/* * 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 http://www.opensolaris.org/os/licensing. * 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 2011 Nexenta Systems, Inc. All rights reserved. * Copyright (c) 2011, 2018 by Delphix. All rights reserved. * Copyright 2020 Joyent, Inc. * Copyright 2024 Oxide Computer Company */ /* Portions Copyright 2010 Robert Milkowski */ /* * ZFS_MDB lets dmu.h know that we don't have dmu_ot, and we will define our * own macros to access the target's dmu_ot. Therefore it must be defined * before including any ZFS headers. Note that we don't define * DMU_OT_IS_ENCRYPTED_IMPL() or DMU_OT_BYTESWAP_IMPL(), therefore using them * will result in a compilation error. If they are needed in the future, we * can implement them similarly to mdb_dmu_ot_is_encrypted_impl(). */ #define ZFS_MDB #define DMU_OT_IS_ENCRYPTED_IMPL(ot) mdb_dmu_ot_is_encrypted_impl(ot) #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #ifdef _KERNEL #define ZFS_OBJ_NAME "zfs" extern int64_t mdb_gethrtime(void); #else #define ZFS_OBJ_NAME "libzpool.so.1" #endif #define ZFS_STRUCT "struct " ZFS_OBJ_NAME "`" #ifndef _KERNEL int aok; #endif enum spa_flags { SPA_FLAG_CONFIG = 1 << 0, SPA_FLAG_VDEVS = 1 << 1, SPA_FLAG_ERRORS = 1 << 2, SPA_FLAG_METASLAB_GROUPS = 1 << 3, SPA_FLAG_METASLABS = 1 << 4, SPA_FLAG_HISTOGRAMS = 1 << 5 }; /* * If any of these flags are set, call spa_vdevs in spa_print */ #define SPA_FLAG_ALL_VDEV \ (SPA_FLAG_VDEVS | SPA_FLAG_ERRORS | SPA_FLAG_METASLAB_GROUPS | \ SPA_FLAG_METASLABS) static int getmember(uintptr_t addr, const char *type, mdb_ctf_id_t *idp, const char *member, int len, void *buf) { mdb_ctf_id_t id; ulong_t off; char name[64]; if (idp == NULL) { if (mdb_ctf_lookup_by_name(type, &id) == -1) { mdb_warn("couldn't find type %s", type); return (DCMD_ERR); } idp = &id; } else { type = name; mdb_ctf_type_name(*idp, name, sizeof (name)); } if (mdb_ctf_offsetof(*idp, member, &off) == -1) { mdb_warn("couldn't find member %s of type %s\n", member, type); return (DCMD_ERR); } if (off % 8 != 0) { mdb_warn("member %s of type %s is unsupported bitfield", member, type); return (DCMD_ERR); } off /= 8; if (mdb_vread(buf, len, addr + off) == -1) { mdb_warn("failed to read %s from %s at %p", member, type, addr + off); return (DCMD_ERR); } /* mdb_warn("read %s from %s at %p+%llx\n", member, type, addr, off); */ return (0); } #define GETMEMB(addr, structname, member, dest) \ getmember(addr, ZFS_STRUCT structname, NULL, #member, \ sizeof (dest), &(dest)) #define GETMEMBID(addr, ctfid, member, dest) \ getmember(addr, NULL, ctfid, #member, sizeof (dest), &(dest)) static boolean_t strisprint(const char *cp) { for (; *cp; cp++) { if (!isprint(*cp)) return (B_FALSE); } return (B_TRUE); } /* * ::sm_entries * * Treat the buffer specified by the given address as a buffer that contains * space map entries. Iterate over the specified number of entries and print * them in both encoded and decoded form. */ /* ARGSUSED */ static int sm_entries(uintptr_t addr, uint_t flags, int argc, const mdb_arg_t *argv) { uint64_t bufsz = 0; boolean_t preview = B_FALSE; if (!(flags & DCMD_ADDRSPEC)) return (DCMD_USAGE); if (argc < 1) { preview = B_TRUE; bufsz = 2; } else if (argc != 1) { return (DCMD_USAGE); } else { switch (argv[0].a_type) { case MDB_TYPE_STRING: bufsz = mdb_strtoull(argv[0].a_un.a_str); break; case MDB_TYPE_IMMEDIATE: bufsz = argv[0].a_un.a_val; break; default: return (DCMD_USAGE); } } char *actions[] = { "ALLOC", "FREE", "INVALID" }; for (uintptr_t bufend = addr + bufsz; addr < bufend; addr += sizeof (uint64_t)) { uint64_t nwords; uint64_t start_addr = addr; uint64_t word = 0; if (mdb_vread(&word, sizeof (word), addr) == -1) { mdb_warn("failed to read space map entry %p", addr); return (DCMD_ERR); } if (SM_PREFIX_DECODE(word) == SM_DEBUG_PREFIX) { (void) mdb_printf("\t [%6llu] %s: txg %llu, " "pass %llu\n", (u_longlong_t)(addr), actions[SM_DEBUG_ACTION_DECODE(word)], (u_longlong_t)SM_DEBUG_TXG_DECODE(word), (u_longlong_t)SM_DEBUG_SYNCPASS_DECODE(word)); continue; } char entry_type; uint64_t raw_offset, raw_run, vdev_id = SM_NO_VDEVID; if (SM_PREFIX_DECODE(word) != SM2_PREFIX) { entry_type = (SM_TYPE_DECODE(word) == SM_ALLOC) ? 'A' : 'F'; raw_offset = SM_OFFSET_DECODE(word); raw_run = SM_RUN_DECODE(word); nwords = 1; } else { ASSERT3U(SM_PREFIX_DECODE(word), ==, SM2_PREFIX); raw_run = SM2_RUN_DECODE(word); vdev_id = SM2_VDEV_DECODE(word); /* it is a two-word entry so we read another word */ addr += sizeof (uint64_t); if (addr >= bufend) { mdb_warn("buffer ends in the middle of a two " "word entry\n", addr); return (DCMD_ERR); } if (mdb_vread(&word, sizeof (word), addr) == -1) { mdb_warn("failed to read space map entry %p", addr); return (DCMD_ERR); } entry_type = (SM2_TYPE_DECODE(word) == SM_ALLOC) ? 'A' : 'F'; raw_offset = SM2_OFFSET_DECODE(word); nwords = 2; } (void) mdb_printf("\t [%6llx] %c range:" " %010llx-%010llx size: %06llx vdev: %06llu words: %llu\n", (u_longlong_t)start_addr, entry_type, (u_longlong_t)raw_offset, (u_longlong_t)(raw_offset + raw_run), (u_longlong_t)raw_run, (u_longlong_t)vdev_id, (u_longlong_t)nwords); if (preview) break; } return (DCMD_OK); } static int mdb_dsl_dir_name(uintptr_t addr, char *buf) { static int gotid; static mdb_ctf_id_t dd_id; uintptr_t dd_parent; char dd_myname[ZFS_MAX_DATASET_NAME_LEN]; if (!gotid) { if (mdb_ctf_lookup_by_name(ZFS_STRUCT "dsl_dir", &dd_id) == -1) { mdb_warn("couldn't find struct dsl_dir"); return (DCMD_ERR); } gotid = TRUE; } if (GETMEMBID(addr, &dd_id, dd_parent, dd_parent) || GETMEMBID(addr, &dd_id, dd_myname, dd_myname)) { return (DCMD_ERR); } if (dd_parent) { if (mdb_dsl_dir_name(dd_parent, buf)) return (DCMD_ERR); strcat(buf, "/"); } if (dd_myname[0]) strcat(buf, dd_myname); else strcat(buf, "???"); return (0); } static int objset_name(uintptr_t addr, char *buf) { static int gotid; static mdb_ctf_id_t os_id, ds_id; uintptr_t os_dsl_dataset; char ds_snapname[ZFS_MAX_DATASET_NAME_LEN]; uintptr_t ds_dir; buf[0] = '\0'; if (!gotid) { if (mdb_ctf_lookup_by_name(ZFS_STRUCT "objset", &os_id) == -1) { mdb_warn("couldn't find struct objset"); return (DCMD_ERR); } if (mdb_ctf_lookup_by_name(ZFS_STRUCT "dsl_dataset", &ds_id) == -1) { mdb_warn("couldn't find struct dsl_dataset"); return (DCMD_ERR); } gotid = TRUE; } if (GETMEMBID(addr, &os_id, os_dsl_dataset, os_dsl_dataset)) return (DCMD_ERR); if (os_dsl_dataset == 0) { strcat(buf, "mos"); return (0); } if (GETMEMBID(os_dsl_dataset, &ds_id, ds_snapname, ds_snapname) || GETMEMBID(os_dsl_dataset, &ds_id, ds_dir, ds_dir)) { return (DCMD_ERR); } if (ds_dir && mdb_dsl_dir_name(ds_dir, buf)) return (DCMD_ERR); if (ds_snapname[0]) { strcat(buf, "@"); strcat(buf, ds_snapname); } return (0); } static int enum_lookup(char *type, int val, const char *prefix, size_t size, char *out) { const char *cp; size_t len = strlen(prefix); mdb_ctf_id_t enum_type; if (mdb_ctf_lookup_by_name(type, &enum_type) != 0) { mdb_warn("Could not find enum for %s", type); return (-1); } if ((cp = mdb_ctf_enum_name(enum_type, val)) != NULL) { if (strncmp(cp, prefix, len) == 0) cp += len; (void) strncpy(out, cp, size); } else { mdb_snprintf(out, size, "? (%d)", val); } return (0); } /* ARGSUSED */ static int zfs_params(uintptr_t addr, uint_t flags, int argc, const mdb_arg_t *argv) { /* * This table can be approximately generated by running: * egrep "^[a-z0-9_]+ [a-z0-9_]+( =.*)?;" *.c | cut -d ' ' -f 2 */ static const char *params[] = { "arc_lotsfree_percent", "arc_pages_pp_reserve", "arc_reduce_dnlc_percent", "arc_swapfs_reserve", "arc_zio_arena_free_shift", "dbuf_cache_hiwater_pct", "dbuf_cache_lowater_pct", "dbuf_cache_max_bytes", "dbuf_cache_max_shift", "ddt_zap_indirect_blockshift", "ddt_zap_leaf_blockshift", "ditto_same_vdev_distance_shift", "dmu_find_threads", "dmu_rescan_dnode_threshold", "dsl_scan_delay_completion", "fzap_default_block_shift", "l2arc_feed_again", "l2arc_feed_min_ms", "l2arc_feed_secs", "l2arc_headroom", "l2arc_headroom_boost", "l2arc_noprefetch", "l2arc_norw", "l2arc_write_boost", "l2arc_write_max", "metaslab_aliquot", "metaslab_bias_enabled", "metaslab_debug_load", "metaslab_debug_unload", "metaslab_df_alloc_threshold", "metaslab_df_free_pct", "metaslab_fragmentation_factor_enabled", "metaslab_force_ganging", "metaslab_lba_weighting_enabled", "metaslab_load_pct", "metaslab_min_alloc_size", "metaslab_ndf_clump_shift", "metaslab_preload_enabled", "metaslab_preload_limit", "metaslab_trace_enabled", "metaslab_trace_max_entries", "metaslab_unload_delay", "metaslabs_per_vdev", "reference_history", "reference_tracking_enable", "send_holes_without_birth_time", "spa_asize_inflation", "spa_load_verify_data", "spa_load_verify_maxinflight", "spa_load_verify_metadata", "spa_max_replication_override", "spa_min_slop", "spa_mode_global", "spa_slop_shift", "space_map_blksz", "vdev_mirror_shift", "zfetch_max_distance", "zfs_abd_chunk_size", "zfs_abd_scatter_enabled", "zfs_arc_average_blocksize", "zfs_arc_evict_batch_limit", "zfs_arc_grow_retry", "zfs_arc_max", "zfs_arc_meta_limit", "zfs_arc_meta_min", "zfs_arc_min", "zfs_arc_p_min_shift", "zfs_arc_shrink_shift", "zfs_async_block_max_blocks", "zfs_ccw_retry_interval", "zfs_commit_timeout_pct", "zfs_compressed_arc_enabled", "zfs_condense_indirect_commit_entry_delay_ticks", "zfs_condense_indirect_vdevs_enable", "zfs_condense_max_obsolete_bytes", "zfs_condense_min_mapping_bytes", "zfs_condense_pct", "zfs_dbgmsg_maxsize", "zfs_deadman_checktime_ms", "zfs_deadman_enabled", "zfs_deadman_synctime_ms", "zfs_dedup_prefetch", "zfs_default_bs", "zfs_default_ibs", "zfs_delay_max_ns", "zfs_delay_min_dirty_percent", "zfs_delay_resolution_ns", "zfs_delay_scale", "zfs_dirty_data_max", "zfs_dirty_data_max_max", "zfs_dirty_data_max_percent", "zfs_dirty_data_sync", "zfs_flags", "zfs_free_bpobj_enabled", "zfs_free_leak_on_eio", "zfs_free_min_time_ms", "zfs_fsync_sync_cnt", "zfs_immediate_write_sz", "zfs_indirect_condense_obsolete_pct", "zfs_lua_check_instrlimit_interval", "zfs_lua_max_instrlimit", "zfs_lua_max_memlimit", "zfs_max_recordsize", "zfs_mdcomp_disable", "zfs_metaslab_condense_block_threshold", "zfs_metaslab_fragmentation_threshold", "zfs_metaslab_segment_weight_enabled", "zfs_metaslab_switch_threshold", "zfs_mg_fragmentation_threshold", "zfs_mg_noalloc_threshold", "zfs_multilist_num_sublists", "zfs_no_scrub_io", "zfs_no_scrub_prefetch", "zfs_nocacheflush", "zfs_nopwrite_enabled", "zfs_object_remap_one_indirect_delay_ticks", "zfs_obsolete_min_time_ms", "zfs_pd_bytes_max", "zfs_per_txg_dirty_frees_percent", "zfs_prefetch_disable", "zfs_read_chunk_size", "zfs_recover", "zfs_recv_queue_length", "zfs_redundant_metadata_most_ditto_level", "zfs_remap_blkptr_enable", "zfs_remove_max_copy_bytes", "zfs_remove_max_segment", "zfs_resilver_delay", "zfs_resilver_min_time_ms", "zfs_scan_idle", "zfs_scan_min_time_ms", "zfs_scrub_delay", "zfs_scrub_limit", "zfs_send_corrupt_data", "zfs_send_queue_length", "zfs_send_set_freerecords_bit", "zfs_sync_pass_deferred_free", "zfs_sync_pass_dont_compress", "zfs_sync_pass_rewrite", "zfs_sync_taskq_batch_pct", "zfs_top_maxinflight", "zfs_txg_timeout", "zfs_vdev_aggregation_limit", "zfs_vdev_async_read_max_active", "zfs_vdev_async_read_min_active", "zfs_vdev_async_write_active_max_dirty_percent", "zfs_vdev_async_write_active_min_dirty_percent", "zfs_vdev_async_write_max_active", "zfs_vdev_async_write_min_active", "zfs_vdev_cache_bshift", "zfs_vdev_cache_max", "zfs_vdev_cache_size", "zfs_vdev_max_active", "zfs_vdev_queue_depth_pct", "zfs_vdev_read_gap_limit", "zfs_vdev_removal_max_active", "zfs_vdev_removal_min_active", "zfs_vdev_scrub_max_active", "zfs_vdev_scrub_min_active", "zfs_vdev_sync_read_max_active", "zfs_vdev_sync_read_min_active", "zfs_vdev_sync_write_max_active", "zfs_vdev_sync_write_min_active", "zfs_vdev_write_gap_limit", "zfs_write_implies_delete_child", "zfs_zil_clean_taskq_maxalloc", "zfs_zil_clean_taskq_minalloc", "zfs_zil_clean_taskq_nthr_pct", "zil_replay_disable", "zil_slog_bulk", "zio_buf_debug_limit", "zio_dva_throttle_enabled", "zio_injection_enabled", "zvol_immediate_write_sz", "zvol_maxphys", "zvol_unmap_enabled", "zvol_unmap_sync_enabled", "zfs_max_dataset_nesting", }; for (int i = 0; i < sizeof (params) / sizeof (params[0]); i++) { int sz; uint64_t val64; uint32_t *val32p = (uint32_t *)&val64; sz = mdb_readvar(&val64, params[i]); if (sz == 4) { mdb_printf("%s = 0x%x\n", params[i], *val32p); } else if (sz == 8) { mdb_printf("%s = 0x%llx\n", params[i], val64); } else { mdb_warn("variable %s not found", params[i]); } } return (DCMD_OK); } /* ARGSUSED */ static int dva(uintptr_t addr, uint_t flags, int argc, const mdb_arg_t *argv) { dva_t dva; if (mdb_vread(&dva, sizeof (dva_t), addr) == -1) { mdb_warn("failed to read dva_t"); return (DCMD_ERR); } mdb_printf("<%llu:%llx:%llx>\n", (u_longlong_t)DVA_GET_VDEV(&dva), (u_longlong_t)DVA_GET_OFFSET(&dva), (u_longlong_t)DVA_GET_ASIZE(&dva)); return (DCMD_OK); } typedef struct mdb_dmu_object_type_info { boolean_t ot_encrypt; } mdb_dmu_object_type_info_t; static boolean_t mdb_dmu_ot_is_encrypted_impl(dmu_object_type_t ot) { mdb_dmu_object_type_info_t mdoti; GElf_Sym sym; size_t sz = mdb_ctf_sizeof_by_name("dmu_object_type_info_t"); if (mdb_lookup_by_obj(ZFS_OBJ_NAME, "dmu_ot", &sym)) { mdb_warn("failed to find " ZFS_OBJ_NAME "`dmu_ot"); return (B_FALSE); } if (mdb_ctf_vread(&mdoti, "dmu_object_type_info_t", "mdb_dmu_object_type_info_t", sym.st_value + sz * ot, 0) != 0) { return (B_FALSE); } return (mdoti.ot_encrypt); } /* ARGSUSED */ static int blkptr(uintptr_t addr, uint_t flags, int argc, const mdb_arg_t *argv) { char type[80], checksum[80], compress[80]; blkptr_t blk, *bp = &blk; char buf[BP_SPRINTF_LEN]; if (mdb_vread(&blk, sizeof (blkptr_t), addr) == -1) { mdb_warn("failed to read blkptr_t"); return (DCMD_ERR); } if (enum_lookup("enum dmu_object_type", BP_GET_TYPE(bp), "DMU_OT_", sizeof (type), type) == -1 || enum_lookup("enum zio_checksum", BP_GET_CHECKSUM(bp), "ZIO_CHECKSUM_", sizeof (checksum), checksum) == -1 || enum_lookup("enum zio_compress", BP_GET_COMPRESS(bp), "ZIO_COMPRESS_", sizeof (compress), compress) == -1) { mdb_warn("Could not find blkptr enumerated types"); return (DCMD_ERR); } SNPRINTF_BLKPTR(mdb_snprintf, '\n', buf, sizeof (buf), bp, type, checksum, compress); mdb_printf("%s\n", buf); return (DCMD_OK); } typedef struct mdb_dmu_buf_impl { struct { uint64_t db_object; uintptr_t db_data; } db; uintptr_t db_objset; uint64_t db_level; uint64_t db_blkid; struct { uint64_t rc_count; } db_holds; } mdb_dmu_buf_impl_t; /* ARGSUSED */ static int dbuf(uintptr_t addr, uint_t flags, int argc, const mdb_arg_t *argv) { mdb_dmu_buf_impl_t db; char objectname[32]; char blkidname[32]; char path[ZFS_MAX_DATASET_NAME_LEN]; int ptr_width = (int)(sizeof (void *)) * 2; if (DCMD_HDRSPEC(flags)) mdb_printf("%*s %8s %3s %9s %5s %s\n", ptr_width, "addr", "object", "lvl", "blkid", "holds", "os"); if (mdb_ctf_vread(&db, ZFS_STRUCT "dmu_buf_impl", "mdb_dmu_buf_impl_t", addr, 0) == -1) return (DCMD_ERR); if (db.db.db_object == DMU_META_DNODE_OBJECT) (void) strcpy(objectname, "mdn"); else (void) mdb_snprintf(objectname, sizeof (objectname), "%llx", (u_longlong_t)db.db.db_object); if (db.db_blkid == DMU_BONUS_BLKID) (void) strcpy(blkidname, "bonus"); else (void) mdb_snprintf(blkidname, sizeof (blkidname), "%llx", (u_longlong_t)db.db_blkid); if (objset_name(db.db_objset, path)) { return (DCMD_ERR); } mdb_printf("%*p %8s %3u %9s %5llu %s\n", ptr_width, addr, objectname, (int)db.db_level, blkidname, db.db_holds.rc_count, path); return (DCMD_OK); } /* ARGSUSED */ static int dbuf_stats(uintptr_t addr, uint_t flags, int argc, const mdb_arg_t *argv) { #define HISTOSZ 32 uintptr_t dbp; dmu_buf_impl_t db; dbuf_hash_table_t ht; uint64_t bucket, ndbufs; uint64_t histo[HISTOSZ]; uint64_t histo2[HISTOSZ]; int i, maxidx; if (mdb_readvar(&ht, "dbuf_hash_table") == -1) { mdb_warn("failed to read 'dbuf_hash_table'"); return (DCMD_ERR); } for (i = 0; i < HISTOSZ; i++) { histo[i] = 0; histo2[i] = 0; } ndbufs = 0; for (bucket = 0; bucket < ht.hash_table_mask+1; bucket++) { int len; if (mdb_vread(&dbp, sizeof (void *), (uintptr_t)(ht.hash_table+bucket)) == -1) { mdb_warn("failed to read hash bucket %u at %p", bucket, ht.hash_table+bucket); return (DCMD_ERR); } len = 0; while (dbp != 0) { if (mdb_vread(&db, sizeof (dmu_buf_impl_t), dbp) == -1) { mdb_warn("failed to read dbuf at %p", dbp); return (DCMD_ERR); } dbp = (uintptr_t)db.db_hash_next; for (i = MIN(len, HISTOSZ - 1); i >= 0; i--) histo2[i]++; len++; ndbufs++; } if (len >= HISTOSZ) len = HISTOSZ-1; histo[len]++; } mdb_printf("hash table has %llu buckets, %llu dbufs " "(avg %llu buckets/dbuf)\n", ht.hash_table_mask+1, ndbufs, (ht.hash_table_mask+1)/ndbufs); mdb_printf("\n"); maxidx = 0; for (i = 0; i < HISTOSZ; i++) if (histo[i] > 0) maxidx = i; mdb_printf("hash chain length number of buckets\n"); for (i = 0; i <= maxidx; i++) mdb_printf("%u %llu\n", i, histo[i]); mdb_printf("\n"); maxidx = 0; for (i = 0; i < HISTOSZ; i++) if (histo2[i] > 0) maxidx = i; mdb_printf("hash chain depth number of dbufs\n"); for (i = 0; i <= maxidx; i++) mdb_printf("%u or more %llu %llu%%\n", i, histo2[i], histo2[i]*100/ndbufs); return (DCMD_OK); } #define CHAIN_END 0xffff /* * ::zap_leaf [-v] * * Print a zap_leaf_phys_t, assumed to be 16k */ /* ARGSUSED */ static int zap_leaf(uintptr_t addr, uint_t flags, int argc, const mdb_arg_t *argv) { char buf[16*1024]; int verbose = B_FALSE; int four = B_FALSE; dmu_buf_t l_dbuf; zap_leaf_t l; zap_leaf_phys_t *zlp = (void *)buf; int i; if (mdb_getopts(argc, argv, 'v', MDB_OPT_SETBITS, TRUE, &verbose, '4', MDB_OPT_SETBITS, TRUE, &four, NULL) != argc) return (DCMD_USAGE); l_dbuf.db_data = zlp; l.l_dbuf = &l_dbuf; l.l_bs = 14; /* assume 16k blocks */ if (four) l.l_bs = 12; if (!(flags & DCMD_ADDRSPEC)) { return (DCMD_USAGE); } if (mdb_vread(buf, sizeof (buf), addr) == -1) { mdb_warn("failed to read zap_leaf_phys_t at %p", addr); return (DCMD_ERR); } if (zlp->l_hdr.lh_block_type != ZBT_LEAF || zlp->l_hdr.lh_magic != ZAP_LEAF_MAGIC) { mdb_warn("This does not appear to be a zap_leaf_phys_t"); return (DCMD_ERR); } mdb_printf("zap_leaf_phys_t at %p:\n", addr); mdb_printf(" lh_prefix_len = %u\n", zlp->l_hdr.lh_prefix_len); mdb_printf(" lh_prefix = %llx\n", zlp->l_hdr.lh_prefix); mdb_printf(" lh_nentries = %u\n", zlp->l_hdr.lh_nentries); mdb_printf(" lh_nfree = %u\n", zlp->l_hdr.lh_nfree, zlp->l_hdr.lh_nfree * 100 / (ZAP_LEAF_NUMCHUNKS(&l))); mdb_printf(" lh_freelist = %u\n", zlp->l_hdr.lh_freelist); mdb_printf(" lh_flags = %x (%s)\n", zlp->l_hdr.lh_flags, zlp->l_hdr.lh_flags & ZLF_ENTRIES_CDSORTED ? "ENTRIES_CDSORTED" : ""); if (verbose) { mdb_printf(" hash table:\n"); for (i = 0; i < ZAP_LEAF_HASH_NUMENTRIES(&l); i++) { if (zlp->l_hash[i] != CHAIN_END) mdb_printf(" %u: %u\n", i, zlp->l_hash[i]); } } mdb_printf(" chunks:\n"); for (i = 0; i < ZAP_LEAF_NUMCHUNKS(&l); i++) { /* LINTED: alignment */ zap_leaf_chunk_t *zlc = &ZAP_LEAF_CHUNK(&l, i); switch (zlc->l_entry.le_type) { case ZAP_CHUNK_FREE: if (verbose) { mdb_printf(" %u: free; lf_next = %u\n", i, zlc->l_free.lf_next); } break; case ZAP_CHUNK_ENTRY: mdb_printf(" %u: entry\n", i); if (verbose) { mdb_printf(" le_next = %u\n", zlc->l_entry.le_next); } mdb_printf(" le_name_chunk = %u\n", zlc->l_entry.le_name_chunk); mdb_printf(" le_name_numints = %u\n", zlc->l_entry.le_name_numints); mdb_printf(" le_value_chunk = %u\n", zlc->l_entry.le_value_chunk); mdb_printf(" le_value_intlen = %u\n", zlc->l_entry.le_value_intlen); mdb_printf(" le_value_numints = %u\n", zlc->l_entry.le_value_numints); mdb_printf(" le_cd = %u\n", zlc->l_entry.le_cd); mdb_printf(" le_hash = %llx\n", zlc->l_entry.le_hash); break; case ZAP_CHUNK_ARRAY: mdb_printf(" %u: array", i); if (strisprint((char *)zlc->l_array.la_array)) mdb_printf(" \"%s\"", zlc->l_array.la_array); mdb_printf("\n"); if (verbose) { int j; mdb_printf(" "); for (j = 0; j < ZAP_LEAF_ARRAY_BYTES; j++) { mdb_printf("%02x ", zlc->l_array.la_array[j]); } mdb_printf("\n"); } if (zlc->l_array.la_next != CHAIN_END) { mdb_printf(" lf_next = %u\n", zlc->l_array.la_next); } break; default: mdb_printf(" %u: undefined type %u\n", zlc->l_entry.le_type); } } return (DCMD_OK); } typedef struct dbufs_data { mdb_ctf_id_t id; uint64_t objset; uint64_t object; uint64_t level; uint64_t blkid; char *osname; } dbufs_data_t; #define DBUFS_UNSET (0xbaddcafedeadbeefULL) /* ARGSUSED */ static int dbufs_cb(uintptr_t addr, const void *unknown, void *arg) { dbufs_data_t *data = arg; uintptr_t objset; dmu_buf_t db; uint8_t level; uint64_t blkid; char osname[ZFS_MAX_DATASET_NAME_LEN]; if (GETMEMBID(addr, &data->id, db_objset, objset) || GETMEMBID(addr, &data->id, db, db) || GETMEMBID(addr, &data->id, db_level, level) || GETMEMBID(addr, &data->id, db_blkid, blkid)) { return (WALK_ERR); } if ((data->objset == DBUFS_UNSET || data->objset == objset) && (data->osname == NULL || (objset_name(objset, osname) == 0 && strcmp(data->osname, osname) == 0)) && (data->object == DBUFS_UNSET || data->object == db.db_object) && (data->level == DBUFS_UNSET || data->level == level) && (data->blkid == DBUFS_UNSET || data->blkid == blkid)) { mdb_printf("%#lr\n", addr); } return (WALK_NEXT); } /* ARGSUSED */ static int dbufs(uintptr_t addr, uint_t flags, int argc, const mdb_arg_t *argv) { dbufs_data_t data; char *object = NULL; char *blkid = NULL; data.objset = data.object = data.level = data.blkid = DBUFS_UNSET; data.osname = NULL; if (mdb_getopts(argc, argv, 'O', MDB_OPT_UINT64, &data.objset, 'n', MDB_OPT_STR, &data.osname, 'o', MDB_OPT_STR, &object, 'l', MDB_OPT_UINT64, &data.level, 'b', MDB_OPT_STR, &blkid, NULL) != argc) { return (DCMD_USAGE); } if (object) { if (strcmp(object, "mdn") == 0) { data.object = DMU_META_DNODE_OBJECT; } else { data.object = mdb_strtoull(object); } } if (blkid) { if (strcmp(blkid, "bonus") == 0) { data.blkid = DMU_BONUS_BLKID; } else { data.blkid = mdb_strtoull(blkid); } } if (mdb_ctf_lookup_by_name(ZFS_STRUCT "dmu_buf_impl", &data.id) == -1) { mdb_warn("couldn't find struct dmu_buf_impl_t"); return (DCMD_ERR); } if (mdb_walk("dmu_buf_impl_t", dbufs_cb, &data) != 0) { mdb_warn("can't walk dbufs"); return (DCMD_ERR); } return (DCMD_OK); } typedef struct abuf_find_data { dva_t dva; mdb_ctf_id_t id; } abuf_find_data_t; /* ARGSUSED */ static int abuf_find_cb(uintptr_t addr, const void *unknown, void *arg) { abuf_find_data_t *data = arg; dva_t dva; if (GETMEMBID(addr, &data->id, b_dva, dva)) { return (WALK_ERR); } if (dva.dva_word[0] == data->dva.dva_word[0] && dva.dva_word[1] == data->dva.dva_word[1]) { mdb_printf("%#lr\n", addr); } return (WALK_NEXT); } typedef struct mdb_arc_state { uintptr_t arcs_list[ARC_BUFC_NUMTYPES]; } mdb_arc_state_t; /* ARGSUSED */ static int abuf_find(uintptr_t addr, uint_t flags, int argc, const mdb_arg_t *argv) { abuf_find_data_t data; GElf_Sym sym; int i, j; const char *syms[] = { "ARC_mru", "ARC_mru_ghost", "ARC_mfu", "ARC_mfu_ghost", }; if (argc != 2) return (DCMD_USAGE); for (i = 0; i < 2; i ++) { switch (argv[i].a_type) { case MDB_TYPE_STRING: data.dva.dva_word[i] = mdb_strtoull(argv[i].a_un.a_str); break; case MDB_TYPE_IMMEDIATE: data.dva.dva_word[i] = argv[i].a_un.a_val; break; default: return (DCMD_USAGE); } } if (mdb_ctf_lookup_by_name(ZFS_STRUCT "arc_buf_hdr", &data.id) == -1) { mdb_warn("couldn't find struct arc_buf_hdr"); return (DCMD_ERR); } for (i = 0; i < sizeof (syms) / sizeof (syms[0]); i++) { mdb_arc_state_t mas; if (mdb_lookup_by_obj(ZFS_OBJ_NAME, syms[i], &sym)) { mdb_warn("can't find symbol %s", syms[i]); return (DCMD_ERR); } if (mdb_ctf_vread(&mas, "arc_state_t", "mdb_arc_state_t", sym.st_value, 0) != 0) { mdb_warn("can't read arcs_list of %s", syms[i]); return (DCMD_ERR); } for (j = 0; j < ARC_BUFC_NUMTYPES; j++) { uintptr_t addr = mas.arcs_list[j]; if (addr == 0) continue; if (mdb_pwalk("multilist", abuf_find_cb, &data, addr) != 0) { mdb_warn("can't walk %s", syms[i]); return (DCMD_ERR); } } } return (DCMD_OK); } typedef struct dbgmsg_arg { boolean_t da_verbose; boolean_t da_verbose_hr; boolean_t da_address; } dbgmsg_arg_t; /* ARGSUSED */ static int dbgmsg_cb(uintptr_t addr, const void *unknown, void *arg) { static mdb_ctf_id_t id; static boolean_t gotid; static ulong_t off; dbgmsg_arg_t *da = arg; time_t timestamp; hrtime_t hrtime; char buf[1024]; if (!gotid) { if (mdb_ctf_lookup_by_name(ZFS_STRUCT "zfs_dbgmsg", &id) == -1) { mdb_warn("couldn't find struct zfs_dbgmsg"); return (WALK_ERR); } gotid = TRUE; if (mdb_ctf_offsetof(id, "zdm_msg", &off) == -1) { mdb_warn("couldn't find zdm_msg"); return (WALK_ERR); } off /= 8; } if (GETMEMBID(addr, &id, zdm_timestamp, timestamp)) { return (WALK_ERR); } if (da->da_verbose_hr) { if (GETMEMBID(addr, &id, zdm_hrtime, hrtime)) { return (WALK_ERR); } } if (mdb_readstr(buf, sizeof (buf), addr + off) == -1) { mdb_warn("failed to read zdm_msg at %p\n", addr + off); return (DCMD_ERR); } if (da->da_address) mdb_printf("%p ", addr); if (da->da_verbose) mdb_printf("%Y ", timestamp); if (da->da_verbose_hr) mdb_printf("%016x ", hrtime); mdb_printf("%s\n", buf); if (da->da_verbose || da->da_verbose_hr) (void) mdb_call_dcmd("whatis", addr, DCMD_ADDRSPEC, 0, NULL); return (WALK_NEXT); } /* ARGSUSED */ static int dbgmsg(uintptr_t addr, uint_t flags, int argc, const mdb_arg_t *argv) { GElf_Sym sym; dbgmsg_arg_t da = { 0 }; if (mdb_getopts(argc, argv, 'v', MDB_OPT_SETBITS, B_TRUE, &da.da_verbose, 'r', MDB_OPT_SETBITS, B_TRUE, &da.da_verbose_hr, 'a', MDB_OPT_SETBITS, B_TRUE, &da.da_address, NULL) != argc) return (DCMD_USAGE); if (mdb_lookup_by_obj(ZFS_OBJ_NAME, "zfs_dbgmsgs", &sym)) { mdb_warn("can't find zfs_dbgmsgs"); return (DCMD_ERR); } if (mdb_pwalk("list", dbgmsg_cb, &da, sym.st_value) != 0) { mdb_warn("can't walk zfs_dbgmsgs"); return (DCMD_ERR); } return (DCMD_OK); } /*ARGSUSED*/ static int arc_print(uintptr_t addr, uint_t flags, int argc, const mdb_arg_t *argv) { kstat_named_t *stats; GElf_Sym sym; int nstats, i; uint_t opt_a = FALSE; uint_t opt_b = FALSE; uint_t shift = 0; const char *suffix; static const char *bytestats[] = { "p", "c", "c_min", "c_max", "size", "duplicate_buffers_size", "arc_meta_used", "arc_meta_limit", "arc_meta_max", "arc_meta_min", "hdr_size", "data_size", "metadata_size", "other_size", "anon_size", "anon_evictable_data", "anon_evictable_metadata", "mru_size", "mru_evictable_data", "mru_evictable_metadata", "mru_ghost_size", "mru_ghost_evictable_data", "mru_ghost_evictable_metadata", "mfu_size", "mfu_evictable_data", "mfu_evictable_metadata", "mfu_ghost_size", "mfu_ghost_evictable_data", "mfu_ghost_evictable_metadata", "evict_l2_cached", "evict_l2_eligible", "evict_l2_ineligible", "l2_read_bytes", "l2_write_bytes", "l2_size", "l2_asize", "l2_hdr_size", "compressed_size", "uncompressed_size", "overhead_size", NULL }; static const char *extras[] = { "arc_no_grow", "arc_tempreserve", NULL }; if (mdb_lookup_by_obj(ZFS_OBJ_NAME, "arc_stats", &sym) == -1) { mdb_warn("failed to find 'arc_stats'"); return (DCMD_ERR); } stats = mdb_zalloc(sym.st_size, UM_SLEEP | UM_GC); if (mdb_vread(stats, sym.st_size, sym.st_value) == -1) { mdb_warn("couldn't read 'arc_stats' at %p", sym.st_value); return (DCMD_ERR); } nstats = sym.st_size / sizeof (kstat_named_t); /* NB: -a / opt_a are ignored for backwards compatability */ if (mdb_getopts(argc, argv, 'a', MDB_OPT_SETBITS, TRUE, &opt_a, 'b', MDB_OPT_SETBITS, TRUE, &opt_b, 'k', MDB_OPT_SETBITS, 10, &shift, 'm', MDB_OPT_SETBITS, 20, &shift, 'g', MDB_OPT_SETBITS, 30, &shift, NULL) != argc) return (DCMD_USAGE); if (!opt_b && !shift) shift = 20; switch (shift) { case 0: suffix = "B"; break; case 10: suffix = "KB"; break; case 20: suffix = "MB"; break; case 30: suffix = "GB"; break; default: suffix = "XX"; } for (i = 0; i < nstats; i++) { int j; boolean_t bytes = B_FALSE; for (j = 0; bytestats[j]; j++) { if (strcmp(stats[i].name, bytestats[j]) == 0) { bytes = B_TRUE; break; } } if (bytes) { mdb_printf("%-25s = %9llu %s\n", stats[i].name, stats[i].value.ui64 >> shift, suffix); } else { mdb_printf("%-25s = %9llu\n", stats[i].name, stats[i].value.ui64); } } for (i = 0; extras[i]; i++) { uint64_t buf; if (mdb_lookup_by_obj(ZFS_OBJ_NAME, extras[i], &sym) == -1) { mdb_warn("failed to find '%s'", extras[i]); return (DCMD_ERR); } if (sym.st_size != sizeof (uint64_t) && sym.st_size != sizeof (uint32_t)) { mdb_warn("expected scalar for variable '%s'\n", extras[i]); return (DCMD_ERR); } if (mdb_vread(&buf, sym.st_size, sym.st_value) == -1) { mdb_warn("couldn't read '%s'", extras[i]); return (DCMD_ERR); } mdb_printf("%-25s = ", extras[i]); /* NB: all the 64-bit extras happen to be byte counts */ if (sym.st_size == sizeof (uint64_t)) mdb_printf("%9llu %s\n", buf >> shift, suffix); if (sym.st_size == sizeof (uint32_t)) mdb_printf("%9d\n", *((uint32_t *)&buf)); } return (DCMD_OK); } typedef struct mdb_spa_print { pool_state_t spa_state; char spa_name[ZFS_MAX_DATASET_NAME_LEN]; uintptr_t spa_normal_class; } mdb_spa_print_t; const char histo_stars[] = "****************************************"; const int 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++) { mdb_printf("%3u: %6llu %s\n", i + offset, (u_longlong_t)histo[i], &histo_stars[(max - histo[i]) * histo_width / max]); } } typedef struct mdb_metaslab_class { uint64_t mc_histogram[RANGE_TREE_HISTOGRAM_SIZE]; } mdb_metaslab_class_t; /* * spa_class_histogram(uintptr_t class_addr) * * Prints free space histogram for a device class * * Returns DCMD_OK, or DCMD_ERR. */ static int spa_class_histogram(uintptr_t class_addr) { mdb_metaslab_class_t mc; if (mdb_ctf_vread(&mc, "metaslab_class_t", "mdb_metaslab_class_t", class_addr, 0) == -1) return (DCMD_ERR); mdb_inc_indent(4); dump_histogram(mc.mc_histogram, RANGE_TREE_HISTOGRAM_SIZE, 0); mdb_dec_indent(4); return (DCMD_OK); } /* * ::spa * * -c Print configuration information as well * -v Print vdev state * -e Print vdev error stats * -m Print vdev metaslab info * -M print vdev metaslab group info * -h Print histogram info (must be combined with -m or -M) * * Print a summarized spa_t. When given no arguments, prints out a table of all * active pools on the system. */ /* ARGSUSED */ static int spa_print(uintptr_t addr, uint_t flags, int argc, const mdb_arg_t *argv) { const char *statetab[] = { "ACTIVE", "EXPORTED", "DESTROYED", "SPARE", "L2CACHE", "UNINIT", "UNAVAIL", "POTENTIAL" }; const char *state; int spa_flags = 0; if (mdb_getopts(argc, argv, 'c', MDB_OPT_SETBITS, SPA_FLAG_CONFIG, &spa_flags, 'v', MDB_OPT_SETBITS, SPA_FLAG_VDEVS, &spa_flags, 'e', MDB_OPT_SETBITS, SPA_FLAG_ERRORS, &spa_flags, 'M', MDB_OPT_SETBITS, SPA_FLAG_METASLAB_GROUPS, &spa_flags, 'm', MDB_OPT_SETBITS, SPA_FLAG_METASLABS, &spa_flags, 'h', MDB_OPT_SETBITS, SPA_FLAG_HISTOGRAMS, &spa_flags, NULL) != argc) return (DCMD_USAGE); if (!(flags & DCMD_ADDRSPEC)) { if (mdb_walk_dcmd("spa", "spa", argc, argv) == -1) { mdb_warn("can't walk spa"); return (DCMD_ERR); } return (DCMD_OK); } if (flags & DCMD_PIPE_OUT) { mdb_printf("%#lr\n", addr); return (DCMD_OK); } if (DCMD_HDRSPEC(flags)) mdb_printf("%%-?s %9s %-*s%\n", "ADDR", "STATE", sizeof (uintptr_t) == 4 ? 60 : 52, "NAME"); mdb_spa_print_t spa; if (mdb_ctf_vread(&spa, "spa_t", "mdb_spa_print_t", addr, 0) == -1) return (DCMD_ERR); if (spa.spa_state < 0 || spa.spa_state > POOL_STATE_UNAVAIL) state = "UNKNOWN"; else state = statetab[spa.spa_state]; mdb_printf("%0?p %9s %s\n", addr, state, spa.spa_name); if (spa_flags & SPA_FLAG_HISTOGRAMS) spa_class_histogram(spa.spa_normal_class); if (spa_flags & SPA_FLAG_CONFIG) { mdb_printf("\n"); mdb_inc_indent(4); if (mdb_call_dcmd("spa_config", addr, flags, 0, NULL) != DCMD_OK) return (DCMD_ERR); mdb_dec_indent(4); } if (spa_flags & SPA_FLAG_ALL_VDEV) { mdb_arg_t v; char opts[100] = "-"; int args = (spa_flags | SPA_FLAG_VDEVS) == SPA_FLAG_VDEVS ? 0 : 1; if (spa_flags & SPA_FLAG_ERRORS) strcat(opts, "e"); if (spa_flags & SPA_FLAG_METASLABS) strcat(opts, "m"); if (spa_flags & SPA_FLAG_METASLAB_GROUPS) strcat(opts, "M"); if (spa_flags & SPA_FLAG_HISTOGRAMS) strcat(opts, "h"); v.a_type = MDB_TYPE_STRING; v.a_un.a_str = opts; mdb_printf("\n"); mdb_inc_indent(4); if (mdb_call_dcmd("spa_vdevs", addr, flags, args, &v) != DCMD_OK) return (DCMD_ERR); mdb_dec_indent(4); } return (DCMD_OK); } typedef struct mdb_spa_config_spa { uintptr_t spa_config; } mdb_spa_config_spa_t; /* * ::spa_config * * Given a spa_t, print the configuration information stored in spa_config. * Since it's just an nvlist, format it as an indented list of name=value pairs. * We simply read the value of spa_config and pass off to ::nvlist. */ /* ARGSUSED */ static int spa_print_config(uintptr_t addr, uint_t flags, int argc, const mdb_arg_t *argv) { mdb_spa_config_spa_t spa; if (argc != 0 || !(flags & DCMD_ADDRSPEC)) return (DCMD_USAGE); if (mdb_ctf_vread(&spa, ZFS_STRUCT "spa", "mdb_spa_config_spa_t", addr, 0) == -1) return (DCMD_ERR); if (spa.spa_config == 0) { mdb_printf("(none)\n"); return (DCMD_OK); } return (mdb_call_dcmd("nvlist", spa.spa_config, flags, 0, NULL)); } typedef struct mdb_range_tree { struct { uint64_t bt_num_elems; uint64_t bt_num_nodes; } rt_root; uint64_t rt_space; range_seg_type_t rt_type; uint8_t rt_shift; uint64_t rt_start; } mdb_range_tree_t; typedef struct mdb_metaslab_group { uint64_t mg_fragmentation; uint64_t mg_histogram[RANGE_TREE_HISTOGRAM_SIZE]; uintptr_t mg_vd; } mdb_metaslab_group_t; typedef struct mdb_metaslab { uint64_t ms_id; uint64_t ms_start; uint64_t ms_size; int64_t ms_deferspace; uint64_t ms_fragmentation; uint64_t ms_weight; uintptr_t ms_allocating[TXG_SIZE]; uintptr_t ms_checkpointing; uintptr_t ms_freeing; uintptr_t ms_freed; uintptr_t ms_allocatable; uintptr_t ms_unflushed_frees; uintptr_t ms_unflushed_allocs; uintptr_t ms_sm; } mdb_metaslab_t; typedef struct mdb_space_map_phys_t { int64_t smp_alloc; uint64_t smp_histogram[SPACE_MAP_HISTOGRAM_SIZE]; } mdb_space_map_phys_t; typedef struct mdb_space_map { uint64_t sm_size; uint8_t sm_shift; uintptr_t sm_phys; } mdb_space_map_t; typedef struct mdb_vdev { uint64_t vdev_id; uint64_t vdev_state; uintptr_t vdev_ops; struct { uint64_t vs_aux; uint64_t vs_ops[VS_ZIO_TYPES]; uint64_t vs_bytes[VS_ZIO_TYPES]; uint64_t vs_read_errors; uint64_t vs_write_errors; uint64_t vs_checksum_errors; } vdev_stat; uintptr_t vdev_child; uint64_t vdev_children; uint64_t vdev_ms_count; uintptr_t vdev_mg; uintptr_t vdev_ms; uintptr_t vdev_path; } mdb_vdev_t; typedef struct mdb_vdev_ops { char vdev_op_type[16]; } mdb_vdev_ops_t; static int metaslab_stats(mdb_vdev_t *vd, int spa_flags) { mdb_inc_indent(4); mdb_printf("%%-?s %6s %20s %10s %10s %10s%\n", "ADDR", "ID", "OFFSET", "FREE", "FRAG", "UCMU"); uintptr_t *vdev_ms = mdb_alloc(vd->vdev_ms_count * sizeof (vdev_ms), UM_SLEEP | UM_GC); if (mdb_vread(vdev_ms, vd->vdev_ms_count * sizeof (uintptr_t), vd->vdev_ms) == -1) { mdb_warn("failed to read vdev_ms at %p\n", vd->vdev_ms); return (DCMD_ERR); } for (int m = 0; m < vd->vdev_ms_count; m++) { mdb_metaslab_t ms; mdb_space_map_t sm = { 0 }; mdb_space_map_phys_t smp = { 0 }; mdb_range_tree_t rt; uint64_t uallocs, ufrees, raw_free, raw_uchanges_mem; char free[MDB_NICENUM_BUFLEN]; char uchanges_mem[MDB_NICENUM_BUFLEN]; if (mdb_ctf_vread(&ms, "metaslab_t", "mdb_metaslab_t", vdev_ms[m], 0) == -1) return (DCMD_ERR); if (ms.ms_sm != 0 && mdb_ctf_vread(&sm, "space_map_t", "mdb_space_map_t", ms.ms_sm, 0) == -1) return (DCMD_ERR); if (mdb_ctf_vread(&rt, "range_tree_t", "mdb_range_tree_t", ms.ms_unflushed_frees, 0) == -1) return (DCMD_ERR); ufrees = rt.rt_space; raw_uchanges_mem = rt.rt_root.bt_num_nodes * BTREE_LEAF_SIZE; if (mdb_ctf_vread(&rt, "range_tree_t", "mdb_range_tree_t", ms.ms_unflushed_allocs, 0) == -1) return (DCMD_ERR); uallocs = rt.rt_space; raw_uchanges_mem += rt.rt_root.bt_num_nodes * BTREE_LEAF_SIZE; mdb_nicenum(raw_uchanges_mem, uchanges_mem); raw_free = ms.ms_size; if (ms.ms_sm != 0 && sm.sm_phys != 0) { (void) mdb_ctf_vread(&smp, "space_map_phys_t", "mdb_space_map_phys_t", sm.sm_phys, 0); raw_free -= smp.smp_alloc; } raw_free += ufrees - uallocs; mdb_nicenum(raw_free, free); mdb_printf("%0?p %6llu %20llx %10s ", vdev_ms[m], ms.ms_id, ms.ms_start, free); if (ms.ms_fragmentation == ZFS_FRAG_INVALID) mdb_printf("%9s ", "-"); else mdb_printf("%9llu%% ", ms.ms_fragmentation); mdb_printf("%10s\n", uchanges_mem); if ((spa_flags & SPA_FLAG_HISTOGRAMS) && ms.ms_sm != 0 && sm.sm_phys != 0) { dump_histogram(smp.smp_histogram, SPACE_MAP_HISTOGRAM_SIZE, sm.sm_shift); } } mdb_dec_indent(4); return (DCMD_OK); } static int metaslab_group_stats(mdb_vdev_t *vd, int spa_flags) { mdb_metaslab_group_t mg; if (mdb_ctf_vread(&mg, "metaslab_group_t", "mdb_metaslab_group_t", vd->vdev_mg, 0) == -1) { mdb_warn("failed to read vdev_mg at %p\n", vd->vdev_mg); return (DCMD_ERR); } mdb_inc_indent(4); mdb_printf("%%-?s %7s %9s%\n", "ADDR", "FRAG", "UCMU"); if (mg.mg_fragmentation == ZFS_FRAG_INVALID) mdb_printf("%0?p %6s\n", vd->vdev_mg, "-"); else mdb_printf("%0?p %6llu%%", vd->vdev_mg, mg.mg_fragmentation); uintptr_t *vdev_ms = mdb_alloc(vd->vdev_ms_count * sizeof (vdev_ms), UM_SLEEP | UM_GC); if (mdb_vread(vdev_ms, vd->vdev_ms_count * sizeof (uintptr_t), vd->vdev_ms) == -1) { mdb_warn("failed to read vdev_ms at %p\n", vd->vdev_ms); return (DCMD_ERR); } uint64_t raw_uchanges_mem = 0; char uchanges_mem[MDB_NICENUM_BUFLEN]; for (int m = 0; m < vd->vdev_ms_count; m++) { mdb_metaslab_t ms; mdb_range_tree_t rt; if (mdb_ctf_vread(&ms, "metaslab_t", "mdb_metaslab_t", vdev_ms[m], 0) == -1) return (DCMD_ERR); if (mdb_ctf_vread(&rt, "range_tree_t", "mdb_range_tree_t", ms.ms_unflushed_frees, 0) == -1) return (DCMD_ERR); raw_uchanges_mem += rt.rt_root.bt_num_nodes * BTREE_LEAF_SIZE; if (mdb_ctf_vread(&rt, "range_tree_t", "mdb_range_tree_t", ms.ms_unflushed_allocs, 0) == -1) return (DCMD_ERR); raw_uchanges_mem += rt.rt_root.bt_num_nodes * BTREE_LEAF_SIZE; } mdb_nicenum(raw_uchanges_mem, uchanges_mem); mdb_printf("%10s\n", uchanges_mem); if (spa_flags & SPA_FLAG_HISTOGRAMS) dump_histogram(mg.mg_histogram, RANGE_TREE_HISTOGRAM_SIZE, 0); mdb_dec_indent(4); return (DCMD_OK); } /* * ::vdev * * Print out a summarized vdev_t, in the following form: * * ADDR STATE AUX DESC * fffffffbcde23df0 HEALTHY - /dev/dsk/c0t0d0 * * If '-r' is specified, recursively visit all children. * * With '-e', the statistics associated with the vdev are printed as well. */ static int do_print_vdev(uintptr_t addr, int flags, int depth, boolean_t recursive, int spa_flags) { mdb_vdev_t vd; if (mdb_ctf_vread(&vd, "vdev_t", "mdb_vdev_t", (uintptr_t)addr, 0) == -1) return (DCMD_ERR); if (flags & DCMD_PIPE_OUT) { mdb_printf("%#lr\n", addr); } else { char desc[MAXNAMELEN]; if (vd.vdev_path != 0) { if (mdb_readstr(desc, sizeof (desc), (uintptr_t)vd.vdev_path) == -1) { mdb_warn("failed to read vdev_path at %p\n", vd.vdev_path); return (DCMD_ERR); } } else if (vd.vdev_ops != 0) { vdev_ops_t ops; if (mdb_vread(&ops, sizeof (ops), (uintptr_t)vd.vdev_ops) == -1) { mdb_warn("failed to read vdev_ops at %p\n", vd.vdev_ops); return (DCMD_ERR); } (void) strcpy(desc, ops.vdev_op_type); } else { (void) strcpy(desc, ""); } if (depth == 0 && DCMD_HDRSPEC(flags)) mdb_printf("%%-?s %-9s %-12s %-*s%\n", "ADDR", "STATE", "AUX", sizeof (uintptr_t) == 4 ? 43 : 35, "DESCRIPTION"); mdb_printf("%0?p ", addr); const char *state, *aux; switch (vd.vdev_state) { case VDEV_STATE_CLOSED: state = "CLOSED"; break; case VDEV_STATE_OFFLINE: state = "OFFLINE"; break; case VDEV_STATE_CANT_OPEN: state = "CANT_OPEN"; break; case VDEV_STATE_DEGRADED: state = "DEGRADED"; break; case VDEV_STATE_HEALTHY: state = "HEALTHY"; break; case VDEV_STATE_REMOVED: state = "REMOVED"; break; case VDEV_STATE_FAULTED: state = "FAULTED"; break; default: state = "UNKNOWN"; break; } switch (vd.vdev_stat.vs_aux) { case VDEV_AUX_NONE: aux = "-"; break; case VDEV_AUX_OPEN_FAILED: aux = "OPEN_FAILED"; break; case VDEV_AUX_CORRUPT_DATA: aux = "CORRUPT_DATA"; break; case VDEV_AUX_NO_REPLICAS: aux = "NO_REPLICAS"; break; case VDEV_AUX_BAD_GUID_SUM: aux = "BAD_GUID_SUM"; break; case VDEV_AUX_TOO_SMALL: aux = "TOO_SMALL"; break; case VDEV_AUX_BAD_LABEL: aux = "BAD_LABEL"; break; case VDEV_AUX_VERSION_NEWER: aux = "VERS_NEWER"; break; case VDEV_AUX_VERSION_OLDER: aux = "VERS_OLDER"; break; case VDEV_AUX_UNSUP_FEAT: aux = "UNSUP_FEAT"; break; case VDEV_AUX_SPARED: aux = "SPARED"; break; case VDEV_AUX_ERR_EXCEEDED: aux = "ERR_EXCEEDED"; break; case VDEV_AUX_IO_FAILURE: aux = "IO_FAILURE"; break; case VDEV_AUX_BAD_LOG: aux = "BAD_LOG"; break; case VDEV_AUX_EXTERNAL: aux = "EXTERNAL"; break; case VDEV_AUX_SPLIT_POOL: aux = "SPLIT_POOL"; break; case VDEV_AUX_CHILDREN_OFFLINE: aux = "CHILDREN_OFFLINE"; break; default: aux = "UNKNOWN"; break; } mdb_printf("%-9s %-12s %*s%s\n", state, aux, depth, "", desc); if (spa_flags & SPA_FLAG_ERRORS) { int i; mdb_inc_indent(4); mdb_printf("\n"); mdb_printf("% %12s %12s %12s %12s " "%12s%\n", "READ", "WRITE", "FREE", "CLAIM", "IOCTL"); mdb_printf("OPS "); for (i = 1; i < VS_ZIO_TYPES; i++) mdb_printf("%11#llx%s", vd.vdev_stat.vs_ops[i], i == VS_ZIO_TYPES - 1 ? "" : " "); mdb_printf("\n"); mdb_printf("BYTES "); for (i = 1; i < VS_ZIO_TYPES; i++) mdb_printf("%11#llx%s", vd.vdev_stat.vs_bytes[i], i == VS_ZIO_TYPES - 1 ? "" : " "); mdb_printf("\n"); mdb_printf("EREAD %10#llx\n", vd.vdev_stat.vs_read_errors); mdb_printf("EWRITE %10#llx\n", vd.vdev_stat.vs_write_errors); mdb_printf("ECKSUM %10#llx\n", vd.vdev_stat.vs_checksum_errors); mdb_dec_indent(4); mdb_printf("\n"); } if ((spa_flags & SPA_FLAG_METASLAB_GROUPS) && vd.vdev_mg != 0) { metaslab_group_stats(&vd, spa_flags); } if ((spa_flags & SPA_FLAG_METASLABS) && vd.vdev_ms != 0) { metaslab_stats(&vd, spa_flags); } } uint64_t children = vd.vdev_children; if (children == 0 || !recursive) return (DCMD_OK); uintptr_t *child = mdb_alloc(children * sizeof (child), UM_SLEEP | UM_GC); if (mdb_vread(child, children * sizeof (void *), vd.vdev_child) == -1) { mdb_warn("failed to read vdev children at %p", vd.vdev_child); return (DCMD_ERR); } for (uint64_t c = 0; c < children; c++) { if (do_print_vdev(child[c], flags, depth + 2, recursive, spa_flags)) { return (DCMD_ERR); } } return (DCMD_OK); } static int vdev_print(uintptr_t addr, uint_t flags, int argc, const mdb_arg_t *argv) { uint64_t depth = 0; boolean_t recursive = B_FALSE; int spa_flags = 0; if (mdb_getopts(argc, argv, 'e', MDB_OPT_SETBITS, SPA_FLAG_ERRORS, &spa_flags, 'm', MDB_OPT_SETBITS, SPA_FLAG_METASLABS, &spa_flags, 'M', MDB_OPT_SETBITS, SPA_FLAG_METASLAB_GROUPS, &spa_flags, 'h', MDB_OPT_SETBITS, SPA_FLAG_HISTOGRAMS, &spa_flags, 'r', MDB_OPT_SETBITS, TRUE, &recursive, 'd', MDB_OPT_UINT64, &depth, NULL) != argc) return (DCMD_USAGE); if (!(flags & DCMD_ADDRSPEC)) { mdb_warn("no vdev_t address given\n"); return (DCMD_ERR); } return (do_print_vdev(addr, flags, (int)depth, recursive, spa_flags)); } typedef struct mdb_metaslab_alloc_trace { uintptr_t mat_mg; uintptr_t mat_msp; uint64_t mat_size; uint64_t mat_weight; uint64_t mat_offset; uint32_t mat_dva_id; int mat_allocator; } mdb_metaslab_alloc_trace_t; static void metaslab_print_weight(uint64_t weight) { char buf[100]; if (WEIGHT_IS_SPACEBASED(weight)) { mdb_nicenum( weight & ~(METASLAB_ACTIVE_MASK | METASLAB_WEIGHT_TYPE), buf); } else { char size[MDB_NICENUM_BUFLEN]; mdb_nicenum(1ULL << WEIGHT_GET_INDEX(weight), size); (void) mdb_snprintf(buf, sizeof (buf), "%llu x %s", WEIGHT_GET_COUNT(weight), size); } mdb_printf("%11s ", buf); } /* ARGSUSED */ static int metaslab_weight(uintptr_t addr, uint_t flags, int argc, const mdb_arg_t *argv) { uint64_t weight = 0; char active; if (argc == 0 && (flags & DCMD_ADDRSPEC)) { if (mdb_vread(&weight, sizeof (uint64_t), addr) == -1) { mdb_warn("failed to read weight at %p\n", addr); return (DCMD_ERR); } } else if (argc == 1 && !(flags & DCMD_ADDRSPEC)) { weight = (argv[0].a_type == MDB_TYPE_IMMEDIATE) ? argv[0].a_un.a_val : mdb_strtoull(argv[0].a_un.a_str); } else { return (DCMD_USAGE); } if (DCMD_HDRSPEC(flags)) { mdb_printf("%%-6s %9s %9s%\n", "ACTIVE", "ALGORITHM", "WEIGHT"); } if (weight & METASLAB_WEIGHT_PRIMARY) active = 'P'; else if (weight & METASLAB_WEIGHT_SECONDARY) active = 'S'; else active = '-'; mdb_printf("%6c %8s ", active, WEIGHT_IS_SPACEBASED(weight) ? "SPACE" : "SEGMENT"); metaslab_print_weight(weight); mdb_printf("\n"); return (DCMD_OK); } /* ARGSUSED */ static int metaslab_trace(uintptr_t addr, uint_t flags, int argc, const mdb_arg_t *argv) { mdb_metaslab_alloc_trace_t mat; mdb_metaslab_group_t mg = { 0 }; char result_type[100]; if (mdb_ctf_vread(&mat, "metaslab_alloc_trace_t", "mdb_metaslab_alloc_trace_t", addr, 0) == -1) { return (DCMD_ERR); } if (!(flags & DCMD_PIPE_OUT) && DCMD_HDRSPEC(flags)) { mdb_printf("%%6s %6s %8s %11s %11s %18s %18s%\n", "MSID", "DVA", "ASIZE", "ALLOCATOR", "WEIGHT", "RESULT", "VDEV"); } if (mat.mat_msp != 0) { mdb_metaslab_t ms; if (mdb_ctf_vread(&ms, "metaslab_t", "mdb_metaslab_t", mat.mat_msp, 0) == -1) { return (DCMD_ERR); } mdb_printf("%6llu ", ms.ms_id); } else { mdb_printf("%6s ", "-"); } mdb_printf("%6d %8llx %11llx ", mat.mat_dva_id, mat.mat_size, mat.mat_allocator); metaslab_print_weight(mat.mat_weight); if ((int64_t)mat.mat_offset < 0) { if (enum_lookup("enum trace_alloc_type", mat.mat_offset, "TRACE_", sizeof (result_type), result_type) == -1) { mdb_warn("Could not find enum for trace_alloc_type"); return (DCMD_ERR); } mdb_printf("%18s ", result_type); } else { mdb_printf("%%18llx% ", mat.mat_offset); } if (mat.mat_mg != 0 && mdb_ctf_vread(&mg, "metaslab_group_t", "mdb_metaslab_group_t", mat.mat_mg, 0) == -1) { return (DCMD_ERR); } if (mg.mg_vd != 0) { mdb_vdev_t vdev; char desc[MAXNAMELEN]; if (mdb_ctf_vread(&vdev, "vdev_t", "mdb_vdev_t", mg.mg_vd, 0) == -1) { return (DCMD_ERR); } if (vdev.vdev_path != 0) { char path[MAXNAMELEN]; if (mdb_readstr(path, sizeof (path), vdev.vdev_path) == -1) { mdb_warn("failed to read vdev_path at %p\n", vdev.vdev_path); return (DCMD_ERR); } char *slash; if ((slash = strrchr(path, '/')) != NULL) { strcpy(desc, slash + 1); } else { strcpy(desc, path); } } else if (vdev.vdev_ops != 0) { mdb_vdev_ops_t ops; if (mdb_ctf_vread(&ops, "vdev_ops_t", "mdb_vdev_ops_t", vdev.vdev_ops, 0) == -1) { mdb_warn("failed to read vdev_ops at %p\n", vdev.vdev_ops); return (DCMD_ERR); } (void) mdb_snprintf(desc, sizeof (desc), "%s-%llu", ops.vdev_op_type, vdev.vdev_id); } else { (void) strcpy(desc, ""); } mdb_printf("%18s\n", desc); } return (DCMD_OK); } typedef struct metaslab_walk_data { uint64_t mw_numvdevs; uintptr_t *mw_vdevs; int mw_curvdev; uint64_t mw_nummss; uintptr_t *mw_mss; int mw_curms; } metaslab_walk_data_t; static int metaslab_walk_step(mdb_walk_state_t *wsp) { metaslab_walk_data_t *mw = wsp->walk_data; metaslab_t ms; uintptr_t msp; if (mw->mw_curvdev >= mw->mw_numvdevs) return (WALK_DONE); if (mw->mw_mss == NULL) { uintptr_t mssp; uintptr_t vdevp; ASSERT(mw->mw_curms == 0); ASSERT(mw->mw_nummss == 0); vdevp = mw->mw_vdevs[mw->mw_curvdev]; if (GETMEMB(vdevp, "vdev", vdev_ms, mssp) || GETMEMB(vdevp, "vdev", vdev_ms_count, mw->mw_nummss)) { return (WALK_ERR); } mw->mw_mss = mdb_alloc(mw->mw_nummss * sizeof (void*), UM_SLEEP | UM_GC); if (mdb_vread(mw->mw_mss, mw->mw_nummss * sizeof (void*), mssp) == -1) { mdb_warn("failed to read vdev_ms at %p", mssp); return (WALK_ERR); } } if (mw->mw_curms >= mw->mw_nummss) { mw->mw_mss = NULL; mw->mw_curms = 0; mw->mw_nummss = 0; mw->mw_curvdev++; return (WALK_NEXT); } msp = mw->mw_mss[mw->mw_curms]; if (mdb_vread(&ms, sizeof (metaslab_t), msp) == -1) { mdb_warn("failed to read metaslab_t at %p", msp); return (WALK_ERR); } mw->mw_curms++; return (wsp->walk_callback(msp, &ms, wsp->walk_cbdata)); } static int metaslab_walk_init(mdb_walk_state_t *wsp) { metaslab_walk_data_t *mw; uintptr_t root_vdevp; uintptr_t childp; if (wsp->walk_addr == 0) { mdb_warn("must supply address of spa_t\n"); return (WALK_ERR); } mw = mdb_zalloc(sizeof (metaslab_walk_data_t), UM_SLEEP | UM_GC); if (GETMEMB(wsp->walk_addr, "spa", spa_root_vdev, root_vdevp) || GETMEMB(root_vdevp, "vdev", vdev_children, mw->mw_numvdevs) || GETMEMB(root_vdevp, "vdev", vdev_child, childp)) { return (DCMD_ERR); } mw->mw_vdevs = mdb_alloc(mw->mw_numvdevs * sizeof (void *), UM_SLEEP | UM_GC); if (mdb_vread(mw->mw_vdevs, mw->mw_numvdevs * sizeof (void *), childp) == -1) { mdb_warn("failed to read root vdev children at %p", childp); return (DCMD_ERR); } wsp->walk_data = mw; return (WALK_NEXT); } typedef struct mdb_spa { uintptr_t spa_dsl_pool; uintptr_t spa_root_vdev; } mdb_spa_t; typedef struct mdb_dsl_pool { uintptr_t dp_root_dir; } mdb_dsl_pool_t; typedef struct mdb_dsl_dir { uintptr_t dd_dbuf; int64_t dd_space_towrite[TXG_SIZE]; } mdb_dsl_dir_t; typedef struct mdb_dsl_dir_phys { uint64_t dd_used_bytes; uint64_t dd_compressed_bytes; uint64_t dd_uncompressed_bytes; } mdb_dsl_dir_phys_t; typedef struct space_data { uint64_t ms_allocating[TXG_SIZE]; uint64_t ms_checkpointing; uint64_t ms_freeing; uint64_t ms_freed; uint64_t ms_unflushed_frees; uint64_t ms_unflushed_allocs; uint64_t ms_allocatable; int64_t ms_deferspace; uint64_t avail; } space_data_t; /* ARGSUSED */ static int space_cb(uintptr_t addr, const void *unknown, void *arg) { space_data_t *sd = arg; mdb_metaslab_t ms; mdb_range_tree_t rt; mdb_space_map_t sm = { 0 }; mdb_space_map_phys_t smp = { 0 }; uint64_t uallocs, ufrees; int i; if (mdb_ctf_vread(&ms, "metaslab_t", "mdb_metaslab_t", addr, 0) == -1) return (WALK_ERR); for (i = 0; i < TXG_SIZE; i++) { if (mdb_ctf_vread(&rt, "range_tree_t", "mdb_range_tree_t", ms.ms_allocating[i], 0) == -1) return (WALK_ERR); sd->ms_allocating[i] += rt.rt_space; } if (mdb_ctf_vread(&rt, "range_tree_t", "mdb_range_tree_t", ms.ms_checkpointing, 0) == -1) return (WALK_ERR); sd->ms_checkpointing += rt.rt_space; if (mdb_ctf_vread(&rt, "range_tree_t", "mdb_range_tree_t", ms.ms_freeing, 0) == -1) return (WALK_ERR); sd->ms_freeing += rt.rt_space; if (mdb_ctf_vread(&rt, "range_tree_t", "mdb_range_tree_t", ms.ms_freed, 0) == -1) return (WALK_ERR); sd->ms_freed += rt.rt_space; if (mdb_ctf_vread(&rt, "range_tree_t", "mdb_range_tree_t", ms.ms_allocatable, 0) == -1) return (WALK_ERR); sd->ms_allocatable += rt.rt_space; if (mdb_ctf_vread(&rt, "range_tree_t", "mdb_range_tree_t", ms.ms_unflushed_frees, 0) == -1) return (WALK_ERR); sd->ms_unflushed_frees += rt.rt_space; ufrees = rt.rt_space; if (mdb_ctf_vread(&rt, "range_tree_t", "mdb_range_tree_t", ms.ms_unflushed_allocs, 0) == -1) return (WALK_ERR); sd->ms_unflushed_allocs += rt.rt_space; uallocs = rt.rt_space; if (ms.ms_sm != 0 && mdb_ctf_vread(&sm, "space_map_t", "mdb_space_map_t", ms.ms_sm, 0) == -1) return (WALK_ERR); if (sm.sm_phys != 0) { (void) mdb_ctf_vread(&smp, "space_map_phys_t", "mdb_space_map_phys_t", sm.sm_phys, 0); } sd->ms_deferspace += ms.ms_deferspace; sd->avail += sm.sm_size - smp.smp_alloc + ufrees - uallocs; return (WALK_NEXT); } /* * ::spa_space [-b] * * Given a spa_t, print out it's on-disk space usage and in-core * estimates of future usage. If -b is given, print space in bytes. * Otherwise print in megabytes. */ /* ARGSUSED */ static int spa_space(uintptr_t addr, uint_t flags, int argc, const mdb_arg_t *argv) { mdb_spa_t spa; mdb_dsl_pool_t dp; mdb_dsl_dir_t dd; mdb_dmu_buf_impl_t db; mdb_dsl_dir_phys_t dsp; space_data_t sd; int shift = 20; char *suffix = "M"; int bytes = B_FALSE; if (mdb_getopts(argc, argv, 'b', MDB_OPT_SETBITS, TRUE, &bytes, NULL) != argc) return (DCMD_USAGE); if (!(flags & DCMD_ADDRSPEC)) return (DCMD_USAGE); if (bytes) { shift = 0; suffix = ""; } if (mdb_ctf_vread(&spa, ZFS_STRUCT "spa", "mdb_spa_t", addr, 0) == -1 || mdb_ctf_vread(&dp, ZFS_STRUCT "dsl_pool", "mdb_dsl_pool_t", spa.spa_dsl_pool, 0) == -1 || mdb_ctf_vread(&dd, ZFS_STRUCT "dsl_dir", "mdb_dsl_dir_t", dp.dp_root_dir, 0) == -1 || mdb_ctf_vread(&db, ZFS_STRUCT "dmu_buf_impl", "mdb_dmu_buf_impl_t", dd.dd_dbuf, 0) == -1 || mdb_ctf_vread(&dsp, ZFS_STRUCT "dsl_dir_phys", "mdb_dsl_dir_phys_t", db.db.db_data, 0) == -1) { return (DCMD_ERR); } mdb_printf("dd_space_towrite = %llu%s %llu%s %llu%s %llu%s\n", dd.dd_space_towrite[0] >> shift, suffix, dd.dd_space_towrite[1] >> shift, suffix, dd.dd_space_towrite[2] >> shift, suffix, dd.dd_space_towrite[3] >> shift, suffix); mdb_printf("dd_phys.dd_used_bytes = %llu%s\n", dsp.dd_used_bytes >> shift, suffix); mdb_printf("dd_phys.dd_compressed_bytes = %llu%s\n", dsp.dd_compressed_bytes >> shift, suffix); mdb_printf("dd_phys.dd_uncompressed_bytes = %llu%s\n", dsp.dd_uncompressed_bytes >> shift, suffix); bzero(&sd, sizeof (sd)); if (mdb_pwalk("metaslab", space_cb, &sd, addr) != 0) { mdb_warn("can't walk metaslabs"); return (DCMD_ERR); } mdb_printf("ms_allocmap = %llu%s %llu%s %llu%s %llu%s\n", sd.ms_allocating[0] >> shift, suffix, sd.ms_allocating[1] >> shift, suffix, sd.ms_allocating[2] >> shift, suffix, sd.ms_allocating[3] >> shift, suffix); mdb_printf("ms_checkpointing = %llu%s\n", sd.ms_checkpointing >> shift, suffix); mdb_printf("ms_freeing = %llu%s\n", sd.ms_freeing >> shift, suffix); mdb_printf("ms_freed = %llu%s\n", sd.ms_freed >> shift, suffix); mdb_printf("ms_unflushed_frees = %llu%s\n", sd.ms_unflushed_frees >> shift, suffix); mdb_printf("ms_unflushed_allocs = %llu%s\n", sd.ms_unflushed_allocs >> shift, suffix); mdb_printf("ms_allocatable = %llu%s\n", sd.ms_allocatable >> shift, suffix); mdb_printf("ms_deferspace = %llu%s\n", sd.ms_deferspace >> shift, suffix); mdb_printf("current avail = %llu%s\n", sd.avail >> shift, suffix); return (DCMD_OK); } typedef struct mdb_spa_aux_vdev { int sav_count; uintptr_t sav_vdevs; } mdb_spa_aux_vdev_t; typedef struct mdb_spa_vdevs { uintptr_t spa_root_vdev; mdb_spa_aux_vdev_t spa_l2cache; mdb_spa_aux_vdev_t spa_spares; } mdb_spa_vdevs_t; static int spa_print_aux(mdb_spa_aux_vdev_t *sav, uint_t flags, mdb_arg_t *v, const char *name) { uintptr_t *aux; size_t len; int ret, i; /* * Iterate over aux vdevs and print those out as well. This is a * little annoying because we don't have a root vdev to pass to ::vdev. * Instead, we print a single line and then call it for each child * vdev. */ if (sav->sav_count != 0) { v[1].a_type = MDB_TYPE_STRING; v[1].a_un.a_str = "-d"; v[2].a_type = MDB_TYPE_IMMEDIATE; v[2].a_un.a_val = 2; len = sav->sav_count * sizeof (uintptr_t); aux = mdb_alloc(len, UM_SLEEP); if (mdb_vread(aux, len, sav->sav_vdevs) == -1) { mdb_free(aux, len); mdb_warn("failed to read l2cache vdevs at %p", sav->sav_vdevs); return (DCMD_ERR); } mdb_printf("%-?s %-9s %-12s %s\n", "-", "-", "-", name); for (i = 0; i < sav->sav_count; i++) { ret = mdb_call_dcmd("vdev", aux[i], flags, 3, v); if (ret != DCMD_OK) { mdb_free(aux, len); return (ret); } } mdb_free(aux, len); } return (0); } /* * ::spa_vdevs * * -e Include error stats * -m Include metaslab information * -M Include metaslab group information * -h Include histogram information (requires -m or -M) * * Print out a summarized list of vdevs for the given spa_t. * This is accomplished by invoking "::vdev -re" on the root vdev, as well as * iterating over the cache devices. */ /* ARGSUSED */ static int spa_vdevs(uintptr_t addr, uint_t flags, int argc, const mdb_arg_t *argv) { mdb_arg_t v[3]; int ret; char opts[100] = "-r"; int spa_flags = 0; if (mdb_getopts(argc, argv, 'e', MDB_OPT_SETBITS, SPA_FLAG_ERRORS, &spa_flags, 'm', MDB_OPT_SETBITS, SPA_FLAG_METASLABS, &spa_flags, 'M', MDB_OPT_SETBITS, SPA_FLAG_METASLAB_GROUPS, &spa_flags, 'h', MDB_OPT_SETBITS, SPA_FLAG_HISTOGRAMS, &spa_flags, NULL) != argc) return (DCMD_USAGE); if (!(flags & DCMD_ADDRSPEC)) return (DCMD_USAGE); mdb_spa_vdevs_t spa; if (mdb_ctf_vread(&spa, "spa_t", "mdb_spa_vdevs_t", addr, 0) == -1) return (DCMD_ERR); /* * Unitialized spa_t structures can have a NULL root vdev. */ if (spa.spa_root_vdev == 0) { mdb_printf("no associated vdevs\n"); return (DCMD_OK); } if (spa_flags & SPA_FLAG_ERRORS) strcat(opts, "e"); if (spa_flags & SPA_FLAG_METASLABS) strcat(opts, "m"); if (spa_flags & SPA_FLAG_METASLAB_GROUPS) strcat(opts, "M"); if (spa_flags & SPA_FLAG_HISTOGRAMS) strcat(opts, "h"); v[0].a_type = MDB_TYPE_STRING; v[0].a_un.a_str = opts; ret = mdb_call_dcmd("vdev", (uintptr_t)spa.spa_root_vdev, flags, 1, v); if (ret != DCMD_OK) return (ret); if (spa_print_aux(&spa.spa_l2cache, flags, v, "cache") != 0 || spa_print_aux(&spa.spa_spares, flags, v, "spares") != 0) return (DCMD_ERR); return (DCMD_OK); } /* * ::zio * * Print a summary of zio_t and all its children. This is intended to display a * zio tree, and hence we only pick the most important pieces of information for * the main summary. More detailed information can always be found by doing a * '::print zio' on the underlying zio_t. The columns we display are: * * ADDRESS TYPE STAGE WAITER TIME_ELAPSED * * The 'address' column is indented by one space for each depth level as we * descend down the tree. */ #define ZIO_MAXINDENT 7 #define ZIO_MAXWIDTH (sizeof (uintptr_t) * 2 + ZIO_MAXINDENT) #define ZIO_WALK_SELF 0 #define ZIO_WALK_CHILD 1 #define ZIO_WALK_PARENT 2 typedef struct zio_print_args { int zpa_current_depth; int zpa_min_depth; int zpa_max_depth; int zpa_type; uint_t zpa_flags; } zio_print_args_t; typedef struct mdb_zio { enum zio_type io_type; enum zio_stage io_stage; uintptr_t io_waiter; uintptr_t io_spa; struct { struct { uintptr_t list_next; } list_head; } io_parent_list; int io_error; } mdb_zio_t; typedef struct mdb_zio_timestamp { hrtime_t io_timestamp; } mdb_zio_timestamp_t; static int zio_child_cb(uintptr_t addr, const void *unknown, void *arg); static int zio_print_cb(uintptr_t addr, zio_print_args_t *zpa) { mdb_ctf_id_t type_enum, stage_enum; int indent = zpa->zpa_current_depth; const char *type, *stage; uintptr_t laddr; mdb_zio_t zio; mdb_zio_timestamp_t zio_timestamp = { 0 }; if (mdb_ctf_vread(&zio, ZFS_STRUCT "zio", "mdb_zio_t", addr, 0) == -1) return (WALK_ERR); (void) mdb_ctf_vread(&zio_timestamp, ZFS_STRUCT "zio", "mdb_zio_timestamp_t", addr, MDB_CTF_VREAD_QUIET); if (indent > ZIO_MAXINDENT) indent = ZIO_MAXINDENT; if (mdb_ctf_lookup_by_name("enum zio_type", &type_enum) == -1 || mdb_ctf_lookup_by_name("enum zio_stage", &stage_enum) == -1) { mdb_warn("failed to lookup zio enums"); return (WALK_ERR); } if ((type = mdb_ctf_enum_name(type_enum, zio.io_type)) != NULL) type += sizeof ("ZIO_TYPE_") - 1; else type = "?"; if (zio.io_error == 0) { stage = mdb_ctf_enum_name(stage_enum, zio.io_stage); if (stage != NULL) stage += sizeof ("ZIO_STAGE_") - 1; else stage = "?"; } else { stage = "FAILED"; } if (zpa->zpa_current_depth >= zpa->zpa_min_depth) { if (zpa->zpa_flags & DCMD_PIPE_OUT) { mdb_printf("%?p\n", addr); } else { mdb_printf("%*s%-*p %-5s %-16s ", indent, "", ZIO_MAXWIDTH - indent, addr, type, stage); if (zio.io_waiter != 0) mdb_printf("%-16lx ", zio.io_waiter); else mdb_printf("%-16s ", "-"); #ifdef _KERNEL if (zio_timestamp.io_timestamp != 0) { mdb_printf("%llums", (mdb_gethrtime() - zio_timestamp.io_timestamp) / 1000000); } else { mdb_printf("%-12s ", "-"); } #else mdb_printf("%-12s ", "-"); #endif mdb_printf("\n"); } } if (zpa->zpa_current_depth >= zpa->zpa_max_depth) return (WALK_NEXT); if (zpa->zpa_type == ZIO_WALK_PARENT) laddr = addr + mdb_ctf_offsetof_by_name(ZFS_STRUCT "zio", "io_parent_list"); else laddr = addr + mdb_ctf_offsetof_by_name(ZFS_STRUCT "zio", "io_child_list"); zpa->zpa_current_depth++; if (mdb_pwalk("list", zio_child_cb, zpa, laddr) != 0) { mdb_warn("failed to walk zio_t children at %p\n", laddr); return (WALK_ERR); } zpa->zpa_current_depth--; return (WALK_NEXT); } /* ARGSUSED */ static int zio_child_cb(uintptr_t addr, const void *unknown, void *arg) { zio_link_t zl; uintptr_t ziop; zio_print_args_t *zpa = arg; if (mdb_vread(&zl, sizeof (zl), addr) == -1) { mdb_warn("failed to read zio_link_t at %p", addr); return (WALK_ERR); } if (zpa->zpa_type == ZIO_WALK_PARENT) ziop = (uintptr_t)zl.zl_parent; else ziop = (uintptr_t)zl.zl_child; return (zio_print_cb(ziop, zpa)); } /* ARGSUSED */ static int zio_print(uintptr_t addr, uint_t flags, int argc, const mdb_arg_t *argv) { zio_print_args_t zpa = { 0 }; if (!(flags & DCMD_ADDRSPEC)) return (DCMD_USAGE); if (mdb_getopts(argc, argv, 'r', MDB_OPT_SETBITS, INT_MAX, &zpa.zpa_max_depth, 'c', MDB_OPT_SETBITS, ZIO_WALK_CHILD, &zpa.zpa_type, 'p', MDB_OPT_SETBITS, ZIO_WALK_PARENT, &zpa.zpa_type, NULL) != argc) return (DCMD_USAGE); zpa.zpa_flags = flags; if (zpa.zpa_max_depth != 0) { if (zpa.zpa_type == ZIO_WALK_SELF) zpa.zpa_type = ZIO_WALK_CHILD; } else if (zpa.zpa_type != ZIO_WALK_SELF) { zpa.zpa_min_depth = 1; zpa.zpa_max_depth = 1; } if (!(flags & DCMD_PIPE_OUT) && DCMD_HDRSPEC(flags)) { mdb_printf("%%-*s %-5s %-16s %-16s %-12s%\n", ZIO_MAXWIDTH, "ADDRESS", "TYPE", "STAGE", "WAITER", "TIME_ELAPSED"); } if (zio_print_cb(addr, &zpa) != WALK_NEXT) return (DCMD_ERR); return (DCMD_OK); } /* * [addr]::zio_state * * Print a summary of all zio_t structures on the system, or for a particular * pool. This is equivalent to '::walk zio_root | ::zio'. */ /*ARGSUSED*/ static int zio_state(uintptr_t addr, uint_t flags, int argc, const mdb_arg_t *argv) { /* * MDB will remember the last address of the pipeline, so if we don't * zero this we'll end up trying to walk zio structures for a * non-existent spa_t. */ if (!(flags & DCMD_ADDRSPEC)) addr = 0; return (mdb_pwalk_dcmd("zio_root", "zio", argc, argv, addr)); } typedef struct mdb_zfs_btree_hdr { uintptr_t bth_parent; boolean_t bth_core; /* * For both leaf and core nodes, represents the number of elements in * the node. For core nodes, they will have bth_count + 1 children. */ uint32_t bth_count; } mdb_zfs_btree_hdr_t; typedef struct mdb_zfs_btree_core { mdb_zfs_btree_hdr_t btc_hdr; uintptr_t btc_children[BTREE_CORE_ELEMS + 1]; uint8_t btc_elems[]; } mdb_zfs_btree_core_t; typedef struct mdb_zfs_btree_leaf { mdb_zfs_btree_hdr_t btl_hdr; uint8_t btl_elems[]; } mdb_zfs_btree_leaf_t; typedef struct mdb_zfs_btree { uintptr_t bt_root; size_t bt_elem_size; } mdb_zfs_btree_t; typedef struct btree_walk_data { mdb_zfs_btree_t bwd_btree; mdb_zfs_btree_hdr_t *bwd_node; uint64_t bwd_offset; // In units of bt_node_size } btree_walk_data_t; static uintptr_t btree_leftmost_child(uintptr_t addr, mdb_zfs_btree_hdr_t *buf) { size_t size = offsetof(zfs_btree_core_t, btc_children) + sizeof (uintptr_t); for (;;) { if (mdb_vread(buf, size, addr) == -1) { mdb_warn("failed to read at %p\n", addr); return ((uintptr_t)0ULL); } if (!buf->bth_core) return (addr); mdb_zfs_btree_core_t *node = (mdb_zfs_btree_core_t *)buf; addr = node->btc_children[0]; } } static int btree_walk_step(mdb_walk_state_t *wsp) { btree_walk_data_t *bwd = wsp->walk_data; size_t elem_size = bwd->bwd_btree.bt_elem_size; if (wsp->walk_addr == 0ULL) return (WALK_DONE); if (!bwd->bwd_node->bth_core) { /* * For the first element in a leaf node, read in the full * leaf, since we only had part of it read in before. */ if (bwd->bwd_offset == 0) { if (mdb_vread(bwd->bwd_node, BTREE_LEAF_SIZE, wsp->walk_addr) == -1) { mdb_warn("failed to read at %p\n", wsp->walk_addr); return (WALK_ERR); } } int status = wsp->walk_callback((uintptr_t)(wsp->walk_addr + offsetof(mdb_zfs_btree_leaf_t, btl_elems) + bwd->bwd_offset * elem_size), bwd->bwd_node, wsp->walk_cbdata); if (status != WALK_NEXT) return (status); bwd->bwd_offset++; /* Find the next element, if we're at the end of the leaf. */ while (bwd->bwd_offset == bwd->bwd_node->bth_count) { uintptr_t par = bwd->bwd_node->bth_parent; uintptr_t cur = wsp->walk_addr; wsp->walk_addr = par; if (par == 0ULL) return (WALK_NEXT); size_t size = sizeof (zfs_btree_core_t) + BTREE_CORE_ELEMS * elem_size; if (mdb_vread(bwd->bwd_node, size, wsp->walk_addr) == -1) { mdb_warn("failed to read at %p\n", wsp->walk_addr); return (WALK_ERR); } mdb_zfs_btree_core_t *node = (mdb_zfs_btree_core_t *)bwd->bwd_node; int i; for (i = 0; i <= bwd->bwd_node->bth_count; i++) { if (node->btc_children[i] == cur) break; } if (i > bwd->bwd_node->bth_count) { mdb_warn("btree parent/child mismatch at " "%#lx\n", cur); return (WALK_ERR); } bwd->bwd_offset = i; } return (WALK_NEXT); } if (!bwd->bwd_node->bth_core) { mdb_warn("Invalid btree node at %#lx\n", wsp->walk_addr); return (WALK_ERR); } mdb_zfs_btree_core_t *node = (mdb_zfs_btree_core_t *)bwd->bwd_node; int status = wsp->walk_callback((uintptr_t)(wsp->walk_addr + offsetof(mdb_zfs_btree_core_t, btc_elems) + bwd->bwd_offset * elem_size), bwd->bwd_node, wsp->walk_cbdata); if (status != WALK_NEXT) return (status); uintptr_t new_child = node->btc_children[bwd->bwd_offset + 1]; wsp->walk_addr = btree_leftmost_child(new_child, bwd->bwd_node); if (wsp->walk_addr == 0ULL) return (WALK_ERR); bwd->bwd_offset = 0; return (WALK_NEXT); } static int btree_walk_init(mdb_walk_state_t *wsp) { btree_walk_data_t *bwd; if (wsp->walk_addr == 0ULL) { mdb_warn("must supply address of zfs_btree_t\n"); return (WALK_ERR); } bwd = mdb_zalloc(sizeof (btree_walk_data_t), UM_SLEEP); if (mdb_ctf_vread(&bwd->bwd_btree, "zfs_btree_t", "mdb_zfs_btree_t", wsp->walk_addr, 0) == -1) { mdb_free(bwd, sizeof (*bwd)); return (WALK_ERR); } if (bwd->bwd_btree.bt_elem_size == 0) { mdb_warn("invalid or uninitialized btree at %#lx\n", wsp->walk_addr); mdb_free(bwd, sizeof (*bwd)); return (WALK_ERR); } size_t size = MAX(BTREE_LEAF_SIZE, sizeof (zfs_btree_core_t) + BTREE_CORE_ELEMS * bwd->bwd_btree.bt_elem_size); bwd->bwd_node = mdb_zalloc(size, UM_SLEEP); uintptr_t node = (uintptr_t)bwd->bwd_btree.bt_root; if (node == 0ULL) { wsp->walk_addr = 0ULL; wsp->walk_data = bwd; return (WALK_NEXT); } node = btree_leftmost_child(node, bwd->bwd_node); if (node == 0ULL) { mdb_free(bwd->bwd_node, size); mdb_free(bwd, sizeof (*bwd)); return (WALK_ERR); } bwd->bwd_offset = 0; wsp->walk_addr = node; wsp->walk_data = bwd; return (WALK_NEXT); } static void btree_walk_fini(mdb_walk_state_t *wsp) { btree_walk_data_t *bwd = (btree_walk_data_t *)wsp->walk_data; if (bwd == NULL) return; size_t size = MAX(BTREE_LEAF_SIZE, sizeof (zfs_btree_core_t) + BTREE_CORE_ELEMS * bwd->bwd_btree.bt_elem_size); if (bwd->bwd_node != NULL) mdb_free(bwd->bwd_node, size); mdb_free(bwd, sizeof (*bwd)); } typedef struct mdb_multilist { uint64_t ml_num_sublists; uintptr_t ml_sublists; } mdb_multilist_t; static int multilist_walk_step(mdb_walk_state_t *wsp) { return (wsp->walk_callback(wsp->walk_addr, wsp->walk_layer, wsp->walk_cbdata)); } static int multilist_walk_init(mdb_walk_state_t *wsp) { mdb_multilist_t ml; ssize_t sublist_sz; int list_offset; size_t i; if (wsp->walk_addr == 0) { mdb_warn("must supply address of multilist_t\n"); return (WALK_ERR); } if (mdb_ctf_vread(&ml, "multilist_t", "mdb_multilist_t", wsp->walk_addr, 0) == -1) { return (WALK_ERR); } if (ml.ml_num_sublists == 0 || ml.ml_sublists == 0) { mdb_warn("invalid or uninitialized multilist at %#lx\n", wsp->walk_addr); return (WALK_ERR); } /* mdb_ctf_sizeof_by_name() will print an error for us */ sublist_sz = mdb_ctf_sizeof_by_name("multilist_sublist_t"); if (sublist_sz == -1) return (WALK_ERR); /* mdb_ctf_offsetof_by_name will print an error for us */ list_offset = mdb_ctf_offsetof_by_name("multilist_sublist_t", "mls_list"); if (list_offset == -1) return (WALK_ERR); for (i = 0; i < ml.ml_num_sublists; i++) { wsp->walk_addr = ml.ml_sublists + i * sublist_sz + list_offset; if (mdb_layered_walk("list", wsp) == -1) { mdb_warn("can't walk multilist sublist"); return (WALK_ERR); } } return (WALK_NEXT); } typedef struct mdb_txg_list { size_t tl_offset; uintptr_t tl_head[TXG_SIZE]; } mdb_txg_list_t; typedef struct txg_list_walk_data { uintptr_t lw_head[TXG_SIZE]; int lw_txgoff; int lw_maxoff; size_t lw_offset; void *lw_obj; } txg_list_walk_data_t; static int txg_list_walk_init_common(mdb_walk_state_t *wsp, int txg, int maxoff) { txg_list_walk_data_t *lwd; mdb_txg_list_t list; int i; lwd = mdb_alloc(sizeof (txg_list_walk_data_t), UM_SLEEP | UM_GC); if (mdb_ctf_vread(&list, "txg_list_t", "mdb_txg_list_t", wsp->walk_addr, 0) == -1) { mdb_warn("failed to read txg_list_t at %#lx", wsp->walk_addr); return (WALK_ERR); } for (i = 0; i < TXG_SIZE; i++) lwd->lw_head[i] = list.tl_head[i]; lwd->lw_offset = list.tl_offset; lwd->lw_obj = mdb_alloc(lwd->lw_offset + sizeof (txg_node_t), UM_SLEEP | UM_GC); lwd->lw_txgoff = txg; lwd->lw_maxoff = maxoff; wsp->walk_addr = lwd->lw_head[lwd->lw_txgoff]; wsp->walk_data = lwd; return (WALK_NEXT); } static int txg_list_walk_init(mdb_walk_state_t *wsp) { return (txg_list_walk_init_common(wsp, 0, TXG_SIZE-1)); } static int txg_list0_walk_init(mdb_walk_state_t *wsp) { return (txg_list_walk_init_common(wsp, 0, 0)); } static int txg_list1_walk_init(mdb_walk_state_t *wsp) { return (txg_list_walk_init_common(wsp, 1, 1)); } static int txg_list2_walk_init(mdb_walk_state_t *wsp) { return (txg_list_walk_init_common(wsp, 2, 2)); } static int txg_list3_walk_init(mdb_walk_state_t *wsp) { return (txg_list_walk_init_common(wsp, 3, 3)); } static int txg_list_walk_step(mdb_walk_state_t *wsp) { txg_list_walk_data_t *lwd = wsp->walk_data; uintptr_t addr; txg_node_t *node; int status; while (wsp->walk_addr == 0 && lwd->lw_txgoff < lwd->lw_maxoff) { lwd->lw_txgoff++; wsp->walk_addr = lwd->lw_head[lwd->lw_txgoff]; } if (wsp->walk_addr == 0) return (WALK_DONE); addr = wsp->walk_addr - lwd->lw_offset; if (mdb_vread(lwd->lw_obj, lwd->lw_offset + sizeof (txg_node_t), addr) == -1) { mdb_warn("failed to read list element at %#lx", addr); return (WALK_ERR); } status = wsp->walk_callback(addr, lwd->lw_obj, wsp->walk_cbdata); node = (txg_node_t *)((uintptr_t)lwd->lw_obj + lwd->lw_offset); wsp->walk_addr = (uintptr_t)node->tn_next[lwd->lw_txgoff]; return (status); } /* * ::walk spa * * Walk all named spa_t structures in the namespace. This is nothing more than * a layered avl walk. */ static int spa_walk_init(mdb_walk_state_t *wsp) { GElf_Sym sym; if (wsp->walk_addr != 0) { mdb_warn("spa walk only supports global walks\n"); return (WALK_ERR); } if (mdb_lookup_by_obj(ZFS_OBJ_NAME, "spa_namespace_avl", &sym) == -1) { mdb_warn("failed to find symbol 'spa_namespace_avl'"); return (WALK_ERR); } wsp->walk_addr = (uintptr_t)sym.st_value; if (mdb_layered_walk("avl", wsp) == -1) { mdb_warn("failed to walk 'avl'\n"); return (WALK_ERR); } return (WALK_NEXT); } static int spa_walk_step(mdb_walk_state_t *wsp) { return (wsp->walk_callback(wsp->walk_addr, NULL, wsp->walk_cbdata)); } /* * [addr]::walk zio * * Walk all active zio_t structures on the system. This is simply a layered * walk on top of ::walk zio_cache, with the optional ability to limit the * structures to a particular pool. */ static int zio_walk_init(mdb_walk_state_t *wsp) { wsp->walk_data = (void *)wsp->walk_addr; if (mdb_layered_walk("zio_cache", wsp) == -1) { mdb_warn("failed to walk 'zio_cache'\n"); return (WALK_ERR); } return (WALK_NEXT); } static int zio_walk_step(mdb_walk_state_t *wsp) { mdb_zio_t zio; uintptr_t spa = (uintptr_t)wsp->walk_data; if (mdb_ctf_vread(&zio, ZFS_STRUCT "zio", "mdb_zio_t", wsp->walk_addr, 0) == -1) return (WALK_ERR); if (spa != 0 && spa != zio.io_spa) return (WALK_NEXT); return (wsp->walk_callback(wsp->walk_addr, &zio, wsp->walk_cbdata)); } /* * [addr]::walk zio_root * * Walk only root zio_t structures, optionally for a particular spa_t. */ static int zio_walk_root_step(mdb_walk_state_t *wsp) { mdb_zio_t zio; uintptr_t spa = (uintptr_t)wsp->walk_data; if (mdb_ctf_vread(&zio, ZFS_STRUCT "zio", "mdb_zio_t", wsp->walk_addr, 0) == -1) return (WALK_ERR); if (spa != 0 && spa != zio.io_spa) return (WALK_NEXT); /* If the parent list is not empty, ignore */ if (zio.io_parent_list.list_head.list_next != wsp->walk_addr + mdb_ctf_offsetof_by_name(ZFS_STRUCT "zio", "io_parent_list") + mdb_ctf_offsetof_by_name("struct list", "list_head")) return (WALK_NEXT); return (wsp->walk_callback(wsp->walk_addr, &zio, wsp->walk_cbdata)); } /* * ::zfs_blkstats * * -v print verbose per-level information * */ static int zfs_blkstats(uintptr_t addr, uint_t flags, int argc, const mdb_arg_t *argv) { boolean_t verbose = B_FALSE; zfs_all_blkstats_t stats; dmu_object_type_t t; zfs_blkstat_t *tzb; uint64_t ditto; if (mdb_getopts(argc, argv, 'v', MDB_OPT_SETBITS, TRUE, &verbose, NULL) != argc) return (DCMD_USAGE); if (!(flags & DCMD_ADDRSPEC)) return (DCMD_USAGE); if (GETMEMB(addr, "spa", spa_dsl_pool, addr) || GETMEMB(addr, "dsl_pool", dp_blkstats, addr) || mdb_vread(&stats, sizeof (zfs_all_blkstats_t), addr) == -1) { mdb_warn("failed to read data at %p;", addr); mdb_printf("maybe no stats? run \"zpool scrub\" first."); return (DCMD_ERR); } tzb = &stats.zab_type[DN_MAX_LEVELS][DMU_OT_TOTAL]; if (tzb->zb_gangs != 0) { mdb_printf("Ganged blocks: %llu\n", (longlong_t)tzb->zb_gangs); } ditto = tzb->zb_ditto_2_of_2_samevdev + tzb->zb_ditto_2_of_3_samevdev + tzb->zb_ditto_3_of_3_samevdev; if (ditto != 0) { mdb_printf("Dittoed blocks on same vdev: %llu\n", (longlong_t)ditto); } mdb_printf("\nBlocks\tLSIZE\tPSIZE\tASIZE" "\t avg\t comp\t%%Total\tType\n"); for (t = 0; t <= DMU_OT_TOTAL; t++) { char csize[MDB_NICENUM_BUFLEN], lsize[MDB_NICENUM_BUFLEN]; char psize[MDB_NICENUM_BUFLEN], asize[MDB_NICENUM_BUFLEN]; char avg[MDB_NICENUM_BUFLEN]; char comp[MDB_NICENUM_BUFLEN], pct[MDB_NICENUM_BUFLEN]; char typename[64]; int l; if (t == DMU_OT_DEFERRED) strcpy(typename, "deferred free"); else if (t == DMU_OT_OTHER) strcpy(typename, "other"); else if (t == DMU_OT_TOTAL) strcpy(typename, "Total"); else if (enum_lookup("enum dmu_object_type", t, "DMU_OT_", sizeof (typename), typename) == -1) { mdb_warn("failed to read type name"); return (DCMD_ERR); } if (stats.zab_type[DN_MAX_LEVELS][t].zb_asize == 0) continue; for (l = -1; l < DN_MAX_LEVELS; l++) { int level = (l == -1 ? DN_MAX_LEVELS : l); zfs_blkstat_t *zb = &stats.zab_type[level][t]; if (zb->zb_asize == 0) continue; /* * Don't print each level unless requested. */ if (!verbose && level != DN_MAX_LEVELS) continue; /* * If all the space is level 0, don't print the * level 0 separately. */ if (level == 0 && zb->zb_asize == stats.zab_type[DN_MAX_LEVELS][t].zb_asize) continue; mdb_nicenum(zb->zb_count, csize); mdb_nicenum(zb->zb_lsize, lsize); mdb_nicenum(zb->zb_psize, psize); mdb_nicenum(zb->zb_asize, asize); mdb_nicenum(zb->zb_asize / zb->zb_count, avg); (void) mdb_snprintfrac(comp, MDB_NICENUM_BUFLEN, zb->zb_lsize, zb->zb_psize, 2); (void) mdb_snprintfrac(pct, MDB_NICENUM_BUFLEN, 100 * zb->zb_asize, tzb->zb_asize, 2); mdb_printf("%6s\t%5s\t%5s\t%5s\t%5s" "\t%5s\t%6s\t", csize, lsize, psize, asize, avg, comp, pct); if (level == DN_MAX_LEVELS) mdb_printf("%s\n", typename); else mdb_printf(" L%d %s\n", level, typename); } } return (DCMD_OK); } typedef struct mdb_reference { uintptr_t ref_holder; uintptr_t ref_removed; uint64_t ref_number; } mdb_reference_t; /* ARGSUSED */ static int reference_cb(uintptr_t addr, const void *ignored, void *arg) { mdb_reference_t ref; boolean_t holder_is_str = B_FALSE; char holder_str[128]; boolean_t removed = (boolean_t)arg; if (mdb_ctf_vread(&ref, "reference_t", "mdb_reference_t", addr, 0) == -1) return (DCMD_ERR); if (mdb_readstr(holder_str, sizeof (holder_str), ref.ref_holder) != -1) holder_is_str = strisprint(holder_str); if (removed) mdb_printf("removed "); mdb_printf("reference "); if (ref.ref_number != 1) mdb_printf("with count=%llu ", ref.ref_number); mdb_printf("with tag %lx", ref.ref_holder); if (holder_is_str) mdb_printf(" \"%s\"", holder_str); mdb_printf(", held at:\n"); (void) mdb_call_dcmd("whatis", addr, DCMD_ADDRSPEC, 0, NULL); if (removed) { mdb_printf("removed at:\n"); (void) mdb_call_dcmd("whatis", ref.ref_removed, DCMD_ADDRSPEC, 0, NULL); } mdb_printf("\n"); return (WALK_NEXT); } typedef struct mdb_zfs_refcount { uint64_t rc_count; } mdb_zfs_refcount_t; typedef struct mdb_zfs_refcount_removed { uint_t rc_removed_count; } mdb_zfs_refcount_removed_t; typedef struct mdb_zfs_refcount_tracked { boolean_t rc_tracked; } mdb_zfs_refcount_tracked_t; /* ARGSUSED */ static int zfs_refcount(uintptr_t addr, uint_t flags, int argc, const mdb_arg_t *argv) { mdb_zfs_refcount_t rc; mdb_zfs_refcount_removed_t rcr; mdb_zfs_refcount_tracked_t rct; int off; boolean_t released = B_FALSE; if (!(flags & DCMD_ADDRSPEC)) return (DCMD_USAGE); if (mdb_getopts(argc, argv, 'r', MDB_OPT_SETBITS, B_TRUE, &released, NULL) != argc) return (DCMD_USAGE); if (mdb_ctf_vread(&rc, "zfs_refcount_t", "mdb_zfs_refcount_t", addr, 0) == -1) return (DCMD_ERR); if (mdb_ctf_vread(&rcr, "zfs_refcount_t", "mdb_zfs_refcount_removed_t", addr, MDB_CTF_VREAD_QUIET) == -1) { mdb_printf("zfs_refcount_t at %p has %llu holds (untracked)\n", addr, (longlong_t)rc.rc_count); return (DCMD_OK); } if (mdb_ctf_vread(&rct, "zfs_refcount_t", "mdb_zfs_refcount_tracked_t", addr, MDB_CTF_VREAD_QUIET) == -1) { /* If this is an old target, it might be tracked. */ rct.rc_tracked = B_TRUE; } mdb_printf("zfs_refcount_t at %p has %llu current holds, " "%llu recently released holds\n", addr, (longlong_t)rc.rc_count, (longlong_t)rcr.rc_removed_count); if (rct.rc_tracked && rc.rc_count > 0) mdb_printf("current holds:\n"); off = mdb_ctf_offsetof_by_name("zfs_refcount_t", "rc_tree"); if (off == -1) return (DCMD_ERR); mdb_pwalk("avl", reference_cb, (void *)B_FALSE, addr + off); if (released && rcr.rc_removed_count > 0) { mdb_printf("released holds:\n"); off = mdb_ctf_offsetof_by_name("zfs_refcount_t", "rc_removed"); if (off == -1) return (DCMD_ERR); mdb_pwalk("list", reference_cb, (void *)B_TRUE, addr + off); } return (DCMD_OK); } /* ARGSUSED */ static int sa_attr_table(uintptr_t addr, uint_t flags, int argc, const mdb_arg_t *argv) { sa_attr_table_t *table; sa_os_t sa_os; char *name; int i; if (mdb_vread(&sa_os, sizeof (sa_os_t), addr) == -1) { mdb_warn("failed to read sa_os at %p", addr); return (DCMD_ERR); } table = mdb_alloc(sizeof (sa_attr_table_t) * sa_os.sa_num_attrs, UM_SLEEP | UM_GC); name = mdb_alloc(MAXPATHLEN, UM_SLEEP | UM_GC); if (mdb_vread(table, sizeof (sa_attr_table_t) * sa_os.sa_num_attrs, (uintptr_t)sa_os.sa_attr_table) == -1) { mdb_warn("failed to read sa_os at %p", addr); return (DCMD_ERR); } mdb_printf("%%-10s %-10s %-10s %-10s %s%\n", "ATTR ID", "REGISTERED", "LENGTH", "BSWAP", "NAME"); for (i = 0; i != sa_os.sa_num_attrs; i++) { mdb_readstr(name, MAXPATHLEN, (uintptr_t)table[i].sa_name); mdb_printf("%5x %8x %8x %8x %-s\n", (int)table[i].sa_attr, (int)table[i].sa_registered, (int)table[i].sa_length, table[i].sa_byteswap, name); } return (DCMD_OK); } static int sa_get_off_table(uintptr_t addr, uint32_t **off_tab, int attr_count) { uintptr_t idx_table; if (GETMEMB(addr, "sa_idx_tab", sa_idx_tab, idx_table)) { mdb_printf("can't find offset table in sa_idx_tab\n"); return (-1); } *off_tab = mdb_alloc(attr_count * sizeof (uint32_t), UM_SLEEP | UM_GC); if (mdb_vread(*off_tab, attr_count * sizeof (uint32_t), idx_table) == -1) { mdb_warn("failed to attribute offset table %p", idx_table); return (-1); } return (DCMD_OK); } /*ARGSUSED*/ static int sa_attr_print(uintptr_t addr, uint_t flags, int argc, const mdb_arg_t *argv) { uint32_t *offset_tab; int attr_count; uint64_t attr_id; uintptr_t attr_addr; uintptr_t bonus_tab, spill_tab; uintptr_t db_bonus, db_spill; uintptr_t os, os_sa; uintptr_t db_data; if (argc != 1) return (DCMD_USAGE); if (argv[0].a_type == MDB_TYPE_STRING) attr_id = mdb_strtoull(argv[0].a_un.a_str); else return (DCMD_USAGE); if (GETMEMB(addr, "sa_handle", sa_bonus_tab, bonus_tab) || GETMEMB(addr, "sa_handle", sa_spill_tab, spill_tab) || GETMEMB(addr, "sa_handle", sa_os, os) || GETMEMB(addr, "sa_handle", sa_bonus, db_bonus) || GETMEMB(addr, "sa_handle", sa_spill, db_spill)) { mdb_printf("Can't find necessary information in sa_handle " "in sa_handle\n"); return (DCMD_ERR); } if (GETMEMB(os, "objset", os_sa, os_sa)) { mdb_printf("Can't find os_sa in objset\n"); return (DCMD_ERR); } if (GETMEMB(os_sa, "sa_os", sa_num_attrs, attr_count)) { mdb_printf("Can't find sa_num_attrs\n"); return (DCMD_ERR); } if (attr_id > attr_count) { mdb_printf("attribute id number is out of range\n"); return (DCMD_ERR); } if (bonus_tab) { if (sa_get_off_table(bonus_tab, &offset_tab, attr_count) == -1) { return (DCMD_ERR); } if (GETMEMB(db_bonus, "dmu_buf", db_data, db_data)) { mdb_printf("can't find db_data in bonus dbuf\n"); return (DCMD_ERR); } } if (bonus_tab && !TOC_ATTR_PRESENT(offset_tab[attr_id]) && spill_tab == 0) { mdb_printf("Attribute does not exist\n"); return (DCMD_ERR); } else if (!TOC_ATTR_PRESENT(offset_tab[attr_id]) && spill_tab) { if (sa_get_off_table(spill_tab, &offset_tab, attr_count) == -1) { return (DCMD_ERR); } if (GETMEMB(db_spill, "dmu_buf", db_data, db_data)) { mdb_printf("can't find db_data in spill dbuf\n"); return (DCMD_ERR); } if (!TOC_ATTR_PRESENT(offset_tab[attr_id])) { mdb_printf("Attribute does not exist\n"); return (DCMD_ERR); } } attr_addr = db_data + TOC_OFF(offset_tab[attr_id]); mdb_printf("%p\n", attr_addr); return (DCMD_OK); } /* ARGSUSED */ static int zfs_ace_print_common(uintptr_t addr, uint_t flags, uint64_t id, uint32_t access_mask, uint16_t ace_flags, uint16_t ace_type, int verbose) { if (DCMD_HDRSPEC(flags) && !verbose) mdb_printf("%%-?s %-8s %-8s %-8s %s%\n", "ADDR", "FLAGS", "MASK", "TYPE", "ID"); if (!verbose) { mdb_printf("%0?p %-8x %-8x %-8x %-llx\n", addr, ace_flags, access_mask, ace_type, id); return (DCMD_OK); } switch (ace_flags & ACE_TYPE_FLAGS) { case ACE_OWNER: mdb_printf("owner@:"); break; case (ACE_IDENTIFIER_GROUP | ACE_GROUP): mdb_printf("group@:"); break; case ACE_EVERYONE: mdb_printf("everyone@:"); break; case ACE_IDENTIFIER_GROUP: mdb_printf("group:%llx:", (u_longlong_t)id); break; case 0: /* User entry */ mdb_printf("user:%llx:", (u_longlong_t)id); break; } /* print out permission mask */ if (access_mask & ACE_READ_DATA) mdb_printf("r"); else mdb_printf("-"); if (access_mask & ACE_WRITE_DATA) mdb_printf("w"); else mdb_printf("-"); if (access_mask & ACE_EXECUTE) mdb_printf("x"); else mdb_printf("-"); if (access_mask & ACE_APPEND_DATA) mdb_printf("p"); else mdb_printf("-"); if (access_mask & ACE_DELETE) mdb_printf("d"); else mdb_printf("-"); if (access_mask & ACE_DELETE_CHILD) mdb_printf("D"); else mdb_printf("-"); if (access_mask & ACE_READ_ATTRIBUTES) mdb_printf("a"); else mdb_printf("-"); if (access_mask & ACE_WRITE_ATTRIBUTES) mdb_printf("A"); else mdb_printf("-"); if (access_mask & ACE_READ_NAMED_ATTRS) mdb_printf("R"); else mdb_printf("-"); if (access_mask & ACE_WRITE_NAMED_ATTRS) mdb_printf("W"); else mdb_printf("-"); if (access_mask & ACE_READ_ACL) mdb_printf("c"); else mdb_printf("-"); if (access_mask & ACE_WRITE_ACL) mdb_printf("C"); else mdb_printf("-"); if (access_mask & ACE_WRITE_OWNER) mdb_printf("o"); else mdb_printf("-"); if (access_mask & ACE_SYNCHRONIZE) mdb_printf("s"); else mdb_printf("-"); mdb_printf(":"); /* Print out inheritance flags */ if (ace_flags & ACE_FILE_INHERIT_ACE) mdb_printf("f"); else mdb_printf("-"); if (ace_flags & ACE_DIRECTORY_INHERIT_ACE) mdb_printf("d"); else mdb_printf("-"); if (ace_flags & ACE_INHERIT_ONLY_ACE) mdb_printf("i"); else mdb_printf("-"); if (ace_flags & ACE_NO_PROPAGATE_INHERIT_ACE) mdb_printf("n"); else mdb_printf("-"); if (ace_flags & ACE_SUCCESSFUL_ACCESS_ACE_FLAG) mdb_printf("S"); else mdb_printf("-"); if (ace_flags & ACE_FAILED_ACCESS_ACE_FLAG) mdb_printf("F"); else mdb_printf("-"); if (ace_flags & ACE_INHERITED_ACE) mdb_printf("I"); else mdb_printf("-"); switch (ace_type) { case ACE_ACCESS_ALLOWED_ACE_TYPE: mdb_printf(":allow\n"); break; case ACE_ACCESS_DENIED_ACE_TYPE: mdb_printf(":deny\n"); break; case ACE_SYSTEM_AUDIT_ACE_TYPE: mdb_printf(":audit\n"); break; case ACE_SYSTEM_ALARM_ACE_TYPE: mdb_printf(":alarm\n"); break; default: mdb_printf(":?\n"); } return (DCMD_OK); } /* ARGSUSED */ static int zfs_ace_print(uintptr_t addr, uint_t flags, int argc, const mdb_arg_t *argv) { zfs_ace_t zace; int verbose = FALSE; uint64_t id; if (!(flags & DCMD_ADDRSPEC)) return (DCMD_USAGE); if (mdb_getopts(argc, argv, 'v', MDB_OPT_SETBITS, TRUE, &verbose, TRUE, NULL) != argc) return (DCMD_USAGE); if (mdb_vread(&zace, sizeof (zfs_ace_t), addr) == -1) { mdb_warn("failed to read zfs_ace_t"); return (DCMD_ERR); } if ((zace.z_hdr.z_flags & ACE_TYPE_FLAGS) == 0 || (zace.z_hdr.z_flags & ACE_TYPE_FLAGS) == ACE_IDENTIFIER_GROUP) id = zace.z_fuid; else id = -1; return (zfs_ace_print_common(addr, flags, id, zace.z_hdr.z_access_mask, zace.z_hdr.z_flags, zace.z_hdr.z_type, verbose)); } /* ARGSUSED */ static int zfs_ace0_print(uintptr_t addr, uint_t flags, int argc, const mdb_arg_t *argv) { ace_t ace; uint64_t id; int verbose = FALSE; if (!(flags & DCMD_ADDRSPEC)) return (DCMD_USAGE); if (mdb_getopts(argc, argv, 'v', MDB_OPT_SETBITS, TRUE, &verbose, TRUE, NULL) != argc) return (DCMD_USAGE); if (mdb_vread(&ace, sizeof (ace_t), addr) == -1) { mdb_warn("failed to read ace_t"); return (DCMD_ERR); } if ((ace.a_flags & ACE_TYPE_FLAGS) == 0 || (ace.a_flags & ACE_TYPE_FLAGS) == ACE_IDENTIFIER_GROUP) id = ace.a_who; else id = -1; return (zfs_ace_print_common(addr, flags, id, ace.a_access_mask, ace.a_flags, ace.a_type, verbose)); } typedef struct acl_dump_args { int a_argc; const mdb_arg_t *a_argv; uint16_t a_version; int a_flags; } acl_dump_args_t; /* ARGSUSED */ static int acl_aces_cb(uintptr_t addr, const void *unknown, void *arg) { acl_dump_args_t *acl_args = (acl_dump_args_t *)arg; if (acl_args->a_version == 1) { if (mdb_call_dcmd("zfs_ace", addr, DCMD_ADDRSPEC|acl_args->a_flags, acl_args->a_argc, acl_args->a_argv) != DCMD_OK) { return (WALK_ERR); } } else { if (mdb_call_dcmd("zfs_ace0", addr, DCMD_ADDRSPEC|acl_args->a_flags, acl_args->a_argc, acl_args->a_argv) != DCMD_OK) { return (WALK_ERR); } } acl_args->a_flags = DCMD_LOOP; return (WALK_NEXT); } /* ARGSUSED */ static int acl_cb(uintptr_t addr, const void *unknown, void *arg) { acl_dump_args_t *acl_args = (acl_dump_args_t *)arg; if (acl_args->a_version == 1) { if (mdb_pwalk("zfs_acl_node_aces", acl_aces_cb, arg, addr) != 0) { mdb_warn("can't walk ACEs"); return (DCMD_ERR); } } else { if (mdb_pwalk("zfs_acl_node_aces0", acl_aces_cb, arg, addr) != 0) { mdb_warn("can't walk ACEs"); return (DCMD_ERR); } } return (WALK_NEXT); } /* ARGSUSED */ static int zfs_acl_dump(uintptr_t addr, uint_t flags, int argc, const mdb_arg_t *argv) { zfs_acl_t zacl; int verbose = FALSE; acl_dump_args_t acl_args; if (!(flags & DCMD_ADDRSPEC)) return (DCMD_USAGE); if (mdb_getopts(argc, argv, 'v', MDB_OPT_SETBITS, TRUE, &verbose, NULL) != argc) return (DCMD_USAGE); if (mdb_vread(&zacl, sizeof (zfs_acl_t), addr) == -1) { mdb_warn("failed to read zfs_acl_t"); return (DCMD_ERR); } acl_args.a_argc = argc; acl_args.a_argv = argv; acl_args.a_version = zacl.z_version; acl_args.a_flags = DCMD_LOOPFIRST; if (mdb_pwalk("zfs_acl_node", acl_cb, &acl_args, addr) != 0) { mdb_warn("can't walk ACL"); return (DCMD_ERR); } return (DCMD_OK); } /* ARGSUSED */ static int zfs_acl_node_walk_init(mdb_walk_state_t *wsp) { if (wsp->walk_addr == 0) { mdb_warn("must supply address of zfs_acl_node_t\n"); return (WALK_ERR); } wsp->walk_addr += mdb_ctf_offsetof_by_name(ZFS_STRUCT "zfs_acl", "z_acl"); if (mdb_layered_walk("list", wsp) == -1) { mdb_warn("failed to walk 'list'\n"); return (WALK_ERR); } return (WALK_NEXT); } static int zfs_acl_node_walk_step(mdb_walk_state_t *wsp) { zfs_acl_node_t aclnode; if (mdb_vread(&aclnode, sizeof (zfs_acl_node_t), wsp->walk_addr) == -1) { mdb_warn("failed to read zfs_acl_node at %p", wsp->walk_addr); return (WALK_ERR); } return (wsp->walk_callback(wsp->walk_addr, &aclnode, wsp->walk_cbdata)); } typedef struct ace_walk_data { int ace_count; int ace_version; } ace_walk_data_t; static int zfs_aces_walk_init_common(mdb_walk_state_t *wsp, int version, int ace_count, uintptr_t ace_data) { ace_walk_data_t *ace_walk_data; if (wsp->walk_addr == 0) { mdb_warn("must supply address of zfs_acl_node_t\n"); return (WALK_ERR); } ace_walk_data = mdb_alloc(sizeof (ace_walk_data_t), UM_SLEEP | UM_GC); ace_walk_data->ace_count = ace_count; ace_walk_data->ace_version = version; wsp->walk_addr = ace_data; wsp->walk_data = ace_walk_data; return (WALK_NEXT); } static int zfs_acl_node_aces_walk_init_common(mdb_walk_state_t *wsp, int version) { static int gotid; static mdb_ctf_id_t acl_id; int z_ace_count; uintptr_t z_acldata; if (!gotid) { if (mdb_ctf_lookup_by_name("struct zfs_acl_node", &acl_id) == -1) { mdb_warn("couldn't find struct zfs_acl_node"); return (DCMD_ERR); } gotid = TRUE; } if (GETMEMBID(wsp->walk_addr, &acl_id, z_ace_count, z_ace_count)) { return (DCMD_ERR); } if (GETMEMBID(wsp->walk_addr, &acl_id, z_acldata, z_acldata)) { return (DCMD_ERR); } return (zfs_aces_walk_init_common(wsp, version, z_ace_count, z_acldata)); } /* ARGSUSED */ static int zfs_acl_node_aces_walk_init(mdb_walk_state_t *wsp) { return (zfs_acl_node_aces_walk_init_common(wsp, 1)); } /* ARGSUSED */ static int zfs_acl_node_aces0_walk_init(mdb_walk_state_t *wsp) { return (zfs_acl_node_aces_walk_init_common(wsp, 0)); } static int zfs_aces_walk_step(mdb_walk_state_t *wsp) { ace_walk_data_t *ace_data = wsp->walk_data; zfs_ace_t zace; ace_t *acep; int status; int entry_type; int allow_type; uintptr_t ptr; if (ace_data->ace_count == 0) return (WALK_DONE); if (mdb_vread(&zace, sizeof (zfs_ace_t), wsp->walk_addr) == -1) { mdb_warn("failed to read zfs_ace_t at %#lx", wsp->walk_addr); return (WALK_ERR); } switch (ace_data->ace_version) { case 0: acep = (ace_t *)&zace; entry_type = acep->a_flags & ACE_TYPE_FLAGS; allow_type = acep->a_type; break; case 1: entry_type = zace.z_hdr.z_flags & ACE_TYPE_FLAGS; allow_type = zace.z_hdr.z_type; break; default: return (WALK_ERR); } ptr = (uintptr_t)wsp->walk_addr; switch (entry_type) { case ACE_OWNER: case ACE_EVERYONE: case (ACE_IDENTIFIER_GROUP | ACE_GROUP): ptr += ace_data->ace_version == 0 ? sizeof (ace_t) : sizeof (zfs_ace_hdr_t); break; case ACE_IDENTIFIER_GROUP: default: switch (allow_type) { case ACE_ACCESS_ALLOWED_OBJECT_ACE_TYPE: case ACE_ACCESS_DENIED_OBJECT_ACE_TYPE: case ACE_SYSTEM_AUDIT_OBJECT_ACE_TYPE: case ACE_SYSTEM_ALARM_OBJECT_ACE_TYPE: ptr += ace_data->ace_version == 0 ? sizeof (ace_t) : sizeof (zfs_object_ace_t); break; default: ptr += ace_data->ace_version == 0 ? sizeof (ace_t) : sizeof (zfs_ace_t); break; } } ace_data->ace_count--; status = wsp->walk_callback(wsp->walk_addr, (void *)(uintptr_t)&zace, wsp->walk_cbdata); wsp->walk_addr = ptr; return (status); } typedef struct mdb_zfs_rrwlock { uintptr_t rr_writer; boolean_t rr_writer_wanted; } mdb_zfs_rrwlock_t; static uint_t rrw_key; /* ARGSUSED */ static int rrwlock(uintptr_t addr, uint_t flags, int argc, const mdb_arg_t *argv) { mdb_zfs_rrwlock_t rrw; if (rrw_key == 0) { if (mdb_ctf_readsym(&rrw_key, "uint_t", "rrw_tsd_key", 0) == -1) return (DCMD_ERR); } if (mdb_ctf_vread(&rrw, "rrwlock_t", "mdb_zfs_rrwlock_t", addr, 0) == -1) return (DCMD_ERR); if (rrw.rr_writer != 0) { mdb_printf("write lock held by thread %lx\n", rrw.rr_writer); return (DCMD_OK); } if (rrw.rr_writer_wanted) { mdb_printf("writer wanted\n"); } mdb_printf("anonymous references:\n"); (void) mdb_call_dcmd("zfs_refcount", addr + mdb_ctf_offsetof_by_name(ZFS_STRUCT "rrwlock", "rr_anon_rcount"), DCMD_ADDRSPEC, 0, NULL); mdb_printf("linked references:\n"); (void) mdb_call_dcmd("zfs_refcount", addr + mdb_ctf_offsetof_by_name(ZFS_STRUCT "rrwlock", "rr_linked_rcount"), DCMD_ADDRSPEC, 0, NULL); /* * XXX This should find references from * "::walk thread | ::tsd -v ", but there is no support * for programmatic consumption of dcmds, so this would be * difficult, potentially requiring reimplementing ::tsd (both * user and kernel versions) in this MDB module. */ return (DCMD_OK); } typedef struct mdb_arc_buf_hdr_t { uint16_t b_psize; uint16_t b_lsize; struct { uint32_t b_bufcnt; uintptr_t b_state; } b_l1hdr; } mdb_arc_buf_hdr_t; enum arc_cflags { ARC_CFLAG_VERBOSE = 1 << 0, ARC_CFLAG_ANON = 1 << 1, ARC_CFLAG_MRU = 1 << 2, ARC_CFLAG_MFU = 1 << 3, ARC_CFLAG_BUFS = 1 << 4, }; typedef struct arc_compression_stats_data { GElf_Sym anon_sym; /* ARC_anon symbol */ GElf_Sym mru_sym; /* ARC_mru symbol */ GElf_Sym mrug_sym; /* ARC_mru_ghost symbol */ GElf_Sym mfu_sym; /* ARC_mfu symbol */ GElf_Sym mfug_sym; /* ARC_mfu_ghost symbol */ GElf_Sym l2c_sym; /* ARC_l2c_only symbol */ uint64_t *anon_c_hist; /* histogram of compressed sizes in anon */ uint64_t *anon_u_hist; /* histogram of uncompressed sizes in anon */ uint64_t *anon_bufs; /* histogram of buffer counts in anon state */ uint64_t *mru_c_hist; /* histogram of compressed sizes in mru */ uint64_t *mru_u_hist; /* histogram of uncompressed sizes in mru */ uint64_t *mru_bufs; /* histogram of buffer counts in mru */ uint64_t *mfu_c_hist; /* histogram of compressed sizes in mfu */ uint64_t *mfu_u_hist; /* histogram of uncompressed sizes in mfu */ uint64_t *mfu_bufs; /* histogram of buffer counts in mfu */ uint64_t *all_c_hist; /* histogram of compressed anon + mru + mfu */ uint64_t *all_u_hist; /* histogram of uncompressed anon + mru + mfu */ uint64_t *all_bufs; /* histogram of buffer counts in all states */ int arc_cflags; /* arc compression flags, specified by user */ int hist_nbuckets; /* number of buckets in each histogram */ ulong_t l1hdr_off; /* offset of b_l1hdr in arc_buf_hdr_t */ } arc_compression_stats_data_t; int highbit64(uint64_t i) { int h = 1; if (i == 0) return (0); if (i & 0xffffffff00000000ULL) { h += 32; i >>= 32; } if (i & 0xffff0000) { h += 16; i >>= 16; } if (i & 0xff00) { h += 8; i >>= 8; } if (i & 0xf0) { h += 4; i >>= 4; } if (i & 0xc) { h += 2; i >>= 2; } if (i & 0x2) { h += 1; } return (h); } /* ARGSUSED */ static int arc_compression_stats_cb(uintptr_t addr, const void *unknown, void *arg) { arc_compression_stats_data_t *data = arg; arc_flags_t flags; mdb_arc_buf_hdr_t hdr; int cbucket, ubucket, bufcnt; /* * mdb_ctf_vread() uses the sizeof the target type (e.g. * sizeof (arc_buf_hdr_t) in the target) to read in the entire contents * of the target type into a buffer and then copy the values of the * desired members from the mdb typename (e.g. mdb_arc_buf_hdr_t) from * this buffer. Unfortunately, the way arc_buf_hdr_t is used by zfs, * the actual size allocated by the kernel for arc_buf_hdr_t is often * smaller than `sizeof (arc_buf_hdr_t)` (see the definitions of * l1arc_buf_hdr_t and arc_buf_hdr_t in * usr/src/uts/common/fs/zfs/arc.c). Attempting to read the entire * contents of arc_buf_hdr_t from the target (as mdb_ctf_vread() does) * can cause an error if the allocated size is indeed smaller--it's * possible that the 'missing' trailing members of arc_buf_hdr_t * (l1arc_buf_hdr_t and/or arc_buf_hdr_crypt_t) may fall into unmapped * memory. * * We use the GETMEMB macro instead which performs an mdb_vread() * but only reads enough of the target to retrieve the desired struct * member instead of the entire struct. */ if (GETMEMB(addr, "arc_buf_hdr", b_flags, flags) == -1) return (WALK_ERR); /* * We only count headers that have data loaded in the kernel. * This means an L1 header must be present as well as the data * that corresponds to the L1 header. If there's no L1 header, * we can skip the arc_buf_hdr_t completely. If it's present, we * must look at the ARC state (b_l1hdr.b_state) to determine if * the data is present. */ if ((flags & ARC_FLAG_HAS_L1HDR) == 0) return (WALK_NEXT); if (GETMEMB(addr, "arc_buf_hdr", b_psize, hdr.b_psize) == -1 || GETMEMB(addr, "arc_buf_hdr", b_lsize, hdr.b_lsize) == -1 || GETMEMB(addr + data->l1hdr_off, "l1arc_buf_hdr", b_bufcnt, hdr.b_l1hdr.b_bufcnt) == -1 || GETMEMB(addr + data->l1hdr_off, "l1arc_buf_hdr", b_state, hdr.b_l1hdr.b_state) == -1) return (WALK_ERR); /* * Headers in the ghost states, or the l2c_only state don't have * arc buffers linked off of them. Thus, their compressed size * is meaningless, so we skip these from the stats. */ if (hdr.b_l1hdr.b_state == data->mrug_sym.st_value || hdr.b_l1hdr.b_state == data->mfug_sym.st_value || hdr.b_l1hdr.b_state == data->l2c_sym.st_value) { return (WALK_NEXT); } /* * The physical size (compressed) and logical size * (uncompressed) are in units of SPA_MINBLOCKSIZE. By default, * we use the log2 of this value (rounded down to the nearest * integer) to determine the bucket to assign this header to. * Thus, the histogram is logarithmic with respect to the size * of the header. For example, the following is a mapping of the * bucket numbers and the range of header sizes they correspond to: * * 0: 0 byte headers * 1: 512 byte headers * 2: [1024 - 2048) byte headers * 3: [2048 - 4096) byte headers * 4: [4096 - 8192) byte headers * 5: [8192 - 16394) byte headers * 6: [16384 - 32768) byte headers * 7: [32768 - 65536) byte headers * 8: [65536 - 131072) byte headers * 9: 131072 byte headers * * If the ARC_CFLAG_VERBOSE flag was specified, we use the * physical and logical sizes directly. Thus, the histogram will * no longer be logarithmic; instead it will be linear with * respect to the size of the header. The following is a mapping * of the first many bucket numbers and the header size they * correspond to: * * 0: 0 byte headers * 1: 512 byte headers * 2: 1024 byte headers * 3: 1536 byte headers * 4: 2048 byte headers * 5: 2560 byte headers * 6: 3072 byte headers * * And so on. Keep in mind that a range of sizes isn't used in * the case of linear scale because the headers can only * increment or decrement in sizes of 512 bytes. So, it's not * possible for a header to be sized in between whats listed * above. * * Also, the above mapping values were calculated assuming a * SPA_MINBLOCKSHIFT of 512 bytes and a SPA_MAXBLOCKSIZE of 128K. */ if (data->arc_cflags & ARC_CFLAG_VERBOSE) { cbucket = hdr.b_psize; ubucket = hdr.b_lsize; } else { cbucket = highbit64(hdr.b_psize); ubucket = highbit64(hdr.b_lsize); } bufcnt = hdr.b_l1hdr.b_bufcnt; if (bufcnt >= data->hist_nbuckets) bufcnt = data->hist_nbuckets - 1; /* Ensure we stay within the bounds of the histogram array */ ASSERT3U(cbucket, <, data->hist_nbuckets); ASSERT3U(ubucket, <, data->hist_nbuckets); if (hdr.b_l1hdr.b_state == data->anon_sym.st_value) { data->anon_c_hist[cbucket]++; data->anon_u_hist[ubucket]++; data->anon_bufs[bufcnt]++; } else if (hdr.b_l1hdr.b_state == data->mru_sym.st_value) { data->mru_c_hist[cbucket]++; data->mru_u_hist[ubucket]++; data->mru_bufs[bufcnt]++; } else if (hdr.b_l1hdr.b_state == data->mfu_sym.st_value) { data->mfu_c_hist[cbucket]++; data->mfu_u_hist[ubucket]++; data->mfu_bufs[bufcnt]++; } data->all_c_hist[cbucket]++; data->all_u_hist[ubucket]++; data->all_bufs[bufcnt]++; return (WALK_NEXT); } /* ARGSUSED */ static int arc_compression_stats(uintptr_t addr, uint_t flags, int argc, const mdb_arg_t *argv) { arc_compression_stats_data_t data = { 0 }; unsigned int max_shifted = SPA_MAXBLOCKSIZE >> SPA_MINBLOCKSHIFT; unsigned int hist_size; char range[32]; int rc = DCMD_OK; int off; if (mdb_getopts(argc, argv, 'v', MDB_OPT_SETBITS, ARC_CFLAG_VERBOSE, &data.arc_cflags, 'a', MDB_OPT_SETBITS, ARC_CFLAG_ANON, &data.arc_cflags, 'b', MDB_OPT_SETBITS, ARC_CFLAG_BUFS, &data.arc_cflags, 'r', MDB_OPT_SETBITS, ARC_CFLAG_MRU, &data.arc_cflags, 'f', MDB_OPT_SETBITS, ARC_CFLAG_MFU, &data.arc_cflags, NULL) != argc) return (DCMD_USAGE); if (mdb_lookup_by_obj(ZFS_OBJ_NAME, "ARC_anon", &data.anon_sym) || mdb_lookup_by_obj(ZFS_OBJ_NAME, "ARC_mru", &data.mru_sym) || mdb_lookup_by_obj(ZFS_OBJ_NAME, "ARC_mru_ghost", &data.mrug_sym) || mdb_lookup_by_obj(ZFS_OBJ_NAME, "ARC_mfu", &data.mfu_sym) || mdb_lookup_by_obj(ZFS_OBJ_NAME, "ARC_mfu_ghost", &data.mfug_sym) || mdb_lookup_by_obj(ZFS_OBJ_NAME, "ARC_l2c_only", &data.l2c_sym)) { mdb_warn("can't find arc state symbol"); return (DCMD_ERR); } /* * Determine the maximum expected size for any header, and use * this to determine the number of buckets needed for each * histogram. If ARC_CFLAG_VERBOSE is specified, this value is * used directly; otherwise the log2 of the maximum size is * used. Thus, if using a log2 scale there's a maximum of 10 * possible buckets, while the linear scale (when using * ARC_CFLAG_VERBOSE) has a maximum of 257 buckets. */ if (data.arc_cflags & ARC_CFLAG_VERBOSE) data.hist_nbuckets = max_shifted + 1; else data.hist_nbuckets = highbit64(max_shifted) + 1; hist_size = sizeof (uint64_t) * data.hist_nbuckets; data.anon_c_hist = mdb_zalloc(hist_size, UM_SLEEP); data.anon_u_hist = mdb_zalloc(hist_size, UM_SLEEP); data.anon_bufs = mdb_zalloc(hist_size, UM_SLEEP); data.mru_c_hist = mdb_zalloc(hist_size, UM_SLEEP); data.mru_u_hist = mdb_zalloc(hist_size, UM_SLEEP); data.mru_bufs = mdb_zalloc(hist_size, UM_SLEEP); data.mfu_c_hist = mdb_zalloc(hist_size, UM_SLEEP); data.mfu_u_hist = mdb_zalloc(hist_size, UM_SLEEP); data.mfu_bufs = mdb_zalloc(hist_size, UM_SLEEP); data.all_c_hist = mdb_zalloc(hist_size, UM_SLEEP); data.all_u_hist = mdb_zalloc(hist_size, UM_SLEEP); data.all_bufs = mdb_zalloc(hist_size, UM_SLEEP); if ((off = mdb_ctf_offsetof_by_name(ZFS_STRUCT "arc_buf_hdr", "b_l1hdr")) == -1) { mdb_warn("could not get offset of b_l1hdr from arc_buf_hdr_t"); rc = DCMD_ERR; goto out; } data.l1hdr_off = off; if (mdb_walk("arc_buf_hdr_t_full", arc_compression_stats_cb, &data) != 0) { mdb_warn("can't walk arc_buf_hdr's"); rc = DCMD_ERR; goto out; } if (data.arc_cflags & ARC_CFLAG_VERBOSE) { rc = mdb_snprintf(range, sizeof (range), "[n*%llu, (n+1)*%llu)", SPA_MINBLOCKSIZE, SPA_MINBLOCKSIZE); } else { rc = mdb_snprintf(range, sizeof (range), "[2^(n-1)*%llu, 2^n*%llu)", SPA_MINBLOCKSIZE, SPA_MINBLOCKSIZE); } if (rc < 0) { /* snprintf failed, abort the dcmd */ rc = DCMD_ERR; goto out; } else { /* snprintf succeeded above, reset return code */ rc = DCMD_OK; } if (data.arc_cflags & ARC_CFLAG_ANON) { if (data.arc_cflags & ARC_CFLAG_BUFS) { mdb_printf("Histogram of the number of anon buffers " "that are associated with an arc hdr.\n"); dump_histogram(data.anon_bufs, data.hist_nbuckets, 0); mdb_printf("\n"); } mdb_printf("Histogram of compressed anon buffers.\n" "Each bucket represents buffers of size: %s.\n", range); dump_histogram(data.anon_c_hist, data.hist_nbuckets, 0); mdb_printf("\n"); mdb_printf("Histogram of uncompressed anon buffers.\n" "Each bucket represents buffers of size: %s.\n", range); dump_histogram(data.anon_u_hist, data.hist_nbuckets, 0); mdb_printf("\n"); } if (data.arc_cflags & ARC_CFLAG_MRU) { if (data.arc_cflags & ARC_CFLAG_BUFS) { mdb_printf("Histogram of the number of mru buffers " "that are associated with an arc hdr.\n"); dump_histogram(data.mru_bufs, data.hist_nbuckets, 0); mdb_printf("\n"); } mdb_printf("Histogram of compressed mru buffers.\n" "Each bucket represents buffers of size: %s.\n", range); dump_histogram(data.mru_c_hist, data.hist_nbuckets, 0); mdb_printf("\n"); mdb_printf("Histogram of uncompressed mru buffers.\n" "Each bucket represents buffers of size: %s.\n", range); dump_histogram(data.mru_u_hist, data.hist_nbuckets, 0); mdb_printf("\n"); } if (data.arc_cflags & ARC_CFLAG_MFU) { if (data.arc_cflags & ARC_CFLAG_BUFS) { mdb_printf("Histogram of the number of mfu buffers " "that are associated with an arc hdr.\n"); dump_histogram(data.mfu_bufs, data.hist_nbuckets, 0); mdb_printf("\n"); } mdb_printf("Histogram of compressed mfu buffers.\n" "Each bucket represents buffers of size: %s.\n", range); dump_histogram(data.mfu_c_hist, data.hist_nbuckets, 0); mdb_printf("\n"); mdb_printf("Histogram of uncompressed mfu buffers.\n" "Each bucket represents buffers of size: %s.\n", range); dump_histogram(data.mfu_u_hist, data.hist_nbuckets, 0); mdb_printf("\n"); } if (data.arc_cflags & ARC_CFLAG_BUFS) { mdb_printf("Histogram of all buffers that " "are associated with an arc hdr.\n"); dump_histogram(data.all_bufs, data.hist_nbuckets, 0); mdb_printf("\n"); } mdb_printf("Histogram of all compressed buffers.\n" "Each bucket represents buffers of size: %s.\n", range); dump_histogram(data.all_c_hist, data.hist_nbuckets, 0); mdb_printf("\n"); mdb_printf("Histogram of all uncompressed buffers.\n" "Each bucket represents buffers of size: %s.\n", range); dump_histogram(data.all_u_hist, data.hist_nbuckets, 0); out: mdb_free(data.anon_c_hist, hist_size); mdb_free(data.anon_u_hist, hist_size); mdb_free(data.anon_bufs, hist_size); mdb_free(data.mru_c_hist, hist_size); mdb_free(data.mru_u_hist, hist_size); mdb_free(data.mru_bufs, hist_size); mdb_free(data.mfu_c_hist, hist_size); mdb_free(data.mfu_u_hist, hist_size); mdb_free(data.mfu_bufs, hist_size); mdb_free(data.all_c_hist, hist_size); mdb_free(data.all_u_hist, hist_size); mdb_free(data.all_bufs, hist_size); return (rc); } typedef struct mdb_range_seg64 { uint64_t rs_start; uint64_t rs_end; } mdb_range_seg64_t; typedef struct mdb_range_seg32 { uint32_t rs_start; uint32_t rs_end; } mdb_range_seg32_t; /* ARGSUSED */ static int range_tree_cb(uintptr_t addr, const void *unknown, void *arg) { mdb_range_tree_t *rt = (mdb_range_tree_t *)arg; uint64_t start, end; if (rt->rt_type == RANGE_SEG64) { mdb_range_seg64_t rs; if (mdb_ctf_vread(&rs, ZFS_STRUCT "range_seg64", "mdb_range_seg64_t", addr, 0) == -1) return (DCMD_ERR); start = rs.rs_start; end = rs.rs_end; } else { ASSERT3U(rt->rt_type, ==, RANGE_SEG32); mdb_range_seg32_t rs; if (mdb_ctf_vread(&rs, ZFS_STRUCT "range_seg32", "mdb_range_seg32_t", addr, 0) == -1) return (DCMD_ERR); start = ((uint64_t)rs.rs_start << rt->rt_shift) + rt->rt_start; end = ((uint64_t)rs.rs_end << rt->rt_shift) + rt->rt_start; } mdb_printf("\t[%llx %llx) (length %llx)\n", start, end, end - start); return (0); } /* ARGSUSED */ static int range_tree(uintptr_t addr, uint_t flags, int argc, const mdb_arg_t *argv) { mdb_range_tree_t rt; uintptr_t btree_addr; if (!(flags & DCMD_ADDRSPEC)) return (DCMD_USAGE); if (mdb_ctf_vread(&rt, ZFS_STRUCT "range_tree", "mdb_range_tree_t", addr, 0) == -1) return (DCMD_ERR); mdb_printf("%p: range tree of %llu entries, %llu bytes\n", addr, rt.rt_root.bt_num_elems, rt.rt_space); btree_addr = addr + mdb_ctf_offsetof_by_name(ZFS_STRUCT "range_tree", "rt_root"); if (mdb_pwalk("zfs_btree", range_tree_cb, &rt, btree_addr) != 0) { mdb_warn("can't walk range_tree segments"); return (DCMD_ERR); } return (DCMD_OK); } typedef struct mdb_spa_log_sm { uint64_t sls_sm_obj; uint64_t sls_txg; uint64_t sls_nblocks; uint64_t sls_mscount; } mdb_spa_log_sm_t; /* ARGSUSED */ static int logsm_stats_cb(uintptr_t addr, const void *unknown, void *arg) { mdb_spa_log_sm_t sls; if (mdb_ctf_vread(&sls, ZFS_STRUCT "spa_log_sm", "mdb_spa_log_sm_t", addr, 0) == -1) return (WALK_ERR); mdb_printf("%7lld %7lld %7lld %7lld\n", sls.sls_txg, sls.sls_nblocks, sls.sls_mscount, sls.sls_sm_obj); return (WALK_NEXT); } typedef struct mdb_log_summary_entry { uint64_t lse_start; uint64_t lse_blkcount; uint64_t lse_mscount; } mdb_log_summary_entry_t; /* ARGSUSED */ static int logsm_summary_cb(uintptr_t addr, const void *unknown, void *arg) { mdb_log_summary_entry_t lse; if (mdb_ctf_vread(&lse, ZFS_STRUCT "log_summary_entry", "mdb_log_summary_entry_t", addr, 0) == -1) return (WALK_ERR); mdb_printf("%7lld %7lld %7lld\n", lse.lse_start, lse.lse_blkcount, lse.lse_mscount); return (WALK_NEXT); } /* ARGSUSED */ static int logsm_stats(uintptr_t addr, uint_t flags, int argc, const mdb_arg_t *argv) { if (!(flags & DCMD_ADDRSPEC)) return (DCMD_USAGE); uintptr_t sls_avl_addr = addr + mdb_ctf_offsetof_by_name(ZFS_STRUCT "spa", "spa_sm_logs_by_txg"); uintptr_t summary_addr = addr + mdb_ctf_offsetof_by_name(ZFS_STRUCT "spa", "spa_log_summary"); mdb_printf("Log Entries:\n"); mdb_printf("%7s %7s %7s %7s\n", "txg", "blk", "ms", "obj"); if (mdb_pwalk("avl", logsm_stats_cb, NULL, sls_avl_addr) != 0) return (DCMD_ERR); mdb_printf("\nSummary Entries:\n"); mdb_printf("%7s %7s %7s\n", "txg", "blk", "ms"); if (mdb_pwalk("list", logsm_summary_cb, NULL, summary_addr) != 0) return (DCMD_ERR); return (DCMD_OK); } /* * MDB module linkage information: * * We declare a list of structures describing our dcmds, and a function * named _mdb_init to return a pointer to our module information. */ static const mdb_dcmd_t dcmds[] = { { "arc", "[-bkmg]", "print ARC variables", arc_print }, { "blkptr", ":", "print blkptr_t", blkptr }, { "dva", ":", "print dva_t", dva }, { "dbuf", ":", "print dmu_buf_impl_t", dbuf }, { "dbuf_stats", ":", "dbuf stats", dbuf_stats }, { "dbufs", "\t[-O objset_t*] [-n objset_name | \"mos\"] " "[-o object | \"mdn\"] \n" "\t[-l level] [-b blkid | \"bonus\"]", "find dmu_buf_impl_t's that match specified criteria", dbufs }, { "abuf_find", "dva_word[0] dva_word[1]", "find arc_buf_hdr_t of a specified DVA", abuf_find }, { "logsm_stats", ":", "print log space map statistics of a spa_t", logsm_stats}, { "spa", "?[-cevmMh]\n" "\t-c display spa config\n" "\t-e display vdev statistics\n" "\t-v display vdev information\n" "\t-m display metaslab statistics\n" "\t-M display metaslab group statistics\n" "\t-h display histogram (requires -m or -M)\n", "spa_t summary", spa_print }, { "spa_config", ":", "print spa_t configuration", spa_print_config }, { "spa_space", ":[-b]", "print spa_t on-disk space usage", spa_space }, { "spa_vdevs", ":[-emMh]\n" "\t-e display vdev statistics\n" "\t-m dispaly metaslab statistics\n" "\t-M display metaslab group statistic\n" "\t-h display histogram (requires -m or -M)\n", "given a spa_t, print vdev summary", spa_vdevs }, { "sm_entries", "", "print out space map entries from a buffer decoded", sm_entries}, { "vdev", ":[-remMh]\n" "\t-r display recursively\n" "\t-e display statistics\n" "\t-m display metaslab statistics (top level vdev only)\n" "\t-M display metaslab group statistics (top level vdev only)\n" "\t-h display histogram (requires -m or -M)\n", "vdev_t summary", vdev_print }, { "zio", ":[-cpr]\n" "\t-c display children\n" "\t-p display parents\n" "\t-r display recursively", "zio_t summary", zio_print }, { "zio_state", "?", "print out all zio_t structures on system or " "for a particular pool", zio_state }, { "zfs_blkstats", ":[-v]", "given a spa_t, print block type stats from last scrub", zfs_blkstats }, { "zfs_params", "", "print zfs tunable parameters", zfs_params }, { "zfs_refcount", ":[-r]\n" "\t-r display recently removed references", "print zfs_refcount_t holders", zfs_refcount }, { "zap_leaf", "", "print zap_leaf_phys_t", zap_leaf }, { "zfs_aces", ":[-v]", "print all ACEs from a zfs_acl_t", zfs_acl_dump }, { "zfs_ace", ":[-v]", "print zfs_ace", zfs_ace_print }, { "zfs_ace0", ":[-v]", "print zfs_ace0", zfs_ace0_print }, { "sa_attr_table", ":", "print SA attribute table from sa_os_t", sa_attr_table}, { "sa_attr", ": attr_id", "print SA attribute address when given sa_handle_t", sa_attr_print}, { "zfs_dbgmsg", ":[-var]", "print zfs debug log", dbgmsg}, { "rrwlock", ":", "print rrwlock_t, including readers", rrwlock}, { "metaslab_weight", "weight", "print metaslab weight", metaslab_weight}, { "metaslab_trace", ":", "print metaslab allocation trace records", metaslab_trace}, { "arc_compression_stats", ":[-vabrf]\n" "\t-v verbose, display a linearly scaled histogram\n" "\t-a display ARC_anon state statistics individually\n" "\t-r display ARC_mru state statistics individually\n" "\t-f display ARC_mfu state statistics individually\n" "\t-b display histogram of buffer counts\n", "print a histogram of compressed arc buffer sizes", arc_compression_stats}, { "range_tree", ":", "print entries in range_tree_t", range_tree}, { NULL } }; static const mdb_walker_t walkers[] = { { "txg_list", "given any txg_list_t *, walk all entries in all txgs", txg_list_walk_init, txg_list_walk_step, NULL }, { "txg_list0", "given any txg_list_t *, walk all entries in txg 0", txg_list0_walk_init, txg_list_walk_step, NULL }, { "txg_list1", "given any txg_list_t *, walk all entries in txg 1", txg_list1_walk_init, txg_list_walk_step, NULL }, { "txg_list2", "given any txg_list_t *, walk all entries in txg 2", txg_list2_walk_init, txg_list_walk_step, NULL }, { "txg_list3", "given any txg_list_t *, walk all entries in txg 3", txg_list3_walk_init, txg_list_walk_step, NULL }, { "zio", "walk all zio structures, optionally for a particular spa_t", zio_walk_init, zio_walk_step, NULL }, { "zio_root", "walk all root zio_t structures, optionally for a particular spa_t", zio_walk_init, zio_walk_root_step, NULL }, { "spa", "walk all spa_t entries in the namespace", spa_walk_init, spa_walk_step, NULL }, { "metaslab", "given a spa_t *, walk all metaslab_t structures", metaslab_walk_init, metaslab_walk_step, NULL }, { "multilist", "given a multilist_t *, walk all list_t structures", multilist_walk_init, multilist_walk_step, NULL }, { "zfs_acl_node", "given a zfs_acl_t, walk all zfs_acl_nodes", zfs_acl_node_walk_init, zfs_acl_node_walk_step, NULL }, { "zfs_acl_node_aces", "given a zfs_acl_node_t, walk all ACEs", zfs_acl_node_aces_walk_init, zfs_aces_walk_step, NULL }, { "zfs_acl_node_aces0", "given a zfs_acl_node_t, walk all ACEs as ace_t", zfs_acl_node_aces0_walk_init, zfs_aces_walk_step, NULL }, { "zfs_btree", "given a zfs_btree_t *, walk all entries", btree_walk_init, btree_walk_step, btree_walk_fini }, { NULL } }; static const mdb_modinfo_t modinfo = { MDB_API_VERSION, dcmds, walkers }; const mdb_modinfo_t * _mdb_init(void) { return (&modinfo); }