sio->sio_phys_birth; bp->blk_birth = sio->sio_birth; bp->blk_fill = 1; /* we always only work with data pointers */ bp->blk_cksum = sio->sio_cksum; ASSERT3U(sio->sio_nr_dvas, >, 0); ASSERT3U(sio->sio_nr_dvas, <=, SPA_DVAS_PER_BP); memcpy(bp->blk_dva, sio->sio_dva, sio->sio_nr_dvas * sizeof (dva_t)); } static inline void bp2sio(const blkptr_t *bp, scan_io_t *sio, int dva_i) { sio->sio_blk_prop = bp->blk_prop; sio->sio_phys_birth = bp->blk_phys_birth; sio->sio_birth = bp->blk_birth; sio->sio_cksum = bp->blk_cksum; sio->sio_nr_dvas = BP_GET_NDVAS(bp); /* * Copy the DVAs to the sio. We need all copies of the block so * that the self healing code can use the alternate copies if the * first is corrupted. We want the DVA at index dva_i to be first * in the sio since this is the primary one that we want to issue. */ for (int i = 0, j = dva_i; i < sio->sio_nr_dvas; i++, j++) { sio->sio_dva[i] = bp->blk_dva[j % sio->sio_nr_dvas]; } } int dsl_scan_init(dsl_pool_t *dp, uint64_t txg) { int err; dsl_scan_t *scn; spa_t *spa = dp->dp_spa; uint64_t f; scn = dp->dp_scan = kmem_zalloc(sizeof (dsl_scan_t), KM_SLEEP); scn->scn_dp = dp; /* * It's possible that we're resuming a scan after a reboot so * make sure that the scan_async_destroying flag is initialized * appropriately. */ ASSERT(!scn->scn_async_destroying); scn->scn_async_destroying = spa_feature_is_active(dp->dp_spa, SPA_FEATURE_ASYNC_DESTROY); /* * Calculate the max number of in-flight bytes for pool-wide * scanning operations (minimum 1MB). Limits for the issuing * phase are done per top-level vdev and are handled separately. */ scn->scn_maxinflight_bytes = MAX(zfs_scan_vdev_limit * dsl_scan_count_data_disks(spa->spa_root_vdev), 1ULL << 20); avl_create(&scn->scn_queue, scan_ds_queue_compare, sizeof (scan_ds_t), offsetof(scan_ds_t, sds_node)); avl_create(&scn->scn_prefetch_queue, scan_prefetch_queue_compare, sizeof (scan_prefetch_issue_ctx_t), offsetof(scan_prefetch_issue_ctx_t, spic_avl_node)); err = zap_lookup(dp->dp_meta_objset, DMU_POOL_DIRECTORY_OBJECT, "scrub_func", sizeof (uint64_t), 1, &f); if (err == 0) { /* * There was an old-style scrub in progress. Restart a * new-style scrub from the beginning. */ scn->scn_restart_txg = txg; zfs_dbgmsg("old-style scrub was in progress for %s; " "restarting new-style scrub in txg %llu", spa->spa_name, (longlong_t)scn->scn_restart_txg); /* * Load the queue obj from the old location so that it * can be freed by dsl_scan_done(). */ (void) zap_lookup(dp->dp_meta_objset, DMU_POOL_DIRECTORY_OBJECT, "scrub_queue", sizeof (uint64_t), 1, &scn->scn_phys.scn_queue_obj); } else { err = zap_lookup(dp->dp_meta_objset, DMU_POOL_DIRECTORY_OBJECT, DMU_POOL_SCAN, sizeof (uint64_t), SCAN_PHYS_NUMINTS, &scn->scn_phys); /* * Detect if the pool contains the signature of #2094. If it * does properly update the scn->scn_phys structure and notify * the administrator by setting an errata for the pool. */ if (err == EOVERFLOW) { uint64_t zaptmp[SCAN_PHYS_NUMINTS + 1]; VERIFY3S(SCAN_PHYS_NUMINTS, ==, 24); VERIFY3S(offsetof(dsl_scan_phys_t, scn_flags), ==, (23 * sizeof (uint64_t))); err = zap_lookup(dp->dp_meta_objset, DMU_POOL_DIRECTORY_OBJECT, DMU_POOL_SCAN, sizeof (uint64_t), SCAN_PHYS_NUMINTS + 1, &zaptmp); if (err == 0) { uint64_t overflow = zaptmp[SCAN_PHYS_NUMINTS]; if (overflow & ~DSL_SCAN_FLAGS_MASK || scn->scn_async_destroying) { spa->spa_errata = ZPOOL_ERRATA_ZOL_2094_ASYNC_DESTROY; return (EOVERFLOW); } memcpy(&scn->scn_phys, zaptmp, SCAN_PHYS_NUMINTS * sizeof (uint64_t)); scn->scn_phys.scn_flags = overflow; /* Required scrub already in progress. */ if (scn->scn_phys.scn_state == DSS_FINISHED || scn->scn_phys.scn_state == DSS_CANCELED) spa->spa_errata = ZPOOL_ERRATA_ZOL_2094_SCRUB; } } if (err == ENOENT) return (0); else if (err) return (err); /* * We might be restarting after a reboot, so jump the issued * counter to how far we've scanned. We know we're consistent * up to here. */ scn->scn_issued_before_pass = scn->scn_phys.scn_examined; if (dsl_scan_is_running(scn) && spa_prev_software_version(dp->dp_spa) < SPA_VERSION_SCAN) { /* * A new-type scrub was in progress on an old * pool, and the pool was accessed by old * software. Restart from the beginning, since * the old software may have changed the pool in * the meantime. */ scn->scn_restart_txg = txg; zfs_dbgmsg("new-style scrub for %s was modified " "by old software; restarting in txg %llu", spa->spa_name, (longlong_t)scn->scn_restart_txg); } else if (dsl_scan_resilvering(dp)) { /* * If a resilver is in progress and there are already * errors, restart it instead of finishing this scan and * then restarting it. If there haven't been any errors * then remember that the incore DTL is valid. */ if (scn->scn_phys.scn_errors > 0) { scn->scn_restart_txg = txg; zfs_dbgmsg("resilver can't excise DTL_MISSING " "when finished; restarting on %s in txg " "%llu", spa->spa_name, (u_longlong_t)scn->scn_restart_txg); } else { /* it's safe to excise DTL when finished */ spa->spa_scrub_started = B_TRUE; } } } memcpy(&scn->scn_phys_cached, &scn->scn_phys, sizeof (scn->scn_phys)); /* reload the queue into the in-core state */ if (scn->scn_phys.scn_queue_obj != 0) { zap_cursor_t zc; zap_attribute_t za; for (zap_cursor_init(&zc, dp->dp_meta_objset, scn->scn_phys.scn_queue_obj); zap_cursor_retrieve(&zc, &za) == 0; (void) zap_cursor_advance(&zc)) { scan_ds_queue_insert(scn, zfs_strtonum(za.za_name, NULL), za.za_first_integer); } zap_cursor_fini(&zc); } spa_scan_stat_init(spa); return (0); } void dsl_scan_fini(dsl_pool_t *dp) { if (dp->dp_scan != NULL) { dsl_scan_t *scn = dp->dp_scan; if (scn->scn_taskq != NULL) taskq_destroy(scn->scn_taskq); scan_ds_queue_clear(scn); avl_destroy(&scn->scn_queue); scan_ds_prefetch_queue_clear(scn); avl_destroy(&scn->scn_prefetch_queue); kmem_free(dp->dp_scan, sizeof (dsl_scan_t)); dp->dp_scan = NULL; } } static boolean_t dsl_scan_restarting(dsl_scan_t *scn, dmu_tx_t *tx) { return (scn->scn_restart_txg != 0 && scn->scn_restart_txg <= tx->tx_txg); } boolean_t dsl_scan_resilver_scheduled(dsl_pool_t *dp) { return ((dp->dp_scan && dp->dp_scan->scn_restart_txg != 0) || (spa_async_tasks(dp->dp_spa) & SPA_ASYNC_RESILVER)); } boolean_t dsl_scan_scrubbing(const dsl_pool_t *dp) { dsl_scan_phys_t *scn_phys = &dp->dp_scan->scn_phys; return (scn_phys->scn_state == DSS_SCANNING && scn_phys->scn_func == POOL_SCAN_SCRUB); } boolean_t dsl_scan_is_paused_scrub(const dsl_scan_t *scn) { return (dsl_scan_scrubbing(scn->scn_dp) && scn->scn_phys.scn_flags & DSF_SCRUB_PAUSED); } /* * Writes out a persistent dsl_scan_phys_t record to the pool directory. * Because we can be running in the block sorting algorithm, we do not always * want to write out the record, only when it is "safe" to do so. This safety * condition is achieved by making sure that the sorting queues are empty * (scn_queues_pending == 0). When this condition is not true, the sync'd state * is inconsistent with how much actual scanning progress has been made. The * kind of sync to be performed is specified by the sync_type argument. If the * sync is optional, we only sync if the queues are empty. If the sync is * mandatory, we do a hard ASSERT to make sure that the queues are empty. The * third possible state is a "cached" sync. This is done in response to: * 1) The dataset that was in the last sync'd dsl_scan_phys_t having been * destroyed, so we wouldn't be able to restart scanning from it. * 2) The snapshot that was in the last sync'd dsl_scan_phys_t having been * superseded by a newer snapshot. * 3) The dataset that was in the last sync'd dsl_scan_phys_t having been * swapped with its clone. * In all cases, a cached sync simply rewrites the last record we've written, * just slightly modified. For the modifications that are performed to the * last written dsl_scan_phys_t, see dsl_scan_ds_destroyed, * dsl_scan_ds_snapshotted and dsl_scan_ds_clone_swapped. */ static void dsl_scan_sync_state(dsl_scan_t *scn, dmu_tx_t *tx, state_sync_type_t sync_type) { int i; spa_t *spa = scn->scn_dp->dp_spa; ASSERT(sync_type != SYNC_MANDATORY || scn->scn_queues_pending == 0); if (scn->scn_queues_pending == 0) { for (i = 0; i < spa->spa_root_vdev->vdev_children; i++) { vdev_t *vd = spa->spa_root_vdev->vdev_child[i]; dsl_scan_io_queue_t *q = vd->vdev_scan_io_queue; if (q == NULL) continue; mutex_enter(&vd->vdev_scan_io_queue_lock); ASSERT3P(avl_first(&q->q_sios_by_addr), ==, NULL); ASSERT3P(zfs_btree_first(&q->q_exts_by_size, NULL), ==, NULL); ASSERT3P(range_tree_first(q->q_exts_by_addr), ==, NULL); mutex_exit(&vd->vdev_scan_io_queue_lock); } if (scn->scn_phys.scn_queue_obj != 0) scan_ds_queue_sync(scn, tx); VERIFY0(zap_update(scn->scn_dp->dp_meta_objset, DMU_POOL_DIRECTORY_OBJECT, DMU_POOL_SCAN, sizeof (uint64_t), SCAN_PHYS_NUMINTS, &scn->scn_phys, tx)); memcpy(&scn->scn_phys_cached, &scn->scn_phys, sizeof (scn->scn_phys)); if (scn->scn_checkpointing) zfs_dbgmsg("finish scan checkpoint for %s", spa->spa_name); scn->scn_checkpointing = B_FALSE; scn->scn_last_checkpoint = ddi_get_lbolt(); } else if (sync_type == SYNC_CACHED) { VERIFY0(zap_update(scn->scn_dp->dp_meta_objset, DMU_POOL_DIRECTORY_OBJECT, DMU_POOL_SCAN, sizeof (uint64_t), SCAN_PHYS_NUMINTS, &scn->scn_phys_cached, tx)); } } int dsl_scan_setup_check(void *arg, dmu_tx_t *tx) { (void) arg; dsl_scan_t *scn = dmu_tx_pool(tx)->dp_scan; vdev_t *rvd = scn->scn_dp->dp_spa->spa_root_vdev; if (dsl_scan_is_running(scn) || vdev_rebuild_active(rvd)) return (SET_ERROR(EBUSY)); return (0); } void dsl_scan_setup_sync(void *arg, dmu_tx_t *tx) { dsl_scan_t *scn = dmu_tx_pool(tx)->dp_scan; pool_scan_func_t *funcp = arg; dmu_object_type_t ot = 0; dsl_pool_t *dp = scn->scn_dp; spa_t *spa = dp->dp_spa; ASSERT(!dsl_scan_is_running(scn)); ASSERT(*funcp > POOL_SCAN_NONE && *funcp < POOL_SCAN_FUNCS); memset(&scn->scn_phys, 0, sizeof (scn->scn_phys)); scn->scn_phys.scn_func = *funcp; scn->scn_phys.scn_state = DSS_SCANNING; scn->scn_phys.scn_min_txg = 0; scn->scn_phys.scn_max_txg = tx->tx_txg; scn->scn_phys.scn_ddt_class_max = DDT_CLASSES - 1; /* the entire DDT */ scn->scn_phys.scn_start_time = gethrestime_sec(); scn->scn_phys.scn_errors = 0; scn->scn_phys.scn_to_examine = spa->spa_root_vdev->vdev_stat.vs_alloc; scn->scn_issued_before_pass = 0; scn->scn_restart_txg = 0; scn->scn_done_txg = 0; scn->scn_last_checkpoint = 0; scn->scn_checkpointing = B_FALSE; spa_scan_stat_init(spa); if (DSL_SCAN_IS_SCRUB_RESILVER(scn)) { scn->scn_phys.scn_ddt_class_max = zfs_scrub_ddt_class_max; /* rewrite all disk labels */ vdev_config_dirty(spa->spa_root_vdev); if (vdev_resilver_needed(spa->spa_root_vdev, &scn->scn_phys.scn_min_txg, &scn->scn_phys.scn_max_txg)) { nvlist_t *aux = fnvlist_alloc(); fnvlist_add_string(aux, ZFS_EV_RESILVER_TYPE, "healing"); spa_event_notify(spa, NULL, aux, ESC_ZFS_RESILVER_START); nvlist_free(aux); } else { spa_event_notify(spa, NULL, NULL, ESC_ZFS_SCRUB_START); } spa->spa_scrub_started = B_TRUE; /* * If this is an incremental scrub, limit the DDT scrub phase * to just the auto-ditto class (for correctness); the rest * of the scrub should go faster using top-down pruning. */ if (scn->scn_phys.scn_min_txg > TXG_INITIAL) scn->scn_phys.scn_ddt_class_max = DDT_CLASS_DITTO; /* * When starting a resilver clear any existing rebuild state. * This is required to prevent stale rebuild status from * being reported when a rebuild is run, then a resilver and * finally a scrub. In which case only the scrub status * should be reported by 'zpool status'. */ if (scn->scn_phys.scn_func == POOL_SCAN_RESILVER) { vdev_t *rvd = spa->spa_root_vdev; for (uint64_t i = 0; i < rvd->vdev_children; i++) { vdev_t *vd = rvd->vdev_child[i]; vdev_rebuild_clear_sync( (void *)(uintptr_t)vd->vdev_id, tx); } } } /* back to the generic stuff */ if (zfs_scan_blkstats) { if (dp->dp_blkstats == NULL) { dp->dp_blkstats = vmem_alloc(sizeof (zfs_all_blkstats_t), KM_SLEEP); } memset(&dp->dp_blkstats->zab_type, 0, sizeof (dp->dp_blkstats->zab_type)); } else { if (dp->dp_blkstats) { vmem_free(dp->dp_blkstats, sizeof (zfs_all_blkstats_t)); dp->dp_blkstats = NULL; } } if (spa_version(spa) < SPA_VERSION_DSL_SCRUB) ot = DMU_OT_ZAP_OTHER; scn->scn_phys.scn_queue_obj = zap_create(dp->dp_meta_objset, ot ? ot : DMU_OT_SCAN_QUEUE, DMU_OT_NONE, 0, tx); memcpy(&scn->scn_phys_cached, &scn->scn_phys, sizeof (scn->scn_phys)); dsl_scan_sync_state(scn, tx, SYNC_MANDATORY); spa_history_log_internal(spa, "scan setup", tx, "func=%u mintxg=%llu maxtxg=%llu", *funcp, (u_longlong_t)scn->scn_phys.scn_min_txg, (u_longlong_t)scn->scn_phys.scn_max_txg); } /* * Called by the ZFS_IOC_POOL_SCAN ioctl to start a scrub or resilver. * Can also be called to resume a paused scrub. */ int dsl_scan(dsl_pool_t *dp, pool_scan_func_t func) { spa_t *spa = dp->dp_spa; dsl_scan_t *scn = dp->dp_scan; /* * Purge all vdev caches and probe all devices. We do this here * rather than in sync context because this requires a writer lock * on the spa_config lock, which we can't do from sync context. The * spa_scrub_reopen flag indicates that vdev_open() should not * attempt to start another scrub. */ spa_vdev_state_enter(spa, SCL_NONE); spa->spa_scrub_reopen = B_TRUE; vdev_reopen(spa->spa_root_vdev); spa->spa_scrub_reopen = B_FALSE; (void) spa_vdev_state_exit(spa, NULL, 0); if (func == POOL_SCAN_RESILVER) { dsl_scan_restart_resilver(spa->spa_dsl_pool, 0); return (0); } if (func == POOL_SCAN_SCRUB && dsl_scan_is_paused_scrub(scn)) { /* got scrub start cmd, resume paused scrub */ int err = dsl_scrub_set_pause_resume(scn->scn_dp, POOL_SCRUB_NORMAL); if (err == 0) { spa_event_notify(spa, NULL, NULL, ESC_ZFS_SCRUB_RESUME); return (SET_ERROR(ECANCELED)); } return (SET_ERROR(err)); } return (dsl_sync_task(spa_name(spa), dsl_scan_setup_check, dsl_scan_setup_sync, &func, 0, ZFS_SPACE_CHECK_EXTRA_RESERVED)); } static void dsl_scan_done(dsl_scan_t *scn, boolean_t complete, dmu_tx_t *tx) { static const char *old_names[] = { "scrub_bookmark", "scrub_ddt_bookmark", "scrub_ddt_class_max", "scrub_queue", "scrub_min_txg", "scrub_max_txg", "scrub_func", "scrub_errors", NULL }; dsl_pool_t *dp = scn->scn_dp; spa_t *spa = dp->dp_spa; int i; /* Remove any remnants of an old-style scrub. */ for (i = 0; old_names[i]; i++) { (void) zap_remove(dp->dp_meta_objset, DMU_POOL_DIRECTORY_OBJECT, old_names[i], tx); } if (scn->scn_phys.scn_queue_obj != 0) { VERIFY0(dmu_object_free(dp->dp_meta_objset, scn->scn_phys.scn_queue_obj, tx)); scn->scn_phys.scn_queue_obj = 0; } scan_ds_queue_clear(scn); scan_ds_prefetch_queue_clear(scn); scn->scn_phys.scn_flags &= ~DSF_SCRUB_PAUSED; /* * If we were "restarted" from a stopped state, don't bother * with anything else. */ if (!dsl_scan_is_running(scn)) { ASSERT(!scn->scn_is_sorted); return; } if (scn->scn_is_sorted) { scan_io_queues_destroy(scn); scn->scn_is_sorted = B_FALSE; if (scn->scn_taskq != NULL) { taskq_destroy(scn->scn_taskq); scn->scn_taskq = NULL; } } scn->scn_phys.scn_state = complete ? DSS_FINISHED : DSS_CANCELED; spa_notify_waiters(spa); if (dsl_scan_restarting(scn, tx)) spa_history_log_internal(spa, "scan aborted, restarting", tx, "errors=%llu", (u_longlong_t)spa_get_errlog_size(spa)); else if (!complete) spa_history_log_internal(spa, "scan cancelled", tx, "errors=%llu", (u_longlong_t)spa_get_errlog_size(spa)); else spa_history_log_internal(spa, "scan done", tx, "errors=%llu", (u_longlong_t)spa_get_errlog_size(spa)); if (DSL_SCAN_IS_SCRUB_RESILVER(scn)) { spa->spa_scrub_active = B_FALSE; /* * If the scrub/resilver completed, update all DTLs to * reflect this. Whether it succeeded or not, vacate * all temporary scrub DTLs. * * As the scrub does not currently support traversing * data that have been freed but are part of a checkpoint, * we don't mark the scrub as done in the DTLs as faults * may still exist in those vdevs. */ if (complete && !spa_feature_is_active(spa, SPA_FEATURE_POOL_CHECKPOINT)) { vdev_dtl_reassess(spa->spa_root_vdev, tx->tx_txg, scn->scn_phys.scn_max_txg, B_TRUE, B_FALSE); if (scn->scn_phys.scn_min_txg) { nvlist_t *aux = fnvlist_alloc(); fnvlist_add_string(aux, ZFS_EV_RESILVER_TYPE, "healing"); spa_event_notify(spa, NULL, aux, ESC_ZFS_RESILVER_FINISH); nvlist_free(aux); } else { spa_event_notify(spa, NULL, NULL, ESC_ZFS_SCRUB_FINISH); } } else { vdev_dtl_reassess(spa->spa_root_vdev, tx->tx_txg, 0, B_TRUE, B_FALSE); } spa_errlog_rotate(spa); /* * Don't clear flag until after vdev_dtl_reassess to ensure that * DTL_MISSING will get updated when possible. */ spa->spa_scrub_started = B_FALSE; /* * We may have finished replacing a device. * Let the async thread assess this and handle the detach. */ spa_async_request(spa, SPA_ASYNC_RESILVER_DONE); /* * Clear any resilver_deferred flags in the config. * If there are drives that need resilvering, kick * off an asynchronous request to start resilver. * vdev_clear_resilver_deferred() may update the config * before the resilver can restart. In the event of * a crash during this period, the spa loading code * will find the drives that need to be resilvered * and start the resilver then. */ if (spa_feature_is_enabled(spa, SPA_FEATURE_RESILVER_DEFER) && vdev_clear_resilver_deferred(spa->spa_root_vdev, tx)) { spa_history_log_internal(spa, "starting deferred resilver", tx, "errors=%llu", (u_longlong_t)spa_get_errlog_size(spa)); spa_async_request(spa, SPA_ASYNC_RESILVER); } /* Clear recent error events (i.e. duplicate events tracking) */ if (complete) zfs_ereport_clear(spa, NULL); } scn->scn_phys.scn_end_time = gethrestime_sec(); if (spa->spa_errata == ZPOOL_ERRATA_ZOL_2094_SCRUB) spa->spa_errata = 0; ASSERT(!dsl_scan_is_running(scn)); } static int dsl_scan_cancel_check(void *arg, dmu_tx_t *tx) { (void) arg; dsl_scan_t *scn = dmu_tx_pool(tx)->dp_scan; if (!dsl_scan_is_running(scn)) return (SET_ERROR(ENOENT)); return (0); } static void dsl_scan_cancel_sync(void *arg, dmu_tx_t *tx) { (void) arg; dsl_scan_t *scn = dmu_tx_pool(tx)->dp_scan; dsl_scan_done(scn, B_FALSE, tx); dsl_scan_sync_state(scn, tx, SYNC_MANDATORY); spa_event_notify(scn->scn_dp->dp_spa, NULL, NULL, ESC_ZFS_SCRUB_ABORT); } int dsl_scan_cancel(dsl_pool_t *dp) { return (dsl_sync_task(spa_name(dp->dp_spa), dsl_scan_cancel_check, dsl_scan_cancel_sync, NULL, 3, ZFS_SPACE_CHECK_RESERVED)); } static int dsl_scrub_pause_resume_check(void *arg, dmu_tx_t *tx) { pool_scrub_cmd_t *cmd = arg; dsl_pool_t *dp = dmu_tx_pool(tx); dsl_scan_t *scn = dp->dp_scan; if (*cmd == POOL_SCRUB_PAUSE) { /* can't pause a scrub when there is no in-progress scrub */ if (!dsl_scan_scrubbing(dp)) return (SET_ERROR(ENOENT)); /* can't pause a paused scrub */ if (dsl_scan_is_paused_scrub(scn)) return (SET_ERROR(EBUSY)); } else if (*cmd != POOL_SCRUB_NORMAL) { return (SET_ERROR(ENOTSUP)); } return (0); } static void dsl_scrub_pause_resume_sync(void *arg, dmu_tx_t *tx) { pool_scrub_cmd_t *cmd = arg; dsl_pool_t *dp = dmu_tx_pool(tx); spa_t *spa = dp->dp_spa; dsl_scan_t *scn = dp->dp_scan; if (*cmd == POOL_SCRUB_PAUSE) { /* can't pause a scrub when there is no in-progress scrub */ spa->spa_scan_pass_scrub_pause = gethrestime_sec(); scn->scn_phys.scn_flags |= DSF_SCRUB_PAUSED; scn->scn_phys_cached.scn_flags |= DSF_SCRUB_PAUSED; dsl_scan_sync_state(scn, tx, SYNC_CACHED); spa_event_notify(spa, NULL, NULL, ESC_ZFS_SCRUB_PAUSED); spa_notify_waiters(spa); } else { ASSERT3U(*cmd, ==, POOL_SCRUB_NORMAL); if (dsl_scan_is_paused_scrub(scn)) { /* * We need to keep track of how much time we spend * paused per pass so that we can adjust the scrub rate * shown in the output of 'zpool status' */ spa->spa_scan_pass_scrub_spent_paused += gethrestime_sec() - spa->spa_scan_pass_scrub_pause; spa->spa_scan_pass_scrub_pause = 0; scn->scn_phys.scn_flags &= ~DSF_SCRUB_PAUSED; scn->scn_phys_cached.scn_flags &= ~DSF_SCRUB_PAUSED; dsl_scan_sync_state(scn, tx, SYNC_CACHED); } } } /* * Set scrub pause/resume state if it makes sense to do so */ int dsl_scrub_set_pause_resume(const dsl_pool_t *dp, pool_scrub_cmd_t cmd) { return (dsl_sync_task(spa_name(dp->dp_spa), dsl_scrub_pause_resume_check, dsl_scrub_pause_resume_sync, &cmd, 3, ZFS_SPACE_CHECK_RESERVED)); } /* start a new scan, or restart an existing one. */ void dsl_scan_restart_resilver(dsl_pool_t *dp, uint64_t txg) { if (txg == 0) { dmu_tx_t *tx; tx = dmu_tx_create_dd(dp->dp_mos_dir); VERIFY(0 == dmu_tx_assign(tx, TXG_WAIT)); txg = dmu_tx_get_txg(tx); dp->dp_scan->scn_restart_txg = txg; dmu_tx_commit(tx); } else { dp->dp_scan->scn_restart_txg = txg; } zfs_dbgmsg("restarting resilver for %s at txg=%llu", dp->dp_spa->spa_name, (longlong_t)txg); } void dsl_free(dsl_pool_t *dp, uint64_t txg, const blkptr_t *bp) { zio_free(dp->dp_spa, txg, bp); } void dsl_free_sync(zio_t *pio, dsl_pool_t *dp, uint64_t txg, const blkptr_t *bpp) { ASSERT(dsl_pool_sync_context(dp)); zio_nowait(zio_free_sync(pio, dp->dp_spa, txg, bpp, pio->io_flags)); } static int scan_ds_queue_compare(const void *a, const void *b) { const scan_ds_t *sds_a = a, *sds_b = b; if (sds_a->sds_dsobj < sds_b->sds_dsobj) return (-1); if (sds_a->sds_dsobj == sds_b->sds_dsobj) return (0); return (1); } static void scan_ds_queue_clear(dsl_scan_t *scn) { void *cookie = NULL; scan_ds_t *sds; while ((sds = avl_destroy_nodes(&scn->scn_queue, &cookie)) != NULL) { kmem_free(sds, sizeof (*sds)); } } static boolean_t scan_ds_queue_contains(dsl_scan_t *scn, uint64_t dsobj, uint64_t *txg) { scan_ds_t srch, *sds; srch.sds_dsobj = dsobj; sds = avl_find(&scn->scn_queue, &srch, NULL); if (sds != NULL && txg != NULL) *txg = sds->sds_txg; return (sds != NULL); } static void scan_ds_queue_insert(dsl_scan_t *scn, uint64_t dsobj, uint64_t txg) { scan_ds_t *sds; avl_index_t where; sds = kmem_zalloc(sizeof (*sds), KM_SLEEP); sds->sds_dsobj = dsobj; sds->sds_txg = txg; VERIFY3P(avl_find(&scn->scn_queue, sds, &where), ==, NULL); avl_insert(&scn->scn_queue, sds, where); } static void scan_ds_queue_remove(dsl_scan_t *scn, uint64_t dsobj) { scan_ds_t srch, *sds; srch.sds_dsobj = dsobj; sds = avl_find(&scn->scn_queue, &srch, NULL); VERIFY(sds != NULL); avl_remove(&scn->scn_queue, sds); kmem_free(sds, sizeof (*sds)); } static void scan_ds_queue_sync(dsl_scan_t *scn, dmu_tx_t *tx) { dsl_pool_t *dp = scn->scn_dp; spa_t *spa = dp->dp_spa; dmu_object_type_t ot = (spa_version(spa) >= SPA_VERSION_DSL_SCRUB) ? DMU_OT_SCAN_QUEUE : DMU_OT_ZAP_OTHER; ASSERT0(scn->scn_queues_pending); ASSERT(scn->scn_phys.scn_queue_obj != 0); VERIFY0(dmu_object_free(dp->dp_meta_objset, scn->scn_phys.scn_queue_obj, tx)); scn->scn_phys.scn_queue_obj = zap_create(dp->dp_meta_objset, ot, DMU_OT_NONE, 0, tx); for (scan_ds_t *sds = avl_first(&scn->scn_queue); sds != NULL; sds = AVL_NEXT(&scn->scn_queue, sds)) { VERIFY0(zap_add_int_key(dp->dp_meta_objset, scn->scn_phys.scn_queue_obj, sds->sds_dsobj, sds->sds_txg, tx)); } } /* * Computes the memory limit state that we're currently in. A sorted scan * needs quite a bit of memory to hold the sorting queue, so we need to * reasonably constrain the size so it doesn't impact overall system * performance. We compute two limits: * 1) Hard memory limit: if the amount of memory used by the sorting * queues on a pool gets above this value, we stop the metadata * scanning portion and start issuing the queued up and sorted * I/Os to reduce memory usage. * This limit is calculated as a fraction of physmem (by default 5%). * We constrain the lower bound of the hard limit to an absolute * minimum of zfs_scan_mem_lim_min (default: 16 MiB). We also constrain * the upper bound to 5% of the total pool size - no chance we'll * ever need that much memory, but just to keep the value in check. * 2) Soft memory limit: once we hit the hard memory limit, we start * issuing I/O to reduce queue memory usage, but we don't want to * completely empty out the queues, since we might be able to find I/Os * that will fill in the gaps of our non-sequential IOs at some point * in the future. So we stop the issuing of I/Os once the amount of * memory used drops below the soft limit (at which point we stop issuing * I/O and start scanning metadata again). * * This limit is calculated by subtracting a fraction of the hard * limit from the hard limit. By default this fraction is 5%, so * the soft limit is 95% of the hard limit. We cap the size of the * difference between the hard and soft limits at an absolute * maximum of zfs_scan_mem_lim_soft_max (default: 128 MiB) - this is * sufficient to not cause too frequent switching between the * metadata scan and I/O issue (even at 2k recordsize, 128 MiB's * worth of queues is about 1.2 GiB of on-pool data, so scanning * that should take at least a decent fraction of a second). */ static boolean_t dsl_scan_should_clear(dsl_scan_t *scn) { spa_t *spa = scn->scn_dp->dp_spa; vdev_t *rvd = scn->scn_dp->dp_spa->spa_root_vdev; uint64_t alloc, mlim_hard, mlim_soft, mused; alloc = metaslab_class_get_alloc(spa_normal_class(spa)); alloc += metaslab_class_get_alloc(spa_special_class(spa)); alloc += metaslab_class_get_alloc(spa_dedup_class(spa)); mlim_hard = MAX((physmem / zfs_scan_mem_lim_fact) * PAGESIZE, zfs_scan_mem_lim_min); mlim_hard = MIN(mlim_hard, alloc / 20); mlim_soft = mlim_hard - MIN(mlim_hard / zfs_scan_mem_lim_soft_fact, zfs_scan_mem_lim_soft_max); mused = 0; for (uint64_t i = 0; i < rvd->vdev_children; i++) { vdev_t *tvd = rvd->vdev_child[i]; dsl_scan_io_queue_t *queue; mutex_enter(&tvd->vdev_scan_io_queue_lock); queue = tvd->vdev_scan_io_queue; if (queue != NULL) { /* * # of extents in exts_by_addr = # in exts_by_size. * B-tree efficiency is ~75%, but can be as low as 50%. */ mused += zfs_btree_numnodes(&queue->q_exts_by_size) * ((sizeof (range_seg_gap_t) + sizeof (uint64_t)) * 3 / 2) + queue->q_sio_memused; } mutex_exit(&tvd->vdev_scan_io_queue_lock); } dprintf("current scan memory usage: %llu bytes\n", (longlong_t)mused); if (mused == 0) ASSERT0(scn->scn_queues_pending); /* * If we are above our hard limit, we need to clear out memory. * If we are below our soft limit, we need to accumulate sequential IOs. * Otherwise, we should keep doing whatever we are currently doing. */ if (mused >= mlim_hard) return (B_TRUE); else if (mused < mlim_soft) return (B_FALSE); else return (scn->scn_clearing); } static boolean_t dsl_scan_check_suspend(dsl_scan_t *scn, const zbookmark_phys_t *zb) { /* we never skip user/group accounting objects */ if (zb && (int64_t)zb->zb_object < 0) return (B_FALSE); if (scn->scn_suspending) return (B_TRUE); /* we're already suspending */ if (!ZB_IS_ZERO(&scn->scn_phys.scn_bookmark)) return (B_FALSE); /* we're resuming */ /* We only know how to resume from level-0 and objset blocks. */ if (zb && (zb->zb_level != 0 && zb->zb_level != ZB_ROOT_LEVEL)) return (B_FALSE); /* * We suspend if: * - we have scanned for at least the minimum time (default 1 sec * for scrub, 3 sec for resilver), and either we have sufficient * dirty data that we are starting to write more quickly * (default 30%), someone is explicitly waiting for this txg * to complete, or we have used up all of the time in the txg * timeout (default 5 sec). * or * - the spa is shutting down because this pool is being exported * or the machine is rebooting. * or * - the scan queue has reached its memory use limit */ uint64_t curr_time_ns = gethrtime(); uint64_t scan_time_ns = curr_time_ns - scn->scn_sync_start_time; uint64_t sync_time_ns = curr_time_ns - scn->scn_dp->dp_spa->spa_sync_starttime; uint64_t dirty_min_bytes = zfs_dirty_data_max * zfs_vdev_async_write_active_min_dirty_percent / 100; int mintime = (scn->scn_phys.scn_func == POOL_SCAN_RESILVER) ? zfs_resilver_min_time_ms : zfs_scrub_min_time_ms; if ((NSEC2MSEC(scan_time_ns) > mintime && (scn->scn_dp->dp_dirty_total >= dirty_min_bytes || txg_sync_waiting(scn->scn_dp) || NSEC2SEC(sync_time_ns) >= zfs_txg_timeout)) || spa_shutting_down(scn->scn_dp->dp_spa) || (zfs_scan_strict_mem_lim && dsl_scan_should_clear(scn))) { if (zb && zb->zb_level == ZB_ROOT_LEVEL) { dprintf("suspending at first available bookmark " "%llx/%llx/%llx/%llx\n", (longlong_t)zb->zb_objset, (longlong_t)zb->zb_object, (longlong_t)zb->zb_level, (longlong_t)zb->zb_blkid); SET_BOOKMARK(&scn->scn_phys.scn_bookmark, zb->zb_objset, 0, 0, 0); } else if (zb != NULL) { dprintf("suspending at bookmark %llx/%llx/%llx/%llx\n", (longlong_t)zb->zb_objset, (longlong_t)zb->zb_object, (longlong_t)zb->zb_level, (longlong_t)zb->zb_blkid); scn->scn_phys.scn_bookmark = *zb; } else { #ifdef ZFS_DEBUG dsl_scan_phys_t *scnp = &scn->scn_phys; dprintf("suspending at at DDT bookmark " "%llx/%llx/%llx/%llx\n", (longlong_t)scnp->scn_ddt_bookmark.ddb_class, (longlong_t)scnp->scn_ddt_bookmark.ddb_type, (longlong_t)scnp->scn_ddt_bookmark.ddb_checksum, (longlong_t)scnp->scn_ddt_bookmark.ddb_cursor); #endif } scn->scn_suspending = B_TRUE; return (B_TRUE); } return (B_FALSE); } typedef struct zil_scan_arg { dsl_pool_t *zsa_dp; zil_header_t *zsa_zh; } zil_scan_arg_t; static int dsl_scan_zil_block(zilog_t *zilog, const blkptr_t *bp, void *arg, uint64_t claim_txg) { (void) zilog; zil_scan_arg_t *zsa = arg; dsl_pool_t *dp = zsa->zsa_dp; dsl_scan_t *scn = dp->dp_scan; zil_header_t *zh = zsa->zsa_zh; zbookmark_phys_t zb; ASSERT(!BP_IS_REDACTED(bp)); if (BP_IS_HOLE(bp) || bp->blk_birth <= scn->scn_phys.scn_cur_min_txg) return (0); /* * One block ("stubby") can be allocated a long time ago; we * want to visit that one because it has been allocated * (on-disk) even if it hasn't been claimed (even though for * scrub there's nothing to do to it). */ if (claim_txg == 0 && bp->blk_birth >= spa_min_claim_txg(dp->dp_spa)) return (0); SET_BOOKMARK(&zb, zh->zh_log.blk_cksum.zc_word[ZIL_ZC_OBJSET], ZB_ZIL_OBJECT, ZB_ZIL_LEVEL, bp->blk_cksum.zc_word[ZIL_ZC_SEQ]); VERIFY(0 == scan_funcs[scn->scn_phys.scn_func](dp, bp, &zb)); return (0); } static int dsl_scan_zil_record(zilog_t *zilog, const lr_t *lrc, void *arg, uint64_t claim_txg) { (void) zilog; if (lrc->lrc_txtype == TX_WRITE) { zil_scan_arg_t *zsa = arg; dsl_pool_t *dp = zsa->zsa_dp; dsl_scan_t *scn = dp->dp_scan; zil_header_t *zh = zsa->zsa_zh; const lr_write_t *lr = (const lr_write_t *)lrc; const blkptr_t *bp = &lr->lr_blkptr; zbookmark_phys_t zb; ASSERT(!BP_IS_REDACTED(bp)); if (BP_IS_HOLE(bp) || bp->blk_birth <= scn->scn_phys.scn_cur_min_txg) return (0); /* * birth can be < claim_txg if this record's txg is * already txg sync'ed (but this log block contains * other records that are not synced) */ if (claim_txg == 0 || bp->blk_birth < claim_txg) return (0); SET_BOOKMARK(&zb, zh->zh_log.blk_cksum.zc_word[ZIL_ZC_OBJSET], lr->lr_foid, ZB_ZIL_LEVEL, lr->lr_offset / BP_GET_LSIZE(bp)); VERIFY(0 == scan_funcs[scn->scn_phys.scn_func](dp, bp, &zb)); } return (0); } static void dsl_scan_zil(dsl_pool_t *dp, zil_header_t *zh) { uint64_t claim_txg = zh->zh_claim_txg; zil_scan_arg_t zsa = { dp, zh }; zilog_t *zilog; ASSERT(spa_writeable(dp->dp_spa)); /* * We only want to visit blocks that have been claimed but not yet * replayed (or, in read-only mode, blocks that *would* be claimed). */ if (claim_txg == 0) return; zilog = zil_alloc(dp->dp_meta_objset, zh); (void) zil_parse(zilog, dsl_scan_zil_block, dsl_scan_zil_record, &zsa, claim_txg, B_FALSE); zil_free(zilog); } /* * We compare scan_prefetch_issue_ctx_t's based on their bookmarks. The idea * here is to sort the AVL tree by the order each block will be needed. */ static int scan_prefetch_queue_compare(const void *a, const void *b) { const scan_prefetch_issue_ctx_t *spic_a = a, *spic_b = b; const scan_prefetch_ctx_t *spc_a = spic_a->spic_spc; const scan_prefetch_ctx_t *spc_b = spic_b->spic_spc; return (zbookmark_compare(spc_a->spc_datablkszsec, spc_a->spc_indblkshift, spc_b->spc_datablkszsec, spc_b->spc_indblkshift, &spic_a->spic_zb, &spic_b->spic_zb)); } static void scan_prefetch_ctx_rele(scan_prefetch_ctx_t *spc, const void *tag) { if (zfs_refcount_remove(&spc->spc_refcnt, tag) == 0) { zfs_refcount_destroy(&spc->spc_refcnt); kmem_free(spc, sizeof (scan_prefetch_ctx_t)); } } static scan_prefetch_ctx_t * scan_prefetch_ctx_create(dsl_scan_t *scn, dnode_phys_t *dnp, const void *tag) { scan_prefetch_ctx_t *spc; spc = kmem_alloc(sizeof (scan_prefetch_ctx_t), KM_SLEEP); zfs_refcount_create(&spc->spc_refcnt); zfs_refcount_add(&spc->spc_refcnt, tag); spc->spc_scn = scn; if (dnp != NULL) { spc->spc_datablkszsec = dnp->dn_datablkszsec; spc->spc_indblkshift = dnp->dn_indblkshift; spc->spc_root = B_FALSE; } else { spc->spc_datablkszsec = 0; spc->spc_indblkshift = 0; spc->spc_root = B_TRUE; } return (spc); } static void scan_prefetch_ctx_add_ref(scan_prefetch_ctx_t *spc, const void *tag) { zfs_refcount_add(&spc->spc_refcnt, tag); } static void scan_ds_prefetch_queue_clear(dsl_scan_t *scn) { spa_t *spa = scn->scn_dp->dp_spa; void *cookie = NULL; scan_prefetch_issue_ctx_t *spic = NULL; mutex_enter(&spa->spa_scrub_lock); while ((spic = avl_destroy_nodes(&scn->scn_prefetch_queue, &cookie)) != NULL) { scan_prefetch_ctx_rele(spic->spic_spc, scn); kmem_free(spic, sizeof (scan_prefetch_issue_ctx_t)); } mutex_exit(&spa->spa_scrub_lock); } static boolean_t dsl_scan_check_prefetch_resume(scan_prefetch_ctx_t *spc, const zbookmark_phys_t *zb) { zbookmark_phys_t *last_zb = &spc->spc_scn->scn_prefetch_bookmark; dnode_phys_t tmp_dnp; dnode_phys_t *dnp = (spc->spc_root) ? NULL : &tmp_dnp; if (zb->zb_objset != last_zb->zb_objset) return (B_TRUE); if ((int64_t)zb->zb_object < 0) return (B_FALSE); tmp_dnp.dn_datablkszsec = spc->spc_datablkszsec; tmp_dnp.dn_indblkshift = spc->spc_indblkshift; if (zbookmark_subtree_completed(dnp, zb, last_zb)) return (B_TRUE); return (B_FALSE); } static void dsl_scan_prefetch(scan_prefetch_ctx_t *spc, blkptr_t *bp, zbookmark_phys_t *zb) { avl_index_t idx; dsl_scan_t *scn = spc->spc_scn; spa_t *spa = scn->scn_dp->dp_spa; scan_prefetch_issue_ctx_t *spic; if (zfs_no_scrub_prefetch || BP_IS_REDACTED(bp)) return; if (BP_IS_HOLE(bp) || bp->blk_birth <= scn->scn_phys.scn_cur_min_txg || (BP_GET_LEVEL(bp) == 0 && BP_GET_TYPE(bp) != DMU_OT_DNODE && BP_GET_TYPE(bp) != DMU_OT_OBJSET)) return; if (dsl_scan_check_prefetch_resume(spc, zb)) return; scan_prefetch_ctx_add_ref(spc, scn); spic = kmem_alloc(sizeof (scan_prefetch_issue_ctx_t), KM_SLEEP); spic->spic_spc = spc; spic->spic_bp = *bp; spic->spic_zb = *zb; /* * Add the IO to the queue of blocks to prefetch. This allows us to * prioritize blocks that we will need first for the main traversal * thread. */ mutex_enter(&spa->spa_scrub_lock); if (avl_find(&scn->scn_prefetch_queue, spic, &idx) != NULL) { /* this block is already queued for prefetch */ kmem_free(spic, sizeof (scan_prefetch_issue_ctx_t)); scan_prefetch_ctx_rele(spc, scn); mutex_exit(&spa->spa_scrub_lock); return; } avl_insert(&scn->scn_prefetch_queue, spic, idx); cv_broadcast(&spa->spa_scrub_io_cv); mutex_exit(&spa->spa_scrub_lock); } static void dsl_scan_prefetch_dnode(dsl_scan_t *scn, dnode_phys_t *dnp, uint64_t objset, uint64_t object) { int i; zbookmark_phys_t zb; scan_prefetch_ctx_t *spc; if (dnp->dn_nblkptr == 0 && !(dnp->dn_flags & DNODE_FLAG_SPILL_BLKPTR)) return; SET_BOOKMARK(&zb, objset, object, 0, 0); spc = scan_prefetch_ctx_create(scn, dnp, FTAG); for (i = 0; i < dnp->dn_nblkptr; i++) { zb.zb_level = BP_GET_LEVEL(&dnp->dn_blkptr[i]); zb.zb_blkid = i; dsl_scan_prefetch(spc, &dnp->dn_blkptr[i], &zb); } if (dnp->dn_flags & DNODE_FLAG_SPILL_BLKPTR) { zb.zb_level = 0; zb.zb_blkid = DMU_SPILL_BLKID; dsl_scan_prefetch(spc, DN_SPILL_BLKPTR(dnp), &zb); } scan_prefetch_ctx_rele(spc, FTAG); } static void dsl_scan_prefetch_cb(zio_t *zio, const zbookmark_phys_t *zb, const blkptr_t *bp, arc_buf_t *buf, void *private) { (void) zio; scan_prefetch_ctx_t *spc = private; dsl_scan_t *scn = spc->spc_scn; spa_t *spa = scn->scn_dp->dp_spa; /* broadcast that the IO has completed for rate limiting purposes */ mutex_enter(&spa->spa_scrub_lock); ASSERT3U(spa->spa_scrub_inflight, >=, BP_GET_PSIZE(bp)); spa->spa_scrub_inflight -= BP_GET_PSIZE(bp); cv_broadcast(&spa->spa_scrub_io_cv); mutex_exit(&spa->spa_scrub_lock); /* if there was an error or we are done prefetching, just cleanup */ if (buf == NULL || scn->scn_prefetch_stop) goto out; if (BP_GET_LEVEL(bp) > 0) { int i; blkptr_t *cbp; int epb = BP_GET_LSIZE(bp) >> SPA_BLKPTRSHIFT; zbookmark_phys_t czb; for (i = 0, cbp = buf->b_data; i < epb; i++, cbp++) { SET_BOOKMARK(&czb, zb->zb_objset, zb->zb_object, zb->zb_level - 1, zb->zb_blkid * epb + i); dsl_scan_prefetch(spc, cbp, &czb); } } else if (BP_GET_TYPE(bp) == DMU_OT_DNODE) { dnode_phys_t *cdnp; int i; int epb = BP_GET_LSIZE(bp) >> DNODE_SHIFT; for (i = 0, cdnp = buf->b_data; i < epb; i += cdnp->dn_extra_slots + 1, cdnp += cdnp->dn_extra_slots + 1) { dsl_scan_prefetch_dnode(scn, cdnp, zb->zb_objset, zb->zb_blkid * epb + i); } } else if (BP_GET_TYPE(bp) == DMU_OT_OBJSET) { objset_phys_t *osp = buf->b_data; dsl_scan_prefetch_dnode(scn, &osp->os_meta_dnode, zb->zb_objset, DMU_META_DNODE_OBJECT); if (OBJSET_BUF_HAS_USERUSED(buf)) { dsl_scan_prefetch_dnode(scn, &osp->os_groupused_dnode, zb->zb_objset, DMU_GROUPUSED_OBJECT); dsl_scan_prefetch_dnode(scn, &osp->os_userused_dnode, zb->zb_objset, DMU_USERUSED_OBJECT); } } out: if (buf != NULL) arc_buf_destroy(buf, private); scan_prefetch_ctx_rele(spc, scn); } static void dsl_scan_prefetch_thread(void *arg) { dsl_scan_t *scn = arg; spa_t *spa = scn->scn_dp->dp_spa; scan_prefetch_issue_ctx_t *spic; /* loop until we are told to stop */ while (!scn->scn_prefetch_stop) { arc_flags_t flags = ARC_FLAG_NOWAIT | ARC_FLAG_PRESCIENT_PREFETCH | ARC_FLAG_PREFETCH; int zio_flags = ZIO_FLAG_CANFAIL | ZIO_FLAG_SCAN_THREAD; mutex_enter(&spa->spa_scrub_lock); /* * Wait until we have an IO to issue and are not above our * maximum in flight limit. */ while (!scn->scn_prefetch_stop && (avl_numnodes(&scn->scn_prefetch_queue) == 0 || spa->spa_scrub_inflight >= scn->scn_maxinflight_bytes)) { cv_wait(&spa->spa_scrub_io_cv, &spa->spa_scrub_lock); } /* recheck if we should stop since we waited for the cv */ if (scn->scn_prefetch_stop) { mutex_exit(&spa->spa_scrub_lock); break; } /* remove the prefetch IO from the tree */ spic = avl_first(&scn->scn_prefetch_queue); spa->spa_scrub_inflight += BP_GET_PSIZE(&spic->spic_bp); avl_remove(&scn->scn_prefetch_queue, spic); mutex_exit(&spa->spa_scrub_lock); if (BP_IS_PROTECTED(&spic->spic_bp)) { ASSERT(BP_GET_TYPE(&spic->spic_bp) == DMU_OT_DNODE || BP_GET_TYPE(&spic->spic_bp) == DMU_OT_OBJSET); ASSERT3U(BP_GET_LEVEL(&spic->spic_bp), ==, 0); zio_flags |= ZIO_FLAG_RAW; } /* issue the prefetch asynchronously */ (void) arc_read(scn->scn_zio_root, scn->scn_dp->dp_spa, &spic->spic_bp, dsl_scan_prefetch_cb, spic->spic_spc, ZIO_PRIORITY_SCRUB, zio_flags, &flags, &spic->spic_zb); kmem_free(spic, sizeof (scan_prefetch_issue_ctx_t)); } ASSERT(scn->scn_prefetch_stop); /* free any prefetches we didn't get to complete */ mutex_enter(&spa->spa_scrub_lock); while ((spic = avl_first(&scn->scn_prefetch_queue)) != NULL) { avl_remove(&scn->scn_prefetch_queue, spic); scan_prefetch_ctx_rele(spic->spic_spc, scn); kmem_free(spic, sizeof (scan_prefetch_issue_ctx_t)); } ASSERT0(avl_numnodes(&scn->scn_prefetch_queue)); mutex_exit(&spa->spa_scrub_lock); } static boolean_t dsl_scan_check_resume(dsl_scan_t *scn, const dnode_phys_t *dnp, const zbookmark_phys_t *zb) { /* * We never skip over user/group accounting objects (obj<0) */ if (!ZB_IS_ZERO(&scn->scn_phys.scn_bookmark) && (int64_t)zb->zb_object >= 0) { /* * If we already visited this bp & everything below (in * a prior txg sync), don't bother doing it again. */ if (zbookmark_subtree_completed(dnp, zb, &scn->scn_phys.scn_bookmark)) return (B_TRUE); /* * If we found the block we're trying to resume from, or * we went past it, zero it out to indicate that it's OK * to start checking for suspending again. */ if (zbookmark_subtree_tbd(dnp, zb, &scn->scn_phys.scn_bookmark)) { dprintf("resuming at %llx/%llx/%llx/%llx\n", (longlong_t)zb->zb_objset, (longlong_t)zb->zb_object, (longlong_t)zb->zb_level, (longlong_t)zb->zb_blkid); memset(&scn->scn_phys.scn_bookmark, 0, sizeof (*zb)); } } return (B_FALSE); } static void dsl_scan_visitbp(blkptr_t *bp, const zbookmark_phys_t *zb, dnode_phys_t *dnp, dsl_dataset_t *ds, dsl_scan_t *scn, dmu_objset_type_t ostype, dmu_tx_t *tx); inline __attribute__((always_inline)) static void dsl_scan_visitdnode( dsl_scan_t *, dsl_dataset_t *ds, dmu_objset_type_t ostype, dnode_phys_t *dnp, uint64_t object, dmu_tx_t *tx); /* * Return nonzero on i/o error. * Return new buf to write out in *bufp. */ inline __attribute__((always_inline)) static int dsl_scan_recurse(dsl_scan_t *scn, dsl_dataset_t *ds, dmu_objset_type_t ostype, dnode_phys_t *dnp, const blkptr_t *bp, const zbookmark_phys_t *zb, dmu_tx_t *tx) { dsl_pool_t *dp = scn->scn_dp; spa_t *spa = dp->dp_spa; int zio_flags = ZIO_FLAG_CANFAIL | ZIO_FLAG_SCAN_THREAD; int err; ASSERT(!BP_IS_REDACTED(bp)); /* * There is an unlikely case of encountering dnodes with contradicting * dn_bonuslen and DNODE_FLAG_SPILL_BLKPTR flag before in files created * or modified before commit 4254acb was merged. As it is not possible * to know which of the two is correct, report an error. */ if (dnp != NULL && dnp->dn_bonuslen > DN_MAX_BONUS_LEN(dnp)) { scn->scn_phys.scn_errors++; spa_log_error(spa, zb); return (SET_ERROR(EINVAL)); } if (BP_GET_LEVEL(bp) > 0) { arc_flags_t flags = ARC_FLAG_WAIT; int i; blkptr_t *cbp; int epb = BP_GET_LSIZE(bp) >> SPA_BLKPTRSHIFT; arc_buf_t *buf; err = arc_read(NULL, spa, bp, arc_getbuf_func, &buf, ZIO_PRIORITY_SCRUB, zio_flags, &flags, zb); if (err) { scn->scn_phys.scn_errors++; return (err); } for (i = 0, cbp = buf->b_data; i < epb; i++, cbp++) { zbookmark_phys_t czb; SET_BOOKMARK(&czb, zb->zb_objset, zb->zb_object, zb->zb_level - 1, zb->zb_blkid * epb + i); dsl_scan_visitbp(cbp, &czb, dnp, ds, scn, ostype, tx); } arc_buf_destroy(buf, &buf); } else if (BP_GET_TYPE(bp) == DMU_OT_DNODE) { arc_flags_t flags = ARC_FLAG_WAIT; dnode_phys_t *cdnp; int i; int epb = BP_GET_LSIZE(bp) >> DNODE_SHIFT; arc_buf_t *buf; if (BP_IS_PROTECTED(bp)) { ASSERT3U(BP_GET_COMPRESS(bp), ==, ZIO_COMPRESS_OFF); zio_flags |= ZIO_FLAG_RAW; } err = arc_read(NULL, spa, bp, arc_getbuf_func, &buf, ZIO_PRIORITY_SCRUB, zio_flags, &flags, zb); if (err) { scn->scn_phys.scn_errors++; return (err); } for (i = 0, cdnp = buf->b_data; i < epb; i += cdnp->dn_extra_slots + 1, cdnp += cdnp->dn_extra_slots + 1) { dsl_scan_visitdnode(scn, ds, ostype, cdnp, zb->zb_blkid * epb + i, tx); } arc_buf_destroy(buf, &buf); } else if (BP_GET_TYPE(bp) == DMU_OT_OBJSET) { arc_flags_t flags = ARC_FLAG_WAIT; objset_phys_t *osp; arc_buf_t *buf; err = arc_read(NULL, spa, bp, arc_getbuf_func, &buf, ZIO_PRIORITY_SCRUB, zio_flags, &flags, zb); if (err) { scn->scn_phys.scn_errors++; return (err); } osp = buf->b_data; dsl_scan_visitdnode(scn, ds, osp->os_type, &osp->os_meta_dnode, DMU_META_DNODE_OBJECT, tx); if (OBJSET_BUF_HAS_USERUSED(buf)) { /* * We also always visit user/group/project accounting * objects, and never skip them, even if we are * suspending. This is necessary so that the * space deltas from this txg get integrated. */ if (OBJSET_BUF_HAS_PROJECTUSED(buf)) dsl_scan_visitdnode(scn, ds, osp->os_type, &osp->os_projectused_dnode, DMU_PROJECTUSED_OBJECT, tx); dsl_scan_visitdnode(scn, ds, osp->os_type, &osp->os_groupused_dnode, DMU_GROUPUSED_OBJECT, tx); dsl_scan_visitdnode(scn, ds, osp->os_type, &osp->os_userused_dnode, DMU_USERUSED_OBJECT, tx); } arc_buf_destroy(buf, &buf); } else if (!zfs_blkptr_verify(spa, bp, B_FALSE, BLK_VERIFY_LOG)) { /* * Sanity check the block pointer contents, this is handled * by arc_read() for the cases above. */ scn->scn_phys.scn_errors++; spa_log_error(spa, zb); return (SET_ERROR(EINVAL)); } return (0); } inline __attribute__((always_inline)) static void dsl_scan_visitdnode(dsl_scan_t *scn, dsl_dataset_t *ds, dmu_objset_type_t ostype, dnode_phys_t *dnp, uint64_t object, dmu_tx_t *tx) { int j; for (j = 0; j < dnp->dn_nblkptr; j++) { zbookmark_phys_t czb; SET_BOOKMARK(&czb, ds ? ds->ds_object : 0, object, dnp->dn_nlevels - 1, j); dsl_scan_visitbp(&dnp->dn_blkptr[j], &czb, dnp, ds, scn, ostype, tx); } if (dnp->dn_flags & DNODE_FLAG_SPILL_BLKPTR) { zbookmark_phys_t czb; SET_BOOKMARK(&czb, ds ? ds->ds_object : 0, object, 0, DMU_SPILL_BLKID); dsl_scan_visitbp(DN_SPILL_BLKPTR(dnp), &czb, dnp, ds, scn, ostype, tx); } } /* * The arguments are in this order because mdb can only print the * first 5; we want them to be useful. */ static void dsl_scan_visitbp(blkptr_t *bp, const zbookmark_phys_t *zb, dnode_phys_t *dnp, dsl_dataset_t *ds, dsl_scan_t *scn, dmu_objset_type_t ostype, dmu_tx_t *tx) { dsl_pool_t *dp = scn->scn_dp; blkptr_t *bp_toread = NULL; if (dsl_scan_check_suspend(scn, zb)) return; if (dsl_scan_check_resume(scn, dnp, zb)) return; scn->scn_visited_this_txg++; if (BP_IS_HOLE(bp)) { scn->scn_holes_this_txg++; return; } if (BP_IS_REDACTED(bp)) { ASSERT(dsl_dataset_feature_is_active(ds, SPA_FEATURE_REDACTED_DATASETS)); return; } if (bp->blk_birth <= scn->scn_phys.scn_cur_min_txg) { scn->scn_lt_min_this_txg++; return; } bp_toread = kmem_alloc(sizeof (blkptr_t), KM_SLEEP); *bp_toread = *bp; if (dsl_scan_recurse(scn, ds, ostype, dnp, bp_toread, zb, tx) != 0) goto out; /* * If dsl_scan_ddt() has already visited this block, it will have * already done any translations or scrubbing, so don't call the * callback again. */ if (ddt_class_contains(dp->dp_spa, scn->scn_phys.scn_ddt_class_max, bp)) { scn->scn_ddt_contained_this_txg++; goto out; } /* * If this block is from the future (after cur_max_txg), then we * are doing this on behalf of a deleted snapshot, and we will * revisit the future block on the next pass of this dataset. * Don't scan it now unless we need to because something * under it was modified. */ if (BP_PHYSICAL_BIRTH(bp) > scn->scn_phys.scn_cur_max_txg) { scn->scn_gt_max_this_txg++; goto out; } scan_funcs[scn->scn_phys.scn_func](dp, bp, zb); out: kmem_free(bp_toread, sizeof (blkptr_t)); } static void dsl_scan_visit_rootbp(dsl_scan_t *scn, dsl_dataset_t *ds, blkptr_t *bp, dmu_tx_t *tx) { zbookmark_phys_t zb; scan_prefetch_ctx_t *spc; SET_BOOKMARK(&zb, ds ? ds->ds_object : DMU_META_OBJSET, ZB_ROOT_OBJECT, ZB_ROOT_LEVEL, ZB_ROOT_BLKID); if (ZB_IS_ZERO(&scn->scn_phys.scn_bookmark)) { SET_BOOKMARK(&scn->scn_prefetch_bookmark, zb.zb_objset, 0, 0, 0); } else { scn->scn_prefetch_bookmark = scn->scn_phys.scn_bookmark; } scn->scn_objsets_visited_this_txg++; spc = scan_prefetch_ctx_create(scn, NULL, FTAG); dsl_scan_prefetch(spc, bp, &zb); scan_prefetch_ctx_rele(spc, FTAG); dsl_scan_visitbp(bp, &zb, NULL, ds, scn, DMU_OST_NONE, tx); dprintf_ds(ds, "finished scan%s", ""); } static void ds_destroyed_scn_phys(dsl_dataset_t *ds, dsl_scan_phys_t *scn_phys) { if (scn_phys->scn_bookmark.zb_objset == ds->ds_object) { if (ds->ds_is_snapshot) { /* * Note: * - scn_cur_{min,max}_txg stays the same. * - Setting the flag is not really necessary if * scn_cur_max_txg == scn_max_txg, because there * is nothing after this snapshot that we care * about. However, we set it anyway and then * ignore it when we retraverse it in * dsl_scan_visitds(). */ scn_phys->scn_bookmark.zb_objset = dsl_dataset_phys(ds)->ds_next_snap_obj; zfs_dbgmsg("destroying ds %llu on %s; currently " "traversing; reset zb_objset to %llu", (u_longlong_t)ds->ds_object, ds->ds_dir->dd_pool->dp_spa->spa_name, (u_longlong_t)dsl_dataset_phys(ds)-> ds_next_snap_obj); scn_phys->scn_flags |= DSF_VISIT_DS_AGAIN; } else { SET_BOOKMARK(&scn_phys->scn_bookmark, ZB_DESTROYED_OBJSET, 0, 0, 0); zfs_dbgmsg("destroying ds %llu on %s; currently " "traversing; reset bookmark to -1,0,0,0", (u_longlong_t)ds->ds_object, ds->ds_dir->dd_pool->dp_spa->spa_name); } } } /* * Invoked when a dataset is destroyed. We need to make sure that: * * 1) If it is the dataset that was currently being scanned, we write * a new dsl_scan_phys_t and marking the objset reference in it * as destroyed. * 2) Remove it from the work queue, if it was present. * * If the dataset was actually a snapshot, instead of marking the dataset * as destroyed, we instead substitute the next snapshot in line. */ void dsl_scan_ds_destroyed(dsl_dataset_t *ds, dmu_tx_t *tx) { dsl_pool_t *dp = ds->ds_dir->dd_pool; dsl_scan_t *scn = dp->dp_scan; uint64_t mintxg; if (!dsl_scan_is_running(scn)) return; ds_destroyed_scn_phys(ds, &scn->scn_phys); ds_destroyed_scn_phys(ds, &scn->scn_phys_cached); if (scan_ds_queue_contains(scn, ds->ds_object, &mintxg)) { scan_ds_queue_remove(scn, ds->ds_object); if (ds->ds_is_snapshot) scan_ds_queue_insert(scn, dsl_dataset_phys(ds)->ds_next_snap_obj, mintxg); } if (zap_lookup_int_key(dp->dp_meta_objset, scn->scn_phys.scn_queue_obj, ds->ds_object, &mintxg) == 0) { ASSERT3U(dsl_dataset_phys(ds)->ds_num_children, <=, 1); VERIFY3U(0, ==, zap_remove_int(dp->dp_meta_objset, scn->scn_phys.scn_queue_obj, ds->ds_object, tx)); if (ds->ds_is_snapshot) { /* * We keep the same mintxg; it could be > * ds_creation_txg if the previous snapshot was * deleted too. */ VERIFY(zap_add_int_key(dp->dp_meta_objset, scn->scn_phys.scn_queue_obj, dsl_dataset_phys(ds)->ds_next_snap_obj, mintxg, tx) == 0); zfs_dbgmsg("destroying ds %llu on %s; in queue; " "replacing with %llu", (u_longlong_t)ds->ds_object, dp->dp_spa->spa_name, (u_longlong_t)dsl_dataset_phys(ds)-> ds_next_snap_obj); } else { zfs_dbgmsg("destroying ds %llu on %s; in queue; " "removing", (u_longlong_t)ds->ds_object, dp->dp_spa->spa_name); } } /* * dsl_scan_sync() should be called after this, and should sync * out our changed state, but just to be safe, do it here. */ dsl_scan_sync_state(scn, tx, SYNC_CACHED); } static void ds_snapshotted_bookmark(dsl_dataset_t *ds, zbookmark_phys_t *scn_bookmark) { if (scn_bookmark->zb_objset == ds->ds_object) { scn_bookmark->zb_objset = dsl_dataset_phys(ds)->ds_prev_snap_obj; zfs_dbgmsg("snapshotting ds %llu on %s; currently traversing; " "reset zb_objset to %llu", (u_longlong_t)ds->ds_object, ds->ds_dir->dd_pool->dp_spa->spa_name, (u_longlong_t)dsl_dataset_phys(ds)->ds_prev_snap_obj); } } /* * Called when a dataset is snapshotted. If we were currently traversing * this snapshot, we reset our bookmark to point at the newly created * snapshot. We also modify our work queue to remove the old snapshot and * replace with the new one. */ void dsl_scan_ds_snapshotted(dsl_dataset_t *ds, dmu_tx_t *tx) { dsl_pool_t *dp = ds->ds_dir->dd_pool; dsl_scan_t *scn = dp->dp_scan; uint64_t mintxg; if (!dsl_scan_is_running(scn)) return; ASSERT(dsl_dataset_phys(ds)->ds_prev_snap_obj != 0); ds_snapshotted_bookmark(ds, &scn->scn_phys.scn_bookmark); ds_snapshotted_bookmark(ds, &scn->scn_phys_cached.scn_bookmark); if (scan_ds_queue_contains(scn, ds->ds_object, &mintxg)) { scan_ds_queue_remove(scn, ds->ds_object); scan_ds_queue_insert(scn, dsl_dataset_phys(ds)->ds_prev_snap_obj, mintxg); } if (zap_lookup_int_key(dp->dp_meta_objset, scn->scn_phys.scn_queue_obj, ds->ds_object, &mintxg) == 0) { VERIFY3U(0, ==, zap_remove_int(dp->dp_meta_objset, scn->scn_phys.scn_queue_obj, ds->ds_object, tx)); VERIFY(zap_add_int_key(dp->dp_meta_objset, scn->scn_phys.scn_queue_obj, dsl_dataset_phys(ds)->ds_prev_snap_obj, mintxg, tx) == 0); zfs_dbgmsg("snapshotting ds %llu on %s; in queue; " "replacing with %llu", (u_longlong_t)ds->ds_object, dp->dp_spa->spa_name, (u_longlong_t)dsl_dataset_phys(ds)->ds_prev_snap_obj); } dsl_scan_sync_state(scn, tx, SYNC_CACHED); } static void ds_clone_swapped_bookmark(dsl_dataset_t *ds1, dsl_dataset_t *ds2, zbookmark_phys_t *scn_bookmark) { if (scn_bookmark->zb_objset == ds1->ds_object) { scn_bookmark->zb_objset = ds2->ds_object; zfs_dbgmsg("clone_swap ds %llu on %s; currently traversing; " "reset zb_objset to %llu", (u_longlong_t)ds1->ds_object, ds1->ds_dir->dd_pool->dp_spa->spa_name, (u_longlong_t)ds2->ds_object); } else if (scn_bookmark->zb_objset == ds2->ds_object) { scn_bookmark->zb_objset = ds1->ds_object; zfs_dbgmsg("clone_swap ds %llu on %s; currently traversing; " "reset zb_objset to %llu", (u_longlong_t)ds2->ds_object, ds2->ds_dir->dd_pool->dp_spa->spa_name, (u_longlong_t)ds1->ds_object); } } /* * Called when an origin dataset and its clone are swapped. If we were * currently traversing the dataset, we need to switch to traversing the * newly promoted clone. */ void dsl_scan_ds_clone_swapped(dsl_dataset_t *ds1, dsl_dataset_t *ds2, dmu_tx_t *tx) { dsl_pool_t *dp = ds1->ds_dir->dd_pool; dsl_scan_t *scn = dp->dp_scan; uint64_t mintxg1, mintxg2; boolean_t ds1_queued, ds2_queued; if (!dsl_scan_is_running(scn)) return; ds_clone_swapped_bookmark(ds1, ds2, &scn->scn_phys.scn_bookmark); ds_clone_swapped_bookmark(ds1, ds2, &scn->scn_phys_cached.scn_bookmark); /* * Handle the in-memory scan queue. */ ds1_queued = scan_ds_queue_contains(scn, ds1->ds_object, &mintxg1); ds2_queued = scan_ds_queue_contains(scn, ds2->ds_object, &mintxg2); /* Sanity checking. */ if (ds1_queued) { ASSERT3U(mintxg1, ==, dsl_dataset_phys(ds1)->ds_prev_snap_txg); ASSERT3U(mintxg1, ==, dsl_dataset_phys(ds2)->ds_prev_snap_txg); } if (ds2_queued) { ASSERT3U(mintxg2, ==, dsl_dataset_phys(ds1)->ds_prev_snap_txg); ASSERT3U(mintxg2, ==, dsl_dataset_phys(ds2)->ds_prev_snap_txg); } if (ds1_queued && ds2_queued) { /* * If both are queued, we don't need to do anything. * The swapping code below would not handle this case correctly, * since we can't insert ds2 if it is already there. That's * because scan_ds_queue_insert() prohibits a duplicate insert * and panics. */ } else if (ds1_queued) { scan_ds_queue_remove(scn, ds1->ds_object); scan_ds_queue_insert(scn, ds2->ds_object, mintxg1); } else if (ds2_queued) { scan_ds_queue_remove(scn, ds2->ds_object); scan_ds_queue_insert(scn, ds1->ds_object, mintxg2); } /* * Handle the on-disk scan queue. * The on-disk state is an out-of-date version of the in-memory state, * so the in-memory and on-disk values for ds1_queued and ds2_queued may * be different. Therefore we need to apply the swap logic to the * on-disk state independently of the in-memory state. */ ds1_queued = zap_lookup_int_key(dp->dp_meta_objset, scn->scn_phys.scn_queue_obj, ds1->ds_object, &mintxg1) == 0; ds2_queued = zap_lookup_int_key(dp->dp_meta_objset, scn->scn_phys.scn_queue_obj, ds2->ds_object, &mintxg2) == 0; /* Sanity checking. */ if (ds1_queued) { ASSERT3U(mintxg1, ==, dsl_dataset_phys(ds1)->ds_prev_snap_txg); ASSERT3U(mintxg1, ==, dsl_dataset_phys(ds2)->ds_prev_snap_txg); } if (ds2_queued) { ASSERT3U(mintxg2, ==, dsl_dataset_phys(ds1)->ds_prev_snap_txg); ASSERT3U(mintxg2, ==, dsl_dataset_phys(ds2)->ds_prev_snap_txg); } if (ds1_queued && ds2_queued) { /* * If both are queued, we don't need to do anything. * Alternatively, we could check for EEXIST from * zap_add_int_key() and back out to the original state, but * that would be more work than checking for this case upfront. */ } else if (ds1_queued) { VERIFY3S(0, ==, zap_remove_int(dp->dp_meta_objset, scn->scn_phys.scn_queue_obj, ds1->ds_object, tx)); VERIFY3S(0, ==, zap_add_int_key(dp->dp_meta_objset, scn->scn_phys.scn_queue_obj, ds2->ds_object, mintxg1, tx)); zfs_dbgmsg("clone_swap ds %llu on %s; in queue; " "replacing with %llu", (u_longlong_t)ds1->ds_object, dp->dp_spa->spa_name, (u_longlong_t)ds2->ds_object); } else if (ds2_queued) { VERIFY3S(0, ==, zap_remove_int(dp->dp_meta_objset, scn->scn_phys.scn_queue_obj, ds2->ds_object, tx)); VERIFY3S(0, ==, zap_add_int_key(dp->dp_meta_objset, scn->scn_phys.scn_queue_obj, ds1->ds_object, mintxg2, tx)); zfs_dbgmsg("clone_swap ds %llu on %s; in queue; " "replacing with %llu", (u_longlong_t)ds2->ds_object, dp->dp_spa->spa_name, (u_longlong_t)ds1->ds_object); } dsl_scan_sync_state(scn, tx, SYNC_CACHED); } static int enqueue_clones_cb(dsl_pool_t *dp, dsl_dataset_t *hds, void *arg) { uint64_t originobj = *(uint64_t *)arg; dsl_dataset_t *ds; int err; dsl_scan_t *scn = dp->dp_scan; if (dsl_dir_phys(hds->ds_dir)->dd_origin_obj != originobj) return (0); err = dsl_dataset_hold_obj(dp, hds->ds_object, FTAG, &ds); if (err) return (err); while (dsl_dataset_phys(ds)->ds_prev_snap_obj != originobj) { dsl_dataset_t *prev; err = dsl_dataset_hold_obj(dp, dsl_dataset_phys(ds)->ds_prev_snap_obj, FTAG, &prev); dsl_dataset_rele(ds, FTAG); if (err) return (err); ds = prev; } scan_ds_queue_insert(scn, ds->ds_object, dsl_dataset_phys(ds)->ds_prev_snap_txg); dsl_dataset_rele(ds, FTAG); return (0); } static void dsl_scan_visitds(dsl_scan_t *scn, uint64_t dsobj, dmu_tx_t *tx) { dsl_pool_t *dp = scn->scn_dp; dsl_dataset_t *ds; VERIFY3U(0, ==, dsl_dataset_hold_obj(dp, dsobj, FTAG, &ds)); if (scn->scn_phys.scn_cur_min_txg >= scn->scn_phys.scn_max_txg) { /* * This can happen if this snapshot was created after the * scan started, and we already completed a previous snapshot * that was created after the scan started. This snapshot * only references blocks with: * * birth < our ds_creation_txg * cur_min_txg is no less than ds_creation_txg. * We have already visited these blocks. * or * birth > scn_max_txg * The scan requested not to visit these blocks. * * Subsequent snapshots (and clones) can reference our * blocks, or blocks with even higher birth times. * Therefore we do not need to visit them either, * so we do not add them to the work queue. * * Note that checking for cur_min_txg >= cur_max_txg * is not sufficient, because in that case we may need to * visit subsequent snapshots. This happens when min_txg > 0, * which raises cur_min_txg. In this case we will visit * this dataset but skip all of its blocks, because the * rootbp's birth time is < cur_min_txg. Then we will * add the next snapshots/clones to the work queue. */ char *dsname = kmem_alloc(ZFS_MAX_DATASET_NAME_LEN, KM_SLEEP); dsl_dataset_name(ds, dsname); zfs_dbgmsg("scanning dataset %llu (%s) is unnecessary because " "cur_min_txg (%llu) >= max_txg (%llu)", (longlong_t)dsobj, dsname, (longlong_t)scn->scn_phys.scn_cur_min_txg, (longlong_t)scn->scn_phys.scn_max_txg); kmem_free(dsname, MAXNAMELEN); goto out; } /* * Only the ZIL in the head (non-snapshot) is valid. Even though * snapshots can have ZIL block pointers (which may be the same * BP as in the head), they must be ignored. In addition, $ORIGIN * doesn't have a objset (i.e. its ds_bp is a hole) so we don't * need to look for a ZIL in it either. So we traverse the ZIL here, * rather than in scan_recurse(), because the regular snapshot * block-sharing rules don't apply to it. */ if (!dsl_dataset_is_snapshot(ds) && (dp->dp_origin_snap == NULL || ds->ds_dir != dp->dp_origin_snap->ds_dir)) { objset_t *os; if (dmu_objset_from_ds(ds, &os) != 0) { goto out; } dsl_scan_zil(dp, &os->os_zil_header); } /* * Iterate over the bps in this ds. */ dmu_buf_will_dirty(ds->ds_dbuf, tx); rrw_enter(&ds->ds_bp_rwlock, RW_READER, FTAG); dsl_scan_visit_rootbp(scn, ds, &dsl_dataset_phys(ds)->ds_bp, tx); rrw_exit(&ds->ds_bp_rwlock, FTAG); char *dsname = kmem_alloc(ZFS_MAX_DATASET_NAME_LEN, KM_SLEEP); dsl_dataset_name(ds, dsname); zfs_dbgmsg("scanned dataset %llu (%s) with min=%llu max=%llu; " "suspending=%u", (longlong_t)dsobj, dsname, (longlong_t)scn->scn_phys.scn_cur_min_txg, (longlong_t)scn->scn_phys.scn_cur_max_txg, (int)scn->scn_suspending); kmem_free(dsname, ZFS_MAX_DATASET_NAME_LEN); if (scn->scn_suspending) goto out; /* * We've finished this pass over this dataset. */ /* * If we did not completely visit this dataset, do another pass. */ if (scn->scn_phys.scn_flags & DSF_VISIT_DS_AGAIN) { zfs_dbgmsg("incomplete pass on %s; visiting again", dp->dp_spa->spa_name); scn->scn_phys.scn_flags &= ~DSF_VISIT_DS_AGAIN; scan_ds_queue_insert(scn, ds->ds_object, scn->scn_phys.scn_cur_max_txg); goto out; } /* * Add descendant datasets to work queue. */ if (dsl_dataset_phys(ds)->ds_next_snap_obj != 0) { scan_ds_queue_insert(scn, dsl_dataset_phys(ds)->ds_next_snap_obj, dsl_dataset_phys(ds)->ds_creation_txg); } if (dsl_dataset_phys(ds)->ds_num_children > 1) { boolean_t usenext = B_FALSE; if (dsl_dataset_phys(ds)->ds_next_clones_obj != 0) { uint64_t count; /* * A bug in a previous version of the code could * cause upgrade_clones_cb() to not set * ds_next_snap_obj when it should, leading to a * missing entry. Therefore we can only use the * next_clones_obj when its count is correct. */ int err = zap_count(dp->dp_meta_objset, dsl_dataset_phys(ds)->ds_next_clones_obj, &count); if (err == 0 && count == dsl_dataset_phys(ds)->ds_num_children - 1) usenext = B_TRUE; } if (usenext) { zap_cursor_t zc; zap_attribute_t za; for (zap_cursor_init(&zc, dp->dp_meta_objset, dsl_dataset_phys(ds)->ds_next_clones_obj); zap_cursor_retrieve(&zc, &za) == 0; (void) zap_cursor_advance(&zc)) { scan_ds_queue_insert(scn, zfs_strtonum(za.za_name, NULL), dsl_dataset_phys(ds)->ds_creation_txg); } zap_cursor_fini(&zc); } else { VERIFY0(dmu_objset_find_dp(dp, dp->dp_root_dir_obj, enqueue_clones_cb, &ds->ds_object, DS_FIND_CHILDREN)); } } out: dsl_dataset_rele(ds, FTAG); } static int enqueue_cb(dsl_pool_t *dp, dsl_dataset_t *hds, void *arg) { (void) arg; dsl_dataset_t *ds; int err; dsl_scan_t *scn = dp->dp_scan; err = dsl_dataset_hold_obj(dp, hds->ds_object, FTAG, &ds); if (err) return (err); while (dsl_dataset_phys(ds)->ds_prev_snap_obj != 0) { dsl_dataset_t *prev; err = dsl_dataset_hold_obj(dp, dsl_dataset_phys(ds)->ds_prev_snap_obj, FTAG, &prev); if (err) { dsl_dataset_rele(ds, FTAG); return (err); } /* * If this is a clone, we don't need to worry about it for now. */ if (dsl_dataset_phys(prev)->ds_next_snap_obj != ds->ds_object) { dsl_dataset_rele(ds, FTAG); dsl_dataset_rele(prev, FTAG); return (0); } dsl_dataset_rele(ds, FTAG); ds = prev; } scan_ds_queue_insert(scn, ds->ds_object, dsl_dataset_phys(ds)->ds_prev_snap_txg); dsl_dataset_rele(ds, FTAG); return (0); } void dsl_scan_ddt_entry(dsl_scan_t *scn, enum zio_checksum checksum, ddt_entry_t *dde, dmu_tx_t *tx) { (void) tx; const ddt_key_t *ddk = &dde->dde_key; ddt_phys_t *ddp = dde->dde_phys; blkptr_t bp; zbookmark_phys_t zb = { 0 }; if (!dsl_scan_is_running(scn)) return; /* * This function is special because it is the only thing * that can add scan_io_t's to the vdev scan queues from * outside dsl_scan_sync(). For the most part this is ok * as long as it is called from within syncing context. * However, dsl_scan_sync() expects that no new sio's will * be added between when all the work for a scan is done * and the next txg when the scan is actually marked as * completed. This check ensures we do not issue new sio's * during this period. */ if (scn->scn_done_txg != 0) return; for (int p = 0; p < DDT_PHYS_TYPES; p++, ddp++) { if (ddp->ddp_phys_birth == 0 || ddp->ddp_phys_birth > scn->scn_phys.scn_max_txg) continue; ddt_bp_create(checksum, ddk, ddp, &bp); scn->scn_visited_this_txg++; scan_funcs[scn->scn_phys.scn_func](scn->scn_dp, &bp, &zb); } } /* * Scrub/dedup interaction. * * If there are N references to a deduped block, we don't want to scrub it * N times -- ideally, we should scrub it exactly once. * * We leverage the fact that the dde's replication class (enum ddt_class) * is ordered from highest replication class (DDT_CLASS_DITTO) to lowest * (DDT_CLASS_UNIQUE) so that we may walk the DDT in that order. * * To prevent excess scrubbing, the scrub begins by walking the DDT * to find all blocks with refcnt > 1, and scrubs each of these once. * Since there are two replication classes which contain blocks with * refcnt > 1, we scrub the highest replication class (DDT_CLASS_DITTO) first. * Finally the top-down scrub begins, only visiting blocks with refcnt == 1. * * There would be nothing more to say if a block's refcnt couldn't change * during a scrub, but of course it can so we must account for changes * in a block's replication class. * * Here's an example of what can occur: * * If a block has refcnt > 1 during the DDT scrub phase, but has refcnt == 1 * when visited during the top-down scrub phase, it will be scrubbed twice. * This negates our scrub optimization, but is otherwise harmless. * * If a block has refcnt == 1 during the DDT scrub phase, but has refcnt > 1 * on each visit during the top-down scrub phase, it will never be scrubbed. * To catch this, ddt_sync_entry() notifies the scrub code whenever a block's * reference class transitions to a higher level (i.e DDT_CLASS_UNIQUE to * DDT_CLASS_DUPLICATE); if it transitions from refcnt == 1 to refcnt > 1 * while a scrub is in progress, it scrubs the block right then. */ static void dsl_scan_ddt(dsl_scan_t *scn, dmu_tx_t *tx) { ddt_bookmark_t *ddb = &scn->scn_phys.scn_ddt_bookmark; ddt_entry_t dde = {{{{0}}}}; int error; uint64_t n = 0; while ((error = ddt_walk(scn->scn_dp->dp_spa, ddb, &dde)) == 0) { ddt_t *ddt; if (ddb->ddb_class > scn->scn_phys.scn_ddt_class_max) break; dprintf("visiting ddb=%llu/%llu/%llu/%llx\n", (longlong_t)ddb->ddb_class, (longlong_t)ddb->ddb_type, (longlong_t)ddb->ddb_checksum, (longlong_t)ddb->ddb_cursor); /* There should be no pending changes to the dedup table */ ddt = scn->scn_dp->dp_spa->spa_ddt[ddb->ddb_checksum]; ASSERT(avl_first(&ddt->ddt_tree) == NULL); dsl_scan_ddt_entry(scn, ddb->ddb_checksum, &dde, tx); n++; if (dsl_scan_check_suspend(scn, NULL)) break; } zfs_dbgmsg("scanned %llu ddt entries on %s with class_max = %u; " "suspending=%u", (longlong_t)n, scn->scn_dp->dp_spa->spa_name, (int)scn->scn_phys.scn_ddt_class_max, (int)scn->scn_suspending); ASSERT(error == 0 || error == ENOENT); ASSERT(error != ENOENT || ddb->ddb_class > scn->scn_phys.scn_ddt_class_max); } static uint64_t dsl_scan_ds_maxtxg(dsl_dataset_t *ds) { uint64_t smt = ds->ds_dir->dd_pool->dp_scan->scn_phys.scn_max_txg; if (ds->ds_is_snapshot) return (MIN(smt, dsl_dataset_phys(ds)->ds_creation_txg)); return (smt); } static void dsl_scan_visit(dsl_scan_t *scn, dmu_tx_t *tx) { scan_ds_t *sds; dsl_pool_t *dp = scn->scn_dp; if (scn->scn_phys.scn_ddt_bookmark.ddb_class <= scn->scn_phys.scn_ddt_class_max) { scn->scn_phys.scn_cur_min_txg = scn->scn_phys.scn_min_txg; scn->scn_phys.scn_cur_max_txg = scn->scn_phys.scn_max_txg; dsl_scan_ddt(scn, tx); if (scn->scn_suspending) return; } if (scn->scn_phys.scn_bookmark.zb_objset == DMU_META_OBJSET) { /* First do the MOS & ORIGIN */ scn->scn_phys.scn_cur_min_txg = scn->scn_phys.scn_min_txg; scn->scn_phys.scn_cur_max_txg = scn->scn_phys.scn_max_txg; dsl_scan_visit_rootbp(scn, NULL, &dp->dp_meta_rootbp, tx); spa_set_rootblkptr(dp->dp_spa, &dp->dp_meta_rootbp); if (scn->scn_suspending) return; if (spa_version(dp->dp_spa) < SPA_VERSION_DSL_SCRUB) { VERIFY0(dmu_objset_find_dp(dp, dp->dp_root_dir_obj, enqueue_cb, NULL, DS_FIND_CHILDREN)); } else { dsl_scan_visitds(scn, dp->dp_origin_snap->ds_object, tx); } ASSERT(!scn->scn_suspending); } else if (scn->scn_phys.scn_bookmark.zb_objset != ZB_DESTROYED_OBJSET) { uint64_t dsobj = scn->scn_phys.scn_bookmark.zb_objset; /* * If we were suspended, continue from here. Note if the * ds we were suspended on was deleted, the zb_objset may * be -1, so we will skip this and find a new objset * below. */ dsl_scan_visitds(scn, dsobj, tx); if (scn->scn_suspending) return; } /* * In case we suspended right at the end of the ds, zero the * bookmark so we don't think that we're still trying to resume. */ memset(&scn->scn_phys.scn_bookmark, 0, sizeof (zbookmark_phys_t)); /* * Keep pulling things out of the dataset avl queue. Updates to the * persistent zap-object-as-queue happen only at checkpoints. */ while ((sds = avl_first(&scn->scn_queue)) != NULL) { dsl_dataset_t *ds; uint64_t dsobj = sds->sds_dsobj; uint64_t txg = sds->sds_txg; /* dequeue and free the ds from the queue */ scan_ds_queue_remove(scn, dsobj); sds = NULL; /* set up min / max txg */ VERIFY3U(0, ==, dsl_dataset_hold_obj(dp, dsobj, FTAG, &ds)); if (txg != 0) { scn->scn_phys.scn_cur_min_txg = MAX(scn->scn_phys.scn_min_txg, txg); } else { scn->scn_phys.scn_cur_min_txg = MAX(scn->scn_phys.scn_min_txg, dsl_dataset_phys(ds)->ds_prev_snap_txg); } scn->scn_phys.scn_cur_max_txg = dsl_scan_ds_maxtxg(ds); dsl_dataset_rele(ds, FTAG); dsl_scan_visitds(scn, dsobj, tx); if (scn->scn_suspending) return; } /* No more objsets to fetch, we're done */ scn->scn_phys.scn_bookmark.zb_objset = ZB_DESTROYED_OBJSET; ASSERT0(scn->scn_suspending); } static uint64_t dsl_scan_count_data_disks(vdev_t *rvd) { uint64_t i, leaves = 0; for (i = 0; i < rvd->vdev_children; i++) { vdev_t *vd = rvd->vdev_child[i]; if (vd->vdev_islog || vd->vdev_isspare || vd->vdev_isl2cache) continue; leaves += vdev_get_ndisks(vd) - vdev_get_nparity(vd); } return (leaves); } static void scan_io_queues_update_zio_stats(dsl_scan_io_queue_t *q, const blkptr_t *bp) { int i; uint64_t cur_size = 0; for (i = 0; i < BP_GET_NDVAS(bp); i++) { cur_size += DVA_GET_ASIZE(&bp->blk_dva[i]); } q->q_total_zio_size_this_txg += cur_size; q->q_zios_this_txg++; } static void scan_io_queues_update_seg_stats(dsl_scan_io_queue_t *q, uint64_t start, uint64_t end) { q->q_total_seg_size_this_txg += end - start; q->q_segs_this_txg++; } static boolean_t scan_io_queue_check_suspend(dsl_scan_t *scn) { /* See comment in dsl_scan_check_suspend() */ uint64_t curr_time_ns = gethrtime(); uint64_t scan_time_ns = curr_time_ns - scn->scn_sync_start_time; uint64_t sync_time_ns = curr_time_ns - scn->scn_dp->dp_spa->spa_sync_starttime; uint64_t dirty_min_bytes = zfs_dirty_data_max * zfs_vdev_async_write_active_min_dirty_percent / 100; int mintime = (scn->scn_phys.scn_func == POOL_SCAN_RESILVER) ? zfs_resilver_min_time_ms : zfs_scrub_min_time_ms; return ((NSEC2MSEC(scan_time_ns) > mintime && (scn->scn_dp->dp_dirty_total >= dirty_min_bytes || txg_sync_waiting(scn->scn_dp) || NSEC2SEC(sync_time_ns) >= zfs_txg_timeout)) || spa_shutting_down(scn->scn_dp->dp_spa)); } /* * Given a list of scan_io_t's in io_list, this issues the I/Os out to * disk. This consumes the io_list and frees the scan_io_t's. This is * called when emptying queues, either when we're up against the memory * limit or when we have finished scanning. Returns B_TRUE if we stopped * processing the list before we finished. Any sios that were not issued * will remain in the io_list. */ static boolean_t scan_io_queue_issue(dsl_scan_io_queue_t *queue, list_t *io_list) { dsl_scan_t *scn = queue->q_scn; scan_io_t *sio; boolean_t suspended = B_FALSE; while ((sio = list_head(io_list)) != NULL) { blkptr_t bp; if (scan_io_queue_check_suspend(scn)) { suspended = B_TRUE; break; } sio2bp(sio, &bp); scan_exec_io(scn->scn_dp, &bp, sio->sio_flags, &sio->sio_zb, queue); (void) list_remove_head(io_list); scan_io_queues_update_zio_stats(queue, &bp); sio_free(sio); } return (suspended); } /* * This function removes sios from an IO queue which reside within a given * range_seg_t and inserts them (in offset order) into a list. Note that * we only ever return a maximum of 32 sios at once. If there are more sios * to process within this segment that did not make it onto the list we * return B_TRUE and otherwise B_FALSE. */ static boolean_t scan_io_queue_gather(dsl_scan_io_queue_t *queue, range_seg_t *rs, list_t *list) { scan_io_t *srch_sio, *sio, *next_sio; avl_index_t idx; uint_t num_sios = 0; int64_t bytes_issued = 0; ASSERT(rs != NULL); ASSERT(MUTEX_HELD(&queue->q_vd->vdev_scan_io_queue_lock)); srch_sio = sio_alloc(1); srch_sio->sio_nr_dvas = 1; SIO_SET_OFFSET(srch_sio, rs_get_start(rs, queue->q_exts_by_addr)); /* * The exact start of the extent might not contain any matching zios, * so if that's the case, examine the next one in the tree. */ sio = avl_find(&queue->q_sios_by_addr, srch_sio, &idx); sio_free(srch_sio); if (sio == NULL) sio = avl_nearest(&queue->q_sios_by_addr, idx, AVL_AFTER); while (sio != NULL && SIO_GET_OFFSET(sio) < rs_get_end(rs, queue->q_exts_by_addr) && num_sios <= 32) { ASSERT3U(SIO_GET_OFFSET(sio), >=, rs_get_start(rs, queue->q_exts_by_addr)); ASSERT3U(SIO_GET_END_OFFSET(sio), <=, rs_get_end(rs, queue->q_exts_by_addr)); next_sio = AVL_NEXT(&queue->q_sios_by_addr, sio); avl_remove(&queue->q_sios_by_addr, sio); if (avl_is_empty(&queue->q_sios_by_addr)) atomic_add_64(&queue->q_scn->scn_queues_pending, -1); queue->q_sio_memused -= SIO_GET_MUSED(sio); bytes_issued += SIO_GET_ASIZE(sio); num_sios++; list_insert_tail(list, sio); sio = next_sio; } /* * We limit the number of sios we process at once to 32 to avoid * biting off more than we can chew. If we didn't take everything * in the segment we update it to reflect the work we were able to * complete. Otherwise, we remove it from the range tree entirely. */ if (sio != NULL && SIO_GET_OFFSET(sio) < rs_get_end(rs, queue->q_exts_by_addr)) { range_tree_adjust_fill(queue->q_exts_by_addr, rs, -bytes_issued); range_tree_resize_segment(queue->q_exts_by_addr, rs, SIO_GET_OFFSET(sio), rs_get_end(rs, queue->q_exts_by_addr) - SIO_GET_OFFSET(sio)); queue->q_last_ext_addr = SIO_GET_OFFSET(sio); return (B_TRUE); } else { uint64_t rstart = rs_get_start(rs, queue->q_exts_by_addr); uint64_t rend = rs_get_end(rs, queue->q_exts_by_addr); range_tree_remove(queue->q_exts_by_addr, rstart, rend - rstart); queue->q_last_ext_addr = -1; return (B_FALSE); } } /* * This is called from the queue emptying thread and selects the next * extent from which we are to issue I/Os. The behavior of this function * depends on the state of the scan, the current memory consumption and * whether or not we are performing a scan shutdown. * 1) We select extents in an elevator algorithm (LBA-order) if the scan * needs to perform a checkpoint * 2) We select the largest available extent if we are up against the * memory limit. * 3) Otherwise we don't select any extents. */ static range_seg_t * scan_io_queue_fetch_ext(dsl_scan_io_queue_t *queue) { dsl_scan_t *scn = queue->q_scn; range_tree_t *rt = queue->q_exts_by_addr; ASSERT(MUTEX_HELD(&queue->q_vd->vdev_scan_io_queue_lock)); ASSERT(scn->scn_is_sorted); if (!scn->scn_checkpointing && !scn->scn_clearing) return (NULL); /* * During normal clearing, we want to issue our largest segments * first, keeping IO as sequential as possible, and leaving the * smaller extents for later with the hope that they might eventually * grow to larger sequential segments. However, when the scan is * checkpointing, no new extents will be added to the sorting queue, * so the way we are sorted now is as good as it will ever get. * In this case, we instead switch to issuing extents in LBA order. */ if ((zfs_scan_issue_strategy < 1 && scn->scn_checkpointing) || zfs_scan_issue_strategy == 1) return (range_tree_first(rt)); /* * Try to continue previous extent if it is not completed yet. After * shrink in scan_io_queue_gather() it may no longer be the best, but * otherwise we leave shorter remnant every txg. */ uint64_t start; - uint64_t size = 1 << rt->rt_shift; + uint64_t size = 1ULL << rt->rt_shift; range_seg_t *addr_rs; if (queue->q_last_ext_addr != -1) { start = queue->q_last_ext_addr; addr_rs = range_tree_find(rt, start, size); if (addr_rs != NULL) return (addr_rs); } /* * Nothing to continue, so find new best extent. */ uint64_t *v = zfs_btree_first(&queue->q_exts_by_size, NULL); if (v == NULL) return (NULL); queue->q_last_ext_addr = start = *v << rt->rt_shift; /* * We need to get the original entry in the by_addr tree so we can * modify it. */ addr_rs = range_tree_find(rt, start, size); ASSERT3P(addr_rs, !=, NULL); ASSERT3U(rs_get_start(addr_rs, rt), ==, start); ASSERT3U(rs_get_end(addr_rs, rt), >, start); return (addr_rs); } static void scan_io_queues_run_one(void *arg) { dsl_scan_io_queue_t *queue = arg; kmutex_t *q_lock = &queue->q_vd->vdev_scan_io_queue_lock; boolean_t suspended = B_FALSE; range_seg_t *rs; scan_io_t *sio; zio_t *zio; list_t sio_list; ASSERT(queue->q_scn->scn_is_sorted); list_create(&sio_list, sizeof (scan_io_t), offsetof(scan_io_t, sio_nodes.sio_list_node)); zio = zio_null(queue->q_scn->scn_zio_root, queue->q_scn->scn_dp->dp_spa, NULL, NULL, NULL, ZIO_FLAG_CANFAIL); mutex_enter(q_lock); queue->q_zio = zio; /* Calculate maximum in-flight bytes for this vdev. */ queue->q_maxinflight_bytes = MAX(1, zfs_scan_vdev_limit * (vdev_get_ndisks(queue->q_vd) - vdev_get_nparity(queue->q_vd))); /* reset per-queue scan statistics for this txg */ queue->q_total_seg_size_this_txg = 0; queue->q_segs_this_txg = 0; queue->q_total_zio_size_this_txg = 0; queue->q_zios_this_txg = 0; /* loop until we run out of time or sios */ while ((rs = scan_io_queue_fetch_ext(queue)) != NULL) { uint64_t seg_start = 0, seg_end = 0; boolean_t more_left; ASSERT(list_is_empty(&sio_list)); /* loop while we still have sios left to process in this rs */ do { scan_io_t *first_sio, *last_sio; /* * We have selected which extent needs to be * processed next. Gather up the corresponding sios. */ more_left = scan_io_queue_gather(queue, rs, &sio_list); ASSERT(!list_is_empty(&sio_list)); first_sio = list_head(&sio_list); last_sio = list_tail(&sio_list); seg_end = SIO_GET_END_OFFSET(last_sio); if (seg_start == 0) seg_start = SIO_GET_OFFSET(first_sio); /* * Issuing sios can take a long time so drop the * queue lock. The sio queue won't be updated by * other threads since we're in syncing context so * we can be sure that our trees will remain exactly * as we left them. */ mutex_exit(q_lock); suspended = scan_io_queue_issue(queue, &sio_list); mutex_enter(q_lock); if (suspended) break; } while (more_left); /* update statistics for debugging purposes */ scan_io_queues_update_seg_stats(queue, seg_start, seg_end); if (suspended) break; } /* * If we were suspended in the middle of processing, * requeue any unfinished sios and exit. */ while ((sio = list_head(&sio_list)) != NULL) { list_remove(&sio_list, sio); scan_io_queue_insert_impl(queue, sio); } queue->q_zio = NULL; mutex_exit(q_lock); zio_nowait(zio); list_destroy(&sio_list); } /* * Performs an emptying run on all scan queues in the pool. This just * punches out one thread per top-level vdev, each of which processes * only that vdev's scan queue. We can parallelize the I/O here because * we know that each queue's I/Os only affect its own top-level vdev. * * This function waits for the queue runs to complete, and must be * called from dsl_scan_sync (or in general, syncing context). */ static void scan_io_queues_run(dsl_scan_t *scn) { spa_t *spa = scn->scn_dp->dp_spa; ASSERT(scn->scn_is_sorted); ASSERT(spa_config_held(spa, SCL_CONFIG, RW_READER)); if (scn->scn_queues_pending == 0) return; if (scn->scn_taskq == NULL) { int nthreads = spa->spa_root_vdev->vdev_children; /* * We need to make this taskq *always* execute as many * threads in parallel as we have top-level vdevs and no * less, otherwise strange serialization of the calls to * scan_io_queues_run_one can occur during spa_sync runs * and that significantly impacts performance. */ scn->scn_taskq = taskq_create("dsl_scan_iss", nthreads, minclsyspri, nthreads, nthreads, TASKQ_PREPOPULATE); } for (uint64_t i = 0; i < spa->spa_root_vdev->vdev_children; i++) { vdev_t *vd = spa->spa_root_vdev->vdev_child[i]; mutex_enter(&vd->vdev_scan_io_queue_lock); if (vd->vdev_scan_io_queue != NULL) { VERIFY(taskq_dispatch(scn->scn_taskq, scan_io_queues_run_one, vd->vdev_scan_io_queue, TQ_SLEEP) != TASKQID_INVALID); } mutex_exit(&vd->vdev_scan_io_queue_lock); } /* * Wait for the queues to finish issuing their IOs for this run * before we return. There may still be IOs in flight at this * point. */ taskq_wait(scn->scn_taskq); } static boolean_t dsl_scan_async_block_should_pause(dsl_scan_t *scn) { uint64_t elapsed_nanosecs; if (zfs_recover) return (B_FALSE); if (zfs_async_block_max_blocks != 0 && scn->scn_visited_this_txg >= zfs_async_block_max_blocks) { return (B_TRUE); } if (zfs_max_async_dedup_frees != 0 && scn->scn_dedup_frees_this_txg >= zfs_max_async_dedup_frees) { return (B_TRUE); } elapsed_nanosecs = gethrtime() - scn->scn_sync_start_time; return (elapsed_nanosecs / NANOSEC > zfs_txg_timeout || (NSEC2MSEC(elapsed_nanosecs) > scn->scn_async_block_min_time_ms && txg_sync_waiting(scn->scn_dp)) || spa_shutting_down(scn->scn_dp->dp_spa)); } static int dsl_scan_free_block_cb(void *arg, const blkptr_t *bp, dmu_tx_t *tx) { dsl_scan_t *scn = arg; if (!scn->scn_is_bptree || (BP_GET_LEVEL(bp) == 0 && BP_GET_TYPE(bp) != DMU_OT_OBJSET)) { if (dsl_scan_async_block_should_pause(scn)) return (SET_ERROR(ERESTART)); } zio_nowait(zio_free_sync(scn->scn_zio_root, scn->scn_dp->dp_spa, dmu_tx_get_txg(tx), bp, 0)); dsl_dir_diduse_space(tx->tx_pool->dp_free_dir, DD_USED_HEAD, -bp_get_dsize_sync(scn->scn_dp->dp_spa, bp), -BP_GET_PSIZE(bp), -BP_GET_UCSIZE(bp), tx); scn->scn_visited_this_txg++; if (BP_GET_DEDUP(bp)) scn->scn_dedup_frees_this_txg++; return (0); } static void dsl_scan_update_stats(dsl_scan_t *scn) { spa_t *spa = scn->scn_dp->dp_spa; uint64_t i; uint64_t seg_size_total = 0, zio_size_total = 0; uint64_t seg_count_total = 0, zio_count_total = 0; for (i = 0; i < spa->spa_root_vdev->vdev_children; i++) { vdev_t *vd = spa->spa_root_vdev->vdev_child[i]; dsl_scan_io_queue_t *queue = vd->vdev_scan_io_queue; if (queue == NULL) continue; seg_size_total += queue->q_total_seg_size_this_txg; zio_size_total += queue->q_total_zio_size_this_txg; seg_count_total += queue->q_segs_this_txg; zio_count_total += queue->q_zios_this_txg; } if (seg_count_total == 0 || zio_count_total == 0) { scn->scn_avg_seg_size_this_txg = 0; scn->scn_avg_zio_size_this_txg = 0; scn->scn_segs_this_txg = 0; scn->scn_zios_this_txg = 0; return; } scn->scn_avg_seg_size_this_txg = seg_size_total / seg_count_total; scn->scn_avg_zio_size_this_txg = zio_size_total / zio_count_total; scn->scn_segs_this_txg = seg_count_total; scn->scn_zios_this_txg = zio_count_total; } static int bpobj_dsl_scan_free_block_cb(void *arg, const blkptr_t *bp, boolean_t bp_freed, dmu_tx_t *tx) { ASSERT(!bp_freed); return (dsl_scan_free_block_cb(arg, bp, tx)); } static int dsl_scan_obsolete_block_cb(void *arg, const blkptr_t *bp, boolean_t bp_freed, dmu_tx_t *tx) { ASSERT(!bp_freed); dsl_scan_t *scn = arg; const dva_t *dva = &bp->blk_dva[0]; if (dsl_scan_async_block_should_pause(scn)) return (SET_ERROR(ERESTART)); spa_vdev_indirect_mark_obsolete(scn->scn_dp->dp_spa, DVA_GET_VDEV(dva), DVA_GET_OFFSET(dva), DVA_GET_ASIZE(dva), tx); scn->scn_visited_this_txg++; return (0); } boolean_t dsl_scan_active(dsl_scan_t *scn) { spa_t *spa = scn->scn_dp->dp_spa; uint64_t used = 0, comp, uncomp; boolean_t clones_left; if (spa->spa_load_state != SPA_LOAD_NONE) return (B_FALSE); if (spa_shutting_down(spa)) return (B_FALSE); if ((dsl_scan_is_running(scn) && !dsl_scan_is_paused_scrub(scn)) || (scn->scn_async_destroying && !scn->scn_async_stalled)) return (B_TRUE); if (spa_version(scn->scn_dp->dp_spa) >= SPA_VERSION_DEADLISTS) { (void) bpobj_space(&scn->scn_dp->dp_free_bpobj, &used, &comp, &uncomp); } clones_left = spa_livelist_delete_check(spa); return ((used != 0) || (clones_left)); } static boolean_t dsl_scan_check_deferred(vdev_t *vd) { boolean_t need_resilver = B_FALSE; for (int c = 0; c < vd->vdev_children; c++) { need_resilver |= dsl_scan_check_deferred(vd->vdev_child[c]); } if (!vdev_is_concrete(vd) || vd->vdev_aux || !vd->vdev_ops->vdev_op_leaf) return (need_resilver); if (!vd->vdev_resilver_deferred) need_resilver = B_TRUE; return (need_resilver); } static boolean_t dsl_scan_need_resilver(spa_t *spa, const dva_t *dva, size_t psize, uint64_t phys_birth) { vdev_t *vd; vd = vdev_lookup_top(spa, DVA_GET_VDEV(dva)); if (vd->vdev_ops == &vdev_indirect_ops) { /* * The indirect vdev can point to multiple * vdevs. For simplicity, always create * the resilver zio_t. zio_vdev_io_start() * will bypass the child resilver i/o's if * they are on vdevs that don't have DTL's. */ return (B_TRUE); } if (DVA_GET_GANG(dva)) { /* * Gang members may be spread across multiple * vdevs, so the best estimate we have is the * scrub range, which has already been checked. * XXX -- it would be better to change our * allocation policy to ensure that all * gang members reside on the same vdev. */ return (B_TRUE); } /* * Check if the top-level vdev must resilver this offset. * When the offset does not intersect with a dirty leaf DTL * then it may be possible to skip the resilver IO. The psize * is provided instead of asize to simplify the check for RAIDZ. */ if (!vdev_dtl_need_resilver(vd, dva, psize, phys_birth)) return (B_FALSE); /* * Check that this top-level vdev has a device under it which * is resilvering and is not deferred. */ if (!dsl_scan_check_deferred(vd)) return (B_FALSE); return (B_TRUE); } static int dsl_process_async_destroys(dsl_pool_t *dp, dmu_tx_t *tx) { dsl_scan_t *scn = dp->dp_scan; spa_t *spa = dp->dp_spa; int err = 0; if (spa_suspend_async_destroy(spa)) return (0); if (zfs_free_bpobj_enabled && spa_version(spa) >= SPA_VERSION_DEADLISTS) { scn->scn_is_bptree = B_FALSE; scn->scn_async_block_min_time_ms = zfs_free_min_time_ms; scn->scn_zio_root = zio_root(spa, NULL, NULL, ZIO_FLAG_MUSTSUCCEED); err = bpobj_iterate(&dp->dp_free_bpobj, bpobj_dsl_scan_free_block_cb, scn, tx); VERIFY0(zio_wait(scn->scn_zio_root)); scn->scn_zio_root = NULL; if (err != 0 && err != ERESTART) zfs_panic_recover("error %u from bpobj_iterate()", err); } if (err == 0 && spa_feature_is_active(spa, SPA_FEATURE_ASYNC_DESTROY)) { ASSERT(scn->scn_async_destroying); scn->scn_is_bptree = B_TRUE; scn->scn_zio_root = zio_root(spa, NULL, NULL, ZIO_FLAG_MUSTSUCCEED); err = bptree_iterate(dp->dp_meta_objset, dp->dp_bptree_obj, B_TRUE, dsl_scan_free_block_cb, scn, tx); VERIFY0(zio_wait(scn->scn_zio_root)); scn->scn_zio_root = NULL; if (err == EIO || err == ECKSUM) { err = 0; } else if (err != 0 && err != ERESTART) { zfs_panic_recover("error %u from " "traverse_dataset_destroyed()", err); } if (bptree_is_empty(dp->dp_meta_objset, dp->dp_bptree_obj)) { /* finished; deactivate async destroy feature */ spa_feature_decr(spa, SPA_FEATURE_ASYNC_DESTROY, tx); ASSERT(!spa_feature_is_active(spa, SPA_FEATURE_ASYNC_DESTROY)); VERIFY0(zap_remove(dp->dp_meta_objset, DMU_POOL_DIRECTORY_OBJECT, DMU_POOL_BPTREE_OBJ, tx)); VERIFY0(bptree_free(dp->dp_meta_objset, dp->dp_bptree_obj, tx)); dp->dp_bptree_obj = 0; scn->scn_async_destroying = B_FALSE; scn->scn_async_stalled = B_FALSE; } else { /* * If we didn't make progress, mark the async * destroy as stalled, so that we will not initiate * a spa_sync() on its behalf. Note that we only * check this if we are not finished, because if the * bptree had no blocks for us to visit, we can * finish without "making progress". */ scn->scn_async_stalled = (scn->scn_visited_this_txg == 0); } } if (scn->scn_visited_this_txg) { zfs_dbgmsg("freed %llu blocks in %llums from " "free_bpobj/bptree on %s in txg %llu; err=%u", (longlong_t)scn->scn_visited_this_txg, (longlong_t) NSEC2MSEC(gethrtime() - scn->scn_sync_start_time), spa->spa_name, (longlong_t)tx->tx_txg, err); scn->scn_visited_this_txg = 0; scn->scn_dedup_frees_this_txg = 0; /* * Write out changes to the DDT that may be required as a * result of the blocks freed. This ensures that the DDT * is clean when a scrub/resilver runs. */ ddt_sync(spa, tx->tx_txg); } if (err != 0) return (err); if (dp->dp_free_dir != NULL && !scn->scn_async_destroying && zfs_free_leak_on_eio && (dsl_dir_phys(dp->dp_free_dir)->dd_used_bytes != 0 || dsl_dir_phys(dp->dp_free_dir)->dd_compressed_bytes != 0 || dsl_dir_phys(dp->dp_free_dir)->dd_uncompressed_bytes != 0)) { /* * We have finished background destroying, but there is still * some space left in the dp_free_dir. Transfer this leaked * space to the dp_leak_dir. */ if (dp->dp_leak_dir == NULL) { rrw_enter(&dp->dp_config_rwlock, RW_WRITER, FTAG); (void) dsl_dir_create_sync(dp, dp->dp_root_dir, LEAK_DIR_NAME, tx); VERIFY0(dsl_pool_open_special_dir(dp, LEAK_DIR_NAME, &dp->dp_leak_dir)); rrw_exit(&dp->dp_config_rwlock, FTAG); } dsl_dir_diduse_space(dp->dp_leak_dir, DD_USED_HEAD, dsl_dir_phys(dp->dp_free_dir)->dd_used_bytes, dsl_dir_phys(dp->dp_free_dir)->dd_compressed_bytes, dsl_dir_phys(dp->dp_free_dir)->dd_uncompressed_bytes, tx); dsl_dir_diduse_space(dp->dp_free_dir, DD_USED_HEAD, -dsl_dir_phys(dp->dp_free_dir)->dd_used_bytes, -dsl_dir_phys(dp->dp_free_dir)->dd_compressed_bytes, -dsl_dir_phys(dp->dp_free_dir)->dd_uncompressed_bytes, tx); } if (dp->dp_free_dir != NULL && !scn->scn_async_destroying && !spa_livelist_delete_check(spa)) { /* finished; verify that space accounting went to zero */ ASSERT0(dsl_dir_phys(dp->dp_free_dir)->dd_used_bytes); ASSERT0(dsl_dir_phys(dp->dp_free_dir)->dd_compressed_bytes); ASSERT0(dsl_dir_phys(dp->dp_free_dir)->dd_uncompressed_bytes); } spa_notify_waiters(spa); EQUIV(bpobj_is_open(&dp->dp_obsolete_bpobj), 0 == zap_contains(dp->dp_meta_objset, DMU_POOL_DIRECTORY_OBJECT, DMU_POOL_OBSOLETE_BPOBJ)); if (err == 0 && bpobj_is_open(&dp->dp_obsolete_bpobj)) { ASSERT(spa_feature_is_active(dp->dp_spa, SPA_FEATURE_OBSOLETE_COUNTS)); scn->scn_is_bptree = B_FALSE; scn->scn_async_block_min_time_ms = zfs_obsolete_min_time_ms; err = bpobj_iterate(&dp->dp_obsolete_bpobj, dsl_scan_obsolete_block_cb, scn, tx); if (err != 0 && err != ERESTART) zfs_panic_recover("error %u from bpobj_iterate()", err); if (bpobj_is_empty(&dp->dp_obsolete_bpobj)) dsl_pool_destroy_obsolete_bpobj(dp, tx); } return (0); } /* * This is the primary entry point for scans that is called from syncing * context. Scans must happen entirely during syncing context so that we * can guarantee that blocks we are currently scanning will not change out * from under us. While a scan is active, this function controls how quickly * transaction groups proceed, instead of the normal handling provided by * txg_sync_thread(). */ void dsl_scan_sync(dsl_pool_t *dp, dmu_tx_t *tx) { int err = 0; dsl_scan_t *scn = dp->dp_scan; spa_t *spa = dp->dp_spa; state_sync_type_t sync_type = SYNC_OPTIONAL; if (spa->spa_resilver_deferred && !spa_feature_is_active(dp->dp_spa, SPA_FEATURE_RESILVER_DEFER)) spa_feature_incr(spa, SPA_FEATURE_RESILVER_DEFER, tx); /* * Check for scn_restart_txg before checking spa_load_state, so * that we can restart an old-style scan while the pool is being * imported (see dsl_scan_init). We also restart scans if there * is a deferred resilver and the user has manually disabled * deferred resilvers via the tunable. */ if (dsl_scan_restarting(scn, tx) || (spa->spa_resilver_deferred && zfs_resilver_disable_defer)) { pool_scan_func_t func = POOL_SCAN_SCRUB; dsl_scan_done(scn, B_FALSE, tx); if (vdev_resilver_needed(spa->spa_root_vdev, NULL, NULL)) func = POOL_SCAN_RESILVER; zfs_dbgmsg("restarting scan func=%u on %s txg=%llu", func, dp->dp_spa->spa_name, (longlong_t)tx->tx_txg); dsl_scan_setup_sync(&func, tx); } /* * Only process scans in sync pass 1. */ if (spa_sync_pass(spa) > 1) return; /* * If the spa is shutting down, then stop scanning. This will * ensure that the scan does not dirty any new data during the * shutdown phase. */ if (spa_shutting_down(spa)) return; /* * If the scan is inactive due to a stalled async destroy, try again. */ if (!scn->scn_async_stalled && !dsl_scan_active(scn)) return; /* reset scan statistics */ scn->scn_visited_this_txg = 0; scn->scn_dedup_frees_this_txg = 0; scn->scn_holes_this_txg = 0; scn->scn_lt_min_this_txg = 0; scn->scn_gt_max_this_txg = 0; scn->scn_ddt_contained_this_txg = 0; scn->scn_objsets_visited_this_txg = 0; scn->scn_avg_seg_size_this_txg = 0; scn->scn_segs_this_txg = 0; scn->scn_avg_zio_size_this_txg = 0; scn->scn_zios_this_txg = 0; scn->scn_suspending = B_FALSE; scn->scn_sync_start_time = gethrtime(); spa->spa_scrub_active = B_TRUE; /* * First process the async destroys. If we suspend, don't do * any scrubbing or resilvering. This ensures that there are no * async destroys while we are scanning, so the scan code doesn't * have to worry about traversing it. It is also faster to free the * blocks than to scrub them. */ err = dsl_process_async_destroys(dp, tx); if (err != 0) return; if (!dsl_scan_is_running(scn) || dsl_scan_is_paused_scrub(scn)) return; /* * Wait a few txgs after importing to begin scanning so that * we can get the pool imported quickly. */ if (spa->spa_syncing_txg < spa->spa_first_txg + SCAN_IMPORT_WAIT_TXGS) return; /* * zfs_scan_suspend_progress can be set to disable scan progress. * We don't want to spin the txg_sync thread, so we add a delay * here to simulate the time spent doing a scan. This is mostly * useful for testing and debugging. */ if (zfs_scan_suspend_progress) { uint64_t scan_time_ns = gethrtime() - scn->scn_sync_start_time; int mintime = (scn->scn_phys.scn_func == POOL_SCAN_RESILVER) ? zfs_resilver_min_time_ms : zfs_scrub_min_time_ms; while (zfs_scan_suspend_progress && !txg_sync_waiting(scn->scn_dp) && !spa_shutting_down(scn->scn_dp->dp_spa) && NSEC2MSEC(scan_time_ns) < mintime) { delay(hz); scan_time_ns = gethrtime() - scn->scn_sync_start_time; } return; } /* * It is possible to switch from unsorted to sorted at any time, * but afterwards the scan will remain sorted unless reloaded from * a checkpoint after a reboot. */ if (!zfs_scan_legacy) { scn->scn_is_sorted = B_TRUE; if (scn->scn_last_checkpoint == 0) scn->scn_last_checkpoint = ddi_get_lbolt(); } /* * For sorted scans, determine what kind of work we will be doing * this txg based on our memory limitations and whether or not we * need to perform a checkpoint. */ if (scn->scn_is_sorted) { /* * If we are over our checkpoint interval, set scn_clearing * so that we can begin checkpointing immediately. The * checkpoint allows us to save a consistent bookmark * representing how much data we have scrubbed so far. * Otherwise, use the memory limit to determine if we should * scan for metadata or start issue scrub IOs. We accumulate * metadata until we hit our hard memory limit at which point * we issue scrub IOs until we are at our soft memory limit. */ if (scn->scn_checkpointing || ddi_get_lbolt() - scn->scn_last_checkpoint > SEC_TO_TICK(zfs_scan_checkpoint_intval)) { if (!scn->scn_checkpointing) zfs_dbgmsg("begin scan checkpoint for %s", spa->spa_name); scn->scn_checkpointing = B_TRUE; scn->scn_clearing = B_TRUE; } else { boolean_t should_clear = dsl_scan_should_clear(scn); if (should_clear && !scn->scn_clearing) { zfs_dbgmsg("begin scan clearing for %s", spa->spa_name); scn->scn_clearing = B_TRUE; } else if (!should_clear && scn->scn_clearing) { zfs_dbgmsg("finish scan clearing for %s", spa->spa_name); scn->scn_clearing = B_FALSE; } } } else { ASSERT0(scn->scn_checkpointing); ASSERT0(scn->scn_clearing); } if (!scn->scn_clearing && scn->scn_done_txg == 0) { /* Need to scan metadata for more blocks to scrub */ dsl_scan_phys_t *scnp = &scn->scn_phys; taskqid_t prefetch_tqid; /* * Recalculate the max number of in-flight bytes for pool-wide * scanning operations (minimum 1MB). Limits for the issuing * phase are done per top-level vdev and are handled separately. */ scn->scn_maxinflight_bytes = MAX(zfs_scan_vdev_limit * dsl_scan_count_data_disks(spa->spa_root_vdev), 1ULL << 20); if (scnp->scn_ddt_bookmark.ddb_class <= scnp->scn_ddt_class_max) { ASSERT(ZB_IS_ZERO(&scnp->scn_bookmark)); zfs_dbgmsg("doing scan sync for %s txg %llu; " "ddt bm=%llu/%llu/%llu/%llx", spa->spa_name, (longlong_t)tx->tx_txg, (longlong_t)scnp->scn_ddt_bookmark.ddb_class, (longlong_t)scnp->scn_ddt_bookmark.ddb_type, (longlong_t)scnp->scn_ddt_bookmark.ddb_checksum, (longlong_t)scnp->scn_ddt_bookmark.ddb_cursor); } else { zfs_dbgmsg("doing scan sync for %s txg %llu; " "bm=%llu/%llu/%llu/%llu", spa->spa_name, (longlong_t)tx->tx_txg, (longlong_t)scnp->scn_bookmark.zb_objset, (longlong_t)scnp->scn_bookmark.zb_object, (longlong_t)scnp->scn_bookmark.zb_level, (longlong_t)scnp->scn_bookmark.zb_blkid); } scn->scn_zio_root = zio_root(dp->dp_spa, NULL, NULL, ZIO_FLAG_CANFAIL); scn->scn_prefetch_stop = B_FALSE; prefetch_tqid = taskq_dispatch(dp->dp_sync_taskq, dsl_scan_prefetch_thread, scn, TQ_SLEEP); ASSERT(prefetch_tqid != TASKQID_INVALID); dsl_pool_config_enter(dp, FTAG); dsl_scan_visit(scn, tx); dsl_pool_config_exit(dp, FTAG); mutex_enter(&dp->dp_spa->spa_scrub_lock); scn->scn_prefetch_stop = B_TRUE; cv_broadcast(&spa->spa_scrub_io_cv); mutex_exit(&dp->dp_spa->spa_scrub_lock); taskq_wait_id(dp->dp_sync_taskq, prefetch_tqid); (void) zio_wait(scn->scn_zio_root); scn->scn_zio_root = NULL; zfs_dbgmsg("scan visited %llu blocks of %s in %llums " "(%llu os's, %llu holes, %llu < mintxg, " "%llu in ddt, %llu > maxtxg)", (longlong_t)scn->scn_visited_this_txg, spa->spa_name, (longlong_t)NSEC2MSEC(gethrtime() - scn->scn_sync_start_time), (longlong_t)scn->scn_objsets_visited_this_txg, (longlong_t)scn->scn_holes_this_txg, (longlong_t)scn->scn_lt_min_this_txg, (longlong_t)scn->scn_ddt_contained_this_txg, (longlong_t)scn->scn_gt_max_this_txg); if (!scn->scn_suspending) { ASSERT0(avl_numnodes(&scn->scn_queue)); scn->scn_done_txg = tx->tx_txg + 1; if (scn->scn_is_sorted) { scn->scn_checkpointing = B_TRUE; scn->scn_clearing = B_TRUE; } zfs_dbgmsg("scan complete for %s txg %llu", spa->spa_name, (longlong_t)tx->tx_txg); } } else if (scn->scn_is_sorted && scn->scn_queues_pending != 0) { ASSERT(scn->scn_clearing); /* need to issue scrubbing IOs from per-vdev queues */ scn->scn_zio_root = zio_root(dp->dp_spa, NULL, NULL, ZIO_FLAG_CANFAIL); scan_io_queues_run(scn); (void) zio_wait(scn->scn_zio_root); scn->scn_zio_root = NULL; /* calculate and dprintf the current memory usage */ (void) dsl_scan_should_clear(scn); dsl_scan_update_stats(scn); zfs_dbgmsg("scan issued %llu blocks for %s (%llu segs) " "in %llums (avg_block_size = %llu, avg_seg_size = %llu)", (longlong_t)scn->scn_zios_this_txg, spa->spa_name, (longlong_t)scn->scn_segs_this_txg, (longlong_t)NSEC2MSEC(gethrtime() - scn->scn_sync_start_time), (longlong_t)scn->scn_avg_zio_size_this_txg, (longlong_t)scn->scn_avg_seg_size_this_txg); } else if (scn->scn_done_txg != 0 && scn->scn_done_txg <= tx->tx_txg) { /* Finished with everything. Mark the scrub as complete */ zfs_dbgmsg("scan issuing complete txg %llu for %s", (longlong_t)tx->tx_txg, spa->spa_name); ASSERT3U(scn->scn_done_txg, !=, 0); ASSERT0(spa->spa_scrub_inflight); ASSERT0(scn->scn_queues_pending); dsl_scan_done(scn, B_TRUE, tx); sync_type = SYNC_MANDATORY; } dsl_scan_sync_state(scn, tx, sync_type); } static void count_block_issued(spa_t *spa, const blkptr_t *bp, boolean_t all) { /* * Don't count embedded bp's, since we already did the work of * scanning these when we scanned the containing block. */ if (BP_IS_EMBEDDED(bp)) return; /* * Update the spa's stats on how many bytes we have issued. * Sequential scrubs create a zio for each DVA of the bp. Each * of these will include all DVAs for repair purposes, but the * zio code will only try the first one unless there is an issue. * Therefore, we should only count the first DVA for these IOs. */ atomic_add_64(&spa->spa_scan_pass_issued, all ? BP_GET_ASIZE(bp) : DVA_GET_ASIZE(&bp->blk_dva[0])); } static void count_block(zfs_all_blkstats_t *zab, const blkptr_t *bp) { /* * If we resume after a reboot, zab will be NULL; don't record * incomplete stats in that case. */ if (zab == NULL) return; for (int i = 0; i < 4; i++) { int l = (i < 2) ? BP_GET_LEVEL(bp) : DN_MAX_LEVELS; int t = (i & 1) ? BP_GET_TYPE(bp) : DMU_OT_TOTAL; if (t & DMU_OT_NEWTYPE) t = DMU_OT_OTHER; zfs_blkstat_t *zb = &zab->zab_type[l][t]; int equal; zb->zb_count++; zb->zb_asize += BP_GET_ASIZE(bp); zb->zb_lsize += BP_GET_LSIZE(bp); zb->zb_psize += BP_GET_PSIZE(bp); zb->zb_gangs += BP_COUNT_GANG(bp); switch (BP_GET_NDVAS(bp)) { case 2: if (DVA_GET_VDEV(&bp->blk_dva[0]) == DVA_GET_VDEV(&bp->blk_dva[1])) zb->zb_ditto_2_of_2_samevdev++; break; case 3: equal = (DVA_GET_VDEV(&bp->blk_dva[0]) == DVA_GET_VDEV(&bp->blk_dva[1])) + (DVA_GET_VDEV(&bp->blk_dva[0]) == DVA_GET_VDEV(&bp->blk_dva[2])) + (DVA_GET_VDEV(&bp->blk_dva[1]) == DVA_GET_VDEV(&bp->blk_dva[2])); if (equal == 1) zb->zb_ditto_2_of_3_samevdev++; else if (equal == 3) zb->zb_ditto_3_of_3_samevdev++; break; } } } static void scan_io_queue_insert_impl(dsl_scan_io_queue_t *queue, scan_io_t *sio) { avl_index_t idx; dsl_scan_t *scn = queue->q_scn; ASSERT(MUTEX_HELD(&queue->q_vd->vdev_scan_io_queue_lock)); if (unlikely(avl_is_empty(&queue->q_sios_by_addr))) atomic_add_64(&scn->scn_queues_pending, 1); if (avl_find(&queue->q_sios_by_addr, sio, &idx) != NULL) { /* block is already scheduled for reading */ sio_free(sio); return; } avl_insert(&queue->q_sios_by_addr, sio, idx); queue->q_sio_memused += SIO_GET_MUSED(sio); range_tree_add(queue->q_exts_by_addr, SIO_GET_OFFSET(sio), SIO_GET_ASIZE(sio)); } /* * Given all the info we got from our metadata scanning process, we * construct a scan_io_t and insert it into the scan sorting queue. The * I/O must already be suitable for us to process. This is controlled * by dsl_scan_enqueue(). */ static void scan_io_queue_insert(dsl_scan_io_queue_t *queue, const blkptr_t *bp, int dva_i, int zio_flags, const zbookmark_phys_t *zb) { scan_io_t *sio = sio_alloc(BP_GET_NDVAS(bp)); ASSERT0(BP_IS_GANG(bp)); ASSERT(MUTEX_HELD(&queue->q_vd->vdev_scan_io_queue_lock)); bp2sio(bp, sio, dva_i); sio->sio_flags = zio_flags; sio->sio_zb = *zb; queue->q_last_ext_addr = -1; scan_io_queue_insert_impl(queue, sio); } /* * Given a set of I/O parameters as discovered by the metadata traversal * process, attempts to place the I/O into the sorted queues (if allowed), * or immediately executes the I/O. */ static void dsl_scan_enqueue(dsl_pool_t *dp, const blkptr_t *bp, int zio_flags, const zbookmark_phys_t *zb) { spa_t *spa = dp->dp_spa; ASSERT(!BP_IS_EMBEDDED(bp)); /* * Gang blocks are hard to issue sequentially, so we just issue them * here immediately instead of queuing them. */ if (!dp->dp_scan->scn_is_sorted || BP_IS_GANG(bp)) { scan_exec_io(dp, bp, zio_flags, zb, NULL); return; } for (int i = 0; i < BP_GET_NDVAS(bp); i++) { dva_t dva; vdev_t *vdev; dva = bp->blk_dva[i]; vdev = vdev_lookup_top(spa, DVA_GET_VDEV(&dva)); ASSERT(vdev != NULL); mutex_enter(&vdev->vdev_scan_io_queue_lock); if (vdev->vdev_scan_io_queue == NULL) vdev->vdev_scan_io_queue = scan_io_queue_create(vdev); ASSERT(dp->dp_scan != NULL); scan_io_queue_insert(vdev->vdev_scan_io_queue, bp, i, zio_flags, zb); mutex_exit(&vdev->vdev_scan_io_queue_lock); } } static int dsl_scan_scrub_cb(dsl_pool_t *dp, const blkptr_t *bp, const zbookmark_phys_t *zb) { dsl_scan_t *scn = dp->dp_scan; spa_t *spa = dp->dp_spa; uint64_t phys_birth = BP_PHYSICAL_BIRTH(bp); size_t psize = BP_GET_PSIZE(bp); boolean_t needs_io = B_FALSE; int zio_flags = ZIO_FLAG_SCAN_THREAD | ZIO_FLAG_RAW | ZIO_FLAG_CANFAIL; count_block(dp->dp_blkstats, bp); if (phys_birth <= scn->scn_phys.scn_min_txg || phys_birth >= scn->scn_phys.scn_max_txg) { count_block_issued(spa, bp, B_TRUE); return (0); } /* Embedded BP's have phys_birth==0, so we reject them above. */ ASSERT(!BP_IS_EMBEDDED(bp)); ASSERT(DSL_SCAN_IS_SCRUB_RESILVER(scn)); if (scn->scn_phys.scn_func == POOL_SCAN_SCRUB) { zio_flags |= ZIO_FLAG_SCRUB; needs_io = B_TRUE; } else { ASSERT3U(scn->scn_phys.scn_func, ==, POOL_SCAN_RESILVER); zio_flags |= ZIO_FLAG_RESILVER; needs_io = B_FALSE; } /* If it's an intent log block, failure is expected. */ if (zb->zb_level == ZB_ZIL_LEVEL) zio_flags |= ZIO_FLAG_SPECULATIVE; for (int d = 0; d < BP_GET_NDVAS(bp); d++) { const dva_t *dva = &bp->blk_dva[d]; /* * Keep track of how much data we've examined so that * zpool(8) status can make useful progress reports. */ uint64_t asize = DVA_GET_ASIZE(dva); scn->scn_phys.scn_examined += asize; spa->spa_scan_pass_exam += asize; /* if it's a resilver, this may not be in the target range */ if (!needs_io) needs_io = dsl_scan_need_resilver(spa, dva, psize, phys_birth); } if (needs_io && !zfs_no_scrub_io) { dsl_scan_enqueue(dp, bp, zio_flags, zb); } else { count_block_issued(spa, bp, B_TRUE); } /* do not relocate this block */ return (0); } static void dsl_scan_scrub_done(zio_t *zio) { spa_t *spa = zio->io_spa; blkptr_t *bp = zio->io_bp; dsl_scan_io_queue_t *queue = zio->io_private; abd_free(zio->io_abd); if (queue == NULL) { mutex_enter(&spa->spa_scrub_lock); ASSERT3U(spa->spa_scrub_inflight, >=, BP_GET_PSIZE(bp)); spa->spa_scrub_inflight -= BP_GET_PSIZE(bp); cv_broadcast(&spa->spa_scrub_io_cv); mutex_exit(&spa->spa_scrub_lock); } else { mutex_enter(&queue->q_vd->vdev_scan_io_queue_lock); ASSERT3U(queue->q_inflight_bytes, >=, BP_GET_PSIZE(bp)); queue->q_inflight_bytes -= BP_GET_PSIZE(bp); cv_broadcast(&queue->q_zio_cv); mutex_exit(&queue->q_vd->vdev_scan_io_queue_lock); } if (zio->io_error && (zio->io_error != ECKSUM || !(zio->io_flags & ZIO_FLAG_SPECULATIVE))) { atomic_inc_64(&spa->spa_dsl_pool->dp_scan->scn_phys.scn_errors); } } /* * Given a scanning zio's information, executes the zio. The zio need * not necessarily be only sortable, this function simply executes the * zio, no matter what it is. The optional queue argument allows the * caller to specify that they want per top level vdev IO rate limiting * instead of the legacy global limiting. */ static void scan_exec_io(dsl_pool_t *dp, const blkptr_t *bp, int zio_flags, const zbookmark_phys_t *zb, dsl_scan_io_queue_t *queue) { spa_t *spa = dp->dp_spa; dsl_scan_t *scn = dp->dp_scan; size_t size = BP_GET_PSIZE(bp); abd_t *data = abd_alloc_for_io(size, B_FALSE); zio_t *pio; if (queue == NULL) { ASSERT3U(scn->scn_maxinflight_bytes, >, 0); mutex_enter(&spa->spa_scrub_lock); while (spa->spa_scrub_inflight >= scn->scn_maxinflight_bytes) cv_wait(&spa->spa_scrub_io_cv, &spa->spa_scrub_lock); spa->spa_scrub_inflight += BP_GET_PSIZE(bp); mutex_exit(&spa->spa_scrub_lock); pio = scn->scn_zio_root; } else { kmutex_t *q_lock = &queue->q_vd->vdev_scan_io_queue_lock; ASSERT3U(queue->q_maxinflight_bytes, >, 0); mutex_enter(q_lock); while (queue->q_inflight_bytes >= queue->q_maxinflight_bytes) cv_wait(&queue->q_zio_cv, q_lock); queue->q_inflight_bytes += BP_GET_PSIZE(bp); pio = queue->q_zio; mutex_exit(q_lock); } ASSERT(pio != NULL); count_block_issued(spa, bp, queue == NULL); zio_nowait(zio_read(pio, spa, bp, data, size, dsl_scan_scrub_done, queue, ZIO_PRIORITY_SCRUB, zio_flags, zb)); } /* * This is the primary extent sorting algorithm. We balance two parameters: * 1) how many bytes of I/O are in an extent * 2) how well the extent is filled with I/O (as a fraction of its total size) * Since we allow extents to have gaps between their constituent I/Os, it's * possible to have a fairly large extent that contains the same amount of * I/O bytes than a much smaller extent, which just packs the I/O more tightly. * The algorithm sorts based on a score calculated from the extent's size, * the relative fill volume (in %) and a "fill weight" parameter that controls * the split between whether we prefer larger extents or more well populated * extents: * * SCORE = FILL_IN_BYTES + (FILL_IN_PERCENT * FILL_IN_BYTES * FILL_WEIGHT) * * Example: * 1) assume extsz = 64 MiB * 2) assume fill = 32 MiB (extent is half full) * 3) assume fill_weight = 3 * 4) SCORE = 32M + (((32M * 100) / 64M) * 3 * 32M) / 100 * SCORE = 32M + (50 * 3 * 32M) / 100 * SCORE = 32M + (4800M / 100) * SCORE = 32M + 48M * ^ ^ * | +--- final total relative fill-based score * +--------- final total fill-based score * SCORE = 80M * * As can be seen, at fill_ratio=3, the algorithm is slightly biased towards * extents that are more completely filled (in a 3:2 ratio) vs just larger. * Note that as an optimization, we replace multiplication and division by * 100 with bitshifting by 7 (which effectively multiplies and divides by 128). * * Since we do not care if one extent is only few percent better than another, * compress the score into 6 bits via binary logarithm AKA highbit64() and * put into otherwise unused due to ashift high bits of offset. This allows * to reduce q_exts_by_size B-tree elements to only 64 bits and compare them * with single operation. Plus it makes scrubs more sequential and reduces * chances that minor extent change move it within the B-tree. */ static int ext_size_compare(const void *x, const void *y) { const uint64_t *a = x, *b = y; return (TREE_CMP(*a, *b)); } static void ext_size_create(range_tree_t *rt, void *arg) { (void) rt; zfs_btree_t *size_tree = arg; zfs_btree_create(size_tree, ext_size_compare, sizeof (uint64_t)); } static void ext_size_destroy(range_tree_t *rt, void *arg) { (void) rt; zfs_btree_t *size_tree = arg; ASSERT0(zfs_btree_numnodes(size_tree)); zfs_btree_destroy(size_tree); } static uint64_t ext_size_value(range_tree_t *rt, range_seg_gap_t *rsg) { (void) rt; uint64_t size = rsg->rs_end - rsg->rs_start; uint64_t score = rsg->rs_fill + ((((rsg->rs_fill << 7) / size) * fill_weight * rsg->rs_fill) >> 7); ASSERT3U(rt->rt_shift, >=, 8); return (((uint64_t)(64 - highbit64(score)) << 56) | rsg->rs_start); } static void ext_size_add(range_tree_t *rt, range_seg_t *rs, void *arg) { zfs_btree_t *size_tree = arg; ASSERT3U(rt->rt_type, ==, RANGE_SEG_GAP); uint64_t v = ext_size_value(rt, (range_seg_gap_t *)rs); zfs_btree_add(size_tree, &v); } static void ext_size_remove(range_tree_t *rt, range_seg_t *rs, void *arg) { zfs_btree_t *size_tree = arg; ASSERT3U(rt->rt_type, ==, RANGE_SEG_GAP); uint64_t v = ext_size_value(rt, (range_seg_gap_t *)rs); zfs_btree_remove(size_tree, &v); } static void ext_size_vacate(range_tree_t *rt, void *arg) { zfs_btree_t *size_tree = arg; zfs_btree_clear(size_tree); zfs_btree_destroy(size_tree); ext_size_create(rt, arg); } static const range_tree_ops_t ext_size_ops = { .rtop_create = ext_size_create, .rtop_destroy = ext_size_destroy, .rtop_add = ext_size_add, .rtop_remove = ext_size_remove, .rtop_vacate = ext_size_vacate }; /* * Comparator for the q_sios_by_addr tree. Sorting is simply performed * based on LBA-order (from lowest to highest). */ static int sio_addr_compare(const void *x, const void *y) { const scan_io_t *a = x, *b = y; return (TREE_CMP(SIO_GET_OFFSET(a), SIO_GET_OFFSET(b))); } /* IO queues are created on demand when they are needed. */ static dsl_scan_io_queue_t * scan_io_queue_create(vdev_t *vd) { dsl_scan_t *scn = vd->vdev_spa->spa_dsl_pool->dp_scan; dsl_scan_io_queue_t *q = kmem_zalloc(sizeof (*q), KM_SLEEP); q->q_scn = scn; q->q_vd = vd; q->q_sio_memused = 0; q->q_last_ext_addr = -1; cv_init(&q->q_zio_cv, NULL, CV_DEFAULT, NULL); q->q_exts_by_addr = range_tree_create_gap(&ext_size_ops, RANGE_SEG_GAP, &q->q_exts_by_size, 0, vd->vdev_ashift, zfs_scan_max_ext_gap); avl_create(&q->q_sios_by_addr, sio_addr_compare, sizeof (scan_io_t), offsetof(scan_io_t, sio_nodes.sio_addr_node)); return (q); } /* * Destroys a scan queue and all segments and scan_io_t's contained in it. * No further execution of I/O occurs, anything pending in the queue is * simply freed without being executed. */ void dsl_scan_io_queue_destroy(dsl_scan_io_queue_t *queue) { dsl_scan_t *scn = queue->q_scn; scan_io_t *sio; void *cookie = NULL; ASSERT(MUTEX_HELD(&queue->q_vd->vdev_scan_io_queue_lock)); if (!avl_is_empty(&queue->q_sios_by_addr)) atomic_add_64(&scn->scn_queues_pending, -1); while ((sio = avl_destroy_nodes(&queue->q_sios_by_addr, &cookie)) != NULL) { ASSERT(range_tree_contains(queue->q_exts_by_addr, SIO_GET_OFFSET(sio), SIO_GET_ASIZE(sio))); queue->q_sio_memused -= SIO_GET_MUSED(sio); sio_free(sio); } ASSERT0(queue->q_sio_memused); range_tree_vacate(queue->q_exts_by_addr, NULL, queue); range_tree_destroy(queue->q_exts_by_addr); avl_destroy(&queue->q_sios_by_addr); cv_destroy(&queue->q_zio_cv); kmem_free(queue, sizeof (*queue)); } /* * Properly transfers a dsl_scan_queue_t from `svd' to `tvd'. This is * called on behalf of vdev_top_transfer when creating or destroying * a mirror vdev due to zpool attach/detach. */ void dsl_scan_io_queue_vdev_xfer(vdev_t *svd, vdev_t *tvd) { mutex_enter(&svd->vdev_scan_io_queue_lock); mutex_enter(&tvd->vdev_scan_io_queue_lock); VERIFY3P(tvd->vdev_scan_io_queue, ==, NULL); tvd->vdev_scan_io_queue = svd->vdev_scan_io_queue; svd->vdev_scan_io_queue = NULL; if (tvd->vdev_scan_io_queue != NULL) tvd->vdev_scan_io_queue->q_vd = tvd; mutex_exit(&tvd->vdev_scan_io_queue_lock); mutex_exit(&svd->vdev_scan_io_queue_lock); } static void scan_io_queues_destroy(dsl_scan_t *scn) { vdev_t *rvd = scn->scn_dp->dp_spa->spa_root_vdev; for (uint64_t i = 0; i < rvd->vdev_children; i++) { vdev_t *tvd = rvd->vdev_child[i]; mutex_enter(&tvd->vdev_scan_io_queue_lock); if (tvd->vdev_scan_io_queue != NULL) dsl_scan_io_queue_destroy(tvd->vdev_scan_io_queue); tvd->vdev_scan_io_queue = NULL; mutex_exit(&tvd->vdev_scan_io_queue_lock); } } static void dsl_scan_freed_dva(spa_t *spa, const blkptr_t *bp, int dva_i) { dsl_pool_t *dp = spa->spa_dsl_pool; dsl_scan_t *scn = dp->dp_scan; vdev_t *vdev; kmutex_t *q_lock; dsl_scan_io_queue_t *queue; scan_io_t *srch_sio, *sio; avl_index_t idx; uint64_t start, size; vdev = vdev_lookup_top(spa, DVA_GET_VDEV(&bp->blk_dva[dva_i])); ASSERT(vdev != NULL); q_lock = &vdev->vdev_scan_io_queue_lock; queue = vdev->vdev_scan_io_queue; mutex_enter(q_lock); if (queue == NULL) { mutex_exit(q_lock); return; } srch_sio = sio_alloc(BP_GET_NDVAS(bp)); bp2sio(bp, srch_sio, dva_i); start = SIO_GET_OFFSET(srch_sio); size = SIO_GET_ASIZE(srch_sio); /* * We can find the zio in two states: * 1) Cold, just sitting in the queue of zio's to be issued at * some point in the future. In this case, all we do is * remove the zio from the q_sios_by_addr tree, decrement * its data volume from the containing range_seg_t and * resort the q_exts_by_size tree to reflect that the * range_seg_t has lost some of its 'fill'. We don't shorten * the range_seg_t - this is usually rare enough not to be * worth the extra hassle of trying keep track of precise * extent boundaries. * 2) Hot, where the zio is currently in-flight in * dsl_scan_issue_ios. In this case, we can't simply * reach in and stop the in-flight zio's, so we instead * block the caller. Eventually, dsl_scan_issue_ios will * be done with issuing the zio's it gathered and will * signal us. */ sio = avl_find(&queue->q_sios_by_addr, srch_sio, &idx); sio_free(srch_sio); if (sio != NULL) { blkptr_t tmpbp; /* Got it while it was cold in the queue */ ASSERT3U(start, ==, SIO_GET_OFFSET(sio)); ASSERT3U(size, ==, SIO_GET_ASIZE(sio)); avl_remove(&queue->q_sios_by_addr, sio); if (avl_is_empty(&queue->q_sios_by_addr)) atomic_add_64(&scn->scn_queues_pending, -1); queue->q_sio_memused -= SIO_GET_MUSED(sio); ASSERT(range_tree_contains(queue->q_exts_by_addr, start, size)); range_tree_remove_fill(queue->q_exts_by_addr, start, size); /* count the block as though we issued it */ sio2bp(sio, &tmpbp); count_block_issued(spa, &tmpbp, B_FALSE); sio_free(sio); } mutex_exit(q_lock); } /* * Callback invoked when a zio_free() zio is executing. This needs to be * intercepted to prevent the zio from deallocating a particular portion * of disk space and it then getting reallocated and written to, while we * still have it queued up for processing. */ void dsl_scan_freed(spa_t *spa, const blkptr_t *bp) { dsl_pool_t *dp = spa->spa_dsl_pool; dsl_scan_t *scn = dp->dp_scan; ASSERT(!BP_IS_EMBEDDED(bp)); ASSERT(scn != NULL); if (!dsl_scan_is_running(scn)) return; for (int i = 0; i < BP_GET_NDVAS(bp); i++) dsl_scan_freed_dva(spa, bp, i); } /* * Check if a vdev needs resilvering (non-empty DTL), if so, and resilver has * not started, start it. Otherwise, only restart if max txg in DTL range is * greater than the max txg in the current scan. If the DTL max is less than * the scan max, then the vdev has not missed any new data since the resilver * started, so a restart is not needed. */ void dsl_scan_assess_vdev(dsl_pool_t *dp, vdev_t *vd) { uint64_t min, max; if (!vdev_resilver_needed(vd, &min, &max)) return; if (!dsl_scan_resilvering(dp)) { spa_async_request(dp->dp_spa, SPA_ASYNC_RESILVER); return; } if (max <= dp->dp_scan->scn_phys.scn_max_txg) return; /* restart is needed, check if it can be deferred */ if (spa_feature_is_enabled(dp->dp_spa, SPA_FEATURE_RESILVER_DEFER)) vdev_defer_resilver(vd); else spa_async_request(dp->dp_spa, SPA_ASYNC_RESILVER); } ZFS_MODULE_PARAM(zfs, zfs_, scan_vdev_limit, ULONG, ZMOD_RW, "Max bytes in flight per leaf vdev for scrubs and resilvers"); ZFS_MODULE_PARAM(zfs, zfs_, scrub_min_time_ms, INT, ZMOD_RW, "Min millisecs to scrub per txg"); ZFS_MODULE_PARAM(zfs, zfs_, obsolete_min_time_ms, INT, ZMOD_RW, "Min millisecs to obsolete per txg"); ZFS_MODULE_PARAM(zfs, zfs_, free_min_time_ms, INT, ZMOD_RW, "Min millisecs to free per txg"); ZFS_MODULE_PARAM(zfs, zfs_, resilver_min_time_ms, INT, ZMOD_RW, "Min millisecs to resilver per txg"); ZFS_MODULE_PARAM(zfs, zfs_, scan_suspend_progress, INT, ZMOD_RW, "Set to prevent scans from progressing"); ZFS_MODULE_PARAM(zfs, zfs_, no_scrub_io, INT, ZMOD_RW, "Set to disable scrub I/O"); ZFS_MODULE_PARAM(zfs, zfs_, no_scrub_prefetch, INT, ZMOD_RW, "Set to disable scrub prefetching"); ZFS_MODULE_PARAM(zfs, zfs_, async_block_max_blocks, ULONG, ZMOD_RW, "Max number of blocks freed in one txg"); ZFS_MODULE_PARAM(zfs, zfs_, max_async_dedup_frees, ULONG, ZMOD_RW, "Max number of dedup blocks freed in one txg"); ZFS_MODULE_PARAM(zfs, zfs_, free_bpobj_enabled, INT, ZMOD_RW, "Enable processing of the free_bpobj"); ZFS_MODULE_PARAM(zfs, zfs_, scan_blkstats, INT, ZMOD_RW, "Enable block statistics calculation during scrub"); ZFS_MODULE_PARAM(zfs, zfs_, scan_mem_lim_fact, INT, ZMOD_RW, "Fraction of RAM for scan hard limit"); ZFS_MODULE_PARAM(zfs, zfs_, scan_issue_strategy, INT, ZMOD_RW, "IO issuing strategy during scrubbing. 0 = default, 1 = LBA, 2 = size"); ZFS_MODULE_PARAM(zfs, zfs_, scan_legacy, INT, ZMOD_RW, "Scrub using legacy non-sequential method"); ZFS_MODULE_PARAM(zfs, zfs_, scan_checkpoint_intval, INT, ZMOD_RW, "Scan progress on-disk checkpointing interval"); ZFS_MODULE_PARAM(zfs, zfs_, scan_max_ext_gap, ULONG, ZMOD_RW, "Max gap in bytes between sequential scrub / resilver I/Os"); ZFS_MODULE_PARAM(zfs, zfs_, scan_mem_lim_soft_fact, INT, ZMOD_RW, "Fraction of hard limit used as soft limit"); ZFS_MODULE_PARAM(zfs, zfs_, scan_strict_mem_lim, INT, ZMOD_RW, "Tunable to attempt to reduce lock contention"); ZFS_MODULE_PARAM(zfs, zfs_, scan_fill_weight, INT, ZMOD_RW, "Tunable to adjust bias towards more filled segments during scans"); ZFS_MODULE_PARAM(zfs, zfs_, resilver_disable_defer, INT, ZMOD_RW, "Process all resilvers immediately"); diff --git a/module/zfs/metaslab.c b/module/zfs/metaslab.c index 02cf121d83d7..4234f8ebf14e 100644 --- a/module/zfs/metaslab.c +++ b/module/zfs/metaslab.c @@ -1,6273 +1,6273 @@ /* * 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) 2005, 2010, Oracle and/or its affiliates. All rights reserved. * Copyright (c) 2011, 2019 by Delphix. All rights reserved. * Copyright (c) 2013 by Saso Kiselkov. All rights reserved. * Copyright (c) 2015, Nexenta Systems, Inc. All rights reserved. * Copyright (c) 2017, Intel Corporation. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #define WITH_DF_BLOCK_ALLOCATOR #define GANG_ALLOCATION(flags) \ ((flags) & (METASLAB_GANG_CHILD | METASLAB_GANG_HEADER)) /* * Metaslab granularity, in bytes. This is roughly similar to what would be * referred to as the "stripe size" in traditional RAID arrays. In normal * operation, we will try to write this amount of data to each disk before * moving on to the next top-level vdev. */ static unsigned long metaslab_aliquot = 1024 * 1024; /* * For testing, make some blocks above a certain size be gang blocks. */ unsigned long metaslab_force_ganging = SPA_MAXBLOCKSIZE + 1; /* * In pools where the log space map feature is not enabled we touch * multiple metaslabs (and their respective space maps) with each * transaction group. Thus, we benefit from having a small space map * block size since it allows us to issue more I/O operations scattered * around the disk. So a sane default for the space map block size * is 8~16K. */ int zfs_metaslab_sm_blksz_no_log = (1 << 14); /* * When the log space map feature is enabled, we accumulate a lot of * changes per metaslab that are flushed once in a while so we benefit * from a bigger block size like 128K for the metaslab space maps. */ int zfs_metaslab_sm_blksz_with_log = (1 << 17); /* * The in-core space map representation is more compact than its on-disk form. * The zfs_condense_pct determines how much more compact the in-core * space map representation must be before we compact it on-disk. * Values should be greater than or equal to 100. */ int zfs_condense_pct = 200; /* * Condensing a metaslab is not guaranteed to actually reduce the amount of * space used on disk. In particular, a space map uses data in increments of * MAX(1 << ashift, space_map_blksz), so a metaslab might use the * same number of blocks after condensing. Since the goal of condensing is to * reduce the number of IOPs required to read the space map, we only want to * condense when we can be sure we will reduce the number of blocks used by the * space map. Unfortunately, we cannot precisely compute whether or not this is * the case in metaslab_should_condense since we are holding ms_lock. Instead, * we apply the following heuristic: do not condense a spacemap unless the * uncondensed size consumes greater than zfs_metaslab_condense_block_threshold * blocks. */ static const int zfs_metaslab_condense_block_threshold = 4; /* * The zfs_mg_noalloc_threshold defines which metaslab groups should * be eligible for allocation. The value is defined as a percentage of * free space. Metaslab groups that have more free space than * zfs_mg_noalloc_threshold are always eligible for allocations. Once * a metaslab group's free space is less than or equal to the * zfs_mg_noalloc_threshold the allocator will avoid allocating to that * group unless all groups in the pool have reached zfs_mg_noalloc_threshold. * Once all groups in the pool reach zfs_mg_noalloc_threshold then all * groups are allowed to accept allocations. Gang blocks are always * eligible to allocate on any metaslab group. The default value of 0 means * no metaslab group will be excluded based on this criterion. */ static int zfs_mg_noalloc_threshold = 0; /* * Metaslab groups are considered eligible for allocations if their * fragmentation metric (measured as a percentage) is less than or * equal to zfs_mg_fragmentation_threshold. If a metaslab group * exceeds this threshold then it will be skipped unless all metaslab * groups within the metaslab class have also crossed this threshold. * * This tunable was introduced to avoid edge cases where we continue * allocating from very fragmented disks in our pool while other, less * fragmented disks, exists. On the other hand, if all disks in the * pool are uniformly approaching the threshold, the threshold can * be a speed bump in performance, where we keep switching the disks * that we allocate from (e.g. we allocate some segments from disk A * making it bypassing the threshold while freeing segments from disk * B getting its fragmentation below the threshold). * * Empirically, we've seen that our vdev selection for allocations is * good enough that fragmentation increases uniformly across all vdevs * the majority of the time. Thus we set the threshold percentage high * enough to avoid hitting the speed bump on pools that are being pushed * to the edge. */ static int zfs_mg_fragmentation_threshold = 95; /* * Allow metaslabs to keep their active state as long as their fragmentation * percentage is less than or equal to zfs_metaslab_fragmentation_threshold. An * active metaslab that exceeds this threshold will no longer keep its active * status allowing better metaslabs to be selected. */ static int zfs_metaslab_fragmentation_threshold = 70; /* * When set will load all metaslabs when pool is first opened. */ int metaslab_debug_load = B_FALSE; /* * When set will prevent metaslabs from being unloaded. */ static int metaslab_debug_unload = B_FALSE; /* * Minimum size which forces the dynamic allocator to change * it's allocation strategy. Once the space map cannot satisfy * an allocation of this size then it switches to using more * aggressive strategy (i.e search by size rather than offset). */ uint64_t metaslab_df_alloc_threshold = SPA_OLD_MAXBLOCKSIZE; /* * The minimum free space, in percent, which must be available * in a space map to continue allocations in a first-fit fashion. * Once the space map's free space drops below this level we dynamically * switch to using best-fit allocations. */ int metaslab_df_free_pct = 4; /* * Maximum distance to search forward from the last offset. Without this * limit, fragmented pools can see >100,000 iterations and * metaslab_block_picker() becomes the performance limiting factor on * high-performance storage. * * With the default setting of 16MB, we typically see less than 500 * iterations, even with very fragmented, ashift=9 pools. The maximum number * of iterations possible is: * metaslab_df_max_search / (2 * (1<60KB (but fewer segments in this * bucket, and therefore a lower weight). */ static int zfs_metaslab_find_max_tries = 100; static uint64_t metaslab_weight(metaslab_t *, boolean_t); static void metaslab_set_fragmentation(metaslab_t *, boolean_t); static void metaslab_free_impl(vdev_t *, uint64_t, uint64_t, boolean_t); static void metaslab_check_free_impl(vdev_t *, uint64_t, uint64_t); static void metaslab_passivate(metaslab_t *msp, uint64_t weight); static uint64_t metaslab_weight_from_range_tree(metaslab_t *msp); static void metaslab_flush_update(metaslab_t *, dmu_tx_t *); static unsigned int metaslab_idx_func(multilist_t *, void *); static void metaslab_evict(metaslab_t *, uint64_t); static void metaslab_rt_add(range_tree_t *rt, range_seg_t *rs, void *arg); kmem_cache_t *metaslab_alloc_trace_cache; typedef struct metaslab_stats { kstat_named_t metaslabstat_trace_over_limit; kstat_named_t metaslabstat_reload_tree; kstat_named_t metaslabstat_too_many_tries; kstat_named_t metaslabstat_try_hard; } metaslab_stats_t; static metaslab_stats_t metaslab_stats = { { "trace_over_limit", KSTAT_DATA_UINT64 }, { "reload_tree", KSTAT_DATA_UINT64 }, { "too_many_tries", KSTAT_DATA_UINT64 }, { "try_hard", KSTAT_DATA_UINT64 }, }; #define METASLABSTAT_BUMP(stat) \ atomic_inc_64(&metaslab_stats.stat.value.ui64); static kstat_t *metaslab_ksp; void metaslab_stat_init(void) { ASSERT(metaslab_alloc_trace_cache == NULL); metaslab_alloc_trace_cache = kmem_cache_create( "metaslab_alloc_trace_cache", sizeof (metaslab_alloc_trace_t), 0, NULL, NULL, NULL, NULL, NULL, 0); metaslab_ksp = kstat_create("zfs", 0, "metaslab_stats", "misc", KSTAT_TYPE_NAMED, sizeof (metaslab_stats) / sizeof (kstat_named_t), KSTAT_FLAG_VIRTUAL); if (metaslab_ksp != NULL) { metaslab_ksp->ks_data = &metaslab_stats; kstat_install(metaslab_ksp); } } void metaslab_stat_fini(void) { if (metaslab_ksp != NULL) { kstat_delete(metaslab_ksp); metaslab_ksp = NULL; } kmem_cache_destroy(metaslab_alloc_trace_cache); metaslab_alloc_trace_cache = NULL; } /* * ========================================================================== * Metaslab classes * ========================================================================== */ metaslab_class_t * metaslab_class_create(spa_t *spa, const metaslab_ops_t *ops) { metaslab_class_t *mc; mc = kmem_zalloc(offsetof(metaslab_class_t, mc_allocator[spa->spa_alloc_count]), KM_SLEEP); mc->mc_spa = spa; mc->mc_ops = ops; mutex_init(&mc->mc_lock, NULL, MUTEX_DEFAULT, NULL); multilist_create(&mc->mc_metaslab_txg_list, sizeof (metaslab_t), offsetof(metaslab_t, ms_class_txg_node), metaslab_idx_func); for (int i = 0; i < spa->spa_alloc_count; i++) { metaslab_class_allocator_t *mca = &mc->mc_allocator[i]; mca->mca_rotor = NULL; zfs_refcount_create_tracked(&mca->mca_alloc_slots); } return (mc); } void metaslab_class_destroy(metaslab_class_t *mc) { spa_t *spa = mc->mc_spa; ASSERT(mc->mc_alloc == 0); ASSERT(mc->mc_deferred == 0); ASSERT(mc->mc_space == 0); ASSERT(mc->mc_dspace == 0); for (int i = 0; i < spa->spa_alloc_count; i++) { metaslab_class_allocator_t *mca = &mc->mc_allocator[i]; ASSERT(mca->mca_rotor == NULL); zfs_refcount_destroy(&mca->mca_alloc_slots); } mutex_destroy(&mc->mc_lock); multilist_destroy(&mc->mc_metaslab_txg_list); kmem_free(mc, offsetof(metaslab_class_t, mc_allocator[spa->spa_alloc_count])); } int metaslab_class_validate(metaslab_class_t *mc) { metaslab_group_t *mg; vdev_t *vd; /* * Must hold one of the spa_config locks. */ ASSERT(spa_config_held(mc->mc_spa, SCL_ALL, RW_READER) || spa_config_held(mc->mc_spa, SCL_ALL, RW_WRITER)); if ((mg = mc->mc_allocator[0].mca_rotor) == NULL) return (0); do { vd = mg->mg_vd; ASSERT(vd->vdev_mg != NULL); ASSERT3P(vd->vdev_top, ==, vd); ASSERT3P(mg->mg_class, ==, mc); ASSERT3P(vd->vdev_ops, !=, &vdev_hole_ops); } while ((mg = mg->mg_next) != mc->mc_allocator[0].mca_rotor); return (0); } static void metaslab_class_space_update(metaslab_class_t *mc, int64_t alloc_delta, int64_t defer_delta, int64_t space_delta, int64_t dspace_delta) { atomic_add_64(&mc->mc_alloc, alloc_delta); atomic_add_64(&mc->mc_deferred, defer_delta); atomic_add_64(&mc->mc_space, space_delta); atomic_add_64(&mc->mc_dspace, dspace_delta); } uint64_t metaslab_class_get_alloc(metaslab_class_t *mc) { return (mc->mc_alloc); } uint64_t metaslab_class_get_deferred(metaslab_class_t *mc) { return (mc->mc_deferred); } uint64_t metaslab_class_get_space(metaslab_class_t *mc) { return (mc->mc_space); } uint64_t metaslab_class_get_dspace(metaslab_class_t *mc) { return (spa_deflate(mc->mc_spa) ? mc->mc_dspace : mc->mc_space); } void metaslab_class_histogram_verify(metaslab_class_t *mc) { spa_t *spa = mc->mc_spa; vdev_t *rvd = spa->spa_root_vdev; uint64_t *mc_hist; int i; if ((zfs_flags & ZFS_DEBUG_HISTOGRAM_VERIFY) == 0) return; mc_hist = kmem_zalloc(sizeof (uint64_t) * RANGE_TREE_HISTOGRAM_SIZE, KM_SLEEP); mutex_enter(&mc->mc_lock); for (int c = 0; c < rvd->vdev_children; c++) { vdev_t *tvd = rvd->vdev_child[c]; metaslab_group_t *mg = vdev_get_mg(tvd, mc); /* * Skip any holes, uninitialized top-levels, or * vdevs that are not in this metalab class. */ if (!vdev_is_concrete(tvd) || tvd->vdev_ms_shift == 0 || mg->mg_class != mc) { continue; } IMPLY(mg == mg->mg_vd->vdev_log_mg, mc == spa_embedded_log_class(mg->mg_vd->vdev_spa)); for (i = 0; i < RANGE_TREE_HISTOGRAM_SIZE; i++) mc_hist[i] += mg->mg_histogram[i]; } for (i = 0; i < RANGE_TREE_HISTOGRAM_SIZE; i++) { VERIFY3U(mc_hist[i], ==, mc->mc_histogram[i]); } mutex_exit(&mc->mc_lock); kmem_free(mc_hist, sizeof (uint64_t) * RANGE_TREE_HISTOGRAM_SIZE); } /* * Calculate the metaslab class's fragmentation metric. The metric * is weighted based on the space contribution of each metaslab group. * The return value will be a number between 0 and 100 (inclusive), or * ZFS_FRAG_INVALID if the metric has not been set. See comment above the * zfs_frag_table for more information about the metric. */ uint64_t metaslab_class_fragmentation(metaslab_class_t *mc) { vdev_t *rvd = mc->mc_spa->spa_root_vdev; uint64_t fragmentation = 0; spa_config_enter(mc->mc_spa, SCL_VDEV, FTAG, RW_READER); for (int c = 0; c < rvd->vdev_children; c++) { vdev_t *tvd = rvd->vdev_child[c]; metaslab_group_t *mg = tvd->vdev_mg; /* * Skip any holes, uninitialized top-levels, * or vdevs that are not in this metalab class. */ if (!vdev_is_concrete(tvd) || tvd->vdev_ms_shift == 0 || mg->mg_class != mc) { continue; } /* * If a metaslab group does not contain a fragmentation * metric then just bail out. */ if (mg->mg_fragmentation == ZFS_FRAG_INVALID) { spa_config_exit(mc->mc_spa, SCL_VDEV, FTAG); return (ZFS_FRAG_INVALID); } /* * Determine how much this metaslab_group is contributing * to the overall pool fragmentation metric. */ fragmentation += mg->mg_fragmentation * metaslab_group_get_space(mg); } fragmentation /= metaslab_class_get_space(mc); ASSERT3U(fragmentation, <=, 100); spa_config_exit(mc->mc_spa, SCL_VDEV, FTAG); return (fragmentation); } /* * Calculate the amount of expandable space that is available in * this metaslab class. If a device is expanded then its expandable * space will be the amount of allocatable space that is currently not * part of this metaslab class. */ uint64_t metaslab_class_expandable_space(metaslab_class_t *mc) { vdev_t *rvd = mc->mc_spa->spa_root_vdev; uint64_t space = 0; spa_config_enter(mc->mc_spa, SCL_VDEV, FTAG, RW_READER); for (int c = 0; c < rvd->vdev_children; c++) { vdev_t *tvd = rvd->vdev_child[c]; metaslab_group_t *mg = tvd->vdev_mg; if (!vdev_is_concrete(tvd) || tvd->vdev_ms_shift == 0 || mg->mg_class != mc) { continue; } /* * Calculate if we have enough space to add additional * metaslabs. We report the expandable space in terms * of the metaslab size since that's the unit of expansion. */ space += P2ALIGN(tvd->vdev_max_asize - tvd->vdev_asize, 1ULL << tvd->vdev_ms_shift); } spa_config_exit(mc->mc_spa, SCL_VDEV, FTAG); return (space); } void metaslab_class_evict_old(metaslab_class_t *mc, uint64_t txg) { multilist_t *ml = &mc->mc_metaslab_txg_list; for (int i = 0; i < multilist_get_num_sublists(ml); i++) { multilist_sublist_t *mls = multilist_sublist_lock(ml, i); metaslab_t *msp = multilist_sublist_head(mls); multilist_sublist_unlock(mls); while (msp != NULL) { mutex_enter(&msp->ms_lock); /* * If the metaslab has been removed from the list * (which could happen if we were at the memory limit * and it was evicted during this loop), then we can't * proceed and we should restart the sublist. */ if (!multilist_link_active(&msp->ms_class_txg_node)) { mutex_exit(&msp->ms_lock); i--; break; } mls = multilist_sublist_lock(ml, i); metaslab_t *next_msp = multilist_sublist_next(mls, msp); multilist_sublist_unlock(mls); if (txg > msp->ms_selected_txg + metaslab_unload_delay && gethrtime() > msp->ms_selected_time + (uint64_t)MSEC2NSEC(metaslab_unload_delay_ms)) { metaslab_evict(msp, txg); } else { /* * Once we've hit a metaslab selected too * recently to evict, we're done evicting for * now. */ mutex_exit(&msp->ms_lock); break; } mutex_exit(&msp->ms_lock); msp = next_msp; } } } static int metaslab_compare(const void *x1, const void *x2) { const metaslab_t *m1 = (const metaslab_t *)x1; const metaslab_t *m2 = (const metaslab_t *)x2; int sort1 = 0; int sort2 = 0; if (m1->ms_allocator != -1 && m1->ms_primary) sort1 = 1; else if (m1->ms_allocator != -1 && !m1->ms_primary) sort1 = 2; if (m2->ms_allocator != -1 && m2->ms_primary) sort2 = 1; else if (m2->ms_allocator != -1 && !m2->ms_primary) sort2 = 2; /* * Sort inactive metaslabs first, then primaries, then secondaries. When * selecting a metaslab to allocate from, an allocator first tries its * primary, then secondary active metaslab. If it doesn't have active * metaslabs, or can't allocate from them, it searches for an inactive * metaslab to activate. If it can't find a suitable one, it will steal * a primary or secondary metaslab from another allocator. */ if (sort1 < sort2) return (-1); if (sort1 > sort2) return (1); int cmp = TREE_CMP(m2->ms_weight, m1->ms_weight); if (likely(cmp)) return (cmp); IMPLY(TREE_CMP(m1->ms_start, m2->ms_start) == 0, m1 == m2); return (TREE_CMP(m1->ms_start, m2->ms_start)); } /* * ========================================================================== * Metaslab groups * ========================================================================== */ /* * Update the allocatable flag and the metaslab group's capacity. * The allocatable flag is set to true if the capacity is below * the zfs_mg_noalloc_threshold or has a fragmentation value that is * greater than zfs_mg_fragmentation_threshold. If a metaslab group * transitions from allocatable to non-allocatable or vice versa then the * metaslab group's class is updated to reflect the transition. */ static void metaslab_group_alloc_update(metaslab_group_t *mg) { vdev_t *vd = mg->mg_vd; metaslab_class_t *mc = mg->mg_class; vdev_stat_t *vs = &vd->vdev_stat; boolean_t was_allocatable; boolean_t was_initialized; ASSERT(vd == vd->vdev_top); ASSERT3U(spa_config_held(mc->mc_spa, SCL_ALLOC, RW_READER), ==, SCL_ALLOC); mutex_enter(&mg->mg_lock); was_allocatable = mg->mg_allocatable; was_initialized = mg->mg_initialized; mg->mg_free_capacity = ((vs->vs_space - vs->vs_alloc) * 100) / (vs->vs_space + 1); mutex_enter(&mc->mc_lock); /* * If the metaslab group was just added then it won't * have any space until we finish syncing out this txg. * At that point we will consider it initialized and available * for allocations. We also don't consider non-activated * metaslab groups (e.g. vdevs that are in the middle of being removed) * to be initialized, because they can't be used for allocation. */ mg->mg_initialized = metaslab_group_initialized(mg); if (!was_initialized && mg->mg_initialized) { mc->mc_groups++; } else if (was_initialized && !mg->mg_initialized) { ASSERT3U(mc->mc_groups, >, 0); mc->mc_groups--; } if (mg->mg_initialized) mg->mg_no_free_space = B_FALSE; /* * A metaslab group is considered allocatable if it has plenty * of free space or is not heavily fragmented. We only take * fragmentation into account if the metaslab group has a valid * fragmentation metric (i.e. a value between 0 and 100). */ mg->mg_allocatable = (mg->mg_activation_count > 0 && mg->mg_free_capacity > zfs_mg_noalloc_threshold && (mg->mg_fragmentation == ZFS_FRAG_INVALID || mg->mg_fragmentation <= zfs_mg_fragmentation_threshold)); /* * The mc_alloc_groups maintains a count of the number of * groups in this metaslab class that are still above the * zfs_mg_noalloc_threshold. This is used by the allocating * threads to determine if they should avoid allocations to * a given group. The allocator will avoid allocations to a group * if that group has reached or is below the zfs_mg_noalloc_threshold * and there are still other groups that are above the threshold. * When a group transitions from allocatable to non-allocatable or * vice versa we update the metaslab class to reflect that change. * When the mc_alloc_groups value drops to 0 that means that all * groups have reached the zfs_mg_noalloc_threshold making all groups * eligible for allocations. This effectively means that all devices * are balanced again. */ if (was_allocatable && !mg->mg_allocatable) mc->mc_alloc_groups--; else if (!was_allocatable && mg->mg_allocatable) mc->mc_alloc_groups++; mutex_exit(&mc->mc_lock); mutex_exit(&mg->mg_lock); } int metaslab_sort_by_flushed(const void *va, const void *vb) { const metaslab_t *a = va; const metaslab_t *b = vb; int cmp = TREE_CMP(a->ms_unflushed_txg, b->ms_unflushed_txg); if (likely(cmp)) return (cmp); uint64_t a_vdev_id = a->ms_group->mg_vd->vdev_id; uint64_t b_vdev_id = b->ms_group->mg_vd->vdev_id; cmp = TREE_CMP(a_vdev_id, b_vdev_id); if (cmp) return (cmp); return (TREE_CMP(a->ms_id, b->ms_id)); } metaslab_group_t * metaslab_group_create(metaslab_class_t *mc, vdev_t *vd, int allocators) { metaslab_group_t *mg; mg = kmem_zalloc(offsetof(metaslab_group_t, mg_allocator[allocators]), KM_SLEEP); mutex_init(&mg->mg_lock, NULL, MUTEX_DEFAULT, NULL); mutex_init(&mg->mg_ms_disabled_lock, NULL, MUTEX_DEFAULT, NULL); cv_init(&mg->mg_ms_disabled_cv, NULL, CV_DEFAULT, NULL); avl_create(&mg->mg_metaslab_tree, metaslab_compare, sizeof (metaslab_t), offsetof(metaslab_t, ms_group_node)); mg->mg_vd = vd; mg->mg_class = mc; mg->mg_activation_count = 0; mg->mg_initialized = B_FALSE; mg->mg_no_free_space = B_TRUE; mg->mg_allocators = allocators; for (int i = 0; i < allocators; i++) { metaslab_group_allocator_t *mga = &mg->mg_allocator[i]; zfs_refcount_create_tracked(&mga->mga_alloc_queue_depth); } mg->mg_taskq = taskq_create("metaslab_group_taskq", metaslab_load_pct, maxclsyspri, 10, INT_MAX, TASKQ_THREADS_CPU_PCT | TASKQ_DYNAMIC); return (mg); } void metaslab_group_destroy(metaslab_group_t *mg) { ASSERT(mg->mg_prev == NULL); ASSERT(mg->mg_next == NULL); /* * We may have gone below zero with the activation count * either because we never activated in the first place or * because we're done, and possibly removing the vdev. */ ASSERT(mg->mg_activation_count <= 0); taskq_destroy(mg->mg_taskq); avl_destroy(&mg->mg_metaslab_tree); mutex_destroy(&mg->mg_lock); mutex_destroy(&mg->mg_ms_disabled_lock); cv_destroy(&mg->mg_ms_disabled_cv); for (int i = 0; i < mg->mg_allocators; i++) { metaslab_group_allocator_t *mga = &mg->mg_allocator[i]; zfs_refcount_destroy(&mga->mga_alloc_queue_depth); } kmem_free(mg, offsetof(metaslab_group_t, mg_allocator[mg->mg_allocators])); } void metaslab_group_activate(metaslab_group_t *mg) { metaslab_class_t *mc = mg->mg_class; spa_t *spa = mc->mc_spa; metaslab_group_t *mgprev, *mgnext; ASSERT3U(spa_config_held(spa, SCL_ALLOC, RW_WRITER), !=, 0); ASSERT(mg->mg_prev == NULL); ASSERT(mg->mg_next == NULL); ASSERT(mg->mg_activation_count <= 0); if (++mg->mg_activation_count <= 0) return; mg->mg_aliquot = metaslab_aliquot * MAX(1, vdev_get_ndisks(mg->mg_vd) - vdev_get_nparity(mg->mg_vd)); metaslab_group_alloc_update(mg); if ((mgprev = mc->mc_allocator[0].mca_rotor) == NULL) { mg->mg_prev = mg; mg->mg_next = mg; } else { mgnext = mgprev->mg_next; mg->mg_prev = mgprev; mg->mg_next = mgnext; mgprev->mg_next = mg; mgnext->mg_prev = mg; } for (int i = 0; i < spa->spa_alloc_count; i++) { mc->mc_allocator[i].mca_rotor = mg; mg = mg->mg_next; } } /* * Passivate a metaslab group and remove it from the allocation rotor. * Callers must hold both the SCL_ALLOC and SCL_ZIO lock prior to passivating * a metaslab group. This function will momentarily drop spa_config_locks * that are lower than the SCL_ALLOC lock (see comment below). */ void metaslab_group_passivate(metaslab_group_t *mg) { metaslab_class_t *mc = mg->mg_class; spa_t *spa = mc->mc_spa; metaslab_group_t *mgprev, *mgnext; int locks = spa_config_held(spa, SCL_ALL, RW_WRITER); ASSERT3U(spa_config_held(spa, SCL_ALLOC | SCL_ZIO, RW_WRITER), ==, (SCL_ALLOC | SCL_ZIO)); if (--mg->mg_activation_count != 0) { for (int i = 0; i < spa->spa_alloc_count; i++) ASSERT(mc->mc_allocator[i].mca_rotor != mg); ASSERT(mg->mg_prev == NULL); ASSERT(mg->mg_next == NULL); ASSERT(mg->mg_activation_count < 0); return; } /* * The spa_config_lock is an array of rwlocks, ordered as * follows (from highest to lowest): * SCL_CONFIG > SCL_STATE > SCL_L2ARC > SCL_ALLOC > * SCL_ZIO > SCL_FREE > SCL_VDEV * (For more information about the spa_config_lock see spa_misc.c) * The higher the lock, the broader its coverage. When we passivate * a metaslab group, we must hold both the SCL_ALLOC and the SCL_ZIO * config locks. However, the metaslab group's taskq might be trying * to preload metaslabs so we must drop the SCL_ZIO lock and any * lower locks to allow the I/O to complete. At a minimum, * we continue to hold the SCL_ALLOC lock, which prevents any future * allocations from taking place and any changes to the vdev tree. */ spa_config_exit(spa, locks & ~(SCL_ZIO - 1), spa); taskq_wait_outstanding(mg->mg_taskq, 0); spa_config_enter(spa, locks & ~(SCL_ZIO - 1), spa, RW_WRITER); metaslab_group_alloc_update(mg); for (int i = 0; i < mg->mg_allocators; i++) { metaslab_group_allocator_t *mga = &mg->mg_allocator[i]; metaslab_t *msp = mga->mga_primary; if (msp != NULL) { mutex_enter(&msp->ms_lock); metaslab_passivate(msp, metaslab_weight_from_range_tree(msp)); mutex_exit(&msp->ms_lock); } msp = mga->mga_secondary; if (msp != NULL) { mutex_enter(&msp->ms_lock); metaslab_passivate(msp, metaslab_weight_from_range_tree(msp)); mutex_exit(&msp->ms_lock); } } mgprev = mg->mg_prev; mgnext = mg->mg_next; if (mg == mgnext) { mgnext = NULL; } else { mgprev->mg_next = mgnext; mgnext->mg_prev = mgprev; } for (int i = 0; i < spa->spa_alloc_count; i++) { if (mc->mc_allocator[i].mca_rotor == mg) mc->mc_allocator[i].mca_rotor = mgnext; } mg->mg_prev = NULL; mg->mg_next = NULL; } boolean_t metaslab_group_initialized(metaslab_group_t *mg) { vdev_t *vd = mg->mg_vd; vdev_stat_t *vs = &vd->vdev_stat; return (vs->vs_space != 0 && mg->mg_activation_count > 0); } uint64_t metaslab_group_get_space(metaslab_group_t *mg) { /* * Note that the number of nodes in mg_metaslab_tree may be one less * than vdev_ms_count, due to the embedded log metaslab. */ mutex_enter(&mg->mg_lock); uint64_t ms_count = avl_numnodes(&mg->mg_metaslab_tree); mutex_exit(&mg->mg_lock); return ((1ULL << mg->mg_vd->vdev_ms_shift) * ms_count); } void metaslab_group_histogram_verify(metaslab_group_t *mg) { uint64_t *mg_hist; avl_tree_t *t = &mg->mg_metaslab_tree; uint64_t ashift = mg->mg_vd->vdev_ashift; if ((zfs_flags & ZFS_DEBUG_HISTOGRAM_VERIFY) == 0) return; mg_hist = kmem_zalloc(sizeof (uint64_t) * RANGE_TREE_HISTOGRAM_SIZE, KM_SLEEP); ASSERT3U(RANGE_TREE_HISTOGRAM_SIZE, >=, SPACE_MAP_HISTOGRAM_SIZE + ashift); mutex_enter(&mg->mg_lock); for (metaslab_t *msp = avl_first(t); msp != NULL; msp = AVL_NEXT(t, msp)) { VERIFY3P(msp->ms_group, ==, mg); /* skip if not active */ if (msp->ms_sm == NULL) continue; for (int i = 0; i < SPACE_MAP_HISTOGRAM_SIZE; i++) { mg_hist[i + ashift] += msp->ms_sm->sm_phys->smp_histogram[i]; } } for (int i = 0; i < RANGE_TREE_HISTOGRAM_SIZE; i ++) VERIFY3U(mg_hist[i], ==, mg->mg_histogram[i]); mutex_exit(&mg->mg_lock); kmem_free(mg_hist, sizeof (uint64_t) * RANGE_TREE_HISTOGRAM_SIZE); } static void metaslab_group_histogram_add(metaslab_group_t *mg, metaslab_t *msp) { metaslab_class_t *mc = mg->mg_class; uint64_t ashift = mg->mg_vd->vdev_ashift; ASSERT(MUTEX_HELD(&msp->ms_lock)); if (msp->ms_sm == NULL) return; mutex_enter(&mg->mg_lock); mutex_enter(&mc->mc_lock); for (int i = 0; i < SPACE_MAP_HISTOGRAM_SIZE; i++) { IMPLY(mg == mg->mg_vd->vdev_log_mg, mc == spa_embedded_log_class(mg->mg_vd->vdev_spa)); mg->mg_histogram[i + ashift] += msp->ms_sm->sm_phys->smp_histogram[i]; mc->mc_histogram[i + ashift] += msp->ms_sm->sm_phys->smp_histogram[i]; } mutex_exit(&mc->mc_lock); mutex_exit(&mg->mg_lock); } void metaslab_group_histogram_remove(metaslab_group_t *mg, metaslab_t *msp) { metaslab_class_t *mc = mg->mg_class; uint64_t ashift = mg->mg_vd->vdev_ashift; ASSERT(MUTEX_HELD(&msp->ms_lock)); if (msp->ms_sm == NULL) return; mutex_enter(&mg->mg_lock); mutex_enter(&mc->mc_lock); for (int i = 0; i < SPACE_MAP_HISTOGRAM_SIZE; i++) { ASSERT3U(mg->mg_histogram[i + ashift], >=, msp->ms_sm->sm_phys->smp_histogram[i]); ASSERT3U(mc->mc_histogram[i + ashift], >=, msp->ms_sm->sm_phys->smp_histogram[i]); IMPLY(mg == mg->mg_vd->vdev_log_mg, mc == spa_embedded_log_class(mg->mg_vd->vdev_spa)); mg->mg_histogram[i + ashift] -= msp->ms_sm->sm_phys->smp_histogram[i]; mc->mc_histogram[i + ashift] -= msp->ms_sm->sm_phys->smp_histogram[i]; } mutex_exit(&mc->mc_lock); mutex_exit(&mg->mg_lock); } static void metaslab_group_add(metaslab_group_t *mg, metaslab_t *msp) { ASSERT(msp->ms_group == NULL); mutex_enter(&mg->mg_lock); msp->ms_group = mg; msp->ms_weight = 0; avl_add(&mg->mg_metaslab_tree, msp); mutex_exit(&mg->mg_lock); mutex_enter(&msp->ms_lock); metaslab_group_histogram_add(mg, msp); mutex_exit(&msp->ms_lock); } static void metaslab_group_remove(metaslab_group_t *mg, metaslab_t *msp) { mutex_enter(&msp->ms_lock); metaslab_group_histogram_remove(mg, msp); mutex_exit(&msp->ms_lock); mutex_enter(&mg->mg_lock); ASSERT(msp->ms_group == mg); avl_remove(&mg->mg_metaslab_tree, msp); metaslab_class_t *mc = msp->ms_group->mg_class; multilist_sublist_t *mls = multilist_sublist_lock_obj(&mc->mc_metaslab_txg_list, msp); if (multilist_link_active(&msp->ms_class_txg_node)) multilist_sublist_remove(mls, msp); multilist_sublist_unlock(mls); msp->ms_group = NULL; mutex_exit(&mg->mg_lock); } static void metaslab_group_sort_impl(metaslab_group_t *mg, metaslab_t *msp, uint64_t weight) { ASSERT(MUTEX_HELD(&msp->ms_lock)); ASSERT(MUTEX_HELD(&mg->mg_lock)); ASSERT(msp->ms_group == mg); avl_remove(&mg->mg_metaslab_tree, msp); msp->ms_weight = weight; avl_add(&mg->mg_metaslab_tree, msp); } static void metaslab_group_sort(metaslab_group_t *mg, metaslab_t *msp, uint64_t weight) { /* * Although in principle the weight can be any value, in * practice we do not use values in the range [1, 511]. */ ASSERT(weight >= SPA_MINBLOCKSIZE || weight == 0); ASSERT(MUTEX_HELD(&msp->ms_lock)); mutex_enter(&mg->mg_lock); metaslab_group_sort_impl(mg, msp, weight); mutex_exit(&mg->mg_lock); } /* * Calculate the fragmentation for a given metaslab group. We can use * a simple average here since all metaslabs within the group must have * the same size. The return value will be a value between 0 and 100 * (inclusive), or ZFS_FRAG_INVALID if less than half of the metaslab in this * group have a fragmentation metric. */ uint64_t metaslab_group_fragmentation(metaslab_group_t *mg) { vdev_t *vd = mg->mg_vd; uint64_t fragmentation = 0; uint64_t valid_ms = 0; for (int m = 0; m < vd->vdev_ms_count; m++) { metaslab_t *msp = vd->vdev_ms[m]; if (msp->ms_fragmentation == ZFS_FRAG_INVALID) continue; if (msp->ms_group != mg) continue; valid_ms++; fragmentation += msp->ms_fragmentation; } if (valid_ms <= mg->mg_vd->vdev_ms_count / 2) return (ZFS_FRAG_INVALID); fragmentation /= valid_ms; ASSERT3U(fragmentation, <=, 100); return (fragmentation); } /* * Determine if a given metaslab group should skip allocations. A metaslab * group should avoid allocations if its free capacity is less than the * zfs_mg_noalloc_threshold or its fragmentation metric is greater than * zfs_mg_fragmentation_threshold and there is at least one metaslab group * that can still handle allocations. If the allocation throttle is enabled * then we skip allocations to devices that have reached their maximum * allocation queue depth unless the selected metaslab group is the only * eligible group remaining. */ static boolean_t metaslab_group_allocatable(metaslab_group_t *mg, metaslab_group_t *rotor, uint64_t psize, int allocator, int d) { spa_t *spa = mg->mg_vd->vdev_spa; metaslab_class_t *mc = mg->mg_class; /* * We can only consider skipping this metaslab group if it's * in the normal metaslab class and there are other metaslab * groups to select from. Otherwise, we always consider it eligible * for allocations. */ if ((mc != spa_normal_class(spa) && mc != spa_special_class(spa) && mc != spa_dedup_class(spa)) || mc->mc_groups <= 1) return (B_TRUE); /* * If the metaslab group's mg_allocatable flag is set (see comments * in metaslab_group_alloc_update() for more information) and * the allocation throttle is disabled then allow allocations to this * device. However, if the allocation throttle is enabled then * check if we have reached our allocation limit (mga_alloc_queue_depth) * to determine if we should allow allocations to this metaslab group. * If all metaslab groups are no longer considered allocatable * (mc_alloc_groups == 0) or we're trying to allocate the smallest * gang block size then we allow allocations on this metaslab group * regardless of the mg_allocatable or throttle settings. */ if (mg->mg_allocatable) { metaslab_group_allocator_t *mga = &mg->mg_allocator[allocator]; int64_t qdepth; uint64_t qmax = mga->mga_cur_max_alloc_queue_depth; if (!mc->mc_alloc_throttle_enabled) return (B_TRUE); /* * If this metaslab group does not have any free space, then * there is no point in looking further. */ if (mg->mg_no_free_space) return (B_FALSE); /* * Relax allocation throttling for ditto blocks. Due to * random imbalances in allocation it tends to push copies * to one vdev, that looks a bit better at the moment. */ qmax = qmax * (4 + d) / 4; qdepth = zfs_refcount_count(&mga->mga_alloc_queue_depth); /* * If this metaslab group is below its qmax or it's * the only allocatable metasable group, then attempt * to allocate from it. */ if (qdepth < qmax || mc->mc_alloc_groups == 1) return (B_TRUE); ASSERT3U(mc->mc_alloc_groups, >, 1); /* * Since this metaslab group is at or over its qmax, we * need to determine if there are metaslab groups after this * one that might be able to handle this allocation. This is * racy since we can't hold the locks for all metaslab * groups at the same time when we make this check. */ for (metaslab_group_t *mgp = mg->mg_next; mgp != rotor; mgp = mgp->mg_next) { metaslab_group_allocator_t *mgap = &mgp->mg_allocator[allocator]; qmax = mgap->mga_cur_max_alloc_queue_depth; qmax = qmax * (4 + d) / 4; qdepth = zfs_refcount_count(&mgap->mga_alloc_queue_depth); /* * If there is another metaslab group that * might be able to handle the allocation, then * we return false so that we skip this group. */ if (qdepth < qmax && !mgp->mg_no_free_space) return (B_FALSE); } /* * We didn't find another group to handle the allocation * so we can't skip this metaslab group even though * we are at or over our qmax. */ return (B_TRUE); } else if (mc->mc_alloc_groups == 0 || psize == SPA_MINBLOCKSIZE) { return (B_TRUE); } return (B_FALSE); } /* * ========================================================================== * Range tree callbacks * ========================================================================== */ /* * Comparison function for the private size-ordered tree using 32-bit * ranges. Tree is sorted by size, larger sizes at the end of the tree. */ static int metaslab_rangesize32_compare(const void *x1, const void *x2) { const range_seg32_t *r1 = x1; const range_seg32_t *r2 = x2; uint64_t rs_size1 = r1->rs_end - r1->rs_start; uint64_t rs_size2 = r2->rs_end - r2->rs_start; int cmp = TREE_CMP(rs_size1, rs_size2); if (likely(cmp)) return (cmp); return (TREE_CMP(r1->rs_start, r2->rs_start)); } /* * Comparison function for the private size-ordered tree using 64-bit * ranges. Tree is sorted by size, larger sizes at the end of the tree. */ static int metaslab_rangesize64_compare(const void *x1, const void *x2) { const range_seg64_t *r1 = x1; const range_seg64_t *r2 = x2; uint64_t rs_size1 = r1->rs_end - r1->rs_start; uint64_t rs_size2 = r2->rs_end - r2->rs_start; int cmp = TREE_CMP(rs_size1, rs_size2); if (likely(cmp)) return (cmp); return (TREE_CMP(r1->rs_start, r2->rs_start)); } typedef struct metaslab_rt_arg { zfs_btree_t *mra_bt; uint32_t mra_floor_shift; } metaslab_rt_arg_t; struct mssa_arg { range_tree_t *rt; metaslab_rt_arg_t *mra; }; static void metaslab_size_sorted_add(void *arg, uint64_t start, uint64_t size) { struct mssa_arg *mssap = arg; range_tree_t *rt = mssap->rt; metaslab_rt_arg_t *mrap = mssap->mra; range_seg_max_t seg = {0}; rs_set_start(&seg, rt, start); rs_set_end(&seg, rt, start + size); metaslab_rt_add(rt, &seg, mrap); } static void metaslab_size_tree_full_load(range_tree_t *rt) { metaslab_rt_arg_t *mrap = rt->rt_arg; METASLABSTAT_BUMP(metaslabstat_reload_tree); ASSERT0(zfs_btree_numnodes(mrap->mra_bt)); mrap->mra_floor_shift = 0; struct mssa_arg arg = {0}; arg.rt = rt; arg.mra = mrap; range_tree_walk(rt, metaslab_size_sorted_add, &arg); } /* * Create any block allocator specific components. The current allocators * rely on using both a size-ordered range_tree_t and an array of uint64_t's. */ static void metaslab_rt_create(range_tree_t *rt, void *arg) { metaslab_rt_arg_t *mrap = arg; zfs_btree_t *size_tree = mrap->mra_bt; size_t size; int (*compare) (const void *, const void *); switch (rt->rt_type) { case RANGE_SEG32: size = sizeof (range_seg32_t); compare = metaslab_rangesize32_compare; break; case RANGE_SEG64: size = sizeof (range_seg64_t); compare = metaslab_rangesize64_compare; break; default: panic("Invalid range seg type %d", rt->rt_type); } zfs_btree_create(size_tree, compare, size); mrap->mra_floor_shift = metaslab_by_size_min_shift; } static void metaslab_rt_destroy(range_tree_t *rt, void *arg) { (void) rt; metaslab_rt_arg_t *mrap = arg; zfs_btree_t *size_tree = mrap->mra_bt; zfs_btree_destroy(size_tree); kmem_free(mrap, sizeof (*mrap)); } static void metaslab_rt_add(range_tree_t *rt, range_seg_t *rs, void *arg) { metaslab_rt_arg_t *mrap = arg; zfs_btree_t *size_tree = mrap->mra_bt; if (rs_get_end(rs, rt) - rs_get_start(rs, rt) < - (1 << mrap->mra_floor_shift)) + (1ULL << mrap->mra_floor_shift)) return; zfs_btree_add(size_tree, rs); } static void metaslab_rt_remove(range_tree_t *rt, range_seg_t *rs, void *arg) { metaslab_rt_arg_t *mrap = arg; zfs_btree_t *size_tree = mrap->mra_bt; - if (rs_get_end(rs, rt) - rs_get_start(rs, rt) < (1 << + if (rs_get_end(rs, rt) - rs_get_start(rs, rt) < (1ULL << mrap->mra_floor_shift)) return; zfs_btree_remove(size_tree, rs); } static void metaslab_rt_vacate(range_tree_t *rt, void *arg) { metaslab_rt_arg_t *mrap = arg; zfs_btree_t *size_tree = mrap->mra_bt; zfs_btree_clear(size_tree); zfs_btree_destroy(size_tree); metaslab_rt_create(rt, arg); } static const range_tree_ops_t metaslab_rt_ops = { .rtop_create = metaslab_rt_create, .rtop_destroy = metaslab_rt_destroy, .rtop_add = metaslab_rt_add, .rtop_remove = metaslab_rt_remove, .rtop_vacate = metaslab_rt_vacate }; /* * ========================================================================== * Common allocator routines * ========================================================================== */ /* * Return the maximum contiguous segment within the metaslab. */ uint64_t metaslab_largest_allocatable(metaslab_t *msp) { zfs_btree_t *t = &msp->ms_allocatable_by_size; range_seg_t *rs; if (t == NULL) return (0); if (zfs_btree_numnodes(t) == 0) metaslab_size_tree_full_load(msp->ms_allocatable); rs = zfs_btree_last(t, NULL); if (rs == NULL) return (0); return (rs_get_end(rs, msp->ms_allocatable) - rs_get_start(rs, msp->ms_allocatable)); } /* * Return the maximum contiguous segment within the unflushed frees of this * metaslab. */ static uint64_t metaslab_largest_unflushed_free(metaslab_t *msp) { ASSERT(MUTEX_HELD(&msp->ms_lock)); if (msp->ms_unflushed_frees == NULL) return (0); if (zfs_btree_numnodes(&msp->ms_unflushed_frees_by_size) == 0) metaslab_size_tree_full_load(msp->ms_unflushed_frees); range_seg_t *rs = zfs_btree_last(&msp->ms_unflushed_frees_by_size, NULL); if (rs == NULL) return (0); /* * When a range is freed from the metaslab, that range is added to * both the unflushed frees and the deferred frees. While the block * will eventually be usable, if the metaslab were loaded the range * would not be added to the ms_allocatable tree until TXG_DEFER_SIZE * txgs had passed. As a result, when attempting to estimate an upper * bound for the largest currently-usable free segment in the * metaslab, we need to not consider any ranges currently in the defer * trees. This algorithm approximates the largest available chunk in * the largest range in the unflushed_frees tree by taking the first * chunk. While this may be a poor estimate, it should only remain so * briefly and should eventually self-correct as frees are no longer * deferred. Similar logic applies to the ms_freed tree. See * metaslab_load() for more details. * * There are two primary sources of inaccuracy in this estimate. Both * are tolerated for performance reasons. The first source is that we * only check the largest segment for overlaps. Smaller segments may * have more favorable overlaps with the other trees, resulting in * larger usable chunks. Second, we only look at the first chunk in * the largest segment; there may be other usable chunks in the * largest segment, but we ignore them. */ uint64_t rstart = rs_get_start(rs, msp->ms_unflushed_frees); uint64_t rsize = rs_get_end(rs, msp->ms_unflushed_frees) - rstart; for (int t = 0; t < TXG_DEFER_SIZE; t++) { uint64_t start = 0; uint64_t size = 0; boolean_t found = range_tree_find_in(msp->ms_defer[t], rstart, rsize, &start, &size); if (found) { if (rstart == start) return (0); rsize = start - rstart; } } uint64_t start = 0; uint64_t size = 0; boolean_t found = range_tree_find_in(msp->ms_freed, rstart, rsize, &start, &size); if (found) rsize = start - rstart; return (rsize); } static range_seg_t * metaslab_block_find(zfs_btree_t *t, range_tree_t *rt, uint64_t start, uint64_t size, zfs_btree_index_t *where) { range_seg_t *rs; range_seg_max_t rsearch; rs_set_start(&rsearch, rt, start); rs_set_end(&rsearch, rt, start + size); rs = zfs_btree_find(t, &rsearch, where); if (rs == NULL) { rs = zfs_btree_next(t, where, where); } return (rs); } #if defined(WITH_DF_BLOCK_ALLOCATOR) || \ defined(WITH_CF_BLOCK_ALLOCATOR) /* * This is a helper function that can be used by the allocator to find a * suitable block to allocate. This will search the specified B-tree looking * for a block that matches the specified criteria. */ static uint64_t metaslab_block_picker(range_tree_t *rt, uint64_t *cursor, uint64_t size, uint64_t max_search) { if (*cursor == 0) *cursor = rt->rt_start; zfs_btree_t *bt = &rt->rt_root; zfs_btree_index_t where; range_seg_t *rs = metaslab_block_find(bt, rt, *cursor, size, &where); uint64_t first_found; int count_searched = 0; if (rs != NULL) first_found = rs_get_start(rs, rt); while (rs != NULL && (rs_get_start(rs, rt) - first_found <= max_search || count_searched < metaslab_min_search_count)) { uint64_t offset = rs_get_start(rs, rt); if (offset + size <= rs_get_end(rs, rt)) { *cursor = offset + size; return (offset); } rs = zfs_btree_next(bt, &where, &where); count_searched++; } *cursor = 0; return (-1ULL); } #endif /* WITH_DF/CF_BLOCK_ALLOCATOR */ #if defined(WITH_DF_BLOCK_ALLOCATOR) /* * ========================================================================== * Dynamic Fit (df) block allocator * * Search for a free chunk of at least this size, starting from the last * offset (for this alignment of block) looking for up to * metaslab_df_max_search bytes (16MB). If a large enough free chunk is not * found within 16MB, then return a free chunk of exactly the requested size (or * larger). * * If it seems like searching from the last offset will be unproductive, skip * that and just return a free chunk of exactly the requested size (or larger). * This is based on metaslab_df_alloc_threshold and metaslab_df_free_pct. This * mechanism is probably not very useful and may be removed in the future. * * The behavior when not searching can be changed to return the largest free * chunk, instead of a free chunk of exactly the requested size, by setting * metaslab_df_use_largest_segment. * ========================================================================== */ static uint64_t metaslab_df_alloc(metaslab_t *msp, uint64_t size) { /* * Find the largest power of 2 block size that evenly divides the * requested size. This is used to try to allocate blocks with similar * alignment from the same area of the metaslab (i.e. same cursor * bucket) but it does not guarantee that other allocations sizes * may exist in the same region. */ uint64_t align = size & -size; uint64_t *cursor = &msp->ms_lbas[highbit64(align) - 1]; range_tree_t *rt = msp->ms_allocatable; int free_pct = range_tree_space(rt) * 100 / msp->ms_size; uint64_t offset; ASSERT(MUTEX_HELD(&msp->ms_lock)); /* * If we're running low on space, find a segment based on size, * rather than iterating based on offset. */ if (metaslab_largest_allocatable(msp) < metaslab_df_alloc_threshold || free_pct < metaslab_df_free_pct) { offset = -1; } else { offset = metaslab_block_picker(rt, cursor, size, metaslab_df_max_search); } if (offset == -1) { range_seg_t *rs; if (zfs_btree_numnodes(&msp->ms_allocatable_by_size) == 0) metaslab_size_tree_full_load(msp->ms_allocatable); if (metaslab_df_use_largest_segment) { /* use largest free segment */ rs = zfs_btree_last(&msp->ms_allocatable_by_size, NULL); } else { zfs_btree_index_t where; /* use segment of this size, or next largest */ rs = metaslab_block_find(&msp->ms_allocatable_by_size, rt, msp->ms_start, size, &where); } if (rs != NULL && rs_get_start(rs, rt) + size <= rs_get_end(rs, rt)) { offset = rs_get_start(rs, rt); *cursor = offset + size; } } return (offset); } const metaslab_ops_t zfs_metaslab_ops = { metaslab_df_alloc }; #endif /* WITH_DF_BLOCK_ALLOCATOR */ #if defined(WITH_CF_BLOCK_ALLOCATOR) /* * ========================================================================== * Cursor fit block allocator - * Select the largest region in the metaslab, set the cursor to the beginning * of the range and the cursor_end to the end of the range. As allocations * are made advance the cursor. Continue allocating from the cursor until * the range is exhausted and then find a new range. * ========================================================================== */ static uint64_t metaslab_cf_alloc(metaslab_t *msp, uint64_t size) { range_tree_t *rt = msp->ms_allocatable; zfs_btree_t *t = &msp->ms_allocatable_by_size; uint64_t *cursor = &msp->ms_lbas[0]; uint64_t *cursor_end = &msp->ms_lbas[1]; uint64_t offset = 0; ASSERT(MUTEX_HELD(&msp->ms_lock)); ASSERT3U(*cursor_end, >=, *cursor); if ((*cursor + size) > *cursor_end) { range_seg_t *rs; if (zfs_btree_numnodes(t) == 0) metaslab_size_tree_full_load(msp->ms_allocatable); rs = zfs_btree_last(t, NULL); if (rs == NULL || (rs_get_end(rs, rt) - rs_get_start(rs, rt)) < size) return (-1ULL); *cursor = rs_get_start(rs, rt); *cursor_end = rs_get_end(rs, rt); } offset = *cursor; *cursor += size; return (offset); } const metaslab_ops_t zfs_metaslab_ops = { metaslab_cf_alloc }; #endif /* WITH_CF_BLOCK_ALLOCATOR */ #if defined(WITH_NDF_BLOCK_ALLOCATOR) /* * ========================================================================== * New dynamic fit allocator - * Select a region that is large enough to allocate 2^metaslab_ndf_clump_shift * contiguous blocks. If no region is found then just use the largest segment * that remains. * ========================================================================== */ /* * Determines desired number of contiguous blocks (2^metaslab_ndf_clump_shift) * to request from the allocator. */ uint64_t metaslab_ndf_clump_shift = 4; static uint64_t metaslab_ndf_alloc(metaslab_t *msp, uint64_t size) { zfs_btree_t *t = &msp->ms_allocatable->rt_root; range_tree_t *rt = msp->ms_allocatable; zfs_btree_index_t where; range_seg_t *rs; range_seg_max_t rsearch; uint64_t hbit = highbit64(size); uint64_t *cursor = &msp->ms_lbas[hbit - 1]; uint64_t max_size = metaslab_largest_allocatable(msp); ASSERT(MUTEX_HELD(&msp->ms_lock)); if (max_size < size) return (-1ULL); rs_set_start(&rsearch, rt, *cursor); rs_set_end(&rsearch, rt, *cursor + size); rs = zfs_btree_find(t, &rsearch, &where); if (rs == NULL || (rs_get_end(rs, rt) - rs_get_start(rs, rt)) < size) { t = &msp->ms_allocatable_by_size; rs_set_start(&rsearch, rt, 0); rs_set_end(&rsearch, rt, MIN(max_size, 1ULL << (hbit + metaslab_ndf_clump_shift))); rs = zfs_btree_find(t, &rsearch, &where); if (rs == NULL) rs = zfs_btree_next(t, &where, &where); ASSERT(rs != NULL); } if ((rs_get_end(rs, rt) - rs_get_start(rs, rt)) >= size) { *cursor = rs_get_start(rs, rt) + size; return (rs_get_start(rs, rt)); } return (-1ULL); } const metaslab_ops_t zfs_metaslab_ops = { metaslab_ndf_alloc }; #endif /* WITH_NDF_BLOCK_ALLOCATOR */ /* * ========================================================================== * Metaslabs * ========================================================================== */ /* * Wait for any in-progress metaslab loads to complete. */ static void metaslab_load_wait(metaslab_t *msp) { ASSERT(MUTEX_HELD(&msp->ms_lock)); while (msp->ms_loading) { ASSERT(!msp->ms_loaded); cv_wait(&msp->ms_load_cv, &msp->ms_lock); } } /* * Wait for any in-progress flushing to complete. */ static void metaslab_flush_wait(metaslab_t *msp) { ASSERT(MUTEX_HELD(&msp->ms_lock)); while (msp->ms_flushing) cv_wait(&msp->ms_flush_cv, &msp->ms_lock); } static unsigned int metaslab_idx_func(multilist_t *ml, void *arg) { metaslab_t *msp = arg; /* * ms_id values are allocated sequentially, so full 64bit * division would be a waste of time, so limit it to 32 bits. */ return ((unsigned int)msp->ms_id % multilist_get_num_sublists(ml)); } uint64_t metaslab_allocated_space(metaslab_t *msp) { return (msp->ms_allocated_space); } /* * Verify that the space accounting on disk matches the in-core range_trees. */ static void metaslab_verify_space(metaslab_t *msp, uint64_t txg) { spa_t *spa = msp->ms_group->mg_vd->vdev_spa; uint64_t allocating = 0; uint64_t sm_free_space, msp_free_space; ASSERT(MUTEX_HELD(&msp->ms_lock)); ASSERT(!msp->ms_condensing); if ((zfs_flags & ZFS_DEBUG_METASLAB_VERIFY) == 0) return; /* * We can only verify the metaslab space when we're called * from syncing context with a loaded metaslab that has an * allocated space map. Calling this in non-syncing context * does not provide a consistent view of the metaslab since * we're performing allocations in the future. */ if (txg != spa_syncing_txg(spa) || msp->ms_sm == NULL || !msp->ms_loaded) return; /* * Even though the smp_alloc field can get negative, * when it comes to a metaslab's space map, that should * never be the case. */ ASSERT3S(space_map_allocated(msp->ms_sm), >=, 0); ASSERT3U(space_map_allocated(msp->ms_sm), >=, range_tree_space(msp->ms_unflushed_frees)); ASSERT3U(metaslab_allocated_space(msp), ==, space_map_allocated(msp->ms_sm) + range_tree_space(msp->ms_unflushed_allocs) - range_tree_space(msp->ms_unflushed_frees)); sm_free_space = msp->ms_size - metaslab_allocated_space(msp); /* * Account for future allocations since we would have * already deducted that space from the ms_allocatable. */ for (int t = 0; t < TXG_CONCURRENT_STATES; t++) { allocating += range_tree_space(msp->ms_allocating[(txg + t) & TXG_MASK]); } ASSERT3U(allocating + msp->ms_allocated_this_txg, ==, msp->ms_allocating_total); ASSERT3U(msp->ms_deferspace, ==, range_tree_space(msp->ms_defer[0]) + range_tree_space(msp->ms_defer[1])); msp_free_space = range_tree_space(msp->ms_allocatable) + allocating + msp->ms_deferspace + range_tree_space(msp->ms_freed); VERIFY3U(sm_free_space, ==, msp_free_space); } static void metaslab_aux_histograms_clear(metaslab_t *msp) { /* * Auxiliary histograms are only cleared when resetting them, * which can only happen while the metaslab is loaded. */ ASSERT(msp->ms_loaded); memset(msp->ms_synchist, 0, sizeof (msp->ms_synchist)); for (int t = 0; t < TXG_DEFER_SIZE; t++) memset(msp->ms_deferhist[t], 0, sizeof (msp->ms_deferhist[t])); } static void metaslab_aux_histogram_add(uint64_t *histogram, uint64_t shift, range_tree_t *rt) { /* * This is modeled after space_map_histogram_add(), so refer to that * function for implementation details. We want this to work like * the space map histogram, and not the range tree histogram, as we * are essentially constructing a delta that will be later subtracted * from the space map histogram. */ int idx = 0; for (int i = shift; i < RANGE_TREE_HISTOGRAM_SIZE; i++) { ASSERT3U(i, >=, idx + shift); histogram[idx] += rt->rt_histogram[i] << (i - idx - shift); if (idx < SPACE_MAP_HISTOGRAM_SIZE - 1) { ASSERT3U(idx + shift, ==, i); idx++; ASSERT3U(idx, <, SPACE_MAP_HISTOGRAM_SIZE); } } } /* * Called at every sync pass that the metaslab gets synced. * * The reason is that we want our auxiliary histograms to be updated * wherever the metaslab's space map histogram is updated. This way * we stay consistent on which parts of the metaslab space map's * histogram are currently not available for allocations (e.g because * they are in the defer, freed, and freeing trees). */ static void metaslab_aux_histograms_update(metaslab_t *msp) { space_map_t *sm = msp->ms_sm; ASSERT(sm != NULL); /* * This is similar to the metaslab's space map histogram updates * that take place in metaslab_sync(). The only difference is that * we only care about segments that haven't made it into the * ms_allocatable tree yet. */ if (msp->ms_loaded) { metaslab_aux_histograms_clear(msp); metaslab_aux_histogram_add(msp->ms_synchist, sm->sm_shift, msp->ms_freed); for (int t = 0; t < TXG_DEFER_SIZE; t++) { metaslab_aux_histogram_add(msp->ms_deferhist[t], sm->sm_shift, msp->ms_defer[t]); } } metaslab_aux_histogram_add(msp->ms_synchist, sm->sm_shift, msp->ms_freeing); } /* * Called every time we are done syncing (writing to) the metaslab, * i.e. at the end of each sync pass. * [see the comment in metaslab_impl.h for ms_synchist, ms_deferhist] */ static void metaslab_aux_histograms_update_done(metaslab_t *msp, boolean_t defer_allowed) { spa_t *spa = msp->ms_group->mg_vd->vdev_spa; space_map_t *sm = msp->ms_sm; if (sm == NULL) { /* * We came here from metaslab_init() when creating/opening a * pool, looking at a metaslab that hasn't had any allocations * yet. */ return; } /* * This is similar to the actions that we take for the ms_freed * and ms_defer trees in metaslab_sync_done(). */ uint64_t hist_index = spa_syncing_txg(spa) % TXG_DEFER_SIZE; if (defer_allowed) { memcpy(msp->ms_deferhist[hist_index], msp->ms_synchist, sizeof (msp->ms_synchist)); } else { memset(msp->ms_deferhist[hist_index], 0, sizeof (msp->ms_deferhist[hist_index])); } memset(msp->ms_synchist, 0, sizeof (msp->ms_synchist)); } /* * Ensure that the metaslab's weight and fragmentation are consistent * with the contents of the histogram (either the range tree's histogram * or the space map's depending whether the metaslab is loaded). */ static void metaslab_verify_weight_and_frag(metaslab_t *msp) { ASSERT(MUTEX_HELD(&msp->ms_lock)); if ((zfs_flags & ZFS_DEBUG_METASLAB_VERIFY) == 0) return; /* * We can end up here from vdev_remove_complete(), in which case we * cannot do these assertions because we hold spa config locks and * thus we are not allowed to read from the DMU. * * We check if the metaslab group has been removed and if that's * the case we return immediately as that would mean that we are * here from the aforementioned code path. */ if (msp->ms_group == NULL) return; /* * Devices being removed always return a weight of 0 and leave * fragmentation and ms_max_size as is - there is nothing for * us to verify here. */ vdev_t *vd = msp->ms_group->mg_vd; if (vd->vdev_removing) return; /* * If the metaslab is dirty it probably means that we've done * some allocations or frees that have changed our histograms * and thus the weight. */ for (int t = 0; t < TXG_SIZE; t++) { if (txg_list_member(&vd->vdev_ms_list, msp, t)) return; } /* * This verification checks that our in-memory state is consistent * with what's on disk. If the pool is read-only then there aren't * any changes and we just have the initially-loaded state. */ if (!spa_writeable(msp->ms_group->mg_vd->vdev_spa)) return; /* some extra verification for in-core tree if you can */ if (msp->ms_loaded) { range_tree_stat_verify(msp->ms_allocatable); VERIFY(space_map_histogram_verify(msp->ms_sm, msp->ms_allocatable)); } uint64_t weight = msp->ms_weight; uint64_t was_active = msp->ms_weight & METASLAB_ACTIVE_MASK; boolean_t space_based = WEIGHT_IS_SPACEBASED(msp->ms_weight); uint64_t frag = msp->ms_fragmentation; uint64_t max_segsize = msp->ms_max_size; msp->ms_weight = 0; msp->ms_fragmentation = 0; /* * This function is used for verification purposes and thus should * not introduce any side-effects/mutations on the system's state. * * Regardless of whether metaslab_weight() thinks this metaslab * should be active or not, we want to ensure that the actual weight * (and therefore the value of ms_weight) would be the same if it * was to be recalculated at this point. * * In addition we set the nodirty flag so metaslab_weight() does * not dirty the metaslab for future TXGs (e.g. when trying to * force condensing to upgrade the metaslab spacemaps). */ msp->ms_weight = metaslab_weight(msp, B_TRUE) | was_active; VERIFY3U(max_segsize, ==, msp->ms_max_size); /* * If the weight type changed then there is no point in doing * verification. Revert fields to their original values. */ if ((space_based && !WEIGHT_IS_SPACEBASED(msp->ms_weight)) || (!space_based && WEIGHT_IS_SPACEBASED(msp->ms_weight))) { msp->ms_fragmentation = frag; msp->ms_weight = weight; return; } VERIFY3U(msp->ms_fragmentation, ==, frag); VERIFY3U(msp->ms_weight, ==, weight); } /* * If we're over the zfs_metaslab_mem_limit, select the loaded metaslab from * this class that was used longest ago, and attempt to unload it. We don't * want to spend too much time in this loop to prevent performance * degradation, and we expect that most of the time this operation will * succeed. Between that and the normal unloading processing during txg sync, * we expect this to keep the metaslab memory usage under control. */ static void metaslab_potentially_evict(metaslab_class_t *mc) { #ifdef _KERNEL uint64_t allmem = arc_all_memory(); uint64_t inuse = spl_kmem_cache_inuse(zfs_btree_leaf_cache); uint64_t size = spl_kmem_cache_entry_size(zfs_btree_leaf_cache); int tries = 0; for (; allmem * zfs_metaslab_mem_limit / 100 < inuse * size && tries < multilist_get_num_sublists(&mc->mc_metaslab_txg_list) * 2; tries++) { unsigned int idx = multilist_get_random_index( &mc->mc_metaslab_txg_list); multilist_sublist_t *mls = multilist_sublist_lock(&mc->mc_metaslab_txg_list, idx); metaslab_t *msp = multilist_sublist_head(mls); multilist_sublist_unlock(mls); while (msp != NULL && allmem * zfs_metaslab_mem_limit / 100 < inuse * size) { VERIFY3P(mls, ==, multilist_sublist_lock( &mc->mc_metaslab_txg_list, idx)); ASSERT3U(idx, ==, metaslab_idx_func(&mc->mc_metaslab_txg_list, msp)); if (!multilist_link_active(&msp->ms_class_txg_node)) { multilist_sublist_unlock(mls); break; } metaslab_t *next_msp = multilist_sublist_next(mls, msp); multilist_sublist_unlock(mls); /* * If the metaslab is currently loading there are two * cases. If it's the metaslab we're evicting, we * can't continue on or we'll panic when we attempt to * recursively lock the mutex. If it's another * metaslab that's loading, it can be safely skipped, * since we know it's very new and therefore not a * good eviction candidate. We check later once the * lock is held that the metaslab is fully loaded * before actually unloading it. */ if (msp->ms_loading) { msp = next_msp; inuse = spl_kmem_cache_inuse(zfs_btree_leaf_cache); continue; } /* * We can't unload metaslabs with no spacemap because * they're not ready to be unloaded yet. We can't * unload metaslabs with outstanding allocations * because doing so could cause the metaslab's weight * to decrease while it's unloaded, which violates an * invariant that we use to prevent unnecessary * loading. We also don't unload metaslabs that are * currently active because they are high-weight * metaslabs that are likely to be used in the near * future. */ mutex_enter(&msp->ms_lock); if (msp->ms_allocator == -1 && msp->ms_sm != NULL && msp->ms_allocating_total == 0) { metaslab_unload(msp); } mutex_exit(&msp->ms_lock); msp = next_msp; inuse = spl_kmem_cache_inuse(zfs_btree_leaf_cache); } } #else (void) mc, (void) zfs_metaslab_mem_limit; #endif } static int metaslab_load_impl(metaslab_t *msp) { int error = 0; ASSERT(MUTEX_HELD(&msp->ms_lock)); ASSERT(msp->ms_loading); ASSERT(!msp->ms_condensing); /* * We temporarily drop the lock to unblock other operations while we * are reading the space map. Therefore, metaslab_sync() and * metaslab_sync_done() can run at the same time as we do. * * If we are using the log space maps, metaslab_sync() can't write to * the metaslab's space map while we are loading as we only write to * it when we are flushing the metaslab, and that can't happen while * we are loading it. * * If we are not using log space maps though, metaslab_sync() can * append to the space map while we are loading. Therefore we load * only entries that existed when we started the load. Additionally, * metaslab_sync_done() has to wait for the load to complete because * there are potential races like metaslab_load() loading parts of the * space map that are currently being appended by metaslab_sync(). If * we didn't, the ms_allocatable would have entries that * metaslab_sync_done() would try to re-add later. * * That's why before dropping the lock we remember the synced length * of the metaslab and read up to that point of the space map, * ignoring entries appended by metaslab_sync() that happen after we * drop the lock. */ uint64_t length = msp->ms_synced_length; mutex_exit(&msp->ms_lock); hrtime_t load_start = gethrtime(); metaslab_rt_arg_t *mrap; if (msp->ms_allocatable->rt_arg == NULL) { mrap = kmem_zalloc(sizeof (*mrap), KM_SLEEP); } else { mrap = msp->ms_allocatable->rt_arg; msp->ms_allocatable->rt_ops = NULL; msp->ms_allocatable->rt_arg = NULL; } mrap->mra_bt = &msp->ms_allocatable_by_size; mrap->mra_floor_shift = metaslab_by_size_min_shift; if (msp->ms_sm != NULL) { error = space_map_load_length(msp->ms_sm, msp->ms_allocatable, SM_FREE, length); /* Now, populate the size-sorted tree. */ metaslab_rt_create(msp->ms_allocatable, mrap); msp->ms_allocatable->rt_ops = &metaslab_rt_ops; msp->ms_allocatable->rt_arg = mrap; struct mssa_arg arg = {0}; arg.rt = msp->ms_allocatable; arg.mra = mrap; range_tree_walk(msp->ms_allocatable, metaslab_size_sorted_add, &arg); } else { /* * Add the size-sorted tree first, since we don't need to load * the metaslab from the spacemap. */ metaslab_rt_create(msp->ms_allocatable, mrap); msp->ms_allocatable->rt_ops = &metaslab_rt_ops; msp->ms_allocatable->rt_arg = mrap; /* * The space map has not been allocated yet, so treat * all the space in the metaslab as free and add it to the * ms_allocatable tree. */ range_tree_add(msp->ms_allocatable, msp->ms_start, msp->ms_size); if (msp->ms_new) { /* * If the ms_sm doesn't exist, this means that this * metaslab hasn't gone through metaslab_sync() and * thus has never been dirtied. So we shouldn't * expect any unflushed allocs or frees from previous * TXGs. */ ASSERT(range_tree_is_empty(msp->ms_unflushed_allocs)); ASSERT(range_tree_is_empty(msp->ms_unflushed_frees)); } } /* * We need to grab the ms_sync_lock to prevent metaslab_sync() from * changing the ms_sm (or log_sm) and the metaslab's range trees * while we are about to use them and populate the ms_allocatable. * The ms_lock is insufficient for this because metaslab_sync() doesn't * hold the ms_lock while writing the ms_checkpointing tree to disk. */ mutex_enter(&msp->ms_sync_lock); mutex_enter(&msp->ms_lock); ASSERT(!msp->ms_condensing); ASSERT(!msp->ms_flushing); if (error != 0) { mutex_exit(&msp->ms_sync_lock); return (error); } ASSERT3P(msp->ms_group, !=, NULL); msp->ms_loaded = B_TRUE; /* * Apply all the unflushed changes to ms_allocatable right * away so any manipulations we do below have a clear view * of what is allocated and what is free. */ range_tree_walk(msp->ms_unflushed_allocs, range_tree_remove, msp->ms_allocatable); range_tree_walk(msp->ms_unflushed_frees, range_tree_add, msp->ms_allocatable); ASSERT3P(msp->ms_group, !=, NULL); spa_t *spa = msp->ms_group->mg_vd->vdev_spa; if (spa_syncing_log_sm(spa) != NULL) { ASSERT(spa_feature_is_enabled(spa, SPA_FEATURE_LOG_SPACEMAP)); /* * If we use a log space map we add all the segments * that are in ms_unflushed_frees so they are available * for allocation. * * ms_allocatable needs to contain all free segments * that are ready for allocations (thus not segments * from ms_freeing, ms_freed, and the ms_defer trees). * But if we grab the lock in this code path at a sync * pass later that 1, then it also contains the * segments of ms_freed (they were added to it earlier * in this path through ms_unflushed_frees). So we * need to remove all the segments that exist in * ms_freed from ms_allocatable as they will be added * later in metaslab_sync_done(). * * When there's no log space map, the ms_allocatable * correctly doesn't contain any segments that exist * in ms_freed [see ms_synced_length]. */ range_tree_walk(msp->ms_freed, range_tree_remove, msp->ms_allocatable); } /* * If we are not using the log space map, ms_allocatable * contains the segments that exist in the ms_defer trees * [see ms_synced_length]. Thus we need to remove them * from ms_allocatable as they will be added again in * metaslab_sync_done(). * * If we are using the log space map, ms_allocatable still * contains the segments that exist in the ms_defer trees. * Not because it read them through the ms_sm though. But * because these segments are part of ms_unflushed_frees * whose segments we add to ms_allocatable earlier in this * code path. */ for (int t = 0; t < TXG_DEFER_SIZE; t++) { range_tree_walk(msp->ms_defer[t], range_tree_remove, msp->ms_allocatable); } /* * Call metaslab_recalculate_weight_and_sort() now that the * metaslab is loaded so we get the metaslab's real weight. * * Unless this metaslab was created with older software and * has not yet been converted to use segment-based weight, we * expect the new weight to be better or equal to the weight * that the metaslab had while it was not loaded. This is * because the old weight does not take into account the * consolidation of adjacent segments between TXGs. [see * comment for ms_synchist and ms_deferhist[] for more info] */ uint64_t weight = msp->ms_weight; uint64_t max_size = msp->ms_max_size; metaslab_recalculate_weight_and_sort(msp); if (!WEIGHT_IS_SPACEBASED(weight)) ASSERT3U(weight, <=, msp->ms_weight); msp->ms_max_size = metaslab_largest_allocatable(msp); ASSERT3U(max_size, <=, msp->ms_max_size); hrtime_t load_end = gethrtime(); msp->ms_load_time = load_end; zfs_dbgmsg("metaslab_load: txg %llu, spa %s, vdev_id %llu, " "ms_id %llu, smp_length %llu, " "unflushed_allocs %llu, unflushed_frees %llu, " "freed %llu, defer %llu + %llu, unloaded time %llu ms, " "loading_time %lld ms, ms_max_size %llu, " "max size error %lld, " "old_weight %llx, new_weight %llx", (u_longlong_t)spa_syncing_txg(spa), spa_name(spa), (u_longlong_t)msp->ms_group->mg_vd->vdev_id, (u_longlong_t)msp->ms_id, (u_longlong_t)space_map_length(msp->ms_sm), (u_longlong_t)range_tree_space(msp->ms_unflushed_allocs), (u_longlong_t)range_tree_space(msp->ms_unflushed_frees), (u_longlong_t)range_tree_space(msp->ms_freed), (u_longlong_t)range_tree_space(msp->ms_defer[0]), (u_longlong_t)range_tree_space(msp->ms_defer[1]), (longlong_t)((load_start - msp->ms_unload_time) / 1000000), (longlong_t)((load_end - load_start) / 1000000), (u_longlong_t)msp->ms_max_size, (u_longlong_t)msp->ms_max_size - max_size, (u_longlong_t)weight, (u_longlong_t)msp->ms_weight); metaslab_verify_space(msp, spa_syncing_txg(spa)); mutex_exit(&msp->ms_sync_lock); return (0); } int metaslab_load(metaslab_t *msp) { ASSERT(MUTEX_HELD(&msp->ms_lock)); /* * There may be another thread loading the same metaslab, if that's * the case just wait until the other thread is done and return. */ metaslab_load_wait(msp); if (msp->ms_loaded) return (0); VERIFY(!msp->ms_loading); ASSERT(!msp->ms_condensing); /* * We set the loading flag BEFORE potentially dropping the lock to * wait for an ongoing flush (see ms_flushing below). This way other * threads know that there is already a thread that is loading this * metaslab. */ msp->ms_loading = B_TRUE; /* * Wait for any in-progress flushing to finish as we drop the ms_lock * both here (during space_map_load()) and in metaslab_flush() (when * we flush our changes to the ms_sm). */ if (msp->ms_flushing) metaslab_flush_wait(msp); /* * In the possibility that we were waiting for the metaslab to be * flushed (where we temporarily dropped the ms_lock), ensure that * no one else loaded the metaslab somehow. */ ASSERT(!msp->ms_loaded); /* * If we're loading a metaslab in the normal class, consider evicting * another one to keep our memory usage under the limit defined by the * zfs_metaslab_mem_limit tunable. */ if (spa_normal_class(msp->ms_group->mg_class->mc_spa) == msp->ms_group->mg_class) { metaslab_potentially_evict(msp->ms_group->mg_class); } int error = metaslab_load_impl(msp); ASSERT(MUTEX_HELD(&msp->ms_lock)); msp->ms_loading = B_FALSE; cv_broadcast(&msp->ms_load_cv); return (error); } void metaslab_unload(metaslab_t *msp) { ASSERT(MUTEX_HELD(&msp->ms_lock)); /* * This can happen if a metaslab is selected for eviction (in * metaslab_potentially_evict) and then unloaded during spa_sync (via * metaslab_class_evict_old). */ if (!msp->ms_loaded) return; range_tree_vacate(msp->ms_allocatable, NULL, NULL); msp->ms_loaded = B_FALSE; msp->ms_unload_time = gethrtime(); msp->ms_activation_weight = 0; msp->ms_weight &= ~METASLAB_ACTIVE_MASK; if (msp->ms_group != NULL) { metaslab_class_t *mc = msp->ms_group->mg_class; multilist_sublist_t *mls = multilist_sublist_lock_obj(&mc->mc_metaslab_txg_list, msp); if (multilist_link_active(&msp->ms_class_txg_node)) multilist_sublist_remove(mls, msp); multilist_sublist_unlock(mls); spa_t *spa = msp->ms_group->mg_vd->vdev_spa; zfs_dbgmsg("metaslab_unload: txg %llu, spa %s, vdev_id %llu, " "ms_id %llu, weight %llx, " "selected txg %llu (%llu ms ago), alloc_txg %llu, " "loaded %llu ms ago, max_size %llu", (u_longlong_t)spa_syncing_txg(spa), spa_name(spa), (u_longlong_t)msp->ms_group->mg_vd->vdev_id, (u_longlong_t)msp->ms_id, (u_longlong_t)msp->ms_weight, (u_longlong_t)msp->ms_selected_txg, (u_longlong_t)(msp->ms_unload_time - msp->ms_selected_time) / 1000 / 1000, (u_longlong_t)msp->ms_alloc_txg, (u_longlong_t)(msp->ms_unload_time - msp->ms_load_time) / 1000 / 1000, (u_longlong_t)msp->ms_max_size); } /* * We explicitly recalculate the metaslab's weight based on its space * map (as it is now not loaded). We want unload metaslabs to always * have their weights calculated from the space map histograms, while * loaded ones have it calculated from their in-core range tree * [see metaslab_load()]. This way, the weight reflects the information * available in-core, whether it is loaded or not. * * If ms_group == NULL means that we came here from metaslab_fini(), * at which point it doesn't make sense for us to do the recalculation * and the sorting. */ if (msp->ms_group != NULL) metaslab_recalculate_weight_and_sort(msp); } /* * We want to optimize the memory use of the per-metaslab range * trees. To do this, we store the segments in the range trees in * units of sectors, zero-indexing from the start of the metaslab. If * the vdev_ms_shift - the vdev_ashift is less than 32, we can store * the ranges using two uint32_ts, rather than two uint64_ts. */ range_seg_type_t metaslab_calculate_range_tree_type(vdev_t *vdev, metaslab_t *msp, uint64_t *start, uint64_t *shift) { if (vdev->vdev_ms_shift - vdev->vdev_ashift < 32 && !zfs_metaslab_force_large_segs) { *shift = vdev->vdev_ashift; *start = msp->ms_start; return (RANGE_SEG32); } else { *shift = 0; *start = 0; return (RANGE_SEG64); } } void metaslab_set_selected_txg(metaslab_t *msp, uint64_t txg) { ASSERT(MUTEX_HELD(&msp->ms_lock)); metaslab_class_t *mc = msp->ms_group->mg_class; multilist_sublist_t *mls = multilist_sublist_lock_obj(&mc->mc_metaslab_txg_list, msp); if (multilist_link_active(&msp->ms_class_txg_node)) multilist_sublist_remove(mls, msp); msp->ms_selected_txg = txg; msp->ms_selected_time = gethrtime(); multilist_sublist_insert_tail(mls, msp); multilist_sublist_unlock(mls); } void metaslab_space_update(vdev_t *vd, metaslab_class_t *mc, int64_t alloc_delta, int64_t defer_delta, int64_t space_delta) { vdev_space_update(vd, alloc_delta, defer_delta, space_delta); ASSERT3P(vd->vdev_spa->spa_root_vdev, ==, vd->vdev_parent); ASSERT(vd->vdev_ms_count != 0); metaslab_class_space_update(mc, alloc_delta, defer_delta, space_delta, vdev_deflated_space(vd, space_delta)); } int metaslab_init(metaslab_group_t *mg, uint64_t id, uint64_t object, uint64_t txg, metaslab_t **msp) { vdev_t *vd = mg->mg_vd; spa_t *spa = vd->vdev_spa; objset_t *mos = spa->spa_meta_objset; metaslab_t *ms; int error; ms = kmem_zalloc(sizeof (metaslab_t), KM_SLEEP); mutex_init(&ms->ms_lock, NULL, MUTEX_DEFAULT, NULL); mutex_init(&ms->ms_sync_lock, NULL, MUTEX_DEFAULT, NULL); cv_init(&ms->ms_load_cv, NULL, CV_DEFAULT, NULL); cv_init(&ms->ms_flush_cv, NULL, CV_DEFAULT, NULL); multilist_link_init(&ms->ms_class_txg_node); ms->ms_id = id; ms->ms_start = id << vd->vdev_ms_shift; ms->ms_size = 1ULL << vd->vdev_ms_shift; ms->ms_allocator = -1; ms->ms_new = B_TRUE; vdev_ops_t *ops = vd->vdev_ops; if (ops->vdev_op_metaslab_init != NULL) ops->vdev_op_metaslab_init(vd, &ms->ms_start, &ms->ms_size); /* * We only open space map objects that already exist. All others * will be opened when we finally allocate an object for it. For * readonly pools there is no need to open the space map object. * * Note: * When called from vdev_expand(), we can't call into the DMU as * we are holding the spa_config_lock as a writer and we would * deadlock [see relevant comment in vdev_metaslab_init()]. in * that case, the object parameter is zero though, so we won't * call into the DMU. */ if (object != 0 && !(spa->spa_mode == SPA_MODE_READ && !spa->spa_read_spacemaps)) { error = space_map_open(&ms->ms_sm, mos, object, ms->ms_start, ms->ms_size, vd->vdev_ashift); if (error != 0) { kmem_free(ms, sizeof (metaslab_t)); return (error); } ASSERT(ms->ms_sm != NULL); ms->ms_allocated_space = space_map_allocated(ms->ms_sm); } uint64_t shift, start; range_seg_type_t type = metaslab_calculate_range_tree_type(vd, ms, &start, &shift); ms->ms_allocatable = range_tree_create(NULL, type, NULL, start, shift); for (int t = 0; t < TXG_SIZE; t++) { ms->ms_allocating[t] = range_tree_create(NULL, type, NULL, start, shift); } ms->ms_freeing = range_tree_create(NULL, type, NULL, start, shift); ms->ms_freed = range_tree_create(NULL, type, NULL, start, shift); for (int t = 0; t < TXG_DEFER_SIZE; t++) { ms->ms_defer[t] = range_tree_create(NULL, type, NULL, start, shift); } ms->ms_checkpointing = range_tree_create(NULL, type, NULL, start, shift); ms->ms_unflushed_allocs = range_tree_create(NULL, type, NULL, start, shift); metaslab_rt_arg_t *mrap = kmem_zalloc(sizeof (*mrap), KM_SLEEP); mrap->mra_bt = &ms->ms_unflushed_frees_by_size; mrap->mra_floor_shift = metaslab_by_size_min_shift; ms->ms_unflushed_frees = range_tree_create(&metaslab_rt_ops, type, mrap, start, shift); ms->ms_trim = range_tree_create(NULL, type, NULL, start, shift); metaslab_group_add(mg, ms); metaslab_set_fragmentation(ms, B_FALSE); /* * If we're opening an existing pool (txg == 0) or creating * a new one (txg == TXG_INITIAL), all space is available now. * If we're adding space to an existing pool, the new space * does not become available until after this txg has synced. * The metaslab's weight will also be initialized when we sync * out this txg. This ensures that we don't attempt to allocate * from it before we have initialized it completely. */ if (txg <= TXG_INITIAL) { metaslab_sync_done(ms, 0); metaslab_space_update(vd, mg->mg_class, metaslab_allocated_space(ms), 0, 0); } if (txg != 0) { vdev_dirty(vd, 0, NULL, txg); vdev_dirty(vd, VDD_METASLAB, ms, txg); } *msp = ms; return (0); } static void metaslab_fini_flush_data(metaslab_t *msp) { spa_t *spa = msp->ms_group->mg_vd->vdev_spa; if (metaslab_unflushed_txg(msp) == 0) { ASSERT3P(avl_find(&spa->spa_metaslabs_by_flushed, msp, NULL), ==, NULL); return; } ASSERT(spa_feature_is_active(spa, SPA_FEATURE_LOG_SPACEMAP)); mutex_enter(&spa->spa_flushed_ms_lock); avl_remove(&spa->spa_metaslabs_by_flushed, msp); mutex_exit(&spa->spa_flushed_ms_lock); spa_log_sm_decrement_mscount(spa, metaslab_unflushed_txg(msp)); spa_log_summary_decrement_mscount(spa, metaslab_unflushed_txg(msp), metaslab_unflushed_dirty(msp)); } uint64_t metaslab_unflushed_changes_memused(metaslab_t *ms) { return ((range_tree_numsegs(ms->ms_unflushed_allocs) + range_tree_numsegs(ms->ms_unflushed_frees)) * ms->ms_unflushed_allocs->rt_root.bt_elem_size); } void metaslab_fini(metaslab_t *msp) { metaslab_group_t *mg = msp->ms_group; vdev_t *vd = mg->mg_vd; spa_t *spa = vd->vdev_spa; metaslab_fini_flush_data(msp); metaslab_group_remove(mg, msp); mutex_enter(&msp->ms_lock); VERIFY(msp->ms_group == NULL); /* * If this metaslab hasn't been through metaslab_sync_done() yet its * space hasn't been accounted for in its vdev and doesn't need to be * subtracted. */ if (!msp->ms_new) { metaslab_space_update(vd, mg->mg_class, -metaslab_allocated_space(msp), 0, -msp->ms_size); } space_map_close(msp->ms_sm); msp->ms_sm = NULL; metaslab_unload(msp); range_tree_destroy(msp->ms_allocatable); range_tree_destroy(msp->ms_freeing); range_tree_destroy(msp->ms_freed); ASSERT3U(spa->spa_unflushed_stats.sus_memused, >=, metaslab_unflushed_changes_memused(msp)); spa->spa_unflushed_stats.sus_memused -= metaslab_unflushed_changes_memused(msp); range_tree_vacate(msp->ms_unflushed_allocs, NULL, NULL); range_tree_destroy(msp->ms_unflushed_allocs); range_tree_destroy(msp->ms_checkpointing); range_tree_vacate(msp->ms_unflushed_frees, NULL, NULL); range_tree_destroy(msp->ms_unflushed_frees); for (int t = 0; t < TXG_SIZE; t++) { range_tree_destroy(msp->ms_allocating[t]); } for (int t = 0; t < TXG_DEFER_SIZE; t++) { range_tree_destroy(msp->ms_defer[t]); } ASSERT0(msp->ms_deferspace); for (int t = 0; t < TXG_SIZE; t++) ASSERT(!txg_list_member(&vd->vdev_ms_list, msp, t)); range_tree_vacate(msp->ms_trim, NULL, NULL); range_tree_destroy(msp->ms_trim); mutex_exit(&msp->ms_lock); cv_destroy(&msp->ms_load_cv); cv_destroy(&msp->ms_flush_cv); mutex_destroy(&msp->ms_lock); mutex_destroy(&msp->ms_sync_lock); ASSERT3U(msp->ms_allocator, ==, -1); kmem_free(msp, sizeof (metaslab_t)); } #define FRAGMENTATION_TABLE_SIZE 17 /* * This table defines a segment size based fragmentation metric that will * allow each metaslab to derive its own fragmentation value. This is done * by calculating the space in each bucket of the spacemap histogram and * multiplying that by the fragmentation metric in this table. Doing * this for all buckets and dividing it by the total amount of free * space in this metaslab (i.e. the total free space in all buckets) gives * us the fragmentation metric. This means that a high fragmentation metric * equates to most of the free space being comprised of small segments. * Conversely, if the metric is low, then most of the free space is in * large segments. A 10% change in fragmentation equates to approximately * double the number of segments. * * This table defines 0% fragmented space using 16MB segments. Testing has * shown that segments that are greater than or equal to 16MB do not suffer * from drastic performance problems. Using this value, we derive the rest * of the table. Since the fragmentation value is never stored on disk, it * is possible to change these calculations in the future. */ static const int zfs_frag_table[FRAGMENTATION_TABLE_SIZE] = { 100, /* 512B */ 100, /* 1K */ 98, /* 2K */ 95, /* 4K */ 90, /* 8K */ 80, /* 16K */ 70, /* 32K */ 60, /* 64K */ 50, /* 128K */ 40, /* 256K */ 30, /* 512K */ 20, /* 1M */ 15, /* 2M */ 10, /* 4M */ 5, /* 8M */ 0 /* 16M */ }; /* * Calculate the metaslab's fragmentation metric and set ms_fragmentation. * Setting this value to ZFS_FRAG_INVALID means that the metaslab has not * been upgraded and does not support this metric. Otherwise, the return * value should be in the range [0, 100]. */ static void metaslab_set_fragmentation(metaslab_t *msp, boolean_t nodirty) { spa_t *spa = msp->ms_group->mg_vd->vdev_spa; uint64_t fragmentation = 0; uint64_t total = 0; boolean_t feature_enabled = spa_feature_is_enabled(spa, SPA_FEATURE_SPACEMAP_HISTOGRAM); if (!feature_enabled) { msp->ms_fragmentation = ZFS_FRAG_INVALID; return; } /* * A null space map means that the entire metaslab is free * and thus is not fragmented. */ if (msp->ms_sm == NULL) { msp->ms_fragmentation = 0; return; } /* * If this metaslab's space map has not been upgraded, flag it * so that we upgrade next time we encounter it. */ if (msp->ms_sm->sm_dbuf->db_size != sizeof (space_map_phys_t)) { uint64_t txg = spa_syncing_txg(spa); vdev_t *vd = msp->ms_group->mg_vd; /* * If we've reached the final dirty txg, then we must * be shutting down the pool. We don't want to dirty * any data past this point so skip setting the condense * flag. We can retry this action the next time the pool * is imported. We also skip marking this metaslab for * condensing if the caller has explicitly set nodirty. */ if (!nodirty && spa_writeable(spa) && txg < spa_final_dirty_txg(spa)) { msp->ms_condense_wanted = B_TRUE; vdev_dirty(vd, VDD_METASLAB, msp, txg + 1); zfs_dbgmsg("txg %llu, requesting force condense: " "ms_id %llu, vdev_id %llu", (u_longlong_t)txg, (u_longlong_t)msp->ms_id, (u_longlong_t)vd->vdev_id); } msp->ms_fragmentation = ZFS_FRAG_INVALID; return; } for (int i = 0; i < SPACE_MAP_HISTOGRAM_SIZE; i++) { uint64_t space = 0; uint8_t shift = msp->ms_sm->sm_shift; int idx = MIN(shift - SPA_MINBLOCKSHIFT + i, FRAGMENTATION_TABLE_SIZE - 1); if (msp->ms_sm->sm_phys->smp_histogram[i] == 0) continue; space = msp->ms_sm->sm_phys->smp_histogram[i] << (i + shift); total += space; ASSERT3U(idx, <, FRAGMENTATION_TABLE_SIZE); fragmentation += space * zfs_frag_table[idx]; } if (total > 0) fragmentation /= total; ASSERT3U(fragmentation, <=, 100); msp->ms_fragmentation = fragmentation; } /* * Compute a weight -- a selection preference value -- for the given metaslab. * This is based on the amount of free space, the level of fragmentation, * the LBA range, and whether the metaslab is loaded. */ static uint64_t metaslab_space_weight(metaslab_t *msp) { metaslab_group_t *mg = msp->ms_group; vdev_t *vd = mg->mg_vd; uint64_t weight, space; ASSERT(MUTEX_HELD(&msp->ms_lock)); /* * The baseline weight is the metaslab's free space. */ space = msp->ms_size - metaslab_allocated_space(msp); if (metaslab_fragmentation_factor_enabled && msp->ms_fragmentation != ZFS_FRAG_INVALID) { /* * Use the fragmentation information to inversely scale * down the baseline weight. We need to ensure that we * don't exclude this metaslab completely when it's 100% * fragmented. To avoid this we reduce the fragmented value * by 1. */ space = (space * (100 - (msp->ms_fragmentation - 1))) / 100; /* * If space < SPA_MINBLOCKSIZE, then we will not allocate from * this metaslab again. The fragmentation metric may have * decreased the space to something smaller than * SPA_MINBLOCKSIZE, so reset the space to SPA_MINBLOCKSIZE * so that we can consume any remaining space. */ if (space > 0 && space < SPA_MINBLOCKSIZE) space = SPA_MINBLOCKSIZE; } weight = space; /* * Modern disks have uniform bit density and constant angular velocity. * Therefore, the outer recording zones are faster (higher bandwidth) * than the inner zones by the ratio of outer to inner track diameter, * which is typically around 2:1. We account for this by assigning * higher weight to lower metaslabs (multiplier ranging from 2x to 1x). * In effect, this means that we'll select the metaslab with the most * free bandwidth rather than simply the one with the most free space. */ if (!vd->vdev_nonrot && metaslab_lba_weighting_enabled) { weight = 2 * weight - (msp->ms_id * weight) / vd->vdev_ms_count; ASSERT(weight >= space && weight <= 2 * space); } /* * If this metaslab is one we're actively using, adjust its * weight to make it preferable to any inactive metaslab so * we'll polish it off. If the fragmentation on this metaslab * has exceed our threshold, then don't mark it active. */ if (msp->ms_loaded && msp->ms_fragmentation != ZFS_FRAG_INVALID && msp->ms_fragmentation <= zfs_metaslab_fragmentation_threshold) { weight |= (msp->ms_weight & METASLAB_ACTIVE_MASK); } WEIGHT_SET_SPACEBASED(weight); return (weight); } /* * Return the weight of the specified metaslab, according to the segment-based * weighting algorithm. The metaslab must be loaded. This function can * be called within a sync pass since it relies only on the metaslab's * range tree which is always accurate when the metaslab is loaded. */ static uint64_t metaslab_weight_from_range_tree(metaslab_t *msp) { uint64_t weight = 0; uint32_t segments = 0; ASSERT(msp->ms_loaded); for (int i = RANGE_TREE_HISTOGRAM_SIZE - 1; i >= SPA_MINBLOCKSHIFT; i--) { uint8_t shift = msp->ms_group->mg_vd->vdev_ashift; int max_idx = SPACE_MAP_HISTOGRAM_SIZE + shift - 1; segments <<= 1; segments += msp->ms_allocatable->rt_histogram[i]; /* * The range tree provides more precision than the space map * and must be downgraded so that all values fit within the * space map's histogram. This allows us to compare loaded * vs. unloaded metaslabs to determine which metaslab is * considered "best". */ if (i > max_idx) continue; if (segments != 0) { WEIGHT_SET_COUNT(weight, segments); WEIGHT_SET_INDEX(weight, i); WEIGHT_SET_ACTIVE(weight, 0); break; } } return (weight); } /* * Calculate the weight based on the on-disk histogram. Should be applied * only to unloaded metaslabs (i.e no incoming allocations) in-order to * give results consistent with the on-disk state */ static uint64_t metaslab_weight_from_spacemap(metaslab_t *msp) { space_map_t *sm = msp->ms_sm; ASSERT(!msp->ms_loaded); ASSERT(sm != NULL); ASSERT3U(space_map_object(sm), !=, 0); ASSERT3U(sm->sm_dbuf->db_size, ==, sizeof (space_map_phys_t)); /* * Create a joint histogram from all the segments that have made * it to the metaslab's space map histogram, that are not yet * available for allocation because they are still in the freeing * pipeline (e.g. freeing, freed, and defer trees). Then subtract * these segments from the space map's histogram to get a more * accurate weight. */ uint64_t deferspace_histogram[SPACE_MAP_HISTOGRAM_SIZE] = {0}; for (int i = 0; i < SPACE_MAP_HISTOGRAM_SIZE; i++) deferspace_histogram[i] += msp->ms_synchist[i]; for (int t = 0; t < TXG_DEFER_SIZE; t++) { for (int i = 0; i < SPACE_MAP_HISTOGRAM_SIZE; i++) { deferspace_histogram[i] += msp->ms_deferhist[t][i]; } } uint64_t weight = 0; for (int i = SPACE_MAP_HISTOGRAM_SIZE - 1; i >= 0; i--) { ASSERT3U(sm->sm_phys->smp_histogram[i], >=, deferspace_histogram[i]); uint64_t count = sm->sm_phys->smp_histogram[i] - deferspace_histogram[i]; if (count != 0) { WEIGHT_SET_COUNT(weight, count); WEIGHT_SET_INDEX(weight, i + sm->sm_shift); WEIGHT_SET_ACTIVE(weight, 0); break; } } return (weight); } /* * Compute a segment-based weight for the specified metaslab. The weight * is determined by highest bucket in the histogram. The information * for the highest bucket is encoded into the weight value. */ static uint64_t metaslab_segment_weight(metaslab_t *msp) { metaslab_group_t *mg = msp->ms_group; uint64_t weight = 0; uint8_t shift = mg->mg_vd->vdev_ashift; ASSERT(MUTEX_HELD(&msp->ms_lock)); /* * The metaslab is completely free. */ if (metaslab_allocated_space(msp) == 0) { int idx = highbit64(msp->ms_size) - 1; int max_idx = SPACE_MAP_HISTOGRAM_SIZE + shift - 1; if (idx < max_idx) { WEIGHT_SET_COUNT(weight, 1ULL); WEIGHT_SET_INDEX(weight, idx); } else { WEIGHT_SET_COUNT(weight, 1ULL << (idx - max_idx)); WEIGHT_SET_INDEX(weight, max_idx); } WEIGHT_SET_ACTIVE(weight, 0); ASSERT(!WEIGHT_IS_SPACEBASED(weight)); return (weight); } ASSERT3U(msp->ms_sm->sm_dbuf->db_size, ==, sizeof (space_map_phys_t)); /* * If the metaslab is fully allocated then just make the weight 0. */ if (metaslab_allocated_space(msp) == msp->ms_size) return (0); /* * If the metaslab is already loaded, then use the range tree to * determine the weight. Otherwise, we rely on the space map information * to generate the weight. */ if (msp->ms_loaded) { weight = metaslab_weight_from_range_tree(msp); } else { weight = metaslab_weight_from_spacemap(msp); } /* * If the metaslab was active the last time we calculated its weight * then keep it active. We want to consume the entire region that * is associated with this weight. */ if (msp->ms_activation_weight != 0 && weight != 0) WEIGHT_SET_ACTIVE(weight, WEIGHT_GET_ACTIVE(msp->ms_weight)); return (weight); } /* * Determine if we should attempt to allocate from this metaslab. If the * metaslab is loaded, then we can determine if the desired allocation * can be satisfied by looking at the size of the maximum free segment * on that metaslab. Otherwise, we make our decision based on the metaslab's * weight. For segment-based weighting we can determine the maximum * allocation based on the index encoded in its value. For space-based * weights we rely on the entire weight (excluding the weight-type bit). */ static boolean_t metaslab_should_allocate(metaslab_t *msp, uint64_t asize, boolean_t try_hard) { /* * If the metaslab is loaded, ms_max_size is definitive and we can use * the fast check. If it's not, the ms_max_size is a lower bound (once * set), and we should use the fast check as long as we're not in * try_hard and it's been less than zfs_metaslab_max_size_cache_sec * seconds since the metaslab was unloaded. */ if (msp->ms_loaded || (msp->ms_max_size != 0 && !try_hard && gethrtime() < msp->ms_unload_time + SEC2NSEC(zfs_metaslab_max_size_cache_sec))) return (msp->ms_max_size >= asize); boolean_t should_allocate; if (!WEIGHT_IS_SPACEBASED(msp->ms_weight)) { /* * The metaslab segment weight indicates segments in the * range [2^i, 2^(i+1)), where i is the index in the weight. * Since the asize might be in the middle of the range, we * should attempt the allocation if asize < 2^(i+1). */ should_allocate = (asize < 1ULL << (WEIGHT_GET_INDEX(msp->ms_weight) + 1)); } else { should_allocate = (asize <= (msp->ms_weight & ~METASLAB_WEIGHT_TYPE)); } return (should_allocate); } static uint64_t metaslab_weight(metaslab_t *msp, boolean_t nodirty) { vdev_t *vd = msp->ms_group->mg_vd; spa_t *spa = vd->vdev_spa; uint64_t weight; ASSERT(MUTEX_HELD(&msp->ms_lock)); metaslab_set_fragmentation(msp, nodirty); /* * Update the maximum size. If the metaslab is loaded, this will * ensure that we get an accurate maximum size if newly freed space * has been added back into the free tree. If the metaslab is * unloaded, we check if there's a larger free segment in the * unflushed frees. This is a lower bound on the largest allocatable * segment size. Coalescing of adjacent entries may reveal larger * allocatable segments, but we aren't aware of those until loading * the space map into a range tree. */ if (msp->ms_loaded) { msp->ms_max_size = metaslab_largest_allocatable(msp); } else { msp->ms_max_size = MAX(msp->ms_max_size, metaslab_largest_unflushed_free(msp)); } /* * Segment-based weighting requires space map histogram support. */ if (zfs_metaslab_segment_weight_enabled && spa_feature_is_enabled(spa, SPA_FEATURE_SPACEMAP_HISTOGRAM) && (msp->ms_sm == NULL || msp->ms_sm->sm_dbuf->db_size == sizeof (space_map_phys_t))) { weight = metaslab_segment_weight(msp); } else { weight = metaslab_space_weight(msp); } return (weight); } void metaslab_recalculate_weight_and_sort(metaslab_t *msp) { ASSERT(MUTEX_HELD(&msp->ms_lock)); /* note: we preserve the mask (e.g. indication of primary, etc..) */ uint64_t was_active = msp->ms_weight & METASLAB_ACTIVE_MASK; metaslab_group_sort(msp->ms_group, msp, metaslab_weight(msp, B_FALSE) | was_active); } static int metaslab_activate_allocator(metaslab_group_t *mg, metaslab_t *msp, int allocator, uint64_t activation_weight) { metaslab_group_allocator_t *mga = &mg->mg_allocator[allocator]; ASSERT(MUTEX_HELD(&msp->ms_lock)); /* * If we're activating for the claim code, we don't want to actually * set the metaslab up for a specific allocator. */ if (activation_weight == METASLAB_WEIGHT_CLAIM) { ASSERT0(msp->ms_activation_weight); msp->ms_activation_weight = msp->ms_weight; metaslab_group_sort(mg, msp, msp->ms_weight | activation_weight); return (0); } metaslab_t **mspp = (activation_weight == METASLAB_WEIGHT_PRIMARY ? &mga->mga_primary : &mga->mga_secondary); mutex_enter(&mg->mg_lock); if (*mspp != NULL) { mutex_exit(&mg->mg_lock); return (EEXIST); } *mspp = msp; ASSERT3S(msp->ms_allocator, ==, -1); msp->ms_allocator = allocator; msp->ms_primary = (activation_weight == METASLAB_WEIGHT_PRIMARY); ASSERT0(msp->ms_activation_weight); msp->ms_activation_weight = msp->ms_weight; metaslab_group_sort_impl(mg, msp, msp->ms_weight | activation_weight); mutex_exit(&mg->mg_lock); return (0); } static int metaslab_activate(metaslab_t *msp, int allocator, uint64_t activation_weight) { ASSERT(MUTEX_HELD(&msp->ms_lock)); /* * The current metaslab is already activated for us so there * is nothing to do. Already activated though, doesn't mean * that this metaslab is activated for our allocator nor our * requested activation weight. The metaslab could have started * as an active one for our allocator but changed allocators * while we were waiting to grab its ms_lock or we stole it * [see find_valid_metaslab()]. This means that there is a * possibility of passivating a metaslab of another allocator * or from a different activation mask, from this thread. */ if ((msp->ms_weight & METASLAB_ACTIVE_MASK) != 0) { ASSERT(msp->ms_loaded); return (0); } int error = metaslab_load(msp); if (error != 0) { metaslab_group_sort(msp->ms_group, msp, 0); return (error); } /* * When entering metaslab_load() we may have dropped the * ms_lock because we were loading this metaslab, or we * were waiting for another thread to load it for us. In * that scenario, we recheck the weight of the metaslab * to see if it was activated by another thread. * * If the metaslab was activated for another allocator or * it was activated with a different activation weight (e.g. * we wanted to make it a primary but it was activated as * secondary) we return error (EBUSY). * * If the metaslab was activated for the same allocator * and requested activation mask, skip activating it. */ if ((msp->ms_weight & METASLAB_ACTIVE_MASK) != 0) { if (msp->ms_allocator != allocator) return (EBUSY); if ((msp->ms_weight & activation_weight) == 0) return (SET_ERROR(EBUSY)); EQUIV((activation_weight == METASLAB_WEIGHT_PRIMARY), msp->ms_primary); return (0); } /* * If the metaslab has literally 0 space, it will have weight 0. In * that case, don't bother activating it. This can happen if the * metaslab had space during find_valid_metaslab, but another thread * loaded it and used all that space while we were waiting to grab the * lock. */ if (msp->ms_weight == 0) { ASSERT0(range_tree_space(msp->ms_allocatable)); return (SET_ERROR(ENOSPC)); } if ((error = metaslab_activate_allocator(msp->ms_group, msp, allocator, activation_weight)) != 0) { return (error); } ASSERT(msp->ms_loaded); ASSERT(msp->ms_weight & METASLAB_ACTIVE_MASK); return (0); } static void metaslab_passivate_allocator(metaslab_group_t *mg, metaslab_t *msp, uint64_t weight) { ASSERT(MUTEX_HELD(&msp->ms_lock)); ASSERT(msp->ms_loaded); if (msp->ms_weight & METASLAB_WEIGHT_CLAIM) { metaslab_group_sort(mg, msp, weight); return; } mutex_enter(&mg->mg_lock); ASSERT3P(msp->ms_group, ==, mg); ASSERT3S(0, <=, msp->ms_allocator); ASSERT3U(msp->ms_allocator, <, mg->mg_allocators); metaslab_group_allocator_t *mga = &mg->mg_allocator[msp->ms_allocator]; if (msp->ms_primary) { ASSERT3P(mga->mga_primary, ==, msp); ASSERT(msp->ms_weight & METASLAB_WEIGHT_PRIMARY); mga->mga_primary = NULL; } else { ASSERT3P(mga->mga_secondary, ==, msp); ASSERT(msp->ms_weight & METASLAB_WEIGHT_SECONDARY); mga->mga_secondary = NULL; } msp->ms_allocator = -1; metaslab_group_sort_impl(mg, msp, weight); mutex_exit(&mg->mg_lock); } static void metaslab_passivate(metaslab_t *msp, uint64_t weight) { uint64_t size __maybe_unused = weight & ~METASLAB_WEIGHT_TYPE; /* * If size < SPA_MINBLOCKSIZE, then we will not allocate from * this metaslab again. In that case, it had better be empty, * or we would be leaving space on the table. */ ASSERT(!WEIGHT_IS_SPACEBASED(msp->ms_weight) || size >= SPA_MINBLOCKSIZE || range_tree_space(msp->ms_allocatable) == 0); ASSERT0(weight & METASLAB_ACTIVE_MASK); ASSERT(msp->ms_activation_weight != 0); msp->ms_activation_weight = 0; metaslab_passivate_allocator(msp->ms_group, msp, weight); ASSERT0(msp->ms_weight & METASLAB_ACTIVE_MASK); } /* * Segment-based metaslabs are activated once and remain active until * we either fail an allocation attempt (similar to space-based metaslabs) * or have exhausted the free space in zfs_metaslab_switch_threshold * buckets since the metaslab was activated. This function checks to see * if we've exhausted the zfs_metaslab_switch_threshold buckets in the * metaslab and passivates it proactively. This will allow us to select a * metaslab with a larger contiguous region, if any, remaining within this * metaslab group. If we're in sync pass > 1, then we continue using this * metaslab so that we don't dirty more block and cause more sync passes. */ static void metaslab_segment_may_passivate(metaslab_t *msp) { spa_t *spa = msp->ms_group->mg_vd->vdev_spa; if (WEIGHT_IS_SPACEBASED(msp->ms_weight) || spa_sync_pass(spa) > 1) return; /* * Since we are in the middle of a sync pass, the most accurate * information that is accessible to us is the in-core range tree * histogram; calculate the new weight based on that information. */ uint64_t weight = metaslab_weight_from_range_tree(msp); int activation_idx = WEIGHT_GET_INDEX(msp->ms_activation_weight); int current_idx = WEIGHT_GET_INDEX(weight); if (current_idx <= activation_idx - zfs_metaslab_switch_threshold) metaslab_passivate(msp, weight); } static void metaslab_preload(void *arg) { metaslab_t *msp = arg; metaslab_class_t *mc = msp->ms_group->mg_class; spa_t *spa = mc->mc_spa; fstrans_cookie_t cookie = spl_fstrans_mark(); ASSERT(!MUTEX_HELD(&msp->ms_group->mg_lock)); mutex_enter(&msp->ms_lock); (void) metaslab_load(msp); metaslab_set_selected_txg(msp, spa_syncing_txg(spa)); mutex_exit(&msp->ms_lock); spl_fstrans_unmark(cookie); } static void metaslab_group_preload(metaslab_group_t *mg) { spa_t *spa = mg->mg_vd->vdev_spa; metaslab_t *msp; avl_tree_t *t = &mg->mg_metaslab_tree; int m = 0; if (spa_shutting_down(spa) || !metaslab_preload_enabled) { taskq_wait_outstanding(mg->mg_taskq, 0); return; } mutex_enter(&mg->mg_lock); /* * Load the next potential metaslabs */ for (msp = avl_first(t); msp != NULL; msp = AVL_NEXT(t, msp)) { ASSERT3P(msp->ms_group, ==, mg); /* * We preload only the maximum number of metaslabs specified * by metaslab_preload_limit. If a metaslab is being forced * to condense then we preload it too. This will ensure * that force condensing happens in the next txg. */ if (++m > metaslab_preload_limit && !msp->ms_condense_wanted) { continue; } VERIFY(taskq_dispatch(mg->mg_taskq, metaslab_preload, msp, TQ_SLEEP) != TASKQID_INVALID); } mutex_exit(&mg->mg_lock); } /* * Determine if the space map's on-disk footprint is past our tolerance for * inefficiency. We would like to use the following criteria to make our * decision: * * 1. Do not condense if the size of the space map object would dramatically * increase as a result of writing out the free space range tree. * * 2. Condense if the on on-disk space map representation is at least * zfs_condense_pct/100 times the size of the optimal representation * (i.e. zfs_condense_pct = 110 and in-core = 1MB, optimal = 1.1MB). * * 3. Do not condense if the on-disk size of the space map does not actually * decrease. * * Unfortunately, we cannot compute the on-disk size of the space map in this * context because we cannot accurately compute the effects of compression, etc. * Instead, we apply the heuristic described in the block comment for * zfs_metaslab_condense_block_threshold - we only condense if the space used * is greater than a threshold number of blocks. */ static boolean_t metaslab_should_condense(metaslab_t *msp) { space_map_t *sm = msp->ms_sm; vdev_t *vd = msp->ms_group->mg_vd; - uint64_t vdev_blocksize = 1 << vd->vdev_ashift; + uint64_t vdev_blocksize = 1ULL << vd->vdev_ashift; ASSERT(MUTEX_HELD(&msp->ms_lock)); ASSERT(msp->ms_loaded); ASSERT(sm != NULL); ASSERT3U(spa_sync_pass(vd->vdev_spa), ==, 1); /* * We always condense metaslabs that are empty and metaslabs for * which a condense request has been made. */ if (range_tree_numsegs(msp->ms_allocatable) == 0 || msp->ms_condense_wanted) return (B_TRUE); uint64_t record_size = MAX(sm->sm_blksz, vdev_blocksize); uint64_t object_size = space_map_length(sm); uint64_t optimal_size = space_map_estimate_optimal_size(sm, msp->ms_allocatable, SM_NO_VDEVID); return (object_size >= (optimal_size * zfs_condense_pct / 100) && object_size > zfs_metaslab_condense_block_threshold * record_size); } /* * Condense the on-disk space map representation to its minimized form. * The minimized form consists of a small number of allocations followed * by the entries of the free range tree (ms_allocatable). The condensed * spacemap contains all the entries of previous TXGs (including those in * the pool-wide log spacemaps; thus this is effectively a superset of * metaslab_flush()), but this TXG's entries still need to be written. */ static void metaslab_condense(metaslab_t *msp, dmu_tx_t *tx) { range_tree_t *condense_tree; space_map_t *sm = msp->ms_sm; uint64_t txg = dmu_tx_get_txg(tx); spa_t *spa = msp->ms_group->mg_vd->vdev_spa; ASSERT(MUTEX_HELD(&msp->ms_lock)); ASSERT(msp->ms_loaded); ASSERT(msp->ms_sm != NULL); /* * In order to condense the space map, we need to change it so it * only describes which segments are currently allocated and free. * * All the current free space resides in the ms_allocatable, all * the ms_defer trees, and all the ms_allocating trees. We ignore * ms_freed because it is empty because we're in sync pass 1. We * ignore ms_freeing because these changes are not yet reflected * in the spacemap (they will be written later this txg). * * So to truncate the space map to represent all the entries of * previous TXGs we do the following: * * 1] We create a range tree (condense tree) that is 100% empty. * 2] We add to it all segments found in the ms_defer trees * as those segments are marked as free in the original space * map. We do the same with the ms_allocating trees for the same * reason. Adding these segments should be a relatively * inexpensive operation since we expect these trees to have a * small number of nodes. * 3] We vacate any unflushed allocs, since they are not frees we * need to add to the condense tree. Then we vacate any * unflushed frees as they should already be part of ms_allocatable. * 4] At this point, we would ideally like to add all segments * in the ms_allocatable tree from the condense tree. This way * we would write all the entries of the condense tree as the * condensed space map, which would only contain freed * segments with everything else assumed to be allocated. * * Doing so can be prohibitively expensive as ms_allocatable can * be large, and therefore computationally expensive to add to * the condense_tree. Instead we first sync out an entry marking * everything as allocated, then the condense_tree and then the * ms_allocatable, in the condensed space map. While this is not * optimal, it is typically close to optimal and more importantly * much cheaper to compute. * * 5] Finally, as both of the unflushed trees were written to our * new and condensed metaslab space map, we basically flushed * all the unflushed changes to disk, thus we call * metaslab_flush_update(). */ ASSERT3U(spa_sync_pass(spa), ==, 1); ASSERT(range_tree_is_empty(msp->ms_freed)); /* since it is pass 1 */ zfs_dbgmsg("condensing: txg %llu, msp[%llu] %px, vdev id %llu, " "spa %s, smp size %llu, segments %llu, forcing condense=%s", (u_longlong_t)txg, (u_longlong_t)msp->ms_id, msp, (u_longlong_t)msp->ms_group->mg_vd->vdev_id, spa->spa_name, (u_longlong_t)space_map_length(msp->ms_sm), (u_longlong_t)range_tree_numsegs(msp->ms_allocatable), msp->ms_condense_wanted ? "TRUE" : "FALSE"); msp->ms_condense_wanted = B_FALSE; range_seg_type_t type; uint64_t shift, start; type = metaslab_calculate_range_tree_type(msp->ms_group->mg_vd, msp, &start, &shift); condense_tree = range_tree_create(NULL, type, NULL, start, shift); for (int t = 0; t < TXG_DEFER_SIZE; t++) { range_tree_walk(msp->ms_defer[t], range_tree_add, condense_tree); } for (int t = 0; t < TXG_CONCURRENT_STATES; t++) { range_tree_walk(msp->ms_allocating[(txg + t) & TXG_MASK], range_tree_add, condense_tree); } ASSERT3U(spa->spa_unflushed_stats.sus_memused, >=, metaslab_unflushed_changes_memused(msp)); spa->spa_unflushed_stats.sus_memused -= metaslab_unflushed_changes_memused(msp); range_tree_vacate(msp->ms_unflushed_allocs, NULL, NULL); range_tree_vacate(msp->ms_unflushed_frees, NULL, NULL); /* * We're about to drop the metaslab's lock thus allowing other * consumers to change it's content. Set the metaslab's ms_condensing * flag to ensure that allocations on this metaslab do not occur * while we're in the middle of committing it to disk. This is only * critical for ms_allocatable as all other range trees use per TXG * views of their content. */ msp->ms_condensing = B_TRUE; mutex_exit(&msp->ms_lock); uint64_t object = space_map_object(msp->ms_sm); space_map_truncate(sm, spa_feature_is_enabled(spa, SPA_FEATURE_LOG_SPACEMAP) ? zfs_metaslab_sm_blksz_with_log : zfs_metaslab_sm_blksz_no_log, tx); /* * space_map_truncate() may have reallocated the spacemap object. * If so, update the vdev_ms_array. */ if (space_map_object(msp->ms_sm) != object) { object = space_map_object(msp->ms_sm); dmu_write(spa->spa_meta_objset, msp->ms_group->mg_vd->vdev_ms_array, sizeof (uint64_t) * msp->ms_id, sizeof (uint64_t), &object, tx); } /* * Note: * When the log space map feature is enabled, each space map will * always have ALLOCS followed by FREES for each sync pass. This is * typically true even when the log space map feature is disabled, * except from the case where a metaslab goes through metaslab_sync() * and gets condensed. In that case the metaslab's space map will have * ALLOCS followed by FREES (due to condensing) followed by ALLOCS * followed by FREES (due to space_map_write() in metaslab_sync()) for * sync pass 1. */ range_tree_t *tmp_tree = range_tree_create(NULL, type, NULL, start, shift); range_tree_add(tmp_tree, msp->ms_start, msp->ms_size); space_map_write(sm, tmp_tree, SM_ALLOC, SM_NO_VDEVID, tx); space_map_write(sm, msp->ms_allocatable, SM_FREE, SM_NO_VDEVID, tx); space_map_write(sm, condense_tree, SM_FREE, SM_NO_VDEVID, tx); range_tree_vacate(condense_tree, NULL, NULL); range_tree_destroy(condense_tree); range_tree_vacate(tmp_tree, NULL, NULL); range_tree_destroy(tmp_tree); mutex_enter(&msp->ms_lock); msp->ms_condensing = B_FALSE; metaslab_flush_update(msp, tx); } static void metaslab_unflushed_add(metaslab_t *msp, dmu_tx_t *tx) { spa_t *spa = msp->ms_group->mg_vd->vdev_spa; ASSERT(spa_syncing_log_sm(spa) != NULL); ASSERT(msp->ms_sm != NULL); ASSERT(range_tree_is_empty(msp->ms_unflushed_allocs)); ASSERT(range_tree_is_empty(msp->ms_unflushed_frees)); mutex_enter(&spa->spa_flushed_ms_lock); metaslab_set_unflushed_txg(msp, spa_syncing_txg(spa), tx); metaslab_set_unflushed_dirty(msp, B_TRUE); avl_add(&spa->spa_metaslabs_by_flushed, msp); mutex_exit(&spa->spa_flushed_ms_lock); spa_log_sm_increment_current_mscount(spa); spa_log_summary_add_flushed_metaslab(spa, B_TRUE); } void metaslab_unflushed_bump(metaslab_t *msp, dmu_tx_t *tx, boolean_t dirty) { spa_t *spa = msp->ms_group->mg_vd->vdev_spa; ASSERT(spa_syncing_log_sm(spa) != NULL); ASSERT(msp->ms_sm != NULL); ASSERT(metaslab_unflushed_txg(msp) != 0); ASSERT3P(avl_find(&spa->spa_metaslabs_by_flushed, msp, NULL), ==, msp); ASSERT(range_tree_is_empty(msp->ms_unflushed_allocs)); ASSERT(range_tree_is_empty(msp->ms_unflushed_frees)); VERIFY3U(tx->tx_txg, <=, spa_final_dirty_txg(spa)); /* update metaslab's position in our flushing tree */ uint64_t ms_prev_flushed_txg = metaslab_unflushed_txg(msp); boolean_t ms_prev_flushed_dirty = metaslab_unflushed_dirty(msp); mutex_enter(&spa->spa_flushed_ms_lock); avl_remove(&spa->spa_metaslabs_by_flushed, msp); metaslab_set_unflushed_txg(msp, spa_syncing_txg(spa), tx); metaslab_set_unflushed_dirty(msp, dirty); avl_add(&spa->spa_metaslabs_by_flushed, msp); mutex_exit(&spa->spa_flushed_ms_lock); /* update metaslab counts of spa_log_sm_t nodes */ spa_log_sm_decrement_mscount(spa, ms_prev_flushed_txg); spa_log_sm_increment_current_mscount(spa); /* update log space map summary */ spa_log_summary_decrement_mscount(spa, ms_prev_flushed_txg, ms_prev_flushed_dirty); spa_log_summary_add_flushed_metaslab(spa, dirty); /* cleanup obsolete logs if any */ spa_cleanup_old_sm_logs(spa, tx); } /* * Called when the metaslab has been flushed (its own spacemap now reflects * all the contents of the pool-wide spacemap log). Updates the metaslab's * metadata and any pool-wide related log space map data (e.g. summary, * obsolete logs, etc..) to reflect that. */ static void metaslab_flush_update(metaslab_t *msp, dmu_tx_t *tx) { metaslab_group_t *mg = msp->ms_group; spa_t *spa = mg->mg_vd->vdev_spa; ASSERT(MUTEX_HELD(&msp->ms_lock)); ASSERT3U(spa_sync_pass(spa), ==, 1); /* * Just because a metaslab got flushed, that doesn't mean that * it will pass through metaslab_sync_done(). Thus, make sure to * update ms_synced_length here in case it doesn't. */ msp->ms_synced_length = space_map_length(msp->ms_sm); /* * We may end up here from metaslab_condense() without the * feature being active. In that case this is a no-op. */ if (!spa_feature_is_active(spa, SPA_FEATURE_LOG_SPACEMAP) || metaslab_unflushed_txg(msp) == 0) return; metaslab_unflushed_bump(msp, tx, B_FALSE); } boolean_t metaslab_flush(metaslab_t *msp, dmu_tx_t *tx) { spa_t *spa = msp->ms_group->mg_vd->vdev_spa; ASSERT(MUTEX_HELD(&msp->ms_lock)); ASSERT3U(spa_sync_pass(spa), ==, 1); ASSERT(spa_feature_is_active(spa, SPA_FEATURE_LOG_SPACEMAP)); ASSERT(msp->ms_sm != NULL); ASSERT(metaslab_unflushed_txg(msp) != 0); ASSERT(avl_find(&spa->spa_metaslabs_by_flushed, msp, NULL) != NULL); /* * There is nothing wrong with flushing the same metaslab twice, as * this codepath should work on that case. However, the current * flushing scheme makes sure to avoid this situation as we would be * making all these calls without having anything meaningful to write * to disk. We assert this behavior here. */ ASSERT3U(metaslab_unflushed_txg(msp), <, dmu_tx_get_txg(tx)); /* * We can not flush while loading, because then we would * not load the ms_unflushed_{allocs,frees}. */ if (msp->ms_loading) return (B_FALSE); metaslab_verify_space(msp, dmu_tx_get_txg(tx)); metaslab_verify_weight_and_frag(msp); /* * Metaslab condensing is effectively flushing. Therefore if the * metaslab can be condensed we can just condense it instead of * flushing it. * * Note that metaslab_condense() does call metaslab_flush_update() * so we can just return immediately after condensing. We also * don't need to care about setting ms_flushing or broadcasting * ms_flush_cv, even if we temporarily drop the ms_lock in * metaslab_condense(), as the metaslab is already loaded. */ if (msp->ms_loaded && metaslab_should_condense(msp)) { metaslab_group_t *mg = msp->ms_group; /* * For all histogram operations below refer to the * comments of metaslab_sync() where we follow a * similar procedure. */ metaslab_group_histogram_verify(mg); metaslab_class_histogram_verify(mg->mg_class); metaslab_group_histogram_remove(mg, msp); metaslab_condense(msp, tx); space_map_histogram_clear(msp->ms_sm); space_map_histogram_add(msp->ms_sm, msp->ms_allocatable, tx); ASSERT(range_tree_is_empty(msp->ms_freed)); for (int t = 0; t < TXG_DEFER_SIZE; t++) { space_map_histogram_add(msp->ms_sm, msp->ms_defer[t], tx); } metaslab_aux_histograms_update(msp); metaslab_group_histogram_add(mg, msp); metaslab_group_histogram_verify(mg); metaslab_class_histogram_verify(mg->mg_class); metaslab_verify_space(msp, dmu_tx_get_txg(tx)); /* * Since we recreated the histogram (and potentially * the ms_sm too while condensing) ensure that the * weight is updated too because we are not guaranteed * that this metaslab is dirty and will go through * metaslab_sync_done(). */ metaslab_recalculate_weight_and_sort(msp); return (B_TRUE); } msp->ms_flushing = B_TRUE; uint64_t sm_len_before = space_map_length(msp->ms_sm); mutex_exit(&msp->ms_lock); space_map_write(msp->ms_sm, msp->ms_unflushed_allocs, SM_ALLOC, SM_NO_VDEVID, tx); space_map_write(msp->ms_sm, msp->ms_unflushed_frees, SM_FREE, SM_NO_VDEVID, tx); mutex_enter(&msp->ms_lock); uint64_t sm_len_after = space_map_length(msp->ms_sm); if (zfs_flags & ZFS_DEBUG_LOG_SPACEMAP) { zfs_dbgmsg("flushing: txg %llu, spa %s, vdev_id %llu, " "ms_id %llu, unflushed_allocs %llu, unflushed_frees %llu, " "appended %llu bytes", (u_longlong_t)dmu_tx_get_txg(tx), spa_name(spa), (u_longlong_t)msp->ms_group->mg_vd->vdev_id, (u_longlong_t)msp->ms_id, (u_longlong_t)range_tree_space(msp->ms_unflushed_allocs), (u_longlong_t)range_tree_space(msp->ms_unflushed_frees), (u_longlong_t)(sm_len_after - sm_len_before)); } ASSERT3U(spa->spa_unflushed_stats.sus_memused, >=, metaslab_unflushed_changes_memused(msp)); spa->spa_unflushed_stats.sus_memused -= metaslab_unflushed_changes_memused(msp); range_tree_vacate(msp->ms_unflushed_allocs, NULL, NULL); range_tree_vacate(msp->ms_unflushed_frees, NULL, NULL); metaslab_verify_space(msp, dmu_tx_get_txg(tx)); metaslab_verify_weight_and_frag(msp); metaslab_flush_update(msp, tx); metaslab_verify_space(msp, dmu_tx_get_txg(tx)); metaslab_verify_weight_and_frag(msp); msp->ms_flushing = B_FALSE; cv_broadcast(&msp->ms_flush_cv); return (B_TRUE); } /* * Write a metaslab to disk in the context of the specified transaction group. */ void metaslab_sync(metaslab_t *msp, uint64_t txg) { metaslab_group_t *mg = msp->ms_group; vdev_t *vd = mg->mg_vd; spa_t *spa = vd->vdev_spa; objset_t *mos = spa_meta_objset(spa); range_tree_t *alloctree = msp->ms_allocating[txg & TXG_MASK]; dmu_tx_t *tx; ASSERT(!vd->vdev_ishole); /* * This metaslab has just been added so there's no work to do now. */ if (msp->ms_new) { ASSERT0(range_tree_space(alloctree)); ASSERT0(range_tree_space(msp->ms_freeing)); ASSERT0(range_tree_space(msp->ms_freed)); ASSERT0(range_tree_space(msp->ms_checkpointing)); ASSERT0(range_tree_space(msp->ms_trim)); return; } /* * Normally, we don't want to process a metaslab if there are no * allocations or frees to perform. However, if the metaslab is being * forced to condense, it's loaded and we're not beyond the final * dirty txg, we need to let it through. Not condensing beyond the * final dirty txg prevents an issue where metaslabs that need to be * condensed but were loaded for other reasons could cause a panic * here. By only checking the txg in that branch of the conditional, * we preserve the utility of the VERIFY statements in all other * cases. */ if (range_tree_is_empty(alloctree) && range_tree_is_empty(msp->ms_freeing) && range_tree_is_empty(msp->ms_checkpointing) && !(msp->ms_loaded && msp->ms_condense_wanted && txg <= spa_final_dirty_txg(spa))) return; VERIFY3U(txg, <=, spa_final_dirty_txg(spa)); /* * The only state that can actually be changing concurrently * with metaslab_sync() is the metaslab's ms_allocatable. No * other thread can be modifying this txg's alloc, freeing, * freed, or space_map_phys_t. We drop ms_lock whenever we * could call into the DMU, because the DMU can call down to * us (e.g. via zio_free()) at any time. * * The spa_vdev_remove_thread() can be reading metaslab state * concurrently, and it is locked out by the ms_sync_lock. * Note that the ms_lock is insufficient for this, because it * is dropped by space_map_write(). */ tx = dmu_tx_create_assigned(spa_get_dsl(spa), txg); /* * Generate a log space map if one doesn't exist already. */ spa_generate_syncing_log_sm(spa, tx); if (msp->ms_sm == NULL) { uint64_t new_object = space_map_alloc(mos, spa_feature_is_enabled(spa, SPA_FEATURE_LOG_SPACEMAP) ? zfs_metaslab_sm_blksz_with_log : zfs_metaslab_sm_blksz_no_log, tx); VERIFY3U(new_object, !=, 0); dmu_write(mos, vd->vdev_ms_array, sizeof (uint64_t) * msp->ms_id, sizeof (uint64_t), &new_object, tx); VERIFY0(space_map_open(&msp->ms_sm, mos, new_object, msp->ms_start, msp->ms_size, vd->vdev_ashift)); ASSERT(msp->ms_sm != NULL); ASSERT(range_tree_is_empty(msp->ms_unflushed_allocs)); ASSERT(range_tree_is_empty(msp->ms_unflushed_frees)); ASSERT0(metaslab_allocated_space(msp)); } if (!range_tree_is_empty(msp->ms_checkpointing) && vd->vdev_checkpoint_sm == NULL) { ASSERT(spa_has_checkpoint(spa)); uint64_t new_object = space_map_alloc(mos, zfs_vdev_standard_sm_blksz, tx); VERIFY3U(new_object, !=, 0); VERIFY0(space_map_open(&vd->vdev_checkpoint_sm, mos, new_object, 0, vd->vdev_asize, vd->vdev_ashift)); ASSERT3P(vd->vdev_checkpoint_sm, !=, NULL); /* * We save the space map object as an entry in vdev_top_zap * so it can be retrieved when the pool is reopened after an * export or through zdb. */ VERIFY0(zap_add(vd->vdev_spa->spa_meta_objset, vd->vdev_top_zap, VDEV_TOP_ZAP_POOL_CHECKPOINT_SM, sizeof (new_object), 1, &new_object, tx)); } mutex_enter(&msp->ms_sync_lock); mutex_enter(&msp->ms_lock); /* * Note: metaslab_condense() clears the space map's histogram. * Therefore we must verify and remove this histogram before * condensing. */ metaslab_group_histogram_verify(mg); metaslab_class_histogram_verify(mg->mg_class); metaslab_group_histogram_remove(mg, msp); if (spa->spa_sync_pass == 1 && msp->ms_loaded && metaslab_should_condense(msp)) metaslab_condense(msp, tx); /* * We'll be going to disk to sync our space accounting, thus we * drop the ms_lock during that time so allocations coming from * open-context (ZIL) for future TXGs do not block. */ mutex_exit(&msp->ms_lock); space_map_t *log_sm = spa_syncing_log_sm(spa); if (log_sm != NULL) { ASSERT(spa_feature_is_enabled(spa, SPA_FEATURE_LOG_SPACEMAP)); if (metaslab_unflushed_txg(msp) == 0) metaslab_unflushed_add(msp, tx); else if (!metaslab_unflushed_dirty(msp)) metaslab_unflushed_bump(msp, tx, B_TRUE); space_map_write(log_sm, alloctree, SM_ALLOC, vd->vdev_id, tx); space_map_write(log_sm, msp->ms_freeing, SM_FREE, vd->vdev_id, tx); mutex_enter(&msp->ms_lock); ASSERT3U(spa->spa_unflushed_stats.sus_memused, >=, metaslab_unflushed_changes_memused(msp)); spa->spa_unflushed_stats.sus_memused -= metaslab_unflushed_changes_memused(msp); range_tree_remove_xor_add(alloctree, msp->ms_unflushed_frees, msp->ms_unflushed_allocs); range_tree_remove_xor_add(msp->ms_freeing, msp->ms_unflushed_allocs, msp->ms_unflushed_frees); spa->spa_unflushed_stats.sus_memused += metaslab_unflushed_changes_memused(msp); } else { ASSERT(!spa_feature_is_enabled(spa, SPA_FEATURE_LOG_SPACEMAP)); space_map_write(msp->ms_sm, alloctree, SM_ALLOC, SM_NO_VDEVID, tx); space_map_write(msp->ms_sm, msp->ms_freeing, SM_FREE, SM_NO_VDEVID, tx); mutex_enter(&msp->ms_lock); } msp->ms_allocated_space += range_tree_space(alloctree); ASSERT3U(msp->ms_allocated_space, >=, range_tree_space(msp->ms_freeing)); msp->ms_allocated_space -= range_tree_space(msp->ms_freeing); if (!range_tree_is_empty(msp->ms_checkpointing)) { ASSERT(spa_has_checkpoint(spa)); ASSERT3P(vd->vdev_checkpoint_sm, !=, NULL); /* * Since we are doing writes to disk and the ms_checkpointing * tree won't be changing during that time, we drop the * ms_lock while writing to the checkpoint space map, for the * same reason mentioned above. */ mutex_exit(&msp->ms_lock); space_map_write(vd->vdev_checkpoint_sm, msp->ms_checkpointing, SM_FREE, SM_NO_VDEVID, tx); mutex_enter(&msp->ms_lock); spa->spa_checkpoint_info.sci_dspace += range_tree_space(msp->ms_checkpointing); vd->vdev_stat.vs_checkpoint_space += range_tree_space(msp->ms_checkpointing); ASSERT3U(vd->vdev_stat.vs_checkpoint_space, ==, -space_map_allocated(vd->vdev_checkpoint_sm)); range_tree_vacate(msp->ms_checkpointing, NULL, NULL); } if (msp->ms_loaded) { /* * When the space map is loaded, we have an accurate * histogram in the range tree. This gives us an opportunity * to bring the space map's histogram up-to-date so we clear * it first before updating it. */ space_map_histogram_clear(msp->ms_sm); space_map_histogram_add(msp->ms_sm, msp->ms_allocatable, tx); /* * Since we've cleared the histogram we need to add back * any free space that has already been processed, plus * any deferred space. This allows the on-disk histogram * to accurately reflect all free space even if some space * is not yet available for allocation (i.e. deferred). */ space_map_histogram_add(msp->ms_sm, msp->ms_freed, tx); /* * Add back any deferred free space that has not been * added back into the in-core free tree yet. This will * ensure that we don't end up with a space map histogram * that is completely empty unless the metaslab is fully * allocated. */ for (int t = 0; t < TXG_DEFER_SIZE; t++) { space_map_histogram_add(msp->ms_sm, msp->ms_defer[t], tx); } } /* * Always add the free space from this sync pass to the space * map histogram. We want to make sure that the on-disk histogram * accounts for all free space. If the space map is not loaded, * then we will lose some accuracy but will correct it the next * time we load the space map. */ space_map_histogram_add(msp->ms_sm, msp->ms_freeing, tx); metaslab_aux_histograms_update(msp); metaslab_group_histogram_add(mg, msp); metaslab_group_histogram_verify(mg); metaslab_class_histogram_verify(mg->mg_class); /* * For sync pass 1, we avoid traversing this txg's free range tree * and instead will just swap the pointers for freeing and freed. * We can safely do this since the freed_tree is guaranteed to be * empty on the initial pass. * * Keep in mind that even if we are currently using a log spacemap * we want current frees to end up in the ms_allocatable (but not * get appended to the ms_sm) so their ranges can be reused as usual. */ if (spa_sync_pass(spa) == 1) { range_tree_swap(&msp->ms_freeing, &msp->ms_freed); ASSERT0(msp->ms_allocated_this_txg); } else { range_tree_vacate(msp->ms_freeing, range_tree_add, msp->ms_freed); } msp->ms_allocated_this_txg += range_tree_space(alloctree); range_tree_vacate(alloctree, NULL, NULL); ASSERT0(range_tree_space(msp->ms_allocating[txg & TXG_MASK])); ASSERT0(range_tree_space(msp->ms_allocating[TXG_CLEAN(txg) & TXG_MASK])); ASSERT0(range_tree_space(msp->ms_freeing)); ASSERT0(range_tree_space(msp->ms_checkpointing)); mutex_exit(&msp->ms_lock); /* * Verify that the space map object ID has been recorded in the * vdev_ms_array. */ uint64_t object; VERIFY0(dmu_read(mos, vd->vdev_ms_array, msp->ms_id * sizeof (uint64_t), sizeof (uint64_t), &object, 0)); VERIFY3U(object, ==, space_map_object(msp->ms_sm)); mutex_exit(&msp->ms_sync_lock); dmu_tx_commit(tx); } static void metaslab_evict(metaslab_t *msp, uint64_t txg) { if (!msp->ms_loaded || msp->ms_disabled != 0) return; for (int t = 1; t < TXG_CONCURRENT_STATES; t++) { VERIFY0(range_tree_space( msp->ms_allocating[(txg + t) & TXG_MASK])); } if (msp->ms_allocator != -1) metaslab_passivate(msp, msp->ms_weight & ~METASLAB_ACTIVE_MASK); if (!metaslab_debug_unload) metaslab_unload(msp); } /* * Called after a transaction group has completely synced to mark * all of the metaslab's free space as usable. */ void metaslab_sync_done(metaslab_t *msp, uint64_t txg) { metaslab_group_t *mg = msp->ms_group; vdev_t *vd = mg->mg_vd; spa_t *spa = vd->vdev_spa; range_tree_t **defer_tree; int64_t alloc_delta, defer_delta; boolean_t defer_allowed = B_TRUE; ASSERT(!vd->vdev_ishole); mutex_enter(&msp->ms_lock); if (msp->ms_new) { /* this is a new metaslab, add its capacity to the vdev */ metaslab_space_update(vd, mg->mg_class, 0, 0, msp->ms_size); /* there should be no allocations nor frees at this point */ VERIFY0(msp->ms_allocated_this_txg); VERIFY0(range_tree_space(msp->ms_freed)); } ASSERT0(range_tree_space(msp->ms_freeing)); ASSERT0(range_tree_space(msp->ms_checkpointing)); defer_tree = &msp->ms_defer[txg % TXG_DEFER_SIZE]; uint64_t free_space = metaslab_class_get_space(spa_normal_class(spa)) - metaslab_class_get_alloc(spa_normal_class(spa)); if (free_space <= spa_get_slop_space(spa) || vd->vdev_removing) { defer_allowed = B_FALSE; } defer_delta = 0; alloc_delta = msp->ms_allocated_this_txg - range_tree_space(msp->ms_freed); if (defer_allowed) { defer_delta = range_tree_space(msp->ms_freed) - range_tree_space(*defer_tree); } else { defer_delta -= range_tree_space(*defer_tree); } metaslab_space_update(vd, mg->mg_class, alloc_delta + defer_delta, defer_delta, 0); if (spa_syncing_log_sm(spa) == NULL) { /* * If there's a metaslab_load() in progress and we don't have * a log space map, it means that we probably wrote to the * metaslab's space map. If this is the case, we need to * make sure that we wait for the load to complete so that we * have a consistent view at the in-core side of the metaslab. */ metaslab_load_wait(msp); } else { ASSERT(spa_feature_is_active(spa, SPA_FEATURE_LOG_SPACEMAP)); } /* * When auto-trimming is enabled, free ranges which are added to * ms_allocatable are also be added to ms_trim. The ms_trim tree is * periodically consumed by the vdev_autotrim_thread() which issues * trims for all ranges and then vacates the tree. The ms_trim tree * can be discarded at any time with the sole consequence of recent * frees not being trimmed. */ if (spa_get_autotrim(spa) == SPA_AUTOTRIM_ON) { range_tree_walk(*defer_tree, range_tree_add, msp->ms_trim); if (!defer_allowed) { range_tree_walk(msp->ms_freed, range_tree_add, msp->ms_trim); } } else { range_tree_vacate(msp->ms_trim, NULL, NULL); } /* * Move the frees from the defer_tree back to the free * range tree (if it's loaded). Swap the freed_tree and * the defer_tree -- this is safe to do because we've * just emptied out the defer_tree. */ range_tree_vacate(*defer_tree, msp->ms_loaded ? range_tree_add : NULL, msp->ms_allocatable); if (defer_allowed) { range_tree_swap(&msp->ms_freed, defer_tree); } else { range_tree_vacate(msp->ms_freed, msp->ms_loaded ? range_tree_add : NULL, msp->ms_allocatable); } msp->ms_synced_length = space_map_length(msp->ms_sm); msp->ms_deferspace += defer_delta; ASSERT3S(msp->ms_deferspace, >=, 0); ASSERT3S(msp->ms_deferspace, <=, msp->ms_size); if (msp->ms_deferspace != 0) { /* * Keep syncing this metaslab until all deferred frees * are back in circulation. */ vdev_dirty(vd, VDD_METASLAB, msp, txg + 1); } metaslab_aux_histograms_update_done(msp, defer_allowed); if (msp->ms_new) { msp->ms_new = B_FALSE; mutex_enter(&mg->mg_lock); mg->mg_ms_ready++; mutex_exit(&mg->mg_lock); } /* * Re-sort metaslab within its group now that we've adjusted * its allocatable space. */ metaslab_recalculate_weight_and_sort(msp); ASSERT0(range_tree_space(msp->ms_allocating[txg & TXG_MASK])); ASSERT0(range_tree_space(msp->ms_freeing)); ASSERT0(range_tree_space(msp->ms_freed)); ASSERT0(range_tree_space(msp->ms_checkpointing)); msp->ms_allocating_total -= msp->ms_allocated_this_txg; msp->ms_allocated_this_txg = 0; mutex_exit(&msp->ms_lock); } void metaslab_sync_reassess(metaslab_group_t *mg) { spa_t *spa = mg->mg_class->mc_spa; spa_config_enter(spa, SCL_ALLOC, FTAG, RW_READER); metaslab_group_alloc_update(mg); mg->mg_fragmentation = metaslab_group_fragmentation(mg); /* * Preload the next potential metaslabs but only on active * metaslab groups. We can get into a state where the metaslab * is no longer active since we dirty metaslabs as we remove a * a device, thus potentially making the metaslab group eligible * for preloading. */ if (mg->mg_activation_count > 0) { metaslab_group_preload(mg); } spa_config_exit(spa, SCL_ALLOC, FTAG); } /* * When writing a ditto block (i.e. more than one DVA for a given BP) on * the same vdev as an existing DVA of this BP, then try to allocate it * on a different metaslab than existing DVAs (i.e. a unique metaslab). */ static boolean_t metaslab_is_unique(metaslab_t *msp, dva_t *dva) { uint64_t dva_ms_id; if (DVA_GET_ASIZE(dva) == 0) return (B_TRUE); if (msp->ms_group->mg_vd->vdev_id != DVA_GET_VDEV(dva)) return (B_TRUE); dva_ms_id = DVA_GET_OFFSET(dva) >> msp->ms_group->mg_vd->vdev_ms_shift; return (msp->ms_id != dva_ms_id); } /* * ========================================================================== * Metaslab allocation tracing facility * ========================================================================== */ /* * Add an allocation trace element to the allocation tracing list. */ static void metaslab_trace_add(zio_alloc_list_t *zal, metaslab_group_t *mg, metaslab_t *msp, uint64_t psize, uint32_t dva_id, uint64_t offset, int allocator) { metaslab_alloc_trace_t *mat; if (!metaslab_trace_enabled) return; /* * When the tracing list reaches its maximum we remove * the second element in the list before adding a new one. * By removing the second element we preserve the original * entry as a clue to what allocations steps have already been * performed. */ if (zal->zal_size == metaslab_trace_max_entries) { metaslab_alloc_trace_t *mat_next; #ifdef ZFS_DEBUG panic("too many entries in allocation list"); #endif METASLABSTAT_BUMP(metaslabstat_trace_over_limit); zal->zal_size--; mat_next = list_next(&zal->zal_list, list_head(&zal->zal_list)); list_remove(&zal->zal_list, mat_next); kmem_cache_free(metaslab_alloc_trace_cache, mat_next); } mat = kmem_cache_alloc(metaslab_alloc_trace_cache, KM_SLEEP); list_link_init(&mat->mat_list_node); mat->mat_mg = mg; mat->mat_msp = msp; mat->mat_size = psize; mat->mat_dva_id = dva_id; mat->mat_offset = offset; mat->mat_weight = 0; mat->mat_allocator = allocator; if (msp != NULL) mat->mat_weight = msp->ms_weight; /* * The list is part of the zio so locking is not required. Only * a single thread will perform allocations for a given zio. */ list_insert_tail(&zal->zal_list, mat); zal->zal_size++; ASSERT3U(zal->zal_size, <=, metaslab_trace_max_entries); } void metaslab_trace_init(zio_alloc_list_t *zal) { list_create(&zal->zal_list, sizeof (metaslab_alloc_trace_t), offsetof(metaslab_alloc_trace_t, mat_list_node)); zal->zal_size = 0; } void metaslab_trace_fini(zio_alloc_list_t *zal) { metaslab_alloc_trace_t *mat; while ((mat = list_remove_head(&zal->zal_list)) != NULL) kmem_cache_free(metaslab_alloc_trace_cache, mat); list_destroy(&zal->zal_list); zal->zal_size = 0; } /* * ========================================================================== * Metaslab block operations * ========================================================================== */ static void metaslab_group_alloc_increment(spa_t *spa, uint64_t vdev, const void *tag, int flags, int allocator) { if (!(flags & METASLAB_ASYNC_ALLOC) || (flags & METASLAB_DONT_THROTTLE)) return; metaslab_group_t *mg = vdev_lookup_top(spa, vdev)->vdev_mg; if (!mg->mg_class->mc_alloc_throttle_enabled) return; metaslab_group_allocator_t *mga = &mg->mg_allocator[allocator]; (void) zfs_refcount_add(&mga->mga_alloc_queue_depth, tag); } static void metaslab_group_increment_qdepth(metaslab_group_t *mg, int allocator) { metaslab_group_allocator_t *mga = &mg->mg_allocator[allocator]; metaslab_class_allocator_t *mca = &mg->mg_class->mc_allocator[allocator]; uint64_t max = mg->mg_max_alloc_queue_depth; uint64_t cur = mga->mga_cur_max_alloc_queue_depth; while (cur < max) { if (atomic_cas_64(&mga->mga_cur_max_alloc_queue_depth, cur, cur + 1) == cur) { atomic_inc_64(&mca->mca_alloc_max_slots); return; } cur = mga->mga_cur_max_alloc_queue_depth; } } void metaslab_group_alloc_decrement(spa_t *spa, uint64_t vdev, const void *tag, int flags, int allocator, boolean_t io_complete) { if (!(flags & METASLAB_ASYNC_ALLOC) || (flags & METASLAB_DONT_THROTTLE)) return; metaslab_group_t *mg = vdev_lookup_top(spa, vdev)->vdev_mg; if (!mg->mg_class->mc_alloc_throttle_enabled) return; metaslab_group_allocator_t *mga = &mg->mg_allocator[allocator]; (void) zfs_refcount_remove(&mga->mga_alloc_queue_depth, tag); if (io_complete) metaslab_group_increment_qdepth(mg, allocator); } void metaslab_group_alloc_verify(spa_t *spa, const blkptr_t *bp, const void *tag, int allocator) { #ifdef ZFS_DEBUG const dva_t *dva = bp->blk_dva; int ndvas = BP_GET_NDVAS(bp); for (int d = 0; d < ndvas; d++) { uint64_t vdev = DVA_GET_VDEV(&dva[d]); metaslab_group_t *mg = vdev_lookup_top(spa, vdev)->vdev_mg; metaslab_group_allocator_t *mga = &mg->mg_allocator[allocator]; VERIFY(zfs_refcount_not_held(&mga->mga_alloc_queue_depth, tag)); } #endif } static uint64_t metaslab_block_alloc(metaslab_t *msp, uint64_t size, uint64_t txg) { uint64_t start; range_tree_t *rt = msp->ms_allocatable; metaslab_class_t *mc = msp->ms_group->mg_class; ASSERT(MUTEX_HELD(&msp->ms_lock)); VERIFY(!msp->ms_condensing); VERIFY0(msp->ms_disabled); start = mc->mc_ops->msop_alloc(msp, size); if (start != -1ULL) { metaslab_group_t *mg = msp->ms_group; vdev_t *vd = mg->mg_vd; VERIFY0(P2PHASE(start, 1ULL << vd->vdev_ashift)); VERIFY0(P2PHASE(size, 1ULL << vd->vdev_ashift)); VERIFY3U(range_tree_space(rt) - size, <=, msp->ms_size); range_tree_remove(rt, start, size); range_tree_clear(msp->ms_trim, start, size); if (range_tree_is_empty(msp->ms_allocating[txg & TXG_MASK])) vdev_dirty(mg->mg_vd, VDD_METASLAB, msp, txg); range_tree_add(msp->ms_allocating[txg & TXG_MASK], start, size); msp->ms_allocating_total += size; /* Track the last successful allocation */ msp->ms_alloc_txg = txg; metaslab_verify_space(msp, txg); } /* * Now that we've attempted the allocation we need to update the * metaslab's maximum block size since it may have changed. */ msp->ms_max_size = metaslab_largest_allocatable(msp); return (start); } /* * Find the metaslab with the highest weight that is less than what we've * already tried. In the common case, this means that we will examine each * metaslab at most once. Note that concurrent callers could reorder metaslabs * by activation/passivation once we have dropped the mg_lock. If a metaslab is * activated by another thread, and we fail to allocate from the metaslab we * have selected, we may not try the newly-activated metaslab, and instead * activate another metaslab. This is not optimal, but generally does not cause * any problems (a possible exception being if every metaslab is completely full * except for the newly-activated metaslab which we fail to examine). */ static metaslab_t * find_valid_metaslab(metaslab_group_t *mg, uint64_t activation_weight, dva_t *dva, int d, boolean_t want_unique, uint64_t asize, int allocator, boolean_t try_hard, zio_alloc_list_t *zal, metaslab_t *search, boolean_t *was_active) { avl_index_t idx; avl_tree_t *t = &mg->mg_metaslab_tree; metaslab_t *msp = avl_find(t, search, &idx); if (msp == NULL) msp = avl_nearest(t, idx, AVL_AFTER); int tries = 0; for (; msp != NULL; msp = AVL_NEXT(t, msp)) { int i; if (!try_hard && tries > zfs_metaslab_find_max_tries) { METASLABSTAT_BUMP(metaslabstat_too_many_tries); return (NULL); } tries++; if (!metaslab_should_allocate(msp, asize, try_hard)) { metaslab_trace_add(zal, mg, msp, asize, d, TRACE_TOO_SMALL, allocator); continue; } /* * If the selected metaslab is condensing or disabled, * skip it. */ if (msp->ms_condensing || msp->ms_disabled > 0) continue; *was_active = msp->ms_allocator != -1; /* * If we're activating as primary, this is our first allocation * from this disk, so we don't need to check how close we are. * If the metaslab under consideration was already active, * we're getting desperate enough to steal another allocator's * metaslab, so we still don't care about distances. */ if (activation_weight == METASLAB_WEIGHT_PRIMARY || *was_active) break; for (i = 0; i < d; i++) { if (want_unique && !metaslab_is_unique(msp, &dva[i])) break; /* try another metaslab */ } if (i == d) break; } if (msp != NULL) { search->ms_weight = msp->ms_weight; search->ms_start = msp->ms_start + 1; search->ms_allocator = msp->ms_allocator; search->ms_primary = msp->ms_primary; } return (msp); } static void metaslab_active_mask_verify(metaslab_t *msp) { ASSERT(MUTEX_HELD(&msp->ms_lock)); if ((zfs_flags & ZFS_DEBUG_METASLAB_VERIFY) == 0) return; if ((msp->ms_weight & METASLAB_ACTIVE_MASK) == 0) return; if (msp->ms_weight & METASLAB_WEIGHT_PRIMARY) { VERIFY0(msp->ms_weight & METASLAB_WEIGHT_SECONDARY); VERIFY0(msp->ms_weight & METASLAB_WEIGHT_CLAIM); VERIFY3S(msp->ms_allocator, !=, -1); VERIFY(msp->ms_primary); return; } if (msp->ms_weight & METASLAB_WEIGHT_SECONDARY) { VERIFY0(msp->ms_weight & METASLAB_WEIGHT_PRIMARY); VERIFY0(msp->ms_weight & METASLAB_WEIGHT_CLAIM); VERIFY3S(msp->ms_allocator, !=, -1); VERIFY(!msp->ms_primary); return; } if (msp->ms_weight & METASLAB_WEIGHT_CLAIM) { VERIFY0(msp->ms_weight & METASLAB_WEIGHT_PRIMARY); VERIFY0(msp->ms_weight & METASLAB_WEIGHT_SECONDARY); VERIFY3S(msp->ms_allocator, ==, -1); return; } } static uint64_t metaslab_group_alloc_normal(metaslab_group_t *mg, zio_alloc_list_t *zal, uint64_t asize, uint64_t txg, boolean_t want_unique, dva_t *dva, int d, int allocator, boolean_t try_hard) { metaslab_t *msp = NULL; uint64_t offset = -1ULL; uint64_t activation_weight = METASLAB_WEIGHT_PRIMARY; for (int i = 0; i < d; i++) { if (activation_weight == METASLAB_WEIGHT_PRIMARY && DVA_GET_VDEV(&dva[i]) == mg->mg_vd->vdev_id) { activation_weight = METASLAB_WEIGHT_SECONDARY; } else if (activation_weight == METASLAB_WEIGHT_SECONDARY && DVA_GET_VDEV(&dva[i]) == mg->mg_vd->vdev_id) { activation_weight = METASLAB_WEIGHT_CLAIM; break; } } /* * If we don't have enough metaslabs active to fill the entire array, we * just use the 0th slot. */ if (mg->mg_ms_ready < mg->mg_allocators * 3) allocator = 0; metaslab_group_allocator_t *mga = &mg->mg_allocator[allocator]; ASSERT3U(mg->mg_vd->vdev_ms_count, >=, 2); metaslab_t *search = kmem_alloc(sizeof (*search), KM_SLEEP); search->ms_weight = UINT64_MAX; search->ms_start = 0; /* * At the end of the metaslab tree are the already-active metaslabs, * first the primaries, then the secondaries. When we resume searching * through the tree, we need to consider ms_allocator and ms_primary so * we start in the location right after where we left off, and don't * accidentally loop forever considering the same metaslabs. */ search->ms_allocator = -1; search->ms_primary = B_TRUE; for (;;) { boolean_t was_active = B_FALSE; mutex_enter(&mg->mg_lock); if (activation_weight == METASLAB_WEIGHT_PRIMARY && mga->mga_primary != NULL) { msp = mga->mga_primary; /* * Even though we don't hold the ms_lock for the * primary metaslab, those fields should not * change while we hold the mg_lock. Thus it is * safe to make assertions on them. */ ASSERT(msp->ms_primary); ASSERT3S(msp->ms_allocator, ==, allocator); ASSERT(msp->ms_loaded); was_active = B_TRUE; ASSERT(msp->ms_weight & METASLAB_ACTIVE_MASK); } else if (activation_weight == METASLAB_WEIGHT_SECONDARY && mga->mga_secondary != NULL) { msp = mga->mga_secondary; /* * See comment above about the similar assertions * for the primary metaslab. */ ASSERT(!msp->ms_primary); ASSERT3S(msp->ms_allocator, ==, allocator); ASSERT(msp->ms_loaded); was_active = B_TRUE; ASSERT(msp->ms_weight & METASLAB_ACTIVE_MASK); } else { msp = find_valid_metaslab(mg, activation_weight, dva, d, want_unique, asize, allocator, try_hard, zal, search, &was_active); } mutex_exit(&mg->mg_lock); if (msp == NULL) { kmem_free(search, sizeof (*search)); return (-1ULL); } mutex_enter(&msp->ms_lock); metaslab_active_mask_verify(msp); /* * This code is disabled out because of issues with * tracepoints in non-gpl kernel modules. */ #if 0 DTRACE_PROBE3(ms__activation__attempt, metaslab_t *, msp, uint64_t, activation_weight, boolean_t, was_active); #endif /* * Ensure that the metaslab we have selected is still * capable of handling our request. It's possible that * another thread may have changed the weight while we * were blocked on the metaslab lock. We check the * active status first to see if we need to set_selected_txg * a new metaslab. */ if (was_active && !(msp->ms_weight & METASLAB_ACTIVE_MASK)) { ASSERT3S(msp->ms_allocator, ==, -1); mutex_exit(&msp->ms_lock); continue; } /* * If the metaslab was activated for another allocator * while we were waiting in the ms_lock above, or it's * a primary and we're seeking a secondary (or vice versa), * we go back and select a new metaslab. */ if (!was_active && (msp->ms_weight & METASLAB_ACTIVE_MASK) && (msp->ms_allocator != -1) && (msp->ms_allocator != allocator || ((activation_weight == METASLAB_WEIGHT_PRIMARY) != msp->ms_primary))) { ASSERT(msp->ms_loaded); ASSERT((msp->ms_weight & METASLAB_WEIGHT_CLAIM) || msp->ms_allocator != -1); mutex_exit(&msp->ms_lock); continue; } /* * This metaslab was used for claiming regions allocated * by the ZIL during pool import. Once these regions are * claimed we don't need to keep the CLAIM bit set * anymore. Passivate this metaslab to zero its activation * mask. */ if (msp->ms_weight & METASLAB_WEIGHT_CLAIM && activation_weight != METASLAB_WEIGHT_CLAIM) { ASSERT(msp->ms_loaded); ASSERT3S(msp->ms_allocator, ==, -1); metaslab_passivate(msp, msp->ms_weight & ~METASLAB_WEIGHT_CLAIM); mutex_exit(&msp->ms_lock); continue; } metaslab_set_selected_txg(msp, txg); int activation_error = metaslab_activate(msp, allocator, activation_weight); metaslab_active_mask_verify(msp); /* * If the metaslab was activated by another thread for * another allocator or activation_weight (EBUSY), or it * failed because another metaslab was assigned as primary * for this allocator (EEXIST) we continue using this * metaslab for our allocation, rather than going on to a * worse metaslab (we waited for that metaslab to be loaded * after all). * * If the activation failed due to an I/O error or ENOSPC we * skip to the next metaslab. */ boolean_t activated; if (activation_error == 0) { activated = B_TRUE; } else if (activation_error == EBUSY || activation_error == EEXIST) { activated = B_FALSE; } else { mutex_exit(&msp->ms_lock); continue; } ASSERT(msp->ms_loaded); /* * Now that we have the lock, recheck to see if we should * continue to use this metaslab for this allocation. The * the metaslab is now loaded so metaslab_should_allocate() * can accurately determine if the allocation attempt should * proceed. */ if (!metaslab_should_allocate(msp, asize, try_hard)) { /* Passivate this metaslab and select a new one. */ metaslab_trace_add(zal, mg, msp, asize, d, TRACE_TOO_SMALL, allocator); goto next; } /* * If this metaslab is currently condensing then pick again * as we can't manipulate this metaslab until it's committed * to disk. If this metaslab is being initialized, we shouldn't * allocate from it since the allocated region might be * overwritten after allocation. */ if (msp->ms_condensing) { metaslab_trace_add(zal, mg, msp, asize, d, TRACE_CONDENSING, allocator); if (activated) { metaslab_passivate(msp, msp->ms_weight & ~METASLAB_ACTIVE_MASK); } mutex_exit(&msp->ms_lock); continue; } else if (msp->ms_disabled > 0) { metaslab_trace_add(zal, mg, msp, asize, d, TRACE_DISABLED, allocator); if (activated) { metaslab_passivate(msp, msp->ms_weight & ~METASLAB_ACTIVE_MASK); } mutex_exit(&msp->ms_lock); continue; } offset = metaslab_block_alloc(msp, asize, txg); metaslab_trace_add(zal, mg, msp, asize, d, offset, allocator); if (offset != -1ULL) { /* Proactively passivate the metaslab, if needed */ if (activated) metaslab_segment_may_passivate(msp); break; } next: ASSERT(msp->ms_loaded); /* * This code is disabled out because of issues with * tracepoints in non-gpl kernel modules. */ #if 0 DTRACE_PROBE2(ms__alloc__failure, metaslab_t *, msp, uint64_t, asize); #endif /* * We were unable to allocate from this metaslab so determine * a new weight for this metaslab. Now that we have loaded * the metaslab we can provide a better hint to the metaslab * selector. * * For space-based metaslabs, we use the maximum block size. * This information is only available when the metaslab * is loaded and is more accurate than the generic free * space weight that was calculated by metaslab_weight(). * This information allows us to quickly compare the maximum * available allocation in the metaslab to the allocation * size being requested. * * For segment-based metaslabs, determine the new weight * based on the highest bucket in the range tree. We * explicitly use the loaded segment weight (i.e. the range * tree histogram) since it contains the space that is * currently available for allocation and is accurate * even within a sync pass. */ uint64_t weight; if (WEIGHT_IS_SPACEBASED(msp->ms_weight)) { weight = metaslab_largest_allocatable(msp); WEIGHT_SET_SPACEBASED(weight); } else { weight = metaslab_weight_from_range_tree(msp); } if (activated) { metaslab_passivate(msp, weight); } else { /* * For the case where we use the metaslab that is * active for another allocator we want to make * sure that we retain the activation mask. * * Note that we could attempt to use something like * metaslab_recalculate_weight_and_sort() that * retains the activation mask here. That function * uses metaslab_weight() to set the weight though * which is not as accurate as the calculations * above. */ weight |= msp->ms_weight & METASLAB_ACTIVE_MASK; metaslab_group_sort(mg, msp, weight); } metaslab_active_mask_verify(msp); /* * We have just failed an allocation attempt, check * that metaslab_should_allocate() agrees. Otherwise, * we may end up in an infinite loop retrying the same * metaslab. */ ASSERT(!metaslab_should_allocate(msp, asize, try_hard)); mutex_exit(&msp->ms_lock); } mutex_exit(&msp->ms_lock); kmem_free(search, sizeof (*search)); return (offset); } static uint64_t metaslab_group_alloc(metaslab_group_t *mg, zio_alloc_list_t *zal, uint64_t asize, uint64_t txg, boolean_t want_unique, dva_t *dva, int d, int allocator, boolean_t try_hard) { uint64_t offset; ASSERT(mg->mg_initialized); offset = metaslab_group_alloc_normal(mg, zal, asize, txg, want_unique, dva, d, allocator, try_hard); mutex_enter(&mg->mg_lock); if (offset == -1ULL) { mg->mg_failed_allocations++; metaslab_trace_add(zal, mg, NULL, asize, d, TRACE_GROUP_FAILURE, allocator); if (asize == SPA_GANGBLOCKSIZE) { /* * This metaslab group was unable to allocate * the minimum gang block size so it must be out of * space. We must notify the allocation throttle * to start skipping allocation attempts to this * metaslab group until more space becomes available. * Note: this failure cannot be caused by the * allocation throttle since the allocation throttle * is only responsible for skipping devices and * not failing block allocations. */ mg->mg_no_free_space = B_TRUE; } } mg->mg_allocations++; mutex_exit(&mg->mg_lock); return (offset); } /* * Allocate a block for the specified i/o. */ int metaslab_alloc_dva(spa_t *spa, metaslab_class_t *mc, uint64_t psize, dva_t *dva, int d, dva_t *hintdva, uint64_t txg, int flags, zio_alloc_list_t *zal, int allocator) { metaslab_class_allocator_t *mca = &mc->mc_allocator[allocator]; metaslab_group_t *mg, *fast_mg, *rotor; vdev_t *vd; boolean_t try_hard = B_FALSE; ASSERT(!DVA_IS_VALID(&dva[d])); /* * For testing, make some blocks above a certain size be gang blocks. * This will result in more split blocks when using device removal, * and a large number of split blocks coupled with ztest-induced * damage can result in extremely long reconstruction times. This * will also test spilling from special to normal. */ if (psize >= metaslab_force_ganging && (random_in_range(100) < 3)) { metaslab_trace_add(zal, NULL, NULL, psize, d, TRACE_FORCE_GANG, allocator); return (SET_ERROR(ENOSPC)); } /* * Start at the rotor and loop through all mgs until we find something. * Note that there's no locking on mca_rotor or mca_aliquot because * nothing actually breaks if we miss a few updates -- we just won't * allocate quite as evenly. It all balances out over time. * * If we are doing ditto or log blocks, try to spread them across * consecutive vdevs. If we're forced to reuse a vdev before we've * allocated all of our ditto blocks, then try and spread them out on * that vdev as much as possible. If it turns out to not be possible, * gradually lower our standards until anything becomes acceptable. * Also, allocating on consecutive vdevs (as opposed to random vdevs) * gives us hope of containing our fault domains to something we're * able to reason about. Otherwise, any two top-level vdev failures * will guarantee the loss of data. With consecutive allocation, * only two adjacent top-level vdev failures will result in data loss. * * If we are doing gang blocks (hintdva is non-NULL), try to keep * ourselves on the same vdev as our gang block header. That * way, we can hope for locality in vdev_cache, plus it makes our * fault domains something tractable. */ if (hintdva) { vd = vdev_lookup_top(spa, DVA_GET_VDEV(&hintdva[d])); /* * It's possible the vdev we're using as the hint no * longer exists or its mg has been closed (e.g. by * device removal). Consult the rotor when * all else fails. */ if (vd != NULL && vd->vdev_mg != NULL) { mg = vdev_get_mg(vd, mc); if (flags & METASLAB_HINTBP_AVOID && mg->mg_next != NULL) mg = mg->mg_next; } else { mg = mca->mca_rotor; } } else if (d != 0) { vd = vdev_lookup_top(spa, DVA_GET_VDEV(&dva[d - 1])); mg = vd->vdev_mg->mg_next; } else if (flags & METASLAB_FASTWRITE) { mg = fast_mg = mca->mca_rotor; do { if (fast_mg->mg_vd->vdev_pending_fastwrite < mg->mg_vd->vdev_pending_fastwrite) mg = fast_mg; } while ((fast_mg = fast_mg->mg_next) != mca->mca_rotor); } else { ASSERT(mca->mca_rotor != NULL); mg = mca->mca_rotor; } /* * If the hint put us into the wrong metaslab class, or into a * metaslab group that has been passivated, just follow the rotor. */ if (mg->mg_class != mc || mg->mg_activation_count <= 0) mg = mca->mca_rotor; rotor = mg; top: do { boolean_t allocatable; ASSERT(mg->mg_activation_count == 1); vd = mg->mg_vd; /* * Don't allocate from faulted devices. */ if (try_hard) { spa_config_enter(spa, SCL_ZIO, FTAG, RW_READER); allocatable = vdev_allocatable(vd); spa_config_exit(spa, SCL_ZIO, FTAG); } else { allocatable = vdev_allocatable(vd); } /* * Determine if the selected metaslab group is eligible * for allocations. If we're ganging then don't allow * this metaslab group to skip allocations since that would * inadvertently return ENOSPC and suspend the pool * even though space is still available. */ if (allocatable && !GANG_ALLOCATION(flags) && !try_hard) { allocatable = metaslab_group_allocatable(mg, rotor, psize, allocator, d); } if (!allocatable) { metaslab_trace_add(zal, mg, NULL, psize, d, TRACE_NOT_ALLOCATABLE, allocator); goto next; } ASSERT(mg->mg_initialized); /* * Avoid writing single-copy data to a failing, * non-redundant vdev, unless we've already tried all * other vdevs. */ if ((vd->vdev_stat.vs_write_errors > 0 || vd->vdev_state < VDEV_STATE_HEALTHY) && d == 0 && !try_hard && vd->vdev_children == 0) { metaslab_trace_add(zal, mg, NULL, psize, d, TRACE_VDEV_ERROR, allocator); goto next; } ASSERT(mg->mg_class == mc); uint64_t asize = vdev_psize_to_asize(vd, psize); ASSERT(P2PHASE(asize, 1ULL << vd->vdev_ashift) == 0); /* * If we don't need to try hard, then require that the * block be on a different metaslab from any other DVAs * in this BP (unique=true). If we are trying hard, then * allow any metaslab to be used (unique=false). */ uint64_t offset = metaslab_group_alloc(mg, zal, asize, txg, !try_hard, dva, d, allocator, try_hard); if (offset != -1ULL) { /* * If we've just selected this metaslab group, * figure out whether the corresponding vdev is * over- or under-used relative to the pool, * and set an allocation bias to even it out. * * Bias is also used to compensate for unequally * sized vdevs so that space is allocated fairly. */ if (mca->mca_aliquot == 0 && metaslab_bias_enabled) { vdev_stat_t *vs = &vd->vdev_stat; int64_t vs_free = vs->vs_space - vs->vs_alloc; int64_t mc_free = mc->mc_space - mc->mc_alloc; int64_t ratio; /* * Calculate how much more or less we should * try to allocate from this device during * this iteration around the rotor. * * This basically introduces a zero-centered * bias towards the devices with the most * free space, while compensating for vdev * size differences. * * Examples: * vdev V1 = 16M/128M * vdev V2 = 16M/128M * ratio(V1) = 100% ratio(V2) = 100% * * vdev V1 = 16M/128M * vdev V2 = 64M/128M * ratio(V1) = 127% ratio(V2) = 72% * * vdev V1 = 16M/128M * vdev V2 = 64M/512M * ratio(V1) = 40% ratio(V2) = 160% */ ratio = (vs_free * mc->mc_alloc_groups * 100) / (mc_free + 1); mg->mg_bias = ((ratio - 100) * (int64_t)mg->mg_aliquot) / 100; } else if (!metaslab_bias_enabled) { mg->mg_bias = 0; } if ((flags & METASLAB_FASTWRITE) || atomic_add_64_nv(&mca->mca_aliquot, asize) >= mg->mg_aliquot + mg->mg_bias) { mca->mca_rotor = mg->mg_next; mca->mca_aliquot = 0; } DVA_SET_VDEV(&dva[d], vd->vdev_id); DVA_SET_OFFSET(&dva[d], offset); DVA_SET_GANG(&dva[d], ((flags & METASLAB_GANG_HEADER) ? 1 : 0)); DVA_SET_ASIZE(&dva[d], asize); if (flags & METASLAB_FASTWRITE) { atomic_add_64(&vd->vdev_pending_fastwrite, psize); } return (0); } next: mca->mca_rotor = mg->mg_next; mca->mca_aliquot = 0; } while ((mg = mg->mg_next) != rotor); /* * If we haven't tried hard, perhaps do so now. */ if (!try_hard && (zfs_metaslab_try_hard_before_gang || GANG_ALLOCATION(flags) || (flags & METASLAB_ZIL) != 0 || psize <= 1 << spa->spa_min_ashift)) { METASLABSTAT_BUMP(metaslabstat_try_hard); try_hard = B_TRUE; goto top; } memset(&dva[d], 0, sizeof (dva_t)); metaslab_trace_add(zal, rotor, NULL, psize, d, TRACE_ENOSPC, allocator); return (SET_ERROR(ENOSPC)); } void metaslab_free_concrete(vdev_t *vd, uint64_t offset, uint64_t asize, boolean_t checkpoint) { metaslab_t *msp; spa_t *spa = vd->vdev_spa; ASSERT(vdev_is_concrete(vd)); ASSERT3U(spa_config_held(spa, SCL_ALL, RW_READER), !=, 0); ASSERT3U(offset >> vd->vdev_ms_shift, <, vd->vdev_ms_count); msp = vd->vdev_ms[offset >> vd->vdev_ms_shift]; VERIFY(!msp->ms_condensing); VERIFY3U(offset, >=, msp->ms_start); VERIFY3U(offset + asize, <=, msp->ms_start + msp->ms_size); VERIFY0(P2PHASE(offset, 1ULL << vd->vdev_ashift)); VERIFY0(P2PHASE(asize, 1ULL << vd->vdev_ashift)); metaslab_check_free_impl(vd, offset, asize); mutex_enter(&msp->ms_lock); if (range_tree_is_empty(msp->ms_freeing) && range_tree_is_empty(msp->ms_checkpointing)) { vdev_dirty(vd, VDD_METASLAB, msp, spa_syncing_txg(spa)); } if (checkpoint) { ASSERT(spa_has_checkpoint(spa)); range_tree_add(msp->ms_checkpointing, offset, asize); } else { range_tree_add(msp->ms_freeing, offset, asize); } mutex_exit(&msp->ms_lock); } void metaslab_free_impl_cb(uint64_t inner_offset, vdev_t *vd, uint64_t offset, uint64_t size, void *arg) { (void) inner_offset; boolean_t *checkpoint = arg; ASSERT3P(checkpoint, !=, NULL); if (vd->vdev_ops->vdev_op_remap != NULL) vdev_indirect_mark_obsolete(vd, offset, size); else metaslab_free_impl(vd, offset, size, *checkpoint); } static void metaslab_free_impl(vdev_t *vd, uint64_t offset, uint64_t size, boolean_t checkpoint) { spa_t *spa = vd->vdev_spa; ASSERT3U(spa_config_held(spa, SCL_ALL, RW_READER), !=, 0); if (spa_syncing_txg(spa) > spa_freeze_txg(spa)) return; if (spa->spa_vdev_removal != NULL && spa->spa_vdev_removal->svr_vdev_id == vd->vdev_id && vdev_is_concrete(vd)) { /* * Note: we check if the vdev is concrete because when * we complete the removal, we first change the vdev to be * an indirect vdev (in open context), and then (in syncing * context) clear spa_vdev_removal. */ free_from_removing_vdev(vd, offset, size); } else if (vd->vdev_ops->vdev_op_remap != NULL) { vdev_indirect_mark_obsolete(vd, offset, size); vd->vdev_ops->vdev_op_remap(vd, offset, size, metaslab_free_impl_cb, &checkpoint); } else { metaslab_free_concrete(vd, offset, size, checkpoint); } } typedef struct remap_blkptr_cb_arg { blkptr_t *rbca_bp; spa_remap_cb_t rbca_cb; vdev_t *rbca_remap_vd; uint64_t rbca_remap_offset; void *rbca_cb_arg; } remap_blkptr_cb_arg_t; static void remap_blkptr_cb(uint64_t inner_offset, vdev_t *vd, uint64_t offset, uint64_t size, void *arg) { remap_blkptr_cb_arg_t *rbca = arg; blkptr_t *bp = rbca->rbca_bp; /* We can not remap split blocks. */ if (size != DVA_GET_ASIZE(&bp->blk_dva[0])) return; ASSERT0(inner_offset); if (rbca->rbca_cb != NULL) { /* * At this point we know that we are not handling split * blocks and we invoke the callback on the previous * vdev which must be indirect. */ ASSERT3P(rbca->rbca_remap_vd->vdev_ops, ==, &vdev_indirect_ops); rbca->rbca_cb(rbca->rbca_remap_vd->vdev_id, rbca->rbca_remap_offset, size, rbca->rbca_cb_arg); /* set up remap_blkptr_cb_arg for the next call */ rbca->rbca_remap_vd = vd; rbca->rbca_remap_offset = offset; } /* * The phys birth time is that of dva[0]. This ensures that we know * when each dva was written, so that resilver can determine which * blocks need to be scrubbed (i.e. those written during the time * the vdev was offline). It also ensures that the key used in * the ARC hash table is unique (i.e. dva[0] + phys_birth). If * we didn't change the phys_birth, a lookup in the ARC for a * remapped BP could find the data that was previously stored at * this vdev + offset. */ vdev_t *oldvd = vdev_lookup_top(vd->vdev_spa, DVA_GET_VDEV(&bp->blk_dva[0])); vdev_indirect_births_t *vib = oldvd->vdev_indirect_births; bp->blk_phys_birth = vdev_indirect_births_physbirth(vib, DVA_GET_OFFSET(&bp->blk_dva[0]), DVA_GET_ASIZE(&bp->blk_dva[0])); DVA_SET_VDEV(&bp->blk_dva[0], vd->vdev_id); DVA_SET_OFFSET(&bp->blk_dva[0], offset); } /* * If the block pointer contains any indirect DVAs, modify them to refer to * concrete DVAs. Note that this will sometimes not be possible, leaving * the indirect DVA in place. This happens if the indirect DVA spans multiple * segments in the mapping (i.e. it is a "split block"). * * If the BP was remapped, calls the callback on the original dva (note the * callback can be called multiple times if the original indirect DVA refers * to another indirect DVA, etc). * * Returns TRUE if the BP was remapped. */ boolean_t spa_remap_blkptr(spa_t *spa, blkptr_t *bp, spa_remap_cb_t callback, void *arg) { remap_blkptr_cb_arg_t rbca; if (!zfs_remap_blkptr_enable) return (B_FALSE); if (!spa_feature_is_enabled(spa, SPA_FEATURE_OBSOLETE_COUNTS)) return (B_FALSE); /* * Dedup BP's can not be remapped, because ddt_phys_select() depends * on DVA[0] being the same in the BP as in the DDT (dedup table). */ if (BP_GET_DEDUP(bp)) return (B_FALSE); /* * Gang blocks can not be remapped, because * zio_checksum_gang_verifier() depends on the DVA[0] that's in * the BP used to read the gang block header (GBH) being the same * as the DVA[0] that we allocated for the GBH. */ if (BP_IS_GANG(bp)) return (B_FALSE); /* * Embedded BP's have no DVA to remap. */ if (BP_GET_NDVAS(bp) < 1) return (B_FALSE); /* * Note: we only remap dva[0]. If we remapped other dvas, we * would no longer know what their phys birth txg is. */ dva_t *dva = &bp->blk_dva[0]; uint64_t offset = DVA_GET_OFFSET(dva); uint64_t size = DVA_GET_ASIZE(dva); vdev_t *vd = vdev_lookup_top(spa, DVA_GET_VDEV(dva)); if (vd->vdev_ops->vdev_op_remap == NULL) return (B_FALSE); rbca.rbca_bp = bp; rbca.rbca_cb = callback; rbca.rbca_remap_vd = vd; rbca.rbca_remap_offset = offset; rbca.rbca_cb_arg = arg; /* * remap_blkptr_cb() will be called in order for each level of * indirection, until a concrete vdev is reached or a split block is * encountered. old_vd and old_offset are updated within the callback * as we go from the one indirect vdev to the next one (either concrete * or indirect again) in that order. */ vd->vdev_ops->vdev_op_remap(vd, offset, size, remap_blkptr_cb, &rbca); /* Check if the DVA wasn't remapped because it is a split block */ if (DVA_GET_VDEV(&rbca.rbca_bp->blk_dva[0]) == vd->vdev_id) return (B_FALSE); return (B_TRUE); } /* * Undo the allocation of a DVA which happened in the given transaction group. */ void metaslab_unalloc_dva(spa_t *spa, const dva_t *dva, uint64_t txg) { metaslab_t *msp; vdev_t *vd; uint64_t vdev = DVA_GET_VDEV(dva); uint64_t offset = DVA_GET_OFFSET(dva); uint64_t size = DVA_GET_ASIZE(dva); ASSERT(DVA_IS_VALID(dva)); ASSERT3U(spa_config_held(spa, SCL_ALL, RW_READER), !=, 0); if (txg > spa_freeze_txg(spa)) return; if ((vd = vdev_lookup_top(spa, vdev)) == NULL || !DVA_IS_VALID(dva) || (offset >> vd->vdev_ms_shift) >= vd->vdev_ms_count) { zfs_panic_recover("metaslab_free_dva(): bad DVA %llu:%llu:%llu", (u_longlong_t)vdev, (u_longlong_t)offset, (u_longlong_t)size); return; } ASSERT(!vd->vdev_removing); ASSERT(vdev_is_concrete(vd)); ASSERT0(vd->vdev_indirect_config.vic_mapping_object); ASSERT3P(vd->vdev_indirect_mapping, ==, NULL); if (DVA_GET_GANG(dva)) size = vdev_gang_header_asize(vd); msp = vd->vdev_ms[offset >> vd->vdev_ms_shift]; mutex_enter(&msp->ms_lock); range_tree_remove(msp->ms_allocating[txg & TXG_MASK], offset, size); msp->ms_allocating_total -= size; VERIFY(!msp->ms_condensing); VERIFY3U(offset, >=, msp->ms_start); VERIFY3U(offset + size, <=, msp->ms_start + msp->ms_size); VERIFY3U(range_tree_space(msp->ms_allocatable) + size, <=, msp->ms_size); VERIFY0(P2PHASE(offset, 1ULL << vd->vdev_ashift)); VERIFY0(P2PHASE(size, 1ULL << vd->vdev_ashift)); range_tree_add(msp->ms_allocatable, offset, size); mutex_exit(&msp->ms_lock); } /* * Free the block represented by the given DVA. */ void metaslab_free_dva(spa_t *spa, const dva_t *dva, boolean_t checkpoint) { uint64_t vdev = DVA_GET_VDEV(dva); uint64_t offset = DVA_GET_OFFSET(dva); uint64_t size = DVA_GET_ASIZE(dva); vdev_t *vd = vdev_lookup_top(spa, vdev); ASSERT(DVA_IS_VALID(dva)); ASSERT3U(spa_config_held(spa, SCL_ALL, RW_READER), !=, 0); if (DVA_GET_GANG(dva)) { size = vdev_gang_header_asize(vd); } metaslab_free_impl(vd, offset, size, checkpoint); } /* * Reserve some allocation slots. The reservation system must be called * before we call into the allocator. If there aren't any available slots * then the I/O will be throttled until an I/O completes and its slots are * freed up. The function returns true if it was successful in placing * the reservation. */ boolean_t metaslab_class_throttle_reserve(metaslab_class_t *mc, int slots, int allocator, zio_t *zio, int flags) { metaslab_class_allocator_t *mca = &mc->mc_allocator[allocator]; uint64_t max = mca->mca_alloc_max_slots; ASSERT(mc->mc_alloc_throttle_enabled); if (GANG_ALLOCATION(flags) || (flags & METASLAB_MUST_RESERVE) || zfs_refcount_count(&mca->mca_alloc_slots) + slots <= max) { /* * The potential race between _count() and _add() is covered * by the allocator lock in most cases, or irrelevant due to * GANG_ALLOCATION() or METASLAB_MUST_RESERVE set in others. * But even if we assume some other non-existing scenario, the * worst that can happen is few more I/Os get to allocation * earlier, that is not a problem. * * We reserve the slots individually so that we can unreserve * them individually when an I/O completes. */ for (int d = 0; d < slots; d++) zfs_refcount_add(&mca->mca_alloc_slots, zio); zio->io_flags |= ZIO_FLAG_IO_ALLOCATING; return (B_TRUE); } return (B_FALSE); } void metaslab_class_throttle_unreserve(metaslab_class_t *mc, int slots, int allocator, zio_t *zio) { metaslab_class_allocator_t *mca = &mc->mc_allocator[allocator]; ASSERT(mc->mc_alloc_throttle_enabled); for (int d = 0; d < slots; d++) zfs_refcount_remove(&mca->mca_alloc_slots, zio); } static int metaslab_claim_concrete(vdev_t *vd, uint64_t offset, uint64_t size, uint64_t txg) { metaslab_t *msp; spa_t *spa = vd->vdev_spa; int error = 0; if (offset >> vd->vdev_ms_shift >= vd->vdev_ms_count) return (SET_ERROR(ENXIO)); ASSERT3P(vd->vdev_ms, !=, NULL); msp = vd->vdev_ms[offset >> vd->vdev_ms_shift]; mutex_enter(&msp->ms_lock); if ((txg != 0 && spa_writeable(spa)) || !msp->ms_loaded) { error = metaslab_activate(msp, 0, METASLAB_WEIGHT_CLAIM); if (error == EBUSY) { ASSERT(msp->ms_loaded); ASSERT(msp->ms_weight & METASLAB_ACTIVE_MASK); error = 0; } } if (error == 0 && !range_tree_contains(msp->ms_allocatable, offset, size)) error = SET_ERROR(ENOENT); if (error || txg == 0) { /* txg == 0 indicates dry run */ mutex_exit(&msp->ms_lock); return (error); } VERIFY(!msp->ms_condensing); VERIFY0(P2PHASE(offset, 1ULL << vd->vdev_ashift)); VERIFY0(P2PHASE(size, 1ULL << vd->vdev_ashift)); VERIFY3U(range_tree_space(msp->ms_allocatable) - size, <=, msp->ms_size); range_tree_remove(msp->ms_allocatable, offset, size); range_tree_clear(msp->ms_trim, offset, size); if (spa_writeable(spa)) { /* don't dirty if we're zdb(8) */ metaslab_class_t *mc = msp->ms_group->mg_class; multilist_sublist_t *mls = multilist_sublist_lock_obj(&mc->mc_metaslab_txg_list, msp); if (!multilist_link_active(&msp->ms_class_txg_node)) { msp->ms_selected_txg = txg; multilist_sublist_insert_head(mls, msp); } multilist_sublist_unlock(mls); if (range_tree_is_empty(msp->ms_allocating[txg & TXG_MASK])) vdev_dirty(vd, VDD_METASLAB, msp, txg); range_tree_add(msp->ms_allocating[txg & TXG_MASK], offset, size); msp->ms_allocating_total += size; } mutex_exit(&msp->ms_lock); return (0); } typedef struct metaslab_claim_cb_arg_t { uint64_t mcca_txg; int mcca_error; } metaslab_claim_cb_arg_t; static void metaslab_claim_impl_cb(uint64_t inner_offset, vdev_t *vd, uint64_t offset, uint64_t size, void *arg) { (void) inner_offset; metaslab_claim_cb_arg_t *mcca_arg = arg; if (mcca_arg->mcca_error == 0) { mcca_arg->mcca_error = metaslab_claim_concrete(vd, offset, size, mcca_arg->mcca_txg); } } int metaslab_claim_impl(vdev_t *vd, uint64_t offset, uint64_t size, uint64_t txg) { if (vd->vdev_ops->vdev_op_remap != NULL) { metaslab_claim_cb_arg_t arg; /* * Only zdb(8) can claim on indirect vdevs. This is used * to detect leaks of mapped space (that are not accounted * for in the obsolete counts, spacemap, or bpobj). */ ASSERT(!spa_writeable(vd->vdev_spa)); arg.mcca_error = 0; arg.mcca_txg = txg; vd->vdev_ops->vdev_op_remap(vd, offset, size, metaslab_claim_impl_cb, &arg); if (arg.mcca_error == 0) { arg.mcca_error = metaslab_claim_concrete(vd, offset, size, txg); } return (arg.mcca_error); } else { return (metaslab_claim_concrete(vd, offset, size, txg)); } } /* * Intent log support: upon opening the pool after a crash, notify the SPA * of blocks that the intent log has allocated for immediate write, but * which are still considered free by the SPA because the last transaction * group didn't commit yet. */ static int metaslab_claim_dva(spa_t *spa, const dva_t *dva, uint64_t txg) { uint64_t vdev = DVA_GET_VDEV(dva); uint64_t offset = DVA_GET_OFFSET(dva); uint64_t size = DVA_GET_ASIZE(dva); vdev_t *vd; if ((vd = vdev_lookup_top(spa, vdev)) == NULL) { return (SET_ERROR(ENXIO)); } ASSERT(DVA_IS_VALID(dva)); if (DVA_GET_GANG(dva)) size = vdev_gang_header_asize(vd); return (metaslab_claim_impl(vd, offset, size, txg)); } int metaslab_alloc(spa_t *spa, metaslab_class_t *mc, uint64_t psize, blkptr_t *bp, int ndvas, uint64_t txg, blkptr_t *hintbp, int flags, zio_alloc_list_t *zal, zio_t *zio, int allocator) { dva_t *dva = bp->blk_dva; dva_t *hintdva = (hintbp != NULL) ? hintbp->blk_dva : NULL; int error = 0; ASSERT(bp->blk_birth == 0); ASSERT(BP_PHYSICAL_BIRTH(bp) == 0); spa_config_enter(spa, SCL_ALLOC, FTAG, RW_READER); if (mc->mc_allocator[allocator].mca_rotor == NULL) { /* no vdevs in this class */ spa_config_exit(spa, SCL_ALLOC, FTAG); return (SET_ERROR(ENOSPC)); } ASSERT(ndvas > 0 && ndvas <= spa_max_replication(spa)); ASSERT(BP_GET_NDVAS(bp) == 0); ASSERT(hintbp == NULL || ndvas <= BP_GET_NDVAS(hintbp)); ASSERT3P(zal, !=, NULL); for (int d = 0; d < ndvas; d++) { error = metaslab_alloc_dva(spa, mc, psize, dva, d, hintdva, txg, flags, zal, allocator); if (error != 0) { for (d--; d >= 0; d--) { metaslab_unalloc_dva(spa, &dva[d], txg); metaslab_group_alloc_decrement(spa, DVA_GET_VDEV(&dva[d]), zio, flags, allocator, B_FALSE); memset(&dva[d], 0, sizeof (dva_t)); } spa_config_exit(spa, SCL_ALLOC, FTAG); return (error); } else { /* * Update the metaslab group's queue depth * based on the newly allocated dva. */ metaslab_group_alloc_increment(spa, DVA_GET_VDEV(&dva[d]), zio, flags, allocator); } } ASSERT(error == 0); ASSERT(BP_GET_NDVAS(bp) == ndvas); spa_config_exit(spa, SCL_ALLOC, FTAG); BP_SET_BIRTH(bp, txg, 0); return (0); } void metaslab_free(spa_t *spa, const blkptr_t *bp, uint64_t txg, boolean_t now) { const dva_t *dva = bp->blk_dva; int ndvas = BP_GET_NDVAS(bp); ASSERT(!BP_IS_HOLE(bp)); ASSERT(!now || bp->blk_birth >= spa_syncing_txg(spa)); /* * If we have a checkpoint for the pool we need to make sure that * the blocks that we free that are part of the checkpoint won't be * reused until the checkpoint is discarded or we revert to it. * * The checkpoint flag is passed down the metaslab_free code path * and is set whenever we want to add a block to the checkpoint's * accounting. That is, we "checkpoint" blocks that existed at the * time the checkpoint was created and are therefore referenced by * the checkpointed uberblock. * * Note that, we don't checkpoint any blocks if the current * syncing txg <= spa_checkpoint_txg. We want these frees to sync * normally as they will be referenced by the checkpointed uberblock. */ boolean_t checkpoint = B_FALSE; if (bp->blk_birth <= spa->spa_checkpoint_txg && spa_syncing_txg(spa) > spa->spa_checkpoint_txg) { /* * At this point, if the block is part of the checkpoint * there is no way it was created in the current txg. */ ASSERT(!now); ASSERT3U(spa_syncing_txg(spa), ==, txg); checkpoint = B_TRUE; } spa_config_enter(spa, SCL_FREE, FTAG, RW_READER); for (int d = 0; d < ndvas; d++) { if (now) { metaslab_unalloc_dva(spa, &dva[d], txg); } else { ASSERT3U(txg, ==, spa_syncing_txg(spa)); metaslab_free_dva(spa, &dva[d], checkpoint); } } spa_config_exit(spa, SCL_FREE, FTAG); } int metaslab_claim(spa_t *spa, const blkptr_t *bp, uint64_t txg) { const dva_t *dva = bp->blk_dva; int ndvas = BP_GET_NDVAS(bp); int error = 0; ASSERT(!BP_IS_HOLE(bp)); if (txg != 0) { /* * First do a dry run to make sure all DVAs are claimable, * so we don't have to unwind from partial failures below. */ if ((error = metaslab_claim(spa, bp, 0)) != 0) return (error); } spa_config_enter(spa, SCL_ALLOC, FTAG, RW_READER); for (int d = 0; d < ndvas; d++) { error = metaslab_claim_dva(spa, &dva[d], txg); if (error != 0) break; } spa_config_exit(spa, SCL_ALLOC, FTAG); ASSERT(error == 0 || txg == 0); return (error); } void metaslab_fastwrite_mark(spa_t *spa, const blkptr_t *bp) { const dva_t *dva = bp->blk_dva; int ndvas = BP_GET_NDVAS(bp); uint64_t psize = BP_GET_PSIZE(bp); int d; vdev_t *vd; ASSERT(!BP_IS_HOLE(bp)); ASSERT(!BP_IS_EMBEDDED(bp)); ASSERT(psize > 0); spa_config_enter(spa, SCL_VDEV, FTAG, RW_READER); for (d = 0; d < ndvas; d++) { if ((vd = vdev_lookup_top(spa, DVA_GET_VDEV(&dva[d]))) == NULL) continue; atomic_add_64(&vd->vdev_pending_fastwrite, psize); } spa_config_exit(spa, SCL_VDEV, FTAG); } void metaslab_fastwrite_unmark(spa_t *spa, const blkptr_t *bp) { const dva_t *dva = bp->blk_dva; int ndvas = BP_GET_NDVAS(bp); uint64_t psize = BP_GET_PSIZE(bp); int d; vdev_t *vd; ASSERT(!BP_IS_HOLE(bp)); ASSERT(!BP_IS_EMBEDDED(bp)); ASSERT(psize > 0); spa_config_enter(spa, SCL_VDEV, FTAG, RW_READER); for (d = 0; d < ndvas; d++) { if ((vd = vdev_lookup_top(spa, DVA_GET_VDEV(&dva[d]))) == NULL) continue; ASSERT3U(vd->vdev_pending_fastwrite, >=, psize); atomic_sub_64(&vd->vdev_pending_fastwrite, psize); } spa_config_exit(spa, SCL_VDEV, FTAG); } static void metaslab_check_free_impl_cb(uint64_t inner, vdev_t *vd, uint64_t offset, uint64_t size, void *arg) { (void) inner, (void) arg; if (vd->vdev_ops == &vdev_indirect_ops) return; metaslab_check_free_impl(vd, offset, size); } static void metaslab_check_free_impl(vdev_t *vd, uint64_t offset, uint64_t size) { metaslab_t *msp; spa_t *spa __maybe_unused = vd->vdev_spa; if ((zfs_flags & ZFS_DEBUG_ZIO_FREE) == 0) return; if (vd->vdev_ops->vdev_op_remap != NULL) { vd->vdev_ops->vdev_op_remap(vd, offset, size, metaslab_check_free_impl_cb, NULL); return; } ASSERT(vdev_is_concrete(vd)); ASSERT3U(offset >> vd->vdev_ms_shift, <, vd->vdev_ms_count); ASSERT3U(spa_config_held(spa, SCL_ALL, RW_READER), !=, 0); msp = vd->vdev_ms[offset >> vd->vdev_ms_shift]; mutex_enter(&msp->ms_lock); if (msp->ms_loaded) { range_tree_verify_not_present(msp->ms_allocatable, offset, size); } /* * Check all segments that currently exist in the freeing pipeline. * * It would intuitively make sense to also check the current allocating * tree since metaslab_unalloc_dva() exists for extents that are * allocated and freed in the same sync pass within the same txg. * Unfortunately there are places (e.g. the ZIL) where we allocate a * segment but then we free part of it within the same txg * [see zil_sync()]. Thus, we don't call range_tree_verify() in the * current allocating tree. */ range_tree_verify_not_present(msp->ms_freeing, offset, size); range_tree_verify_not_present(msp->ms_checkpointing, offset, size); range_tree_verify_not_present(msp->ms_freed, offset, size); for (int j = 0; j < TXG_DEFER_SIZE; j++) range_tree_verify_not_present(msp->ms_defer[j], offset, size); range_tree_verify_not_present(msp->ms_trim, offset, size); mutex_exit(&msp->ms_lock); } void metaslab_check_free(spa_t *spa, const blkptr_t *bp) { if ((zfs_flags & ZFS_DEBUG_ZIO_FREE) == 0) return; spa_config_enter(spa, SCL_VDEV, FTAG, RW_READER); for (int i = 0; i < BP_GET_NDVAS(bp); i++) { uint64_t vdev = DVA_GET_VDEV(&bp->blk_dva[i]); vdev_t *vd = vdev_lookup_top(spa, vdev); uint64_t offset = DVA_GET_OFFSET(&bp->blk_dva[i]); uint64_t size = DVA_GET_ASIZE(&bp->blk_dva[i]); if (DVA_GET_GANG(&bp->blk_dva[i])) size = vdev_gang_header_asize(vd); ASSERT3P(vd, !=, NULL); metaslab_check_free_impl(vd, offset, size); } spa_config_exit(spa, SCL_VDEV, FTAG); } static void metaslab_group_disable_wait(metaslab_group_t *mg) { ASSERT(MUTEX_HELD(&mg->mg_ms_disabled_lock)); while (mg->mg_disabled_updating) { cv_wait(&mg->mg_ms_disabled_cv, &mg->mg_ms_disabled_lock); } } static void metaslab_group_disabled_increment(metaslab_group_t *mg) { ASSERT(MUTEX_HELD(&mg->mg_ms_disabled_lock)); ASSERT(mg->mg_disabled_updating); while (mg->mg_ms_disabled >= max_disabled_ms) { cv_wait(&mg->mg_ms_disabled_cv, &mg->mg_ms_disabled_lock); } mg->mg_ms_disabled++; ASSERT3U(mg->mg_ms_disabled, <=, max_disabled_ms); } /* * Mark the metaslab as disabled to prevent any allocations on this metaslab. * We must also track how many metaslabs are currently disabled within a * metaslab group and limit them to prevent allocation failures from * occurring because all metaslabs are disabled. */ void metaslab_disable(metaslab_t *msp) { ASSERT(!MUTEX_HELD(&msp->ms_lock)); metaslab_group_t *mg = msp->ms_group; mutex_enter(&mg->mg_ms_disabled_lock); /* * To keep an accurate count of how many threads have disabled * a specific metaslab group, we only allow one thread to mark * the metaslab group at a time. This ensures that the value of * ms_disabled will be accurate when we decide to mark a metaslab * group as disabled. To do this we force all other threads * to wait till the metaslab's mg_disabled_updating flag is no * longer set. */ metaslab_group_disable_wait(mg); mg->mg_disabled_updating = B_TRUE; if (msp->ms_disabled == 0) { metaslab_group_disabled_increment(mg); } mutex_enter(&msp->ms_lock); msp->ms_disabled++; mutex_exit(&msp->ms_lock); mg->mg_disabled_updating = B_FALSE; cv_broadcast(&mg->mg_ms_disabled_cv); mutex_exit(&mg->mg_ms_disabled_lock); } void metaslab_enable(metaslab_t *msp, boolean_t sync, boolean_t unload) { metaslab_group_t *mg = msp->ms_group; spa_t *spa = mg->mg_vd->vdev_spa; /* * Wait for the outstanding IO to be synced to prevent newly * allocated blocks from being overwritten. This used by * initialize and TRIM which are modifying unallocated space. */ if (sync) txg_wait_synced(spa_get_dsl(spa), 0); mutex_enter(&mg->mg_ms_disabled_lock); mutex_enter(&msp->ms_lock); if (--msp->ms_disabled == 0) { mg->mg_ms_disabled--; cv_broadcast(&mg->mg_ms_disabled_cv); if (unload) metaslab_unload(msp); } mutex_exit(&msp->ms_lock); mutex_exit(&mg->mg_ms_disabled_lock); } void metaslab_set_unflushed_dirty(metaslab_t *ms, boolean_t dirty) { ms->ms_unflushed_dirty = dirty; } static void metaslab_update_ondisk_flush_data(metaslab_t *ms, dmu_tx_t *tx) { vdev_t *vd = ms->ms_group->mg_vd; spa_t *spa = vd->vdev_spa; objset_t *mos = spa_meta_objset(spa); ASSERT(spa_feature_is_active(spa, SPA_FEATURE_LOG_SPACEMAP)); metaslab_unflushed_phys_t entry = { .msp_unflushed_txg = metaslab_unflushed_txg(ms), }; uint64_t entry_size = sizeof (entry); uint64_t entry_offset = ms->ms_id * entry_size; uint64_t object = 0; int err = zap_lookup(mos, vd->vdev_top_zap, VDEV_TOP_ZAP_MS_UNFLUSHED_PHYS_TXGS, sizeof (uint64_t), 1, &object); if (err == ENOENT) { object = dmu_object_alloc(mos, DMU_OTN_UINT64_METADATA, SPA_OLD_MAXBLOCKSIZE, DMU_OT_NONE, 0, tx); VERIFY0(zap_add(mos, vd->vdev_top_zap, VDEV_TOP_ZAP_MS_UNFLUSHED_PHYS_TXGS, sizeof (uint64_t), 1, &object, tx)); } else { VERIFY0(err); } dmu_write(spa_meta_objset(spa), object, entry_offset, entry_size, &entry, tx); } void metaslab_set_unflushed_txg(metaslab_t *ms, uint64_t txg, dmu_tx_t *tx) { ms->ms_unflushed_txg = txg; metaslab_update_ondisk_flush_data(ms, tx); } boolean_t metaslab_unflushed_dirty(metaslab_t *ms) { return (ms->ms_unflushed_dirty); } uint64_t metaslab_unflushed_txg(metaslab_t *ms) { return (ms->ms_unflushed_txg); } ZFS_MODULE_PARAM(zfs_metaslab, metaslab_, aliquot, ULONG, ZMOD_RW, "Allocation granularity (a.k.a. stripe size)"); ZFS_MODULE_PARAM(zfs_metaslab, metaslab_, debug_load, INT, ZMOD_RW, "Load all metaslabs when pool is first opened"); ZFS_MODULE_PARAM(zfs_metaslab, metaslab_, debug_unload, INT, ZMOD_RW, "Prevent metaslabs from being unloaded"); ZFS_MODULE_PARAM(zfs_metaslab, metaslab_, preload_enabled, INT, ZMOD_RW, "Preload potential metaslabs during reassessment"); ZFS_MODULE_PARAM(zfs_metaslab, metaslab_, unload_delay, INT, ZMOD_RW, "Delay in txgs after metaslab was last used before unloading"); ZFS_MODULE_PARAM(zfs_metaslab, metaslab_, unload_delay_ms, INT, ZMOD_RW, "Delay in milliseconds after metaslab was last used before unloading"); /* BEGIN CSTYLED */ ZFS_MODULE_PARAM(zfs_mg, zfs_mg_, noalloc_threshold, INT, ZMOD_RW, "Percentage of metaslab group size that should be free to make it " "eligible for allocation"); ZFS_MODULE_PARAM(zfs_mg, zfs_mg_, fragmentation_threshold, INT, ZMOD_RW, "Percentage of metaslab group size that should be considered eligible " "for allocations unless all metaslab groups within the metaslab class " "have also crossed this threshold"); ZFS_MODULE_PARAM(zfs_metaslab, metaslab_, fragmentation_factor_enabled, INT, ZMOD_RW, "Use the fragmentation metric to prefer less fragmented metaslabs"); /* END CSTYLED */ ZFS_MODULE_PARAM(zfs_metaslab, zfs_metaslab_, fragmentation_threshold, INT, ZMOD_RW, "Fragmentation for metaslab to allow allocation"); ZFS_MODULE_PARAM(zfs_metaslab, metaslab_, lba_weighting_enabled, INT, ZMOD_RW, "Prefer metaslabs with lower LBAs"); ZFS_MODULE_PARAM(zfs_metaslab, metaslab_, bias_enabled, INT, ZMOD_RW, "Enable metaslab group biasing"); ZFS_MODULE_PARAM(zfs_metaslab, zfs_metaslab_, segment_weight_enabled, INT, ZMOD_RW, "Enable segment-based metaslab selection"); ZFS_MODULE_PARAM(zfs_metaslab, zfs_metaslab_, switch_threshold, INT, ZMOD_RW, "Segment-based metaslab selection maximum buckets before switching"); ZFS_MODULE_PARAM(zfs_metaslab, metaslab_, force_ganging, ULONG, ZMOD_RW, "Blocks larger than this size are forced to be gang blocks"); ZFS_MODULE_PARAM(zfs_metaslab, metaslab_, df_max_search, INT, ZMOD_RW, "Max distance (bytes) to search forward before using size tree"); ZFS_MODULE_PARAM(zfs_metaslab, metaslab_, df_use_largest_segment, INT, ZMOD_RW, "When looking in size tree, use largest segment instead of exact fit"); ZFS_MODULE_PARAM(zfs_metaslab, zfs_metaslab_, max_size_cache_sec, ULONG, ZMOD_RW, "How long to trust the cached max chunk size of a metaslab"); ZFS_MODULE_PARAM(zfs_metaslab, zfs_metaslab_, mem_limit, INT, ZMOD_RW, "Percentage of memory that can be used to store metaslab range trees"); ZFS_MODULE_PARAM(zfs_metaslab, zfs_metaslab_, try_hard_before_gang, INT, ZMOD_RW, "Try hard to allocate before ganging"); ZFS_MODULE_PARAM(zfs_metaslab, zfs_metaslab_, find_max_tries, INT, ZMOD_RW, "Normally only consider this many of the best metaslabs in each vdev");