/* * Copyright (C) 2001-2004 Sistina Software, Inc. All rights reserved. * Copyright (C) 2004-2017 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 #include "metadata.h" #include "lv_alloc.h" #include "pv_alloc.h" #include "str_list.h" #include "segtype.h" /* * Attempt to merge two adjacent segments. * Currently only supports striped segments on AREA_PV. * Returns success if successful, in which case 'first' * gets adjusted to contain both areas. */ static int _merge(struct lv_segment *first, struct lv_segment *second) { if (!first || !second || first->segtype != second->segtype || !first->segtype->ops->merge_segments) return 0; return first->segtype->ops->merge_segments(first, second); } int lv_merge_segments(struct logical_volume *lv) { struct dm_list *segh, *t; struct lv_segment *seg, *current, *prev = NULL; /* * Don't interfere with pvmoves as they rely upon two LVs * having a matching segment structure. */ if (lv_is_locked(lv) || lv_is_pvmove(lv)) return 1; if (lv_is_mirror_image(lv) && (seg = get_only_segment_using_this_lv(lv)) && (lv_is_locked(seg->lv) || lv_is_pvmove(seg->lv))) return 1; dm_list_iterate_safe(segh, t, &lv->segments) { current = dm_list_item(segh, struct lv_segment); if (_merge(prev, current)) dm_list_del(¤t->list); else prev = current; } return 1; } #define ERROR_MAX 100 #define inc_error_count \ if (error_count++ > ERROR_MAX) \ goto out #define seg_error(msg) { \ log_error("LV %s, segment %u invalid: %s for %s segment.", \ seg->lv->name, seg_count, (msg), lvseg_name(seg)); \ if ((*error_count)++ > ERROR_MAX) \ return; \ } /* * RAID segment property checks. * * Checks in here shall catch any * bogus segment structure setup. */ #define raid_seg_error(msg) { \ log_error("LV %s invalid: %s for %s segment", \ seg->lv->name, (msg), lvseg_name(seg)); \ if ((*error_count)++ > ERROR_MAX) \ return; \ } #define raid_seg_error_val(msg, val) { \ log_error("LV %s invalid: %s (is %u) for %s segment", \ seg->lv->name, (msg), (val), lvseg_name(seg)); \ if ((*error_count)++ > ERROR_MAX) \ return; \ } /* Check raid0 segment properties in @seg */ static void _check_raid0_seg(struct lv_segment *seg, int *error_count) { if (seg_is_raid0_meta(seg) && !seg->meta_areas) raid_seg_error("no meta areas"); if (!seg_is_raid0_meta(seg) && seg->meta_areas) raid_seg_error("meta areas"); if (!seg->stripe_size) raid_seg_error("zero stripe size"); if (!is_power_of_2(seg->stripe_size)) raid_seg_error_val("non power of 2 stripe size", seg->stripe_size); if (seg->region_size) raid_seg_error_val("non-zero region_size", seg->region_size); if (seg->writebehind) raid_seg_error_val("non-zero write behind", seg->writebehind); if (seg->min_recovery_rate) raid_seg_error_val("non-zero min recovery rate", seg->min_recovery_rate); if (seg->max_recovery_rate) raid_seg_error_val("non-zero max recovery rate", seg->max_recovery_rate); if (seg->lv->status & LV_RESHAPE_DATA_OFFSET) raid_seg_error_val("data_offset", seg->data_offset); } /* Check RAID @seg for non-zero, power of 2 region size and min recovery rate <= max */ static void _check_raid_region_recovery(struct lv_segment *seg, int *error_count) { if (!seg->region_size) raid_seg_error("zero region_size"); if (!is_power_of_2(seg->region_size)) raid_seg_error_val("non power of 2 region size", seg->region_size); /* min/max recovery rate may be zero but min may not be larger than max if set */ if (seg->max_recovery_rate && seg->min_recovery_rate > seg->max_recovery_rate) raid_seg_error_val("min recovery larger than max recovery", seg->min_recovery_rate); } /* Check raid1 segment properties in @seg */ static void _check_raid1_seg(struct lv_segment *seg, int *error_count) { if (!seg->meta_areas) raid_seg_error("no meta areas"); if (seg->stripe_size) raid_seg_error_val("non-zero stripe size", seg->stripe_size); if (seg->lv->status & LV_RESHAPE_DATA_OFFSET) raid_seg_error_val("data_offset", seg->data_offset); _check_raid_region_recovery(seg, error_count); } /* Check raid4/5/6/10 segment properties in @seg */ static void _check_raid45610_seg(struct lv_segment *seg, int *error_count) { /* Checks applying to any raid4/5/6/10 */ /* * Allow raid4 + raid5_n to get activated w/o metadata. * * This is mandatory during conversion between them, * because switching the dedicated parity SubLVs * beginning <-> end changes the roles of all SubLVs * which the kernel would reject. */ if (!(seg_is_raid4(seg) || seg_is_raid5_n(seg)) && !seg->meta_areas) raid_seg_error("no meta areas"); if (!seg->stripe_size) raid_seg_error("zero stripe size"); if (!is_power_of_2(seg->stripe_size)) raid_seg_error_val("non power of 2 stripe size", seg->stripe_size); _check_raid_region_recovery(seg, error_count); /* END: checks applying to any raid4/5/6/10 */ if ((seg->lv->status & LV_RESHAPE_DATA_OFFSET) && (seg->data_offset & (seg->lv->vg->extent_size - 1))) raid_seg_error_val("data_offset", seg->data_offset); /* Specific checks per raid level */ if (seg_is_raid4(seg) || seg_is_any_raid5(seg)) { /* * To allow for takeover between the MD raid1 and * raid4/5 personalities, exactly 2 areas (i.e. DataLVs) * can be mirrored by all raid1, raid4 and raid5 personalities. * Hence allow a minimum of 2 areas. */ if (seg->area_count < 2) raid_seg_error_val("minimum 2 areas required", seg->area_count); } else if (seg_is_any_raid6(seg)) { /* * FIXME: MD raid6 supports a minimum of 4 areas. * LVM requests a minimum of 5 due to easier * processing of SubLVs to replace. * * Once that obstacle got removed, allow for a minimum of 4. */ if (seg->area_count < 5) raid_seg_error_val("minimum 5 areas required", seg->area_count); } else if (seg_is_raid10(seg)) { /* * FIXME: raid10 area_count minimum has to change to 2 once we * support data_copies and odd numbers of stripes */ if (seg->area_count < 4) raid_seg_error_val("minimum 4 areas required", seg->area_count); if (seg->writebehind) raid_seg_error_val("non-zero writebehind", seg->writebehind); } } /* Check any non-RAID segment struct members in @seg and increment @error_count for any bogus ones */ static void _check_non_raid_seg_members(struct lv_segment *seg, int *error_count) { if (seg->origin) /* snap and thin */ raid_seg_error("non-zero origin LV"); if (seg->cow) /* snap */ raid_seg_error("non-zero cow LV"); if (!dm_list_empty(&seg->origin_list)) /* snap */ raid_seg_error("non-zero origin_list"); /* replicator members (deprecated) */ if (seg->replicator) raid_seg_error("non-zero replicator"); if (seg->rlog_lv) raid_seg_error("non-zero rlog LV"); if (seg->rlog_type) raid_seg_error("non-zero rlog type"); if (seg->rdevice_index_highest) raid_seg_error("non-zero rdevice_index_highests"); if (seg->rsite_index_highest) raid_seg_error("non-zero rsite_index_highests"); /* .... more members? */ } /* * Check RAID segment struct members of @seg for acceptable * properties and increment @error_count for any bogus ones. */ static void _check_raid_seg(struct lv_segment *seg, int *error_count) { uint32_t area_len, s; /* General checks applying to all RAIDs */ if (!seg->area_count) raid_seg_error("zero area count"); if (!seg->areas) raid_seg_error("zero areas"); if (seg->extents_copied > seg->len) raid_seg_error_val("extents_copied too large", seg->extents_copied); /* Default < 10, change once raid1 split shift and rename SubLVs works! */ if (seg_is_raid1(seg)) { if (seg->area_count > DEFAULT_RAID1_MAX_IMAGES) { log_error("LV %s invalid: maximum supported areas %u (is %u) for %s segment", seg->lv->name, DEFAULT_RAID1_MAX_IMAGES, seg->area_count, lvseg_name(seg)); if ((*error_count)++ > ERROR_MAX) return; } } else if (seg->area_count > DEFAULT_RAID_MAX_IMAGES) { log_error("LV %s invalid: maximum supported areas %u (is %u) for %s segment", seg->lv->name, DEFAULT_RAID_MAX_IMAGES, seg->area_count, lvseg_name(seg)); if ((*error_count)++ > ERROR_MAX) return; } /* FIXME: should we check any non-RAID segment struct members at all? */ _check_non_raid_seg_members(seg, error_count); /* Check for any DataLV flaws like non-existing ones or size variations */ for (area_len = s = 0; s < seg->area_count; s++) { if (seg_type(seg, s) != AREA_LV) raid_seg_error("no DataLV"); if (!lv_is_raid_image(seg_lv(seg, s))) raid_seg_error("DataLV without RAID image flag"); if (area_len && area_len != seg_lv(seg, s)->le_count) { raid_seg_error_val("DataLV size variations", seg_lv(seg, s)->le_count); } else area_len = seg_lv(seg, s)->le_count; } /* Check for any MetaLV flaws like non-existing ones or size variations */ if (seg->meta_areas) for (area_len = s = 0; s < seg->area_count; s++) { if (seg_metatype(seg, s) != AREA_LV) { raid_seg_error("no MetaLV"); continue; } if (!lv_is_raid_metadata(seg_metalv(seg, s))) raid_seg_error("MetaLV without RAID metadata flag"); if (area_len && area_len != seg_metalv(seg, s)->le_count) { raid_seg_error_val("MetaLV size variations", seg_metalv(seg, s)->le_count); } else area_len = seg_metalv(seg, s)->le_count; } /* END: general checks applying to all RAIDs */ /* Specific segment type checks from here on */ if (seg_is_any_raid0(seg)) _check_raid0_seg(seg, error_count); else if (seg_is_raid1(seg)) _check_raid1_seg(seg, error_count); else if (seg_is_raid4(seg) || seg_is_any_raid5(seg) || seg_is_any_raid6(seg) || seg_is_raid10(seg)) _check_raid45610_seg(seg, error_count); else raid_seg_error("bogus RAID segment type"); } /* END: RAID segment property checks. */ static void _check_lv_segment(struct logical_volume *lv, struct lv_segment *seg, unsigned seg_count, int *error_count) { struct lv_segment *seg2; if (lv_is_mirror_image(lv) && (!(seg2 = find_mirror_seg(seg)) || !seg_is_mirrored(seg2))) seg_error("mirror image is not mirrored"); if (seg_is_cache(seg)) { if (!lv_is_cache(lv)) seg_error("is not flagged as cache LV"); if (!seg->pool_lv) { seg_error("is missing cache pool LV"); } else if (!lv_is_cache_pool(seg->pool_lv)) seg_error("is not referencing cache pool LV"); } else { /* !cache */ if (seg->cleaner_policy) seg_error("sets cleaner_policy"); } if (seg_is_cache_pool(seg)) { if (!dm_list_empty(&seg->lv->segs_using_this_lv)) { switch (seg->cache_metadata_format) { case CACHE_METADATA_FORMAT_2: case CACHE_METADATA_FORMAT_1: break; default: seg_error("has invalid cache metadata format"); } switch (seg->cache_mode) { case CACHE_MODE_WRITETHROUGH: case CACHE_MODE_WRITEBACK: case CACHE_MODE_PASSTHROUGH: break; default: seg_error("has invalid cache's feature flag") } if (!seg->policy_name) seg_error("is missing cache policy name"); } if (!validate_cache_chunk_size(lv->vg->cmd, seg->chunk_size)) seg_error("has invalid chunk size."); if (seg->lv->status & LV_METADATA_FORMAT) { if (seg->cache_metadata_format != CACHE_METADATA_FORMAT_2) seg_error("sets METADATA_FORMAT flag"); } else if (seg->cache_metadata_format == CACHE_METADATA_FORMAT_2) seg_error("is missing METADATA_FORMAT flag"); } else { /* !cache_pool */ if (seg->cache_metadata_format) seg_error("sets cache metadata format"); if (seg->cache_mode) seg_error("sets cache mode"); if (seg->policy_name) seg_error("sets policy name"); if (seg->policy_settings) seg_error("sets policy settings"); if (seg->lv->status & LV_METADATA_FORMAT) seg_error("sets METADATA_FORMAT flag"); } if (!seg_can_error_when_full(seg) && lv_is_error_when_full(lv)) seg_error("does not support flag ERROR_WHEN_FULL."); if (seg_is_mirrored(seg)) { /* Check mirror log - which is attached to the mirrored seg */ if (seg->log_lv) { if (!lv_is_mirror_log(seg->log_lv)) seg_error("log LV is not a mirror log"); if (!(seg2 = first_seg(seg->log_lv)) || (find_mirror_seg(seg2) != seg)) seg_error("log LV does not point back to mirror segment"); } } else { /* !mirrored */ if (seg->log_lv) { if (lv_is_raid_image(lv)) seg_error("log LV is not a mirror log or a RAID image"); } } if (seg_is_raid(seg)) _check_raid_seg(seg, error_count); if (seg_is_pool(seg)) { if ((seg->area_count != 1) || (seg_type(seg, 0) != AREA_LV)) { seg_error("is missing a pool data LV"); } else if (!(seg2 = first_seg(seg_lv(seg, 0))) || (find_pool_seg(seg2) != seg)) seg_error("data LV does not refer back to pool LV"); if (!seg->metadata_lv) { seg_error("is missing a pool metadata LV"); } else if (!(seg2 = first_seg(seg->metadata_lv)) || (find_pool_seg(seg2) != seg)) seg_error("metadata LV does not refer back to pool LV"); } else { /* !thin_pool && !cache_pool */ if (seg->metadata_lv) seg_error("must not have pool metadata LV set"); } if (seg_is_thin_pool(seg)) { if (!lv_is_thin_pool(lv)) seg_error("is not flagged as thin pool LV"); if (lv_is_thin_volume(lv)) seg_error("is a thin volume that must not contain thin pool segment"); if (!validate_thin_pool_chunk_size(lv->vg->cmd, seg->chunk_size)) seg_error("has invalid chunk size."); if (seg->zero_new_blocks != THIN_ZERO_YES && seg->zero_new_blocks != THIN_ZERO_NO) seg_error("zero_new_blocks is invalid"); } else { /* !thin_pool */ if (seg->zero_new_blocks != THIN_ZERO_UNSELECTED) seg_error("sets zero_new_blocks"); if (seg->discards != THIN_DISCARDS_UNSELECTED) seg_error("sets discards"); if (!dm_list_empty(&seg->thin_messages)) seg_error("sets thin_messages list"); } if (seg_is_thin_volume(seg)) { if (!lv_is_thin_volume(lv)) seg_error("is not flagged as thin volume LV"); if (lv_is_thin_pool(lv)) seg_error("is a thin pool that must not contain thin volume segment"); if (!seg->pool_lv) { seg_error("is missing thin pool LV"); } else if (!lv_is_thin_pool(seg->pool_lv)) seg_error("is not referencing thin pool LV"); if (seg->device_id > DM_THIN_MAX_DEVICE_ID) seg_error("has too large device id"); if (seg->external_lv && !lv_is_external_origin(seg->external_lv)) seg_error("external LV is not flagged as a external origin LV"); if (seg->merge_lv) { if (!lv_is_thin_volume(seg->merge_lv)) seg_error("merge LV is not flagged as a thin LV"); if (!lv_is_merging_origin(seg->merge_lv)) seg_error("merge LV is not flagged as merging"); } } else { /* !thin */ if (seg->device_id) seg_error("sets device_id"); if (seg->external_lv) seg_error("sets external LV"); if (seg->merge_lv) seg_error("sets merge LV"); if (seg->indirect_origin) seg_error("sets indirect_origin LV"); } /* Some multi-seg vars excluded here */ if (!seg_is_cache(seg) && !seg_is_thin_volume(seg)) { if (seg->pool_lv) seg_error("sets pool LV"); } if (!seg_is_pool(seg) && /* FIXME: format_pool/import_export.c _add_linear_seg() sets chunk_size */ !seg_is_linear(seg) && !seg_is_snapshot(seg)) { if (seg->chunk_size) seg_error("sets chunk_size"); } if (!seg_is_thin_pool(seg) && !seg_is_thin_volume(seg)) { if (seg->transaction_id) seg_error("sets transaction_id"); } if (!seg_unknown(seg)) { if (seg->segtype_private) seg_error("set segtype_private"); } } /* * Verify that an LV's segments are consecutive, complete and don't overlap. */ int check_lv_segments(struct logical_volume *lv, int complete_vg) { struct lv_segment *seg, *seg2; uint32_t le = 0; unsigned seg_count = 0, seg_found, external_lv_found = 0; uint32_t data_rimage_count, s; struct seg_list *sl; struct glv_list *glvl; int error_count = 0; struct replicator_site *rsite; struct replicator_device *rdev; dm_list_iterate_items(seg, &lv->segments) { seg_count++; if (seg->lv != lv) { log_error("LV %s invalid: segment %u is referencing different LV.", lv->name, seg_count); inc_error_count; } if (seg->le != le) { log_error("LV %s invalid: segment %u should begin at " "LE %" PRIu32 " (found %" PRIu32 ").", lv->name, seg_count, le, seg->le); inc_error_count; } data_rimage_count = seg->area_count - seg->segtype->parity_devs; /* FIXME: raid varies seg->area_len? */ if (seg->len != seg->area_len && seg->len != seg->area_len * data_rimage_count) { log_error("LV %s: segment %u with len=%u " " has inconsistent area_len %u", lv->name, seg_count, seg->len, seg->area_len); inc_error_count; } if (seg_is_snapshot(seg)) { if (seg->cow && seg->cow == seg->origin) { log_error("LV %s: segment %u has same LV %s for " "both origin and snapshot", lv->name, seg_count, seg->cow->name); inc_error_count; } } if (seg_is_replicator(seg) && !check_replicator_segment(seg)) inc_error_count; if (complete_vg) _check_lv_segment(lv, seg, seg_count, &error_count); for (s = 0; s < seg->area_count; s++) { if (seg_type(seg, s) == AREA_UNASSIGNED) { log_error("LV %s: segment %u has unassigned " "area %u.", lv->name, seg_count, s); inc_error_count; } else if (seg_type(seg, s) == AREA_PV) { if (!seg_pvseg(seg, s) || seg_pvseg(seg, s)->lvseg != seg || seg_pvseg(seg, s)->lv_area != s) { log_error("LV %s: segment %u has " "inconsistent PV area %u", lv->name, seg_count, s); inc_error_count; } } else { if (!seg_lv(seg, s) || seg_lv(seg, s)->vg != lv->vg || seg_lv(seg, s) == lv) { log_error("LV %s: segment %u has " "inconsistent LV area %u", lv->name, seg_count, s); inc_error_count; } if (complete_vg && seg_lv(seg, s) && lv_is_mirror_image(seg_lv(seg, s)) && (!(seg2 = find_seg_by_le(seg_lv(seg, s), seg_le(seg, s))) || find_mirror_seg(seg2) != seg)) { log_error("LV %s: segment %u mirror " "image %u missing mirror ptr", lv->name, seg_count, s); inc_error_count; } /* FIXME I don't think this ever holds? if (seg_le(seg, s) != le) { log_error("LV %s: segment %u has " "inconsistent LV area %u " "size", lv->name, seg_count, s); inc_error_count; } */ seg_found = 0; dm_list_iterate_items(sl, &seg_lv(seg, s)->segs_using_this_lv) if (sl->seg == seg) seg_found++; if (!seg_found) { log_error("LV %s segment %u uses LV %s," " but missing ptr from %s to %s", lv->name, seg_count, seg_lv(seg, s)->name, seg_lv(seg, s)->name, lv->name); inc_error_count; } else if (seg_found > 1) { log_error("LV %s has duplicated links " "to LV %s segment %u", seg_lv(seg, s)->name, lv->name, seg_count); inc_error_count; } } if (complete_vg && seg_is_mirrored(seg) && !seg_is_raid(seg) && seg_type(seg, s) == AREA_LV && seg_lv(seg, s)->le_count != seg->area_len) { log_error("LV %s: mirrored LV segment %u has " "wrong size %u (should be %u).", lv->name, s, seg_lv(seg, s)->le_count, seg->area_len); inc_error_count; } } le += seg->len; } if (le != lv->le_count) { log_error("LV %s: inconsistent LE count %u != %u", lv->name, le, lv->le_count); inc_error_count; } dm_list_iterate_items(sl, &lv->segs_using_this_lv) { seg = sl->seg; seg_found = 0; for (s = 0; s < seg->area_count; s++) { if (seg_type(seg, s) != AREA_LV) continue; if (lv == seg_lv(seg, s)) seg_found++; if (seg->meta_areas && seg_is_raid_with_meta(seg) && (lv == seg_metalv(seg, s))) seg_found++; } if (seg_is_replicator_dev(seg)) { dm_list_iterate_items(rsite, &seg->replicator->rsites) { dm_list_iterate_items(rdev, &rsite->rdevices) { if (lv == rdev->lv || lv == rdev->slog) seg_found++; } } if (lv == seg->replicator) seg_found++; } if (seg_is_replicator(seg) && lv == seg->rlog_lv) seg_found++; if (seg->log_lv == lv) seg_found++; if (seg->metadata_lv == lv || seg->pool_lv == lv) seg_found++; if (seg_is_thin_volume(seg) && (seg->origin == lv || seg->external_lv == lv)) seg_found++; if (!seg_found) { log_error("LV %s is used by LV %s:%" PRIu32 "-%" PRIu32 ", but missing ptr from %s to %s", lv->name, seg->lv->name, seg->le, seg->le + seg->len - 1, seg->lv->name, lv->name); inc_error_count; } else if (seg_found != sl->count) { log_error("Reference count mismatch: LV %s has %u " "links to LV %s:%" PRIu32 "-%" PRIu32 ", which has %u links", lv->name, sl->count, seg->lv->name, seg->le, seg->le + seg->len - 1, seg_found); inc_error_count; } seg_found = 0; dm_list_iterate_items(seg2, &seg->lv->segments) if (seg == seg2) { seg_found++; break; } if (!seg_found) { log_error("LV segment %s:%" PRIu32 "-%" PRIu32 " is incorrectly listed as being used by LV %s", seg->lv->name, seg->le, seg->le + seg->len - 1, lv->name); inc_error_count; } /* Validation of external origin counter */ if (seg->external_lv == lv) external_lv_found++; } dm_list_iterate_items(glvl, &lv->indirect_glvs) { if (glvl->glv->is_historical) { if (glvl->glv->historical->indirect_origin != lv->this_glv) { log_error("LV %s is indirectly used by historical LV %s" "but that historical LV does not point back to LV %s", lv->name, glvl->glv->historical->name, lv->name); inc_error_count; } } else { if (!(seg = first_seg(glvl->glv->live)) || seg->indirect_origin != lv->this_glv) { log_error("LV %s is indirectly used by LV %s" "but that LV does not point back to LV %s", lv->name, glvl->glv->live->name, lv->name); inc_error_count; } } } /* Check LV flags match first segment type */ if (complete_vg) { if ((seg_count != 1) && (lv_is_cache(lv) || lv_is_cache_pool(lv) || lv_is_raid(lv) || lv_is_snapshot(lv) || lv_is_thin_pool(lv) || lv_is_thin_volume(lv))) { log_error("LV %s must have exactly one segment.", lv->name); inc_error_count; } if (lv_is_pool_data(lv) && (!(seg2 = first_seg(lv)) || !(seg2 = find_pool_seg(seg2)) || seg2->area_count != 1 || seg_type(seg2, 0) != AREA_LV || seg_lv(seg2, 0) != lv)) { log_error("LV %s: segment 1 pool data LV does not point back to same LV", lv->name); inc_error_count; } if (lv_is_thin_pool_metadata(lv) && !strstr(lv->name, "_tmeta")) { log_error("LV %s: thin pool metadata LV does not use _tmeta.", lv->name); inc_error_count; } else if (lv_is_cache_pool_metadata(lv) && !strstr(lv->name, "_cmeta")) { log_error("LV %s: cache pool metadata LV does not use _cmeta.", lv->name); inc_error_count; } if (lv_is_external_origin(lv)) { if (lv->external_count != external_lv_found) { log_error("LV %s: external origin count does not match.", lv->name); inc_error_count; } if (lv->status & LVM_WRITE) { log_error("LV %s: external origin cant't be writable.", lv->name); inc_error_count; } } } out: return !error_count; } /* * Split the supplied segment at the supplied logical extent * NB Use LE numbering that works across stripes PV1: 0,2,4 PV2: 1,3,5 etc. */ static int _lv_split_segment(struct logical_volume *lv, struct lv_segment *seg, uint32_t le) { struct lv_segment *split_seg; uint32_t s; uint32_t offset = le - seg->le; uint32_t area_offset; if (!seg_can_split(seg)) { log_error("Unable to split the %s segment at LE %" PRIu32 " in LV %s", lvseg_name(seg), le, lv->name); return 0; } /* Clone the existing segment */ if (!(split_seg = alloc_lv_segment(seg->segtype, seg->lv, seg->le, seg->len, seg->reshape_len, seg->status, seg->stripe_size, seg->log_lv, seg->area_count, seg->area_len, seg->data_copies, seg->chunk_size, seg->region_size, seg->extents_copied, seg->pvmove_source_seg))) { log_error("Couldn't allocate cloned LV segment."); return 0; } if (!str_list_dup(lv->vg->vgmem, &split_seg->tags, &seg->tags)) { log_error("LV segment tags duplication failed"); return 0; } /* In case of a striped segment, the offset has to be / stripes */ area_offset = offset; if (seg_is_striped(seg)) area_offset /= seg->area_count; split_seg->area_len -= area_offset; seg->area_len = area_offset; split_seg->len -= offset; seg->len = offset; split_seg->le = seg->le + seg->len; /* Adjust the PV mapping */ for (s = 0; s < seg->area_count; s++) { seg_type(split_seg, s) = seg_type(seg, s); /* Split area at the offset */ switch (seg_type(seg, s)) { case AREA_LV: if (!set_lv_segment_area_lv(split_seg, s, seg_lv(seg, s), seg_le(seg, s) + seg->area_len, 0)) return_0; log_debug_alloc("Split %s:%u[%u] at %u: %s LE %u", lv->name, seg->le, s, le, seg_lv(seg, s)->name, seg_le(split_seg, s)); break; case AREA_PV: if (!(seg_pvseg(split_seg, s) = assign_peg_to_lvseg(seg_pv(seg, s), seg_pe(seg, s) + seg->area_len, seg_pvseg(seg, s)->len - seg->area_len, split_seg, s))) return_0; log_debug_alloc("Split %s:%u[%u] at %u: %s PE %u", lv->name, seg->le, s, le, dev_name(seg_dev(seg, s)), seg_pe(split_seg, s)); break; case AREA_UNASSIGNED: log_error("Unassigned area %u found in segment", s); return 0; } } /* Add split off segment to the list _after_ the original one */ dm_list_add_h(&seg->list, &split_seg->list); return 1; } /* * Ensure there's a segment boundary at the given logical extent */ int lv_split_segment(struct logical_volume *lv, uint32_t le) { struct lv_segment *seg; if (!(seg = find_seg_by_le(lv, le))) { log_error("Segment with extent %" PRIu32 " in LV %s not found", le, lv->name); return 0; } /* This is a segment start already */ if (le == seg->le) return 1; if (!_lv_split_segment(lv, seg, le)) return_0; if (!vg_validate(lv->vg)) return_0; return 1; }