/* * Copyright (C) 2014-2015 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.h" #include "metadata.h" #include "locking.h" #include "lvm-string.h" #include "toolcontext.h" #include "display.h" #include "segtype.h" #include "activate.h" #include "defaults.h" #include "lv_alloc.h" #include "lvm-signal.h" /* https://github.com/jthornber/thin-provisioning-tools/blob/master/caching/cache_metadata_size.cc */ #define DM_TRANSACTION_OVERHEAD 4096 /* KiB */ #define DM_BYTES_PER_BLOCK 16 /* bytes */ #define DM_HINT_OVERHEAD_PER_BLOCK 8 /* bytes */ #define DM_MAX_HINT_WIDTH (4+16) /* bytes. FIXME Configurable? */ const char *display_cache_mode(const struct lv_segment *seg) { if (seg_is_cache(seg)) seg = first_seg(seg->pool_lv); if (!seg_is_cache_pool(seg) || (seg->cache_mode == CACHE_MODE_UNSELECTED)) return ""; return get_cache_mode_name(seg); } const char *get_cache_mode_name(const struct lv_segment *pool_seg) { switch (pool_seg->cache_mode) { default: log_error(INTERNAL_ERROR "Cache pool %s has undefined cache mode, using writethrough instead.", display_lvname(pool_seg->lv)); /* Fall through */ case CACHE_MODE_WRITETHROUGH: return "writethrough"; case CACHE_MODE_WRITEBACK: return "writeback"; case CACHE_MODE_PASSTHROUGH: return "passthrough"; } } int set_cache_mode(cache_mode_t *mode, const char *cache_mode) { if (!strcasecmp(cache_mode, "writethrough")) *mode = CACHE_MODE_WRITETHROUGH; else if (!strcasecmp(cache_mode, "writeback")) *mode = CACHE_MODE_WRITEBACK; else if (!strcasecmp(cache_mode, "passthrough")) *mode = CACHE_MODE_PASSTHROUGH; else { log_error("Unknown cache mode: %s.", cache_mode); return 0; } return 1; } int cache_set_cache_mode(struct lv_segment *seg, cache_mode_t mode) { struct cmd_context *cmd = seg->lv->vg->cmd; struct profile *profile = seg->lv->profile; const char *str; int id; if (seg_is_cache(seg)) seg = first_seg(seg->pool_lv); else if (seg_is_cache_pool(seg)) { if (mode == CACHE_MODE_UNSELECTED) return 1; /* Defaults only for cache */ } else { log_error(INTERNAL_ERROR "Cannot set cache mode for non cache volume %s.", display_lvname(seg->lv)); return 0; } if (mode != CACHE_MODE_UNSELECTED) { seg->cache_mode = mode; return 1; } if (seg->cache_mode != CACHE_MODE_UNSELECTED) return 1; /* Default already set in cache pool */ /* Figure default settings from config/profiles */ id = allocation_cache_mode_CFG; /* If present, check backward compatible settings */ if (!find_config_node(cmd, cmd->cft, id) && find_config_node(cmd, cmd->cft, allocation_cache_pool_cachemode_CFG)) id = allocation_cache_pool_cachemode_CFG; if (!(str = find_config_tree_str(cmd, id, profile))) { log_error(INTERNAL_ERROR "Cache mode is not determined."); return 0; } if (!(set_cache_mode(&seg->cache_mode, str))) return_0; return 1; } /* * At least warn a user if certain cache stacks may present some problems */ void cache_check_for_warns(const struct lv_segment *seg) { struct logical_volume *origin_lv = seg_lv(seg, 0); if (lv_is_raid(origin_lv) && first_seg(seg->pool_lv)->cache_mode == CACHE_MODE_WRITEBACK) log_warn("WARNING: Data redundancy is lost with writeback " "caching of raid logical volume!"); if (lv_is_thin_pool_data(seg->lv)) log_warn("WARNING: Cached thin pool's data cannot be currently " "resized and require manual uncache before resize!"); } /* * Returns minimum size of cache metadata volume for give data and chunk size * (all values in sector) * Default meta size is: (Overhead + mapping size + hint size) */ static uint64_t _cache_min_metadata_size(uint64_t data_size, uint32_t chunk_size) { uint64_t min_meta_size; min_meta_size = data_size / chunk_size; /* nr_chunks */ min_meta_size *= (DM_BYTES_PER_BLOCK + DM_MAX_HINT_WIDTH + DM_HINT_OVERHEAD_PER_BLOCK); min_meta_size = (min_meta_size + (SECTOR_SIZE - 1)) >> SECTOR_SHIFT; /* in sectors */ min_meta_size += DM_TRANSACTION_OVERHEAD * (1024 >> SECTOR_SHIFT); return min_meta_size; } int update_cache_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) { uint64_t min_meta_size; uint64_t pool_metadata_size = (uint64_t) *pool_metadata_extents * extent_size; uint64_t pool_data_size = (uint64_t) pool_data_extents * extent_size; const uint64_t max_chunks = get_default_allocation_cache_pool_max_chunks_CFG(cmd, profile); /* min chunk size in a multiple of DM_CACHE_MIN_DATA_BLOCK_SIZE */ uint64_t min_chunk_size = (((pool_data_size + max_chunks - 1) / max_chunks + DM_CACHE_MIN_DATA_BLOCK_SIZE - 1) / DM_CACHE_MIN_DATA_BLOCK_SIZE) * DM_CACHE_MIN_DATA_BLOCK_SIZE; if (!*chunk_size) { if (!(*chunk_size = find_config_tree_int(cmd, allocation_cache_pool_chunk_size_CFG, profile) * 2)) *chunk_size = get_default_allocation_cache_pool_chunk_size_CFG(cmd, profile); if (*chunk_size < min_chunk_size) { /* * When using more then 'standard' default, * keep user informed he might be using things in untintended direction */ log_print_unless_silent("Using %s chunk size instead of default %s, " "so cache pool has less then " FMTu64 " chunks.", display_size(cmd, min_chunk_size), display_size(cmd, *chunk_size), max_chunks); *chunk_size = min_chunk_size; } else log_verbose("Setting chunk size to %s.", display_size(cmd, *chunk_size)); } else if (*chunk_size < min_chunk_size) { log_error("Chunk size %s is less then required minimal chunk size %s " "for a cache pool of %s size and limit " FMTu64 " chunks.", display_size(cmd, *chunk_size), display_size(cmd, min_chunk_size), display_size(cmd, pool_data_size), max_chunks); log_error("To allow use of more chunks, see setting allocation/cache_pool_max_chunks."); return 0; } if (!validate_cache_chunk_size(cmd, *chunk_size)) return_0; min_meta_size = _cache_min_metadata_size((uint64_t) pool_data_extents * extent_size, *chunk_size); /* Round up to extent size */ if (min_meta_size % extent_size) min_meta_size += extent_size - min_meta_size % extent_size; if (!pool_metadata_size) pool_metadata_size = min_meta_size; if (pool_metadata_size > (2 * DEFAULT_CACHE_POOL_MAX_METADATA_SIZE)) { pool_metadata_size = 2 * DEFAULT_CACHE_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 < min_meta_size) { if (*pool_metadata_extents) log_warn("WARNING: Minimum required pool metadata size is %s " "(needs extra %s).", display_size(cmd, min_meta_size), display_size(cmd, min_meta_size - pool_metadata_size)); pool_metadata_size = min_meta_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; } log_verbose("Preferred pool metadata size %s.", display_size(cmd, (uint64_t)*pool_metadata_extents * extent_size)); return 1; } /* * Validate if existing cache-pool can be used with given chunk size * i.e. cache-pool metadata size fits all info. */ int validate_lv_cache_chunk_size(struct logical_volume *pool_lv, uint32_t chunk_size) { struct volume_group *vg = pool_lv->vg; const uint64_t max_chunks = get_default_allocation_cache_pool_max_chunks_CFG(vg->cmd, pool_lv->profile); uint64_t min_size = _cache_min_metadata_size(pool_lv->size, chunk_size); uint64_t chunks = pool_lv->size / chunk_size; int r = 1; if (min_size > first_seg(pool_lv)->metadata_lv->size) { log_error("Cannot use chunk size %s with cache pool %s metadata size %s.", display_size(vg->cmd, chunk_size), display_lvname(pool_lv), display_size(vg->cmd, first_seg(pool_lv)->metadata_lv->size)); log_error("Minimal size for cache pool %s metadata with chunk size %s would be %s.", display_lvname(pool_lv), display_size(vg->cmd, chunk_size), display_size(vg->cmd, min_size)); r = 0; } if (chunks > max_chunks) { log_error("Cannot use too small chunk size %s with cache pool %s data volume size %s.", display_size(vg->cmd, chunk_size), display_lvname(pool_lv), display_size(pool_lv->vg->cmd, pool_lv->size)); log_error("Maximum configured chunks for a cache pool is " FMTu64 ".", max_chunks); log_error("Use smaller cache pool (<%s) or bigger cache chunk size (>=%s) or enable higher " "values in 'allocation/cache_pool_max_chunks'.", display_size(vg->cmd, chunk_size * max_chunks), display_size(vg->cmd, pool_lv->size / max_chunks)); r = 0; } return r; } /* * Validate arguments for converting origin into cached volume with given cache pool. * * Always validates origin_lv, and when it is known also cache pool_lv */ int validate_lv_cache_create_pool(const struct logical_volume *pool_lv) { struct lv_segment *seg; if (!lv_is_cache_pool(pool_lv)) { log_error("Logical volume %s is not a cache pool.", display_lvname(pool_lv)); return 0; } if (lv_is_locked(pool_lv)) { log_error("Cannot use locked cache pool %s.", display_lvname(pool_lv)); return 0; } if (!dm_list_empty(&pool_lv->segs_using_this_lv)) { seg = get_only_segment_using_this_lv(pool_lv); log_error("Logical volume %s is already in use by %s.", display_lvname(pool_lv), seg ? display_lvname(seg->lv) : "another LV"); return 0; } return 1; } int validate_lv_cache_create_origin(const struct logical_volume *origin_lv) { if (lv_is_locked(origin_lv)) { log_error("Cannot use locked origin volume %s.", display_lvname(origin_lv)); return 0; } /* For now we only support conversion of thin pool data volume */ if (!lv_is_visible(origin_lv) && !lv_is_thin_pool_data(origin_lv)) { log_error("Can't convert internal LV %s.", display_lvname(origin_lv)); return 0; } /* * Only linear, striped or raid supported. * FIXME Tidy up all these type restrictions. */ if (lv_is_cache_type(origin_lv) || lv_is_mirror_type(origin_lv) || lv_is_thin_volume(origin_lv) || lv_is_thin_pool_metadata(origin_lv) || lv_is_merging_origin(origin_lv) || lv_is_cow(origin_lv) || lv_is_merging_cow(origin_lv) || lv_is_virtual(origin_lv)) { log_error("Cache is not supported with %s segment type of the original logical volume %s.", lvseg_name(first_seg(origin_lv)), display_lvname(origin_lv)); return 0; } return 1; } int validate_cache_chunk_size(struct cmd_context *cmd, uint32_t chunk_size) { const uint32_t min_size = DM_CACHE_MIN_DATA_BLOCK_SIZE; const uint32_t max_size = DM_CACHE_MAX_DATA_BLOCK_SIZE; int r = 1; if ((chunk_size < min_size) || (chunk_size > max_size)) { log_error("Cache 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("Cache chunk size %s must be a multiple of %s.", display_size(cmd, chunk_size), display_size(cmd, min_size)); r = 0; } return r; } /* * lv_cache_create * @pool * @origin * * Given a cache_pool and an origin, link the two and create a * cached LV. * * Returns: cache LV on success, NULL on failure */ struct logical_volume *lv_cache_create(struct logical_volume *pool_lv, struct logical_volume *origin_lv) { const struct segment_type *segtype; struct cmd_context *cmd = pool_lv->vg->cmd; struct logical_volume *cache_lv = origin_lv; struct lv_segment *seg; if (!validate_lv_cache_create_pool(pool_lv) || !validate_lv_cache_create_origin(cache_lv)) return_NULL; if (lv_is_thin_pool(cache_lv)) cache_lv = seg_lv(first_seg(cache_lv), 0); /* cache _tdata */ if (!(segtype = get_segtype_from_string(cmd, SEG_TYPE_NAME_CACHE))) return_NULL; if (!insert_layer_for_lv(cmd, cache_lv, CACHE, "_corig")) return_NULL; seg = first_seg(cache_lv); seg->segtype = segtype; if (!attach_pool_lv(seg, pool_lv, NULL, NULL, NULL)) return_NULL; if (!seg->lv->profile) /* Inherit profile from cache-pool */ seg->lv->profile = seg->pool_lv->profile; return cache_lv; } /* * Checks cache status and loops until there are not dirty blocks * Set 1 to *is_clean when there are no dirty blocks on return. */ int lv_cache_wait_for_clean(struct logical_volume *cache_lv, int *is_clean) { const struct logical_volume *lock_lv = lv_lock_holder(cache_lv); struct lv_segment *cache_seg = first_seg(cache_lv); struct lv_status_cache *status; int cleaner_policy, writeback; uint64_t dirty_blocks; *is_clean = 0; //FIXME: use polling to do this... for (;;) { sigint_allow(); sigint_restore(); if (sigint_caught()) { sigint_clear(); log_error("Flushing of %s aborted.", display_lvname(cache_lv)); if (cache_seg->cleaner_policy) { cache_seg->cleaner_policy = 0; /* Restore normal table */ if (!lv_update_and_reload_origin(cache_lv)) stack; } return 0; } if (!lv_cache_status(cache_lv, &status)) return_0; if (status->cache->fail) { dm_pool_destroy(status->mem); log_warn("WARNING: Skippping flush for failed cache %s.", display_lvname(cache_lv)); return 1; } cleaner_policy = !strcmp(status->cache->policy_name, "cleaner"); dirty_blocks = status->cache->dirty_blocks; writeback = (status->cache->feature_flags & DM_CACHE_FEATURE_WRITEBACK); dm_pool_destroy(status->mem); /* Only clear when policy is Clear or mode != writeback */ if (!dirty_blocks && (cleaner_policy || !writeback)) break; log_print_unless_silent("Flushing " FMTu64 " blocks for cache %s.", dirty_blocks, display_lvname(cache_lv)); if (cleaner_policy) { /* TODO: Use centralized place */ sigint_allow(); usleep(500000); sigint_restore(); continue; } if (!(cache_lv->status & LVM_WRITE)) { log_warn("WARNING: Dirty blocks found on read-only cache volume %s.", display_lvname(cache_lv)); /* TODO: can we actually clean something? */ } /* Switch to cleaner policy to flush the cache */ cache_seg->cleaner_policy = 1; /* Reload cache volume with "cleaner" policy */ if (!lv_update_and_reload_origin(cache_lv)) return_0; if (!sync_local_dev_names(cache_lv->vg->cmd)) { log_error("Failed to sync local devices when clearing cache volume %s.", display_lvname(cache_lv)); return 0; } } /* * TODO: add check if extra suspend resume is necessary * ATM this is workaround for missing cache sync when cache gets clean */ if (1) { if (!lv_refresh_suspend_resume(lock_lv)) return_0; if (!sync_local_dev_names(cache_lv->vg->cmd)) { log_error("Failed to sync local devices after final clearing of cache %s.", display_lvname(cache_lv)); return 0; } } cache_seg->cleaner_policy = 0; *is_clean = 1; return 1; } /* * lv_cache_remove * @cache_lv * * Given a cache LV, remove the cache layer. This will unlink * the origin and cache_pool, remove the cache LV layer, and promote * the origin to a usable non-cached LV of the same name as the * given cache_lv. * * Returns: 1 on success, 0 on failure */ int lv_cache_remove(struct logical_volume *cache_lv) { struct lv_segment *cache_seg = first_seg(cache_lv); struct logical_volume *corigin_lv; struct logical_volume *cache_pool_lv; int is_clear; if (!lv_is_cache(cache_lv)) { log_error(INTERNAL_ERROR "LV %s is not cache volume.", display_lvname(cache_lv)); return 0; } if (lv_is_pending_delete(cache_lv)) { log_error(INTERNAL_ERROR "LV %s is already dropped cache volume.", display_lvname(cache_lv)); goto remove; /* Already dropped */ } /* Localy active volume is needed for writeback */ if (!lv_info(cache_lv->vg->cmd, cache_lv, 1, NULL, 0, 0)) { /* Give up any remote locks */ if (!deactivate_lv(cache_lv->vg->cmd, cache_lv)) { log_error("Cannot deactivate remotely active cache volume %s.", display_lvname(cache_lv)); return 0; } switch (first_seg(cache_seg->pool_lv)->cache_mode) { case CACHE_MODE_WRITETHROUGH: case CACHE_MODE_PASSTHROUGH: /* For inactive pass/writethrough just drop cache layer */ corigin_lv = seg_lv(cache_seg, 0); if (!detach_pool_lv(cache_seg)) return_0; if (!remove_layer_from_lv(cache_lv, corigin_lv)) return_0; if (!lv_remove(corigin_lv)) return_0; return 1; default: /* Otherwise localy activate volume to sync dirty blocks */ cache_lv->status |= LV_TEMPORARY; if (!activate_lv_excl_local(cache_lv->vg->cmd, cache_lv) || !lv_is_active_locally(cache_lv)) { log_error("Failed to active cache locally %s.", display_lvname(cache_lv)); return 0; } cache_lv->status &= ~LV_TEMPORARY; } } /* * FIXME: * Before the link can be broken, we must ensure that the * cache has been flushed. This may already be the case * if the cache mode is writethrough (or the cleaner * policy is in place from a previous half-finished attempt * to remove the cache_pool). It could take a long time to * flush the cache - it should probably be done in the background. * * Also, if we do perform the flush in the background and we * happen to also be removing the cache/origin LV, then we * could check if the cleaner policy is in place and simply * remove the cache_pool then without waiting for the flush to * complete. */ if (!lv_cache_wait_for_clean(cache_lv, &is_clear)) return_0; cache_pool_lv = cache_seg->pool_lv; if (!detach_pool_lv(cache_seg)) return_0; /* * Drop layer from cache LV and make _corigin to appear again as regular LV * And use 'existing' _corigin volume to keep reference on cache-pool * This way we still have a way to reference _corigin in dm table and we * know it's been 'cache' LV and we can drop all needed table entries via * activation and deactivation of it. * * This 'cache' LV without origin is temporary LV, which still could be * easily operated by lvm2 commands - it could be activate/deactivated/removed. * However in the dm-table it will use 'error' target for _corigin volume. */ corigin_lv = seg_lv(cache_seg, 0); lv_set_visible(corigin_lv); if (!remove_layer_from_lv(cache_lv, corigin_lv)) return_0; /* Replace 'error' with 'cache' segtype */ cache_seg = first_seg(corigin_lv); if (!(cache_seg->segtype = get_segtype_from_string(corigin_lv->vg->cmd, SEG_TYPE_NAME_CACHE))) return_0; if (!(cache_seg->areas = dm_pool_zalloc(cache_lv->vg->vgmem, sizeof(*cache_seg->areas)))) return_0; if (!set_lv_segment_area_lv(cache_seg, 0, cache_lv, 0, 0)) return_0; cache_seg->area_count = 1; corigin_lv->le_count = cache_lv->le_count; corigin_lv->size = cache_lv->size; corigin_lv->status |= LV_PENDING_DELETE; /* Reattach cache pool */ if (!attach_pool_lv(cache_seg, cache_pool_lv, NULL, NULL, NULL)) return_0; /* Suspend/resume also deactivates deleted LV via support of LV_PENDING_DELETE */ if (!lv_update_and_reload(cache_lv)) return_0; cache_lv = corigin_lv; remove: if (!detach_pool_lv(cache_seg)) return_0; if (!lv_remove(cache_lv)) /* Will use LV_PENDING_DELETE */ return_0; return 1; } int lv_is_cache_origin(const struct logical_volume *lv) { struct lv_segment *seg; /* Make sure there's exactly one segment in segs_using_this_lv! */ if (dm_list_empty(&lv->segs_using_this_lv) || (dm_list_size(&lv->segs_using_this_lv) > 1)) return 0; seg = get_only_segment_using_this_lv(lv); return seg && lv_is_cache(seg->lv) && !lv_is_pending_delete(seg->lv) && (seg_lv(seg, 0) == lv); } static const char *_get_default_cache_policy(struct cmd_context *cmd) { const struct segment_type *segtype = get_segtype_from_string(cmd, SEG_TYPE_NAME_CACHE); unsigned attr = ~0; const char *def = NULL; if (!segtype || !segtype->ops->target_present || !segtype->ops->target_present(cmd, NULL, &attr)) { log_warn("WARNING: Cannot detect default cache policy, using \"" DEFAULT_CACHE_POLICY "\"."); return DEFAULT_CACHE_POLICY; } if (attr & CACHE_FEATURE_POLICY_SMQ) def = "smq"; else if (attr & CACHE_FEATURE_POLICY_MQ) def = "mq"; else { log_error("Default cache policy is not available."); return NULL; } log_debug_metadata("Detected default cache_policy \"%s\".", def); return def; } /* Autodetect best available cache metadata format for a user */ static cache_metadata_format_t _get_default_cache_metadata_format(struct cmd_context *cmd) { const struct segment_type *segtype = get_segtype_from_string(cmd, SEG_TYPE_NAME_CACHE); unsigned attr; cache_metadata_format_t f; if (!segtype || !segtype->ops->target_present || !segtype->ops->target_present(cmd, NULL, &attr)) { f = CACHE_METADATA_FORMAT_1; log_warn("WARNING: Cannot detect default cache metadata format, using format: %u.", f); } else { f = (attr & CACHE_FEATURE_METADATA2) ? CACHE_METADATA_FORMAT_2 : CACHE_METADATA_FORMAT_1; log_debug_metadata("Detected default cache metadata format: %u.", f); } return f; } int cache_set_policy(struct lv_segment *seg, const char *name, const struct dm_config_tree *settings) { struct dm_config_node *cn; const struct dm_config_node *cns; struct dm_config_tree *old = NULL, *new = NULL, *tmp = NULL; int r = 0; struct profile *profile = seg->lv->profile; if (seg_is_cache(seg)) seg = first_seg(seg->pool_lv); else if (seg_is_cache_pool(seg)) { if (!name && !settings) return 1; /* Policy and settings can be selected later when caching LV */ } else { log_error(INTERNAL_ERROR "Cannot set cache metadata format for non cache volume %s.", display_lvname(seg->lv)); return 0; } if (name) { if (!(seg->policy_name = dm_pool_strdup(seg->lv->vg->vgmem, name))) { log_error("Failed to duplicate policy name."); return 0; } } else if (!seg->policy_name) { if (!(seg->policy_name = find_config_tree_str(seg->lv->vg->cmd, allocation_cache_policy_CFG, profile)) && !(seg->policy_name = _get_default_cache_policy(seg->lv->vg->cmd))) return_0; if (!seg->policy_name) { log_error(INTERNAL_ERROR "Can't set policy settings without policy name."); return 0; } } if (settings) { if (seg->policy_settings) { if (!(old = dm_config_create())) goto_out; if (!(new = dm_config_create())) goto_out; new->root = settings->root; old->root = seg->policy_settings; new->cascade = old; if (!(tmp = dm_config_flatten(new))) goto_out; } if ((cn = dm_config_find_node((tmp) ? tmp->root : settings->root, "policy_settings")) && !(seg->policy_settings = dm_config_clone_node_with_mem(seg->lv->vg->vgmem, cn, 0))) goto_out; } else if (!seg->policy_settings) { if ((cns = find_config_tree_node(seg->lv->vg->cmd, allocation_cache_settings_CFG_SECTION, profile))) { /* Try to find our section for given policy */ for (cn = cns->child; cn; cn = cn->sib) { if (!cn->child) continue; /* Ignore section without settings */ if (cn->v || strcmp(cn->key, seg->policy_name) != 0) continue; /* Ignore mismatching sections */ /* Clone nodes with policy name */ if (!(seg->policy_settings = dm_config_clone_node_with_mem(seg->lv->vg->vgmem, cn, 0))) return_0; /* Replace policy name key with 'policy_settings' */ seg->policy_settings->key = "policy_settings"; break; /* Only first match counts */ } } } restart: /* remove any 'default" nodes */ cn = seg->policy_settings ? seg->policy_settings->child : NULL; while (cn) { if (cn->v->type == DM_CFG_STRING && !strcmp(cn->v->v.str, "default")) { dm_config_remove_node(seg->policy_settings, cn); goto restart; } cn = cn->sib; } r = 1; out: if (tmp) dm_config_destroy(tmp); if (new) dm_config_destroy(new); if (old) dm_config_destroy(old); return r; } /* * Sets metadata format on cache pool segment with these rules: * 1. When 'cache-pool' segment is passed, sets only for selected formats (1 or 2). * 2. For 'cache' segment passed in we know cache pool segment. * When passed format is 0 (UNSELECTED) with 'cache' segment - it's the moment * lvm2 has to figure out 'default' metadata format (1 or 2) from * configuration or profiles. * 3. If still unselected or selected format is != 1, figure the best supported format * and either use it or validate users settings is possible. * * Reasoning: A user may create cache-pool and may or may not specify CMFormat. * If the CMFormat has been selected (1 or 2) store this in metadata, otherwise * for an unused cache-pool UNSELECTED CMFormat is used. When caching LV, CMFormat * must be decided and from this moment it's always stored. To support backward * compatibility 'CMFormat 1' is used when it is NOT specified for a cached LV in * lvm2 metadata (no metadata_format=#F element in cache-pool segment). */ int cache_set_metadata_format(struct lv_segment *seg, cache_metadata_format_t format) { cache_metadata_format_t best; struct profile *profile = seg->lv->profile; if (seg_is_cache(seg)) seg = first_seg(seg->pool_lv); else if (seg_is_cache_pool(seg)) { if (format == CACHE_METADATA_FORMAT_UNSELECTED) return 1; /* Format can be selected later when caching LV */ } else { log_error(INTERNAL_ERROR "Cannot set cache metadata format for non cache volume %s.", display_lvname(seg->lv)); return 0; } /* Check if we need to search for configured cache metadata format */ if (format == CACHE_METADATA_FORMAT_UNSELECTED) { if (seg->cache_metadata_format != CACHE_METADATA_FORMAT_UNSELECTED) return 1; /* Format already selected in cache pool */ /* Check configurations and profiles */ format = find_config_tree_int(seg->lv->vg->cmd, allocation_cache_metadata_format_CFG, profile); } /* See what is a 'best' available cache metadata format * when the specifed format is other then always existing CMFormat 1 */ if (format != CACHE_METADATA_FORMAT_1) { best = _get_default_cache_metadata_format(seg->lv->vg->cmd); /* Format was not selected, so use best present on a system */ if (format == CACHE_METADATA_FORMAT_UNSELECTED) format = best; else if (format != best) { /* Format is not valid (Only Format 1 or 2 is supported ATM) */ log_error("Cache metadata format %u is not supported by kernel target.", format); return 0; } } switch (format) { case CACHE_METADATA_FORMAT_2: seg->lv->status |= LV_METADATA_FORMAT; break; case CACHE_METADATA_FORMAT_1: seg->lv->status &= ~LV_METADATA_FORMAT; break; default: log_error(INTERNAL_ERROR "Invalid cache metadata format %u for cache volume %s.", format, display_lvname(seg->lv)); return 0; } seg->cache_metadata_format = format; return 1; } /* * Universal 'wrapper' function do-it-all * to update all commonly specified cache parameters */ int cache_set_params(struct lv_segment *seg, uint32_t chunk_size, cache_metadata_format_t format, cache_mode_t mode, const char *policy_name, const struct dm_config_tree *policy_settings) { struct lv_segment *pool_seg; struct cmd_context *cmd = seg->lv->vg->cmd; if (!cache_set_metadata_format(seg, format)) return_0; if (!cache_set_cache_mode(seg, mode)) return_0; if (!cache_set_policy(seg, policy_name, policy_settings)) return_0; pool_seg = seg_is_cache(seg) ? first_seg(seg->pool_lv) : seg; if (chunk_size) { if (seg_is_cache(seg) && !validate_lv_cache_chunk_size(pool_seg->lv, chunk_size)) return_0; pool_seg->chunk_size = chunk_size; } else if (seg_is_cache(seg)) { /* Chunk size in profile has priority over cache-pool chunk size */ if ((chunk_size = find_config_tree_int(cmd, allocation_cache_pool_chunk_size_CFG, seg->lv->profile) * 2)) { if (!validate_lv_cache_chunk_size(pool_seg->lv, chunk_size)) return_0; if (pool_seg->chunk_size != chunk_size) log_verbose("Replacing chunk size %s in cache pool %s with " "chunk size %s from profile.", display_size(cmd, pool_seg->chunk_size), display_lvname(seg->lv), display_size(cmd, chunk_size)); pool_seg->chunk_size = chunk_size; } } else if (seg_is_cache_pool(seg)) { if (!pool_seg->chunk_size && /* TODO: some calc_policy solution for cache ? */ !recalculate_pool_chunk_size_with_dev_hints(pool_seg->lv, THIN_CHUNK_SIZE_CALC_METHOD_GENERIC)) return_0; } if (seg_is_cache(seg)) cache_check_for_warns(seg); return 1; } /* * Wipe cache pool metadata area before use. * * Activates metadata volume as 'cache-pool' so regular wiping * of existing visible volume may proceed. */ int wipe_cache_pool(struct logical_volume *cache_pool_lv) { int r; /* Only unused cache-pool could be activated and wiped */ if (!lv_is_cache_pool(cache_pool_lv) || !dm_list_empty(&cache_pool_lv->segs_using_this_lv)) { log_error(INTERNAL_ERROR "Failed to wipe cache pool for volume %s.", display_lvname(cache_pool_lv)); return 0; } cache_pool_lv->status |= LV_TEMPORARY; if (!activate_lv_local(cache_pool_lv->vg->cmd, cache_pool_lv)) { log_error("Aborting. Failed to activate cache pool %s.", display_lvname(cache_pool_lv)); return 0; } cache_pool_lv->status &= ~LV_TEMPORARY; if (!(r = wipe_lv(cache_pool_lv, (struct wipe_params) { .do_zero = 1 }))) { log_error("Aborting. Failed to wipe cache pool %s.", display_lvname(cache_pool_lv)); /* Delay return of error after deactivation */ } /* Deactivate cleared cache-pool metadata */ if (!deactivate_lv(cache_pool_lv->vg->cmd, cache_pool_lv)) { log_error("Aborting. Could not deactivate cache pool %s.", display_lvname(cache_pool_lv)); r = 0; } return r; }