/* * Copyright (C) 2011-2013 Red Hat, Inc. All rights reserved. * * This file is part of LVM2. * * This copyrighted material is made available to anyone wishing to use, * modify, copy, or redistribute it subject to the terms and conditions * of the GNU Lesser General Public License v.2.1. * * You should have received a copy of the GNU Lesser General Public License * along with this program; if not, write to the Free Software Foundation, * Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA */ #include "lib/misc/lib.h" #include "lib/activate/activate.h" #include "lib/locking/locking.h" #include "lib/mm/memlock.h" #include "lib/metadata/metadata.h" #include "lib/metadata/segtype.h" #include "lib/config/defaults.h" #include "lib/display/display.h" /* TODO: drop unused no_update */ int attach_pool_message(struct lv_segment *pool_seg, dm_thin_message_t type, struct logical_volume *lv, uint32_t delete_id, int no_update) { struct lv_thin_message *tmsg; if (!seg_is_thin_pool(pool_seg)) { log_error(INTERNAL_ERROR "Cannot attach message to non-pool LV %s.", display_lvname(pool_seg->lv)); return 0; } if (pool_has_message(pool_seg, lv, delete_id)) { if (lv) log_error("Message referring LV %s already queued in pool %s.", display_lvname(lv), display_lvname(pool_seg->lv)); else log_error("Delete for device %u already queued in pool %s.", delete_id, display_lvname(pool_seg->lv)); return 0; } if (!(tmsg = dm_pool_alloc(pool_seg->lv->vg->vgmem, sizeof(*tmsg)))) { log_error("Failed to allocate memory for message."); return 0; } switch (type) { case DM_THIN_MESSAGE_CREATE_SNAP: case DM_THIN_MESSAGE_CREATE_THIN: tmsg->u.lv = lv; break; case DM_THIN_MESSAGE_DELETE: tmsg->u.delete_id = delete_id; break; default: log_error(INTERNAL_ERROR "Unsupported message type %u.", type); return 0; } tmsg->type = type; /* If the 1st message is add in non-read-only mode, modify transaction_id */ if (!no_update && dm_list_empty(&pool_seg->thin_messages)) pool_seg->transaction_id++; dm_list_add(&pool_seg->thin_messages, &tmsg->list); log_debug_metadata("Added %s message.", (type == DM_THIN_MESSAGE_CREATE_SNAP || type == DM_THIN_MESSAGE_CREATE_THIN) ? "create" : (type == DM_THIN_MESSAGE_DELETE) ? "delete" : "unknown"); return 1; } int attach_thin_external_origin(struct lv_segment *seg, struct logical_volume *external_lv) { if (seg->external_lv) { log_error(INTERNAL_ERROR "LV %s already has external origin.", display_lvname(seg->lv)); return 0; } seg->external_lv = external_lv; if (external_lv) { if (!add_seg_to_segs_using_this_lv(external_lv, seg)) return_0; external_lv->external_count++; if (external_lv->status & LVM_WRITE) { log_verbose("Setting logical volume \"%s\" read-only.", display_lvname(external_lv)); external_lv->status &= ~LVM_WRITE; } /* FIXME Mark origin read-only? if (lv_is_cache(external_lv)) // read-only corigin of cache LV seg_lv(first_seg(external_lv), 0)->status &= ~LVM_WRITE; */ } return 1; } int detach_thin_external_origin(struct lv_segment *seg) { if (seg->external_lv) { if (!lv_is_external_origin(seg->external_lv)) { log_error(INTERNAL_ERROR "Inconsitent external origin."); return 0; } if (!remove_seg_from_segs_using_this_lv(seg->external_lv, seg)) return_0; seg->external_lv->external_count--; seg->external_lv = NULL; } return 1; } int lv_is_merging_thin_snapshot(const struct logical_volume *lv) { struct lv_segment *seg = first_seg(lv); return (seg && seg->status & MERGING) ? 1 : 0; } /* * Check whether pool has some message queued for LV or for device_id * When LV is NULL and device_id is 0 it just checks for any message. */ int pool_has_message(const struct lv_segment *seg, const struct logical_volume *lv, uint32_t device_id) { const struct lv_thin_message *tmsg; if (!seg_is_thin_pool(seg)) { log_error(INTERNAL_ERROR "LV %s is not pool.", display_lvname(seg->lv)); return 0; } if (!lv && !device_id) return !dm_list_empty(&seg->thin_messages); dm_list_iterate_items(tmsg, &seg->thin_messages) { switch (tmsg->type) { case DM_THIN_MESSAGE_CREATE_SNAP: case DM_THIN_MESSAGE_CREATE_THIN: if (tmsg->u.lv == lv) return 1; break; case DM_THIN_MESSAGE_DELETE: if (tmsg->u.delete_id == device_id) return 1; break; default: break; } } return 0; } int pool_is_active(const struct logical_volume *lv) { struct lvinfo info; const struct seg_list *sl; if (!lv_is_thin_pool(lv)) { log_error(INTERNAL_ERROR "pool_is_active called with non-pool volume %s.", display_lvname(lv)); return 0; } /* On clustered VG, query every related thin pool volume */ if (vg_is_clustered(lv->vg)) { if (lv_is_active(lv)) return 1; dm_list_iterate_items(sl, &lv->segs_using_this_lv) if (lv_is_active(sl->seg->lv)) { log_debug_activation("Pool's thin volume %s is active.", display_lvname(sl->seg->lv)); return 1; } } else if (lv_info(lv->vg->cmd, lv, 1, &info, 0, 0) && info.exists) return 1; /* Non clustered VG - just checks for '-tpool' */ return 0; } int thin_pool_feature_supported(const struct logical_volume *lv, int feature) { static unsigned attr = 0U; struct lv_segment *seg; if (!lv_is_thin_pool(lv)) { log_error(INTERNAL_ERROR "LV %s is not thin pool.", display_lvname(lv)); return 0; } seg = first_seg(lv); if ((attr == 0U) && activation() && seg->segtype && seg->segtype->ops->target_present && !seg->segtype->ops->target_present(lv->vg->cmd, NULL, &attr)) { log_error("%s: Required device-mapper target(s) not " "detected in your kernel.", lvseg_name(seg)); return 0; } return (attr & feature) ? 1 : 0; } int pool_metadata_min_threshold(const struct lv_segment *pool_seg) { /* * Hardcoded minimal requirement for thin pool target. * * In the metadata LV there should be minimum from either 4MiB of free space * or at least 25% of free space, which applies when the size of thin pool's * metadata is less than 16MiB. */ const dm_percent_t meta_min = DM_PERCENT_1 * 25; dm_percent_t meta_free = dm_make_percent(((4096 * 1024) >> SECTOR_SHIFT), pool_seg->metadata_lv->size); if (meta_min < meta_free) meta_free = meta_min; return DM_PERCENT_100 - meta_free; } int pool_below_threshold(const struct lv_segment *pool_seg) { struct cmd_context *cmd = pool_seg->lv->vg->cmd; dm_percent_t percent; dm_percent_t min_threshold = pool_metadata_min_threshold(pool_seg); dm_percent_t threshold = DM_PERCENT_1 * find_config_tree_int(cmd, activation_thin_pool_autoextend_threshold_CFG, lv_config_profile(pool_seg->lv)); /* Data */ if (!lv_thin_pool_percent(pool_seg->lv, 0, &percent)) return_0; if (percent > threshold || percent >= DM_PERCENT_100) { log_debug("Threshold configured for free data space in " "thin pool %s has been reached (%s%% >= %s%%).", display_lvname(pool_seg->lv), display_percent(cmd, percent), display_percent(cmd, threshold)); return 0; } /* Metadata */ if (!lv_thin_pool_percent(pool_seg->lv, 1, &percent)) return_0; if (percent >= min_threshold) { log_warn("WARNING: Remaining free space in metadata of thin pool %s " "is too low (%s%% >= %s%%). " "Resize is recommended.", display_lvname(pool_seg->lv), display_percent(cmd, percent), display_percent(cmd, min_threshold)); return 0; } if (percent > threshold) { log_debug("Threshold configured for free metadata space in " "thin pool %s has been reached (%s%% > %s%%).", display_lvname(pool_seg->lv), display_percent(cmd, percent), display_percent(cmd, threshold)); return 0; } return 1; } /* * Detect overprovisioning and check lvm2 is configured for auto resize. * * If passed LV is thin volume/pool, check first only this one for overprovisiong. * Lots of test combined together. * Test is not detecting status of dmeventd, too complex for now... */ int pool_check_overprovisioning(const struct logical_volume *lv) { const struct lv_list *lvl; const struct seg_list *sl; const struct logical_volume *pool_lv = NULL; struct cmd_context *cmd = lv->vg->cmd; const char *txt = ""; uint64_t thinsum = 0, poolsum = 0, sz = ~0; int threshold, max_threshold = 0; int percent, min_percent = 100; int more_pools = 0; /* When passed thin volume, check related pool first */ if (lv_is_thin_volume(lv)) pool_lv = first_seg(lv)->pool_lv; else if (lv_is_thin_pool(lv)) pool_lv = lv; if (pool_lv) { poolsum += pool_lv->size; dm_list_iterate_items(sl, &pool_lv->segs_using_this_lv) thinsum += sl->seg->lv->size; if (thinsum <= poolsum) return 1; /* All thins fit into this thin pool */ } /* Sum all thins and all thin pools in VG */ dm_list_iterate_items(lvl, &lv->vg->lvs) { if (!lv_is_thin_pool(lvl->lv)) continue; threshold = find_config_tree_int(cmd, activation_thin_pool_autoextend_threshold_CFG, lv_config_profile(lvl->lv)); percent = find_config_tree_int(cmd, activation_thin_pool_autoextend_percent_CFG, lv_config_profile(lvl->lv)); if (threshold > max_threshold) max_threshold = threshold; if (percent < min_percent) min_percent = percent; if (lvl->lv == pool_lv) continue; /* Skip iteration for already checked thin pool */ more_pools++; poolsum += lvl->lv->size; dm_list_iterate_items(sl, &lvl->lv->segs_using_this_lv) thinsum += sl->seg->lv->size; } if (thinsum <= poolsum) return 1; /* All fits for all pools */ if ((sz = vg_size(lv->vg)) < thinsum) /* Thin sum size is above VG size */ txt = " and the size of whole volume group"; else if ((sz = vg_free(lv->vg)) < thinsum) /* Thin sum size is more then free space in a VG */ txt = !sz ? "" : " and the amount of free space in volume group"; else if ((max_threshold > 99) || !min_percent) /* There is some free space in VG, but it is not configured * for growing - threshold is 100% or percent is 0% */ sz = poolsum; else sz = UINT64_C(~0); /* No warning */ if (sz != UINT64_C(~0)) { log_warn("WARNING: Sum of all thin volume sizes (%s) exceeds the " "size of thin pool%s%s%s (%s).", display_size(cmd, thinsum), more_pools ? "" : " ", more_pools ? "s" : display_lvname(pool_lv), txt, (sz > 0) ? display_size(cmd, sz) : "no free space in volume group"); if (max_threshold > 99 || !min_percent) log_print_unless_silent("WARNING: You have not turned on protection against thin pools running out of space."); if (max_threshold > 99) log_print_unless_silent("WARNING: Set activation/thin_pool_autoextend_threshold below 100 to trigger automatic extension of thin pools before they get full."); if (!min_percent) log_print_unless_silent("WARNING: Set activation/thin_pool_autoextend_percent above 0 to specify by how much to extend thin pools reaching the threshold."); /* FIXME Also warn if there isn't sufficient free space for one pool extension to occur? */ } return 1; } /* * Validate given external origin could be used with thin pool */ int pool_supports_external_origin(const struct lv_segment *pool_seg, const struct logical_volume *external_lv) { uint32_t csize = pool_seg->chunk_size; if (((external_lv->size < csize) || (external_lv->size % csize)) && !thin_pool_feature_supported(pool_seg->lv, THIN_FEATURE_EXTERNAL_ORIGIN_EXTEND)) { log_error("Can't use \"%s\" as external origin with \"%s\" pool. " "Size %s is not a multiple of pool's chunk size %s.", display_lvname(external_lv), display_lvname(pool_seg->lv), display_size(external_lv->vg->cmd, external_lv->size), display_size(external_lv->vg->cmd, csize)); return 0; } return 1; } struct logical_volume *find_pool_lv(const struct logical_volume *lv) { struct lv_segment *seg; if (!(seg = first_seg(lv))) { log_error("LV %s has no segment.", display_lvname(lv)); return NULL; } if (!(seg = find_pool_seg(seg))) return_NULL; return seg->lv; } /* * Find a free device_id for given thin_pool segment. * * \return * Free device id, or 0 if free device_id is not found. * * FIXME: Improve naive search and keep the value cached * and updated during VG lifetime (so no const for lv_segment) */ uint32_t get_free_pool_device_id(struct lv_segment *thin_pool_seg) { uint32_t max_id = 0; struct seg_list *sl; if (!seg_is_thin_pool(thin_pool_seg)) { log_error(INTERNAL_ERROR "Segment in %s is not a thin pool segment.", display_lvname(thin_pool_seg->lv)); return 0; } dm_list_iterate_items(sl, &thin_pool_seg->lv->segs_using_this_lv) if (sl->seg->device_id > max_id) max_id = sl->seg->device_id; if (++max_id > DM_THIN_MAX_DEVICE_ID) { /* FIXME Find empty holes instead of aborting! */ log_error("Cannot find free device_id."); return 0; } log_debug_metadata("Found free pool device_id %u.", max_id); return max_id; } static int _check_pool_create(const struct logical_volume *lv) { const struct lv_thin_message *lmsg; struct lvinfo info; dm_list_iterate_items(lmsg, &first_seg(lv)->thin_messages) { if (lmsg->type != DM_THIN_MESSAGE_CREATE_THIN) continue; /* When creating new thin LV, check for size would be needed */ if (!lv_info(lv->vg->cmd, lv, 1, &info, 0, 0) || !info.exists) { log_error("Pool %s needs to be locally active for threshold check.", display_lvname(lv)); return 0; } if (!pool_below_threshold(first_seg(lv))) { log_error("Free space in pool %s is above threshold, new volumes are not allowed.", display_lvname(lv)); return 0; } break; } return 1; } int update_pool_lv(struct logical_volume *lv, int activate) { int monitored; int ret = 1; if (!lv_is_thin_pool(lv)) { log_error(INTERNAL_ERROR "Updated LV %s is not pool.", display_lvname(lv)); return 0; } if (dm_list_empty(&(first_seg(lv)->thin_messages))) return 1; /* No messages */ if (activate) { /* If the pool is not active, do activate deactivate */ monitored = dmeventd_monitor_mode(); init_dmeventd_monitor(DMEVENTD_MONITOR_IGNORE); if (!lv_is_active(lv)) { /* * FIXME: * Rewrite activation code to handle whole tree of thinLVs * as this version has major problem when it does not know * which Node has pool active. */ if (!activate_lv(lv->vg->cmd, lv)) { (void) init_dmeventd_monitor(monitored); return_0; } if (!lv_is_active(lv)) { (void) init_dmeventd_monitor(monitored); log_error("Cannot activate thin pool %s, perhaps skipped in lvm.conf volume_list?", display_lvname(lv)); return 0; } } else activate = 0; /* Was already active */ if (!(ret = _check_pool_create(lv))) stack; /* Safety guard, needs local presence of thin-pool target */ else { if (!(ret = suspend_lv_origin(lv->vg->cmd, lv))) /* Send messages */ log_error("Failed to suspend %s with queued messages.", display_lvname(lv)); /* Even failing suspend needs resume */ if (!resume_lv_origin(lv->vg->cmd, lv)) { log_error("Failed to resume %s.", display_lvname(lv)); ret = 0; } } if (!sync_local_dev_names(lv->vg->cmd)) { log_error("Failed to sync local devices LV %s.", display_lvname(lv)); return 0; } if (activate && !deactivate_lv(lv->vg->cmd, lv)) { log_error("Failed to deactivate %s.", display_lvname(lv)); ret = 0; } init_dmeventd_monitor(monitored); /* Unlock memory if possible */ memlock_unlock(lv->vg->cmd); if (!ret) return_0; } dm_list_init(&(first_seg(lv)->thin_messages)); if (!vg_write(lv->vg) || !vg_commit(lv->vg)) return_0; return ret; } static uint64_t _estimate_size(uint32_t data_extents, uint32_t extent_size, uint64_t size) { /* * nr_pool_blocks = data_size / metadata_size * chunk_size = nr_pool_blocks * 64b / sector_size */ return (uint64_t) data_extents * extent_size / (size * (SECTOR_SIZE / UINT64_C(64))); } /* Estimate thin pool metadata size from data size and chunks size (in sector units) */ static uint64_t _estimate_metadata_size(uint32_t data_extents, uint32_t extent_size, uint32_t chunk_size) { return _estimate_size(data_extents, extent_size, chunk_size); } /* Estimate maximal supportable thin pool data size for given chunk_size */ static uint64_t _estimate_max_data_size(uint32_t chunk_size) { return chunk_size * (DEFAULT_THIN_POOL_MAX_METADATA_SIZE * 2) * SECTOR_SIZE / UINT64_C(64); } /* Estimate thin pool chunk size from data and metadata size (in sector units) */ static uint32_t _estimate_chunk_size(uint32_t data_extents, uint32_t extent_size, uint64_t metadata_size, int attr) { uint32_t chunk_size = _estimate_size(data_extents, extent_size, metadata_size); const uint32_t BIG_CHUNK = 2 * DEFAULT_THIN_POOL_CHUNK_SIZE_ALIGNED - 1; if ((attr & THIN_FEATURE_BLOCK_SIZE) && (chunk_size > BIG_CHUNK) && (chunk_size < (UINT32_MAX - BIG_CHUNK))) chunk_size = (chunk_size + BIG_CHUNK) & ~BIG_CHUNK; else /* Round up to nearest power of 2 of 32-bit */ chunk_size = 1 << (32 - clz(chunk_size - 1)); if (chunk_size < DM_THIN_MIN_DATA_BLOCK_SIZE) chunk_size = DM_THIN_MIN_DATA_BLOCK_SIZE; else if (chunk_size > DM_THIN_MAX_DATA_BLOCK_SIZE) chunk_size = DM_THIN_MAX_DATA_BLOCK_SIZE; return chunk_size; } int get_default_allocation_thin_pool_chunk_size(struct cmd_context *cmd, struct profile *profile, uint32_t *chunk_size, int *chunk_size_calc_method) { const char *str; if (!(str = find_config_tree_str(cmd, allocation_thin_pool_chunk_size_policy_CFG, profile))) { log_error(INTERNAL_ERROR "Cannot find configuration."); return 0; } if (!strcasecmp(str, "generic")) { *chunk_size = DEFAULT_THIN_POOL_CHUNK_SIZE * 2; *chunk_size_calc_method = THIN_CHUNK_SIZE_CALC_METHOD_GENERIC; } else if (!strcasecmp(str, "performance")) { *chunk_size = DEFAULT_THIN_POOL_CHUNK_SIZE_PERFORMANCE * 2; *chunk_size_calc_method = THIN_CHUNK_SIZE_CALC_METHOD_PERFORMANCE; } else { log_error("Thin pool chunk size calculation policy \"%s\" is unrecognised.", str); return 0; } return 1; } int update_thin_pool_params(struct cmd_context *cmd, struct profile *profile, uint32_t extent_size, const struct segment_type *segtype, unsigned attr, uint32_t pool_data_extents, uint32_t *pool_metadata_extents, int *chunk_size_calc_method, uint32_t *chunk_size, thin_discards_t *discards, thin_zero_t *zero_new_blocks) { uint64_t pool_metadata_size = (uint64_t) *pool_metadata_extents * extent_size; uint32_t estimate_chunk_size; uint64_t max_pool_data_size; const char *str; if (!*chunk_size && find_config_tree_node(cmd, allocation_thin_pool_chunk_size_CFG, profile)) *chunk_size = find_config_tree_int(cmd, allocation_thin_pool_chunk_size_CFG, profile) * 2; if (*chunk_size && !(attr & THIN_FEATURE_BLOCK_SIZE) && !is_power_of_2(*chunk_size)) { log_error("Chunk size must be a power of 2 for this thin target version."); return 0; } if ((*discards == THIN_DISCARDS_UNSELECTED) && find_config_tree_node(cmd, allocation_thin_pool_discards_CFG, profile)) { if (!(str = find_config_tree_str(cmd, allocation_thin_pool_discards_CFG, profile))) { log_error(INTERNAL_ERROR "Could not find configuration."); return 0; } if (!set_pool_discards(discards, str)) return_0; } if ((*zero_new_blocks == THIN_ZERO_UNSELECTED) && find_config_tree_node(cmd, allocation_thin_pool_zero_CFG, profile)) *zero_new_blocks = find_config_tree_bool(cmd, allocation_thin_pool_zero_CFG, profile) ? THIN_ZERO_YES : THIN_ZERO_NO; if (!pool_metadata_size) { if (!*chunk_size) { if (!get_default_allocation_thin_pool_chunk_size(cmd, profile, chunk_size, chunk_size_calc_method)) return_0; pool_metadata_size = _estimate_metadata_size(pool_data_extents, extent_size, *chunk_size); /* Check if we should eventually use bigger chunk size */ while ((pool_metadata_size > (DEFAULT_THIN_POOL_OPTIMAL_METADATA_SIZE * 2)) && (*chunk_size < DM_THIN_MAX_DATA_BLOCK_SIZE)) { *chunk_size <<= 1; pool_metadata_size >>= 1; } log_verbose("Setting chunk size to %s.", display_size(cmd, *chunk_size)); } else { pool_metadata_size = _estimate_metadata_size(pool_data_extents, extent_size, *chunk_size); if (pool_metadata_size > (DEFAULT_THIN_POOL_MAX_METADATA_SIZE * 2)) { /* Suggest bigger chunk size */ estimate_chunk_size = _estimate_chunk_size(pool_data_extents, extent_size, (DEFAULT_THIN_POOL_MAX_METADATA_SIZE * 2), attr); log_warn("WARNING: Chunk size is too small for pool, suggested minimum is %s.", display_size(cmd, estimate_chunk_size)); } } /* Round up to extent size silently */ if (pool_metadata_size % extent_size) pool_metadata_size += extent_size - pool_metadata_size % extent_size; } else { estimate_chunk_size = _estimate_chunk_size(pool_data_extents, extent_size, pool_metadata_size, attr); /* Check to eventually use bigger chunk size */ if (!*chunk_size) { *chunk_size = estimate_chunk_size; log_verbose("Setting chunk size %s.", display_size(cmd, *chunk_size)); } else if (*chunk_size < estimate_chunk_size) { /* Suggest bigger chunk size */ log_warn("WARNING: Chunk size is smaller then suggested minimum size %s.", display_size(cmd, estimate_chunk_size)); } } max_pool_data_size = _estimate_max_data_size(*chunk_size); if ((max_pool_data_size / extent_size) < pool_data_extents) { log_error("Selected chunk size %s cannot address more then %s of thin pool data space.", display_size(cmd, *chunk_size), display_size(cmd, max_pool_data_size)); return 0; } log_print_unless_silent("Thin pool volume with chunk size %s can address at most %s of data.", display_size(cmd, *chunk_size), display_size(cmd, max_pool_data_size)); if (!validate_thin_pool_chunk_size(cmd, *chunk_size)) return_0; if (pool_metadata_size > (2 * DEFAULT_THIN_POOL_MAX_METADATA_SIZE)) { pool_metadata_size = 2 * DEFAULT_THIN_POOL_MAX_METADATA_SIZE; if (*pool_metadata_extents) log_warn("WARNING: Maximum supported pool metadata size is %s.", display_size(cmd, pool_metadata_size)); } else if (pool_metadata_size < (2 * DEFAULT_THIN_POOL_MIN_METADATA_SIZE)) { pool_metadata_size = 2 * DEFAULT_THIN_POOL_MIN_METADATA_SIZE; if (*pool_metadata_extents) log_warn("WARNING: Minimum supported pool metadata size is %s.", display_size(cmd, pool_metadata_size)); } if (!(*pool_metadata_extents = extents_from_size(cmd, pool_metadata_size, extent_size))) return_0; if ((uint64_t) *chunk_size > (uint64_t) pool_data_extents * extent_size) { log_error("Size of %s data volume cannot be smaller than chunk size %s.", segtype->name, display_size(cmd, *chunk_size)); return 0; } if ((*discards == THIN_DISCARDS_UNSELECTED) && !set_pool_discards(discards, DEFAULT_THIN_POOL_DISCARDS)) return_0; if (*zero_new_blocks == THIN_ZERO_UNSELECTED) { *zero_new_blocks = (DEFAULT_THIN_POOL_ZERO) ? THIN_ZERO_YES : THIN_ZERO_NO; log_verbose("%s pool zeroing on default.", (*zero_new_blocks == THIN_ZERO_YES) ? "Enabling" : "Disabling"); } if ((*zero_new_blocks == THIN_ZERO_YES) && (*chunk_size >= DEFAULT_THIN_POOL_CHUNK_SIZE_PERFORMANCE * 2)) { log_warn("WARNING: Pool zeroing and %s large chunk size slows down thin provisioning.", display_size(cmd, *chunk_size)); log_warn("WARNING: Consider disabling zeroing (-Zn) or using smaller chunk size (<%s).", display_size(cmd, DEFAULT_THIN_POOL_CHUNK_SIZE_PERFORMANCE * 2)); } log_verbose("Preferred pool metadata size %s.", display_size(cmd, (uint64_t)*pool_metadata_extents * extent_size)); return 1; } int set_pool_discards(thin_discards_t *discards, const char *str) { if (!strcasecmp(str, "passdown")) *discards = THIN_DISCARDS_PASSDOWN; else if (!strcasecmp(str, "nopassdown")) *discards = THIN_DISCARDS_NO_PASSDOWN; else if (!strcasecmp(str, "ignore")) *discards = THIN_DISCARDS_IGNORE; else { log_error("Thin pool discards type \"%s\" is unknown.", str); return 0; } return 1; } const char *get_pool_discards_name(thin_discards_t discards) { switch (discards) { case THIN_DISCARDS_PASSDOWN: return "passdown"; case THIN_DISCARDS_NO_PASSDOWN: return "nopassdown"; case THIN_DISCARDS_IGNORE: return "ignore"; default: log_error(INTERNAL_ERROR "Unknown discards type encountered."); return "unknown"; } } int lv_is_thin_origin(const struct logical_volume *lv, unsigned int *snap_count) { struct seg_list *segl; int r = 0; if (snap_count) *snap_count = 0; if (lv_is_thin_volume(lv)) dm_list_iterate_items(segl, &lv->segs_using_this_lv) if (segl->seg->origin == lv) { r = 1; if (!snap_count) break;/* not interested in number of snapshots */ (*snap_count)++; } return r; } int lv_is_thin_snapshot(const struct logical_volume *lv) { struct lv_segment *seg; if (!lv_is_thin_volume(lv)) return 0; if ((seg = first_seg(lv)) && (seg->origin || seg->external_lv)) return 1; return 0; } /* * Explict check of new thin pool for usability * * Allow use of thin pools by external apps. When lvm2 metadata has * transaction_id == 0 for a new thin pool, it will explicitely validate * the pool is still unused. * * To prevent lvm2 to create thin volumes in externally used thin pools * simply increment its transaction_id. */ int check_new_thin_pool(const struct logical_volume *pool_lv) { struct cmd_context *cmd = pool_lv->vg->cmd; uint64_t transaction_id; /* For transaction_id check LOCAL activation is required */ if (!activate_lv(cmd, pool_lv)) { log_error("Aborting. Failed to locally activate thin pool %s.", display_lvname(pool_lv)); return 0; } /* With volume lists, check pool really is locally active */ if (!lv_thin_pool_transaction_id(pool_lv, &transaction_id)) { log_error("Cannot read thin pool %s transaction id locally, perhaps skipped in lvm.conf volume_list?", display_lvname(pool_lv)); return 0; } /* Require pool to have same transaction_id as new */ if (first_seg(pool_lv)->transaction_id != transaction_id) { log_error("Cannot use thin pool %s with transaction id " FMTu64 " for thin volumes. " "Expected transaction id %" PRIu64 ".", display_lvname(pool_lv), transaction_id, first_seg(pool_lv)->transaction_id); return 0; } log_verbose("Deactivating public thin pool %s.", display_lvname(pool_lv)); /* Prevent any 'race' with in-use thin pool and always deactivate */ if (!deactivate_lv(pool_lv->vg->cmd, pool_lv)) { log_error("Aborting. Could not deactivate thin pool %s.", display_lvname(pool_lv)); return 0; } return 1; } int validate_thin_pool_chunk_size(struct cmd_context *cmd, uint32_t chunk_size) { const uint32_t min_size = DM_THIN_MIN_DATA_BLOCK_SIZE; const uint32_t max_size = DM_THIN_MAX_DATA_BLOCK_SIZE; int r = 1; if ((chunk_size < min_size) || (chunk_size > max_size)) { log_error("Thin pool chunk size %s is not in the range %s to %s.", display_size(cmd, chunk_size), display_size(cmd, min_size), display_size(cmd, max_size)); r = 0; } if (chunk_size & (min_size - 1)) { log_error("Thin pool chunk size %s must be a multiple of %s.", display_size(cmd, chunk_size), display_size(cmd, min_size)); r = 0; } return r; } uint64_t estimate_thin_pool_metadata_size(uint32_t data_extents, uint32_t extent_size, uint32_t chunk_size) { uint64_t sz = _estimate_metadata_size(data_extents, extent_size, chunk_size); if (sz > (2 * DEFAULT_THIN_POOL_MAX_METADATA_SIZE)) sz = 2 * DEFAULT_THIN_POOL_MAX_METADATA_SIZE; else if (sz < (2 * DEFAULT_THIN_POOL_MIN_METADATA_SIZE)) sz = 2 * DEFAULT_THIN_POOL_MIN_METADATA_SIZE; return sz; }