/* * Copyright (C) 2011 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., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA */ #include "lib.h" #include "metadata.h" #include "toolcontext.h" #include "segtype.h" #include "display.h" #include "activate.h" #include "lv_alloc.h" #include "lvm-string.h" #define RAID_REGION_SIZE 1024 static int _lv_is_raid_with_tracking(const struct logical_volume *lv, struct logical_volume **tracking) { uint32_t s; struct lv_segment *seg; *tracking = NULL; seg = first_seg(lv); if (!(lv->status & RAID)) return 0; for (s = 0; s < seg->area_count; s++) if (lv_is_visible(seg_lv(seg, s)) && !(seg_lv(seg, s)->status & LVM_WRITE)) *tracking = seg_lv(seg, s); return *tracking ? 1 : 0; } int lv_is_raid_with_tracking(const struct logical_volume *lv) { struct logical_volume *tracking; return _lv_is_raid_with_tracking(lv, &tracking); } uint32_t lv_raid_image_count(const struct logical_volume *lv) { struct lv_segment *seg = first_seg(lv); if (!seg_is_raid(seg)) return 1; return seg->area_count; } /* * Resume sub-LVs first, then top-level LV */ static int _bottom_up_resume(struct logical_volume *lv) { uint32_t s; struct lv_segment *seg = first_seg(lv); if (seg_is_raid(seg) && (seg->area_count > 1)) { for (s = 0; s < seg->area_count; s++) if (!resume_lv(lv->vg->cmd, seg_lv(seg, s)) || !resume_lv(lv->vg->cmd, seg_metalv(seg, s))) return_0; } return resume_lv(lv->vg->cmd, lv); } static int _activate_sublv_preserving_excl(struct logical_volume *top_lv, struct logical_volume *sub_lv) { struct cmd_context *cmd = top_lv->vg->cmd; /* If top RAID was EX, use EX */ if (lv_is_active_exclusive_locally(top_lv)) { if (!activate_lv_excl(cmd, sub_lv)) return_0; } else { if (!activate_lv(cmd, sub_lv)) return_0; } return 1; } /* * _lv_is_on_pv * @lv: * @pv: * * If any of the component devices of the LV are on the given PV, 1 * is returned; otherwise 0. For example if one of the images of a RAID * (or its metadata device) is on the PV, 1 would be returned for the * top-level LV. * If you wish to check the images themselves, you should pass them. * * FIXME: This should be made more generic, possibly use 'for_each_sub_lv', * and be put in lv_manip.c. 'for_each_sub_lv' does not yet allow us to * short-circuit execution or pass back the values we need yet though... */ static int _lv_is_on_pv(struct logical_volume *lv, struct physical_volume *pv) { uint32_t s; struct physical_volume *pv2; struct lv_segment *seg; if (!lv) return 0; seg = first_seg(lv); if (!seg) return 0; /* Check mirror log */ if (_lv_is_on_pv(seg->log_lv, pv)) return 1; /* Check stack of LVs */ dm_list_iterate_items(seg, &lv->segments) { for (s = 0; s < seg->area_count; s++) { if (seg_type(seg, s) == AREA_PV) { pv2 = seg_pv(seg, s); if (id_equal(&pv->id, &pv2->id)) return 1; if (pv->dev && pv2->dev && (pv->dev->dev == pv2->dev->dev)) return 1; } if ((seg_type(seg, s) == AREA_LV) && _lv_is_on_pv(seg_lv(seg, s), pv)) return 1; if (!seg_is_raid(seg)) continue; /* This is RAID, so we know the meta_area is AREA_LV */ if (_lv_is_on_pv(seg_metalv(seg, s), pv)) return 1; } } return 0; } static int _lv_is_on_pvs(struct logical_volume *lv, struct dm_list *pvs) { struct pv_list *pvl; dm_list_iterate_items(pvl, pvs) if (_lv_is_on_pv(lv, pvl->pv)) { log_debug("%s is on %s", lv->name, pv_dev_name(pvl->pv)); return 1; } else log_debug("%s is not on %s", lv->name, pv_dev_name(pvl->pv)); return 0; } static int _get_pv_list_for_lv(struct logical_volume *lv, struct dm_list *pvs) { uint32_t s; struct pv_list *pvl; struct lv_segment *seg = first_seg(lv); if (!seg_is_linear(seg)) { log_error(INTERNAL_ERROR "_get_pv_list_for_lv only handles linear volumes"); return 0; } log_debug("Getting list of PVs that %s/%s is on:", lv->vg->name, lv->name); dm_list_iterate_items(seg, &lv->segments) { for (s = 0; s < seg->area_count; s++) { if (seg_type(seg, s) != AREA_PV) { log_error(INTERNAL_ERROR "Linear seg_type should be AREA_PV"); return 0; } if (!(pvl = dm_pool_zalloc(lv->vg->cmd->mem, sizeof(*pvl)))) { log_error("Failed to allocate memory"); return 0; } pvl->pv = seg_pv(seg, s); log_debug(" %s/%s is on %s", lv->vg->name, lv->name, pv_dev_name(pvl->pv)); dm_list_add(pvs, &pvl->list); } } return 1; } /* * _raid_in_sync * @lv * * _raid_in_sync works for all types of RAID segtypes, as well * as 'mirror' segtype. (This is because 'lv_raid_percent' is * simply a wrapper around 'lv_mirror_percent'. * * Returns: 1 if in-sync, 0 otherwise. */ static int _raid_in_sync(struct logical_volume *lv) { percent_t sync_percent; if (!lv_raid_percent(lv, &sync_percent)) { log_error("Unable to determine sync status of %s/%s.", lv->vg->name, lv->name); return 0; } return (sync_percent == PERCENT_100) ? 1 : 0; } /* * _raid_remove_top_layer * @lv * @removal_list * * Remove top layer of RAID LV in order to convert to linear. * This function makes no on-disk changes. The residual LVs * returned in 'removal_list' must be freed by the caller. * * Returns: 1 on succes, 0 on failure */ static int _raid_remove_top_layer(struct logical_volume *lv, struct dm_list *removal_list) { struct lv_list *lvl_array, *lvl; struct lv_segment *seg = first_seg(lv); if (!seg_is_mirrored(seg)) { log_error(INTERNAL_ERROR "Unable to remove RAID layer from segment type %s", seg->segtype->name); return 0; } if (seg->area_count != 1) { log_error(INTERNAL_ERROR "Unable to remove RAID layer when there" " is more than one sub-lv"); return 0; } lvl_array = dm_pool_alloc(lv->vg->vgmem, 2 * sizeof(*lvl)); if (!lvl_array) { log_error("Memory allocation failed."); return 0; } /* Add last metadata area to removal_list */ lvl_array[0].lv = seg_metalv(seg, 0); lv_set_visible(seg_metalv(seg, 0)); remove_seg_from_segs_using_this_lv(seg_metalv(seg, 0), seg); seg_metatype(seg, 0) = AREA_UNASSIGNED; dm_list_add(removal_list, &(lvl_array[0].list)); /* Remove RAID layer and add residual LV to removal_list*/ seg_lv(seg, 0)->status &= ~RAID_IMAGE; lv_set_visible(seg_lv(seg, 0)); lvl_array[1].lv = seg_lv(seg, 0); dm_list_add(removal_list, &(lvl_array[1].list)); if (!remove_layer_from_lv(lv, seg_lv(seg, 0))) return_0; lv->status &= ~(MIRRORED | RAID); return 1; } /* * _clear_lv * @lv * * If LV is active: * clear first block of device * otherwise: * activate, clear, deactivate * * Returns: 1 on success, 0 on failure */ static int _clear_lv(struct logical_volume *lv) { int was_active = lv_is_active(lv); if (!was_active && !activate_lv(lv->vg->cmd, lv)) { log_error("Failed to activate %s for clearing", lv->name); return 0; } log_verbose("Clearing metadata area of %s/%s", lv->vg->name, lv->name); /* * Rather than wiping lv->size, we can simply * wipe the first sector to remove the superblock of any previous * RAID devices. It is much quicker. */ if (!set_lv(lv->vg->cmd, lv, 1, 0)) { log_error("Failed to zero %s", lv->name); return 0; } if (!was_active && !deactivate_lv(lv->vg->cmd, lv)) { log_error("Failed to deactivate %s", lv->name); return 0; } return 1; } /* Makes on-disk metadata changes */ static int _clear_lvs(struct dm_list *lv_list) { struct lv_list *lvl; struct volume_group *vg = NULL; if (dm_list_empty(lv_list)) { log_debug(INTERNAL_ERROR "Empty list of LVs given for clearing"); return 1; } dm_list_iterate_items(lvl, lv_list) { if (!lv_is_visible(lvl->lv)) { log_error(INTERNAL_ERROR "LVs must be set visible before clearing"); return 0; } vg = lvl->lv->vg; } /* * FIXME: only vg_[write|commit] if LVs are not already written * as visible in the LVM metadata (which is never the case yet). */ if (!vg || !vg_write(vg) || !vg_commit(vg)) return_0; dm_list_iterate_items(lvl, lv_list) if (!_clear_lv(lvl->lv)) return 0; return 1; } /* * _shift_and_rename_image_components * @seg: Top-level RAID segment * * Shift all higher indexed segment areas down to fill in gaps where * there are 'AREA_UNASSIGNED' areas and rename data/metadata LVs so * that their names match their new index. When finished, set * seg->area_count to new reduced total. * * Returns: 1 on success, 0 on failure */ static int _shift_and_rename_image_components(struct lv_segment *seg) { int len; char *shift_name; uint32_t s, missing; struct cmd_context *cmd = seg->lv->vg->cmd; /* * All LVs must be properly named for their index before * shifting begins. (e.g. Index '0' must contain *_rimage_0 and * *_rmeta_0. Index 'n' must contain *_rimage_n and *_rmeta_n.) */ if (!seg_is_raid(seg)) return_0; if (seg->area_count > 10) { /* * FIXME: Handling more would mean I'd have * to handle double digits */ log_error("Unable handle arrays with more than 10 devices"); return 0; } log_very_verbose("Shifting images in %s", seg->lv->name); for (s = 0, missing = 0; s < seg->area_count; s++) { if (seg_type(seg, s) == AREA_UNASSIGNED) { if (seg_metatype(seg, s) != AREA_UNASSIGNED) { log_error(INTERNAL_ERROR "Metadata segment area" " #%d should be AREA_UNASSIGNED", s); return 0; } missing++; continue; } if (!missing) continue; log_very_verbose("Shifting %s and %s by %u", seg_metalv(seg, s)->name, seg_lv(seg, s)->name, missing); /* Alter rmeta name */ shift_name = dm_pool_strdup(cmd->mem, seg_metalv(seg, s)->name); if (!shift_name) { log_error("Memory allocation failed."); return 0; } len = strlen(shift_name) - 1; shift_name[len] -= missing; seg_metalv(seg, s)->name = shift_name; /* Alter rimage name */ shift_name = dm_pool_strdup(cmd->mem, seg_lv(seg, s)->name); if (!shift_name) { log_error("Memory allocation failed."); return 0; } len = strlen(shift_name) - 1; shift_name[len] -= missing; seg_lv(seg, s)->name = shift_name; seg->areas[s - missing] = seg->areas[s]; seg->meta_areas[s - missing] = seg->meta_areas[s]; } seg->area_count -= missing; return 1; } /* * Create an LV of specified type. Set visible after creation. * This function does not make metadata changes. */ static int _alloc_image_component(struct logical_volume *lv, const char *alt_base_name, struct alloc_handle *ah, uint32_t first_area, uint64_t type, struct logical_volume **new_lv) { uint64_t status; size_t len = strlen(lv->name) + 32; char img_name[len]; const char *base_name = (alt_base_name) ? alt_base_name : lv->name; struct logical_volume *tmp_lv; const struct segment_type *segtype; if (type == RAID_META) { if (dm_snprintf(img_name, len, "%s_rmeta_%%d", base_name) < 0) return_0; } else if (type == RAID_IMAGE) { if (dm_snprintf(img_name, len, "%s_rimage_%%d", base_name) < 0) return_0; } else { log_error(INTERNAL_ERROR "Bad type provided to _alloc_raid_component"); return 0; } if (!ah) { first_area = 0; log_error(INTERNAL_ERROR "Stand-alone %s area allocation not implemented", (type == RAID_META) ? "metadata" : "data"); return 0; } status = LVM_READ | LVM_WRITE | LV_REBUILD | type; tmp_lv = lv_create_empty(img_name, NULL, status, ALLOC_INHERIT, lv->vg); if (!tmp_lv) { log_error("Failed to allocate new raid component, %s", img_name); return 0; } segtype = get_segtype_from_string(lv->vg->cmd, "striped"); if (!lv_add_segment(ah, first_area, 1, tmp_lv, segtype, 0, status, 0)) { log_error("Failed to add segment to LV, %s", img_name); return 0; } lv_set_visible(tmp_lv); *new_lv = tmp_lv; return 1; } static int _alloc_image_components(struct logical_volume *lv, struct dm_list *pvs, uint32_t count, struct dm_list *new_meta_lvs, struct dm_list *new_data_lvs) { uint32_t s; uint32_t region_size; uint32_t extents; struct lv_segment *seg = first_seg(lv); const struct segment_type *segtype; struct alloc_handle *ah; struct dm_list *parallel_areas; struct logical_volume *tmp_lv; struct lv_list *lvl_array; lvl_array = dm_pool_alloc(lv->vg->vgmem, sizeof(*lvl_array) * count * 2); if (!lvl_array) return_0; if (!(parallel_areas = build_parallel_areas_from_lv(lv, 0))) return_0; if (seg_is_linear(seg)) region_size = RAID_REGION_SIZE; else region_size = seg->region_size; if (seg_is_raid(seg)) segtype = seg->segtype; else if (!(segtype = get_segtype_from_string(lv->vg->cmd, "raid1"))) return_0; /* * The number of extents is based on the RAID type. For RAID1, * each of the rimages is the same size - 'le_count'. However * for RAID 4/5/6, the stripes add together (NOT including the parity * devices) to equal 'le_count'. Thus, when we are allocating * individual devies, we must specify how large the individual device * is along with the number we want ('count'). */ extents = (segtype->parity_devs) ? (lv->le_count / (seg->area_count - segtype->parity_devs)) : lv->le_count; if (!(ah = allocate_extents(lv->vg, NULL, segtype, 0, count, count, region_size, extents, pvs, lv->alloc, parallel_areas))) return_0; for (s = 0; s < count; s++) { /* * The allocation areas are grouped together. First * come the rimage allocated areas, then come the metadata * allocated areas. Thus, the metadata areas are pulled * from 's + count'. */ if (!_alloc_image_component(lv, NULL, ah, s + count, RAID_META, &tmp_lv)) return_0; lvl_array[s + count].lv = tmp_lv; dm_list_add(new_meta_lvs, &(lvl_array[s + count].list)); if (!_alloc_image_component(lv, NULL, ah, s, RAID_IMAGE, &tmp_lv)) return_0; lvl_array[s].lv = tmp_lv; dm_list_add(new_data_lvs, &(lvl_array[s].list)); } alloc_destroy(ah); return 1; } /* * _alloc_rmeta_for_lv * @lv * * Allocate a RAID metadata device for the given LV (which is or will * be the associated RAID data device). The new metadata device must * be allocated from the same PV(s) as the data device. */ static int _alloc_rmeta_for_lv(struct logical_volume *data_lv, struct logical_volume **meta_lv) { struct dm_list allocatable_pvs; struct alloc_handle *ah; struct lv_segment *seg = first_seg(data_lv); char *p, base_name[strlen(data_lv->name) + 1]; dm_list_init(&allocatable_pvs); if (!seg_is_linear(seg)) { log_error(INTERNAL_ERROR "Unable to allocate RAID metadata " "area for non-linear LV, %s", data_lv->name); return 0; } sprintf(base_name, "%s", data_lv->name); if ((p = strstr(base_name, "_mimage_"))) *p = '\0'; if (!_get_pv_list_for_lv(data_lv, &allocatable_pvs)) { log_error("Failed to build list of PVs for %s/%s", data_lv->vg->name, data_lv->name); return 0; } if (!(ah = allocate_extents(data_lv->vg, NULL, seg->segtype, 0, 1, 0, seg->region_size, 1 /*RAID_METADATA_AREA_LEN*/, &allocatable_pvs, data_lv->alloc, NULL))) return_0; if (!_alloc_image_component(data_lv, base_name, ah, 0, RAID_META, meta_lv)) return_0; alloc_destroy(ah); return 1; } static int _raid_add_images(struct logical_volume *lv, uint32_t new_count, struct dm_list *pvs) { int rebuild_flag_cleared = 0; uint32_t s; uint32_t old_count = lv_raid_image_count(lv); uint32_t count = new_count - old_count; uint64_t status_mask = -1; struct cmd_context *cmd = lv->vg->cmd; struct lv_segment *seg = first_seg(lv); struct dm_list meta_lvs, data_lvs; struct lv_list *lvl; struct lv_segment_area *new_areas; dm_list_init(&meta_lvs); /* For image addition */ dm_list_init(&data_lvs); /* For image addition */ /* * If the segtype is linear, then we must allocate a metadata * LV to accompany it. */ if (seg_is_linear(seg)) { /* A complete resync will be done, no need to mark each sub-lv */ status_mask = ~(LV_REBUILD); if (!(lvl = dm_pool_alloc(lv->vg->vgmem, sizeof(*lvl)))) { log_error("Memory allocation failed"); return 0; } if (!_alloc_rmeta_for_lv(lv, &lvl->lv)) return_0; dm_list_add(&meta_lvs, &lvl->list); } else if (!seg_is_raid(seg)) { log_error("Unable to add RAID images to %s of segment type %s", lv->name, seg->segtype->name); return 0; } if (!_alloc_image_components(lv, pvs, count, &meta_lvs, &data_lvs)) { log_error("Failed to allocate new image components"); return 0; } /* * If linear, we must correct data LV names. They are off-by-one * because the linear volume hasn't taken its proper name of "_rimage_0" * yet. This action must be done before '_clear_lvs' because it * commits the LVM metadata before clearing the LVs. */ if (seg_is_linear(seg)) { char *name; size_t len; struct dm_list *l; struct lv_list *lvl_tmp; dm_list_iterate(l, &data_lvs) { if (l == dm_list_last(&data_lvs)) { lvl = dm_list_item(l, struct lv_list); len = strlen(lv->name) + strlen("_rimage_XXX"); if (!(name = dm_pool_alloc(lv->vg->vgmem, len))) { log_error("Failed to allocate rimage name."); return 0; } sprintf(name, "%s_rimage_%u", lv->name, count); lvl->lv->name = name; continue; } lvl = dm_list_item(l, struct lv_list); lvl_tmp = dm_list_item(l->n, struct lv_list); lvl->lv->name = lvl_tmp->lv->name; } } /* Metadata LVs must be cleared before being added to the array */ if (!_clear_lvs(&meta_lvs)) goto fail; if (seg_is_linear(seg)) { first_seg(lv)->status |= RAID_IMAGE; if (!insert_layer_for_lv(lv->vg->cmd, lv, RAID | LVM_READ | LVM_WRITE, "_rimage_0")) return_0; lv->status |= RAID; seg = first_seg(lv); seg_lv(seg, 0)->status |= RAID_IMAGE | LVM_READ | LVM_WRITE; seg->region_size = RAID_REGION_SIZE; seg->segtype = get_segtype_from_string(lv->vg->cmd, "raid1"); if (!seg->segtype) return_0; } /* FIXME: It would be proper to activate the new LVs here, instead of having them activated by the suspend. However, this causes residual device nodes to be left for these sub-lvs. dm_list_iterate_items(lvl, &meta_lvs) if (!do_correct_activate(lv, lvl->lv)) return_0; dm_list_iterate_items(lvl, &data_lvs) if (!do_correct_activate(lv, lvl->lv)) return_0; */ /* Expand areas array */ if (!(new_areas = dm_pool_zalloc(lv->vg->cmd->mem, new_count * sizeof(*new_areas)))) goto fail; memcpy(new_areas, seg->areas, seg->area_count * sizeof(*seg->areas)); seg->areas = new_areas; /* Expand meta_areas array */ if (!(new_areas = dm_pool_zalloc(lv->vg->cmd->mem, new_count * sizeof(*new_areas)))) goto fail; if (seg->meta_areas) memcpy(new_areas, seg->meta_areas, seg->area_count * sizeof(*seg->meta_areas)); seg->meta_areas = new_areas; seg->area_count = new_count; /* Add extra meta area when converting from linear */ s = (old_count == 1) ? 0 : old_count; /* Set segment areas for metadata sub_lvs */ dm_list_iterate_items(lvl, &meta_lvs) { log_debug("Adding %s to %s", lvl->lv->name, lv->name); lvl->lv->status &= status_mask; first_seg(lvl->lv)->status &= status_mask; if (!set_lv_segment_area_lv(seg, s, lvl->lv, 0, lvl->lv->status)) { log_error("Failed to add %s to %s", lvl->lv->name, lv->name); goto fail; } s++; } s = old_count; /* Set segment areas for data sub_lvs */ dm_list_iterate_items(lvl, &data_lvs) { log_debug("Adding %s to %s", lvl->lv->name, lv->name); lvl->lv->status &= status_mask; first_seg(lvl->lv)->status &= status_mask; if (!set_lv_segment_area_lv(seg, s, lvl->lv, 0, lvl->lv->status)) { log_error("Failed to add %s to %s", lvl->lv->name, lv->name); goto fail; } s++; } /* * FIXME: Failure handling during these points is harder. */ dm_list_iterate_items(lvl, &meta_lvs) lv_set_hidden(lvl->lv); dm_list_iterate_items(lvl, &data_lvs) lv_set_hidden(lvl->lv); if (!vg_write(lv->vg)) { log_error("Failed to write changes to %s in %s", lv->name, lv->vg->name); return 0; } if (!suspend_lv_origin(cmd, lv)) { log_error("Failed to suspend %s/%s before committing changes", lv->vg->name, lv->name); return 0; } if (!vg_commit(lv->vg)) { log_error("Failed to commit changes to %s in %s", lv->name, lv->vg->name); return 0; } if (!resume_lv_origin(cmd, lv)) { log_error("Failed to resume %s/%s after committing changes", lv->vg->name, lv->name); return 0; } /* * Now that the 'REBUILD' has made its way to the kernel, we must * remove the flag so that the individual devices are not rebuilt * upon every activation. */ seg = first_seg(lv); for (s = 0; s < seg->area_count; s++) { if ((seg_lv(seg, s)->status & LV_REBUILD) || (seg_metalv(seg, s)->status & LV_REBUILD)) { seg_metalv(seg, s)->status &= ~LV_REBUILD; seg_lv(seg, s)->status &= ~LV_REBUILD; rebuild_flag_cleared = 1; } } if (rebuild_flag_cleared && (!vg_write(lv->vg) || !vg_commit(lv->vg))) { log_error("Failed to clear REBUILD flag for %s/%s components", lv->vg->name, lv->name); return 0; } return 1; fail: /* Cleanly remove newly-allocated LVs that failed insertion attempt */ dm_list_iterate_items(lvl, &meta_lvs) if (!lv_remove(lvl->lv)) return_0; dm_list_iterate_items(lvl, &data_lvs) if (!lv_remove(lvl->lv)) return_0; return_0; } /* * _extract_image_components * @seg * @idx: The index in the areas array to remove * @extracted_rmeta: The displaced metadata LV * @extracted_rimage: The displaced data LV * * This function extracts the image components - setting the respective * 'extracted' pointers. It appends '_extracted' to the LVs' names, so that * there are not future conflicts. It does /not/ commit the results. * (IOW, erroring-out requires no unwinding of operations.) * * This function does /not/ attempt to: * 1) shift the 'areas' or 'meta_areas' arrays. * The '[meta_]areas' are left as AREA_UNASSIGNED. * 2) Adjust the seg->area_count * 3) Name the extracted LVs appropriately (appends '_extracted' to names) * These actions must be performed by the caller. * * Returns: 1 on success, 0 on failure */ static int _extract_image_components(struct lv_segment *seg, uint32_t idx, struct logical_volume **extracted_rmeta, struct logical_volume **extracted_rimage) { int len; char *tmp_name; struct volume_group *vg = seg->lv->vg; struct logical_volume *data_lv = seg_lv(seg, idx); struct logical_volume *meta_lv = seg_metalv(seg, idx); log_very_verbose("Extracting image components %s and %s from %s", data_lv->name, meta_lv->name, seg->lv->name); data_lv->status &= ~RAID_IMAGE; meta_lv->status &= ~RAID_META; lv_set_visible(data_lv); lv_set_visible(meta_lv); /* release removes data and meta areas */ remove_seg_from_segs_using_this_lv(data_lv, seg); remove_seg_from_segs_using_this_lv(meta_lv, seg); seg_type(seg, idx) = AREA_UNASSIGNED; seg_metatype(seg, idx) = AREA_UNASSIGNED; len = strlen(meta_lv->name) + strlen("_extracted") + 1; tmp_name = dm_pool_alloc(vg->vgmem, len); if (!tmp_name) return_0; sprintf(tmp_name, "%s_extracted", meta_lv->name); meta_lv->name = tmp_name; len = strlen(data_lv->name) + strlen("_extracted") + 1; tmp_name = dm_pool_alloc(vg->vgmem, len); if (!tmp_name) return_0; sprintf(tmp_name, "%s_extracted", data_lv->name); data_lv->name = tmp_name; *extracted_rmeta = meta_lv; *extracted_rimage = data_lv; return 1; } /* * _raid_extract_images * @lv * @new_count: The absolute count of images (e.g. '2' for a 2-way mirror) * @target_pvs: The list of PVs that are candidates for removal * @shift: If set, use _shift_and_rename_image_components(). * Otherwise, leave the [meta_]areas as AREA_UNASSIGNED and * seg->area_count unchanged. * @extracted_[meta|data]_lvs: The LVs removed from the array. If 'shift' * is set, then there will likely be name conflicts. * * This function extracts _both_ portions of the indexed image. It * does /not/ commit the results. (IOW, erroring-out requires no unwinding * of operations.) * * Returns: 1 on success, 0 on failure */ static int _raid_extract_images(struct logical_volume *lv, uint32_t new_count, struct dm_list *target_pvs, int shift, struct dm_list *extracted_meta_lvs, struct dm_list *extracted_data_lvs) { int s, extract, lvl_idx = 0; struct lv_list *lvl_array; struct lv_segment *seg = first_seg(lv); struct logical_volume *rmeta_lv, *rimage_lv; extract = seg->area_count - new_count; log_verbose("Extracting %u %s from %s/%s", extract, (extract > 1) ? "images" : "image", lv->vg->name, lv->name); lvl_array = dm_pool_alloc(lv->vg->vgmem, sizeof(*lvl_array) * extract * 2); if (!lvl_array) return_0; for (s = seg->area_count - 1; (s >= 0) && extract; s--) { if (!_lv_is_on_pvs(seg_lv(seg, s), target_pvs) || !_lv_is_on_pvs(seg_metalv(seg, s), target_pvs)) continue; if (!_raid_in_sync(lv) && (!seg_is_mirrored(seg) || (s == 0))) { log_error("Unable to extract %sRAID image" " while RAID array is not in-sync", seg_is_mirrored(seg) ? "primary " : ""); return 0; } if (!_extract_image_components(seg, s, &rmeta_lv, &rimage_lv)) { log_error("Failed to extract %s from %s", seg_lv(seg, s)->name, lv->name); return 0; } if (shift && !_shift_and_rename_image_components(seg)) { log_error("Failed to shift and rename image components"); return 0; } lvl_array[lvl_idx].lv = rmeta_lv; lvl_array[lvl_idx + 1].lv = rimage_lv; dm_list_add(extracted_meta_lvs, &(lvl_array[lvl_idx++].list)); dm_list_add(extracted_data_lvs, &(lvl_array[lvl_idx++].list)); extract--; } if (extract) { log_error("Unable to extract enough images to satisfy request"); return 0; } return 1; } static int _raid_remove_images(struct logical_volume *lv, uint32_t new_count, struct dm_list *pvs) { struct dm_list removal_list; struct lv_list *lvl; dm_list_init(&removal_list); if (!_raid_extract_images(lv, new_count, pvs, 1, &removal_list, &removal_list)) { log_error("Failed to extract images from %s/%s", lv->vg->name, lv->name); return 0; } /* Convert to linear? */ if ((new_count == 1) && !_raid_remove_top_layer(lv, &removal_list)) { log_error("Failed to remove RAID layer after linear conversion"); return 0; } if (!vg_write(lv->vg)) { log_error("Failed to write changes to %s in %s", lv->name, lv->vg->name); return 0; } if (!suspend_lv(lv->vg->cmd, lv)) { log_error("Failed to suspend %s/%s before committing changes", lv->vg->name, lv->name); return 0; } if (!vg_commit(lv->vg)) { log_error("Failed to commit changes to %s in %s", lv->name, lv->vg->name); return 0; } /* * We resume the extracted sub-LVs first so they are renamed * and won't conflict with the remaining (possibly shifted) * sub-LVs. */ dm_list_iterate_items(lvl, &removal_list) { if (!resume_lv(lv->vg->cmd, lvl->lv)) { log_error("Failed to resume extracted LVs"); return 0; } } /* * Resume the remaining LVs * We must start by resuming the sub-LVs first (which would * otherwise be handled automatically) because the shifting * of positions could otherwise cause name collisions. For * example, if position 0 of a 3-way array is removed, position * 1 and 2 must be shifted and renamed 0 and 1. If position 2 * tries to rename first, it will collide with the existing * position 1. */ if (!_bottom_up_resume(lv)) { log_error("Failed to resume %s/%s after committing changes", lv->vg->name, lv->name); return 0; } /* * Eliminate the extracted LVs */ sync_local_dev_names(lv->vg->cmd); if (!dm_list_empty(&removal_list)) { dm_list_iterate_items(lvl, &removal_list) { if (!deactivate_lv(lv->vg->cmd, lvl->lv)) return_0; if (!lv_remove(lvl->lv)) return_0; } if (!vg_write(lv->vg) || !vg_commit(lv->vg)) return_0; } return 1; } /* * lv_raid_change_image_count * @lv * @new_count: The absolute count of images (e.g. '2' for a 2-way mirror) * @pvs: The list of PVs that are candidates for removal (or empty list) * * RAID arrays have 'images' which are composed of two parts, they are: * - 'rimage': The data/parity holding portion * - 'rmeta' : The metadata holding portion (i.e. superblock/bitmap area) * This function adds or removes _both_ portions of the image and commits * the results. * * Returns: 1 on success, 0 on failure */ int lv_raid_change_image_count(struct logical_volume *lv, uint32_t new_count, struct dm_list *pvs) { uint32_t old_count = lv_raid_image_count(lv); if (old_count == new_count) { log_error("%s/%s already has image count of %d", lv->vg->name, lv->name, new_count); return 1; } if (old_count > new_count) return _raid_remove_images(lv, new_count, pvs); return _raid_add_images(lv, new_count, pvs); } int lv_raid_split(struct logical_volume *lv, const char *split_name, uint32_t new_count, struct dm_list *splittable_pvs) { const char *old_name; struct lv_list *lvl; struct dm_list removal_list, data_list; struct cmd_context *cmd = lv->vg->cmd; uint32_t old_count = lv_raid_image_count(lv); struct logical_volume *tracking; struct dm_list tracking_pvs; dm_list_init(&removal_list); dm_list_init(&data_list); if ((old_count - new_count) != 1) { log_error("Unable to split more than one image from %s/%s", lv->vg->name, lv->name); return 0; } if (!seg_is_mirrored(first_seg(lv))) { log_error("Unable to split logical volume of segment type, %s", first_seg(lv)->segtype->name); return 0; } if (find_lv_in_vg(lv->vg, split_name)) { log_error("Logical Volume \"%s\" already exists in %s", split_name, lv->vg->name); return 0; } if (!_raid_in_sync(lv)) { log_error("Unable to split %s/%s while it is not in-sync.", lv->vg->name, lv->name); return 0; } /* * We only allow a split while there is tracking if it is to * complete the split of the tracking sub-LV */ if (_lv_is_raid_with_tracking(lv, &tracking)) { if (!_lv_is_on_pvs(tracking, splittable_pvs)) { log_error("Unable to split additional image from %s " "while tracking changes for %s", lv->name, tracking->name); return 0; } else { /* Ensure we only split the tracking image */ dm_list_init(&tracking_pvs); splittable_pvs = &tracking_pvs; if (!_get_pv_list_for_lv(tracking, splittable_pvs)) return_0; } } if (!_raid_extract_images(lv, new_count, splittable_pvs, 1, &removal_list, &data_list)) { log_error("Failed to extract images from %s/%s", lv->vg->name, lv->name); return 0; } /* Convert to linear? */ if ((new_count == 1) && !_raid_remove_top_layer(lv, &removal_list)) { log_error("Failed to remove RAID layer after linear conversion"); return 0; } /* Get first item */ dm_list_iterate_items(lvl, &data_list) break; old_name = lvl->lv->name; lvl->lv->name = split_name; if (!vg_write(lv->vg)) { log_error("Failed to write changes to %s in %s", lv->name, lv->vg->name); return 0; } if (!suspend_lv(cmd, lv)) { log_error("Failed to suspend %s/%s before committing changes", lv->vg->name, lv->name); return 0; } if (!vg_commit(lv->vg)) { log_error("Failed to commit changes to %s in %s", lv->name, lv->vg->name); return 0; } /* * First resume the newly split LV and LVs on the removal list. * This is necessary so that there are no name collisions due to * the original RAID LV having possibly had sub-LVs that have been * shifted and renamed. */ if (!resume_lv(cmd, lvl->lv)) return_0; dm_list_iterate_items(lvl, &removal_list) if (!resume_lv(cmd, lvl->lv)) return_0; /* * Resume the remaining LVs * We must start by resuming the sub-LVs first (which would * otherwise be handled automatically) because the shifting * of positions could otherwise cause name collisions. For * example, if position 0 of a 3-way array is split, position * 1 and 2 must be shifted and renamed 0 and 1. If position 2 * tries to rename first, it will collide with the existing * position 1. */ if (!_bottom_up_resume(lv)) { log_error("Failed to resume %s/%s after committing changes", lv->vg->name, lv->name); return 0; } /* * Eliminate the residual LVs */ dm_list_iterate_items(lvl, &removal_list) { if (!deactivate_lv(cmd, lvl->lv)) return_0; if (!lv_remove(lvl->lv)) return_0; } if (!vg_write(lv->vg) || !vg_commit(lv->vg)) return_0; return 1; } /* * lv_raid_split_and_track * @lv * @splittable_pvs * * Only allows a single image to be split while tracking. The image * never actually leaves the mirror. It is simply made visible. This * action triggers two things: 1) users are able to access the (data) image * and 2) lower layers replace images marked with a visible flag with * error targets. * * Returns: 1 on success, 0 on error */ int lv_raid_split_and_track(struct logical_volume *lv, struct dm_list *splittable_pvs) { int s; struct lv_segment *seg = first_seg(lv); if (!seg_is_mirrored(seg)) { log_error("Unable to split images from non-mirrored RAID"); return 0; } if (!_raid_in_sync(lv)) { log_error("Unable to split image from %s/%s while not in-sync", lv->vg->name, lv->name); return 0; } /* Cannot track two split images at once */ if (lv_is_raid_with_tracking(lv)) { log_error("Cannot track more than one split image at a time"); return 0; } for (s = seg->area_count - 1; s >= 0; s--) { if (!_lv_is_on_pvs(seg_lv(seg, s), splittable_pvs)) continue; lv_set_visible(seg_lv(seg, s)); seg_lv(seg, s)->status &= ~LVM_WRITE; break; } if (s >= seg->area_count) { log_error("Unable to find image to satisfy request"); return 0; } if (!vg_write(lv->vg)) { log_error("Failed to write changes to %s in %s", lv->name, lv->vg->name); return 0; } if (!suspend_lv(lv->vg->cmd, lv)) { log_error("Failed to suspend %s/%s before committing changes", lv->vg->name, lv->name); return 0; } if (!vg_commit(lv->vg)) { log_error("Failed to commit changes to %s in %s", lv->name, lv->vg->name); return 0; } log_print_unless_silent("%s split from %s for read-only purposes.", seg_lv(seg, s)->name, lv->name); /* Resume original LV */ if (!resume_lv(lv->vg->cmd, lv)) { log_error("Failed to resume %s/%s after committing changes", lv->vg->name, lv->name); return 0; } /* Activate the split (and tracking) LV */ if (!_activate_sublv_preserving_excl(lv, seg_lv(seg, s))) return 0; log_print_unless_silent("Use 'lvconvert --merge %s/%s' to merge back into %s", lv->vg->name, seg_lv(seg, s)->name, lv->name); return 1; } int lv_raid_merge(struct logical_volume *image_lv) { uint32_t s; char *p, *lv_name; struct lv_list *lvl; struct logical_volume *lv; struct logical_volume *meta_lv = NULL; struct lv_segment *seg; struct volume_group *vg = image_lv->vg; lv_name = dm_pool_strdup(vg->vgmem, image_lv->name); if (!lv_name) return_0; if (!(p = strstr(lv_name, "_rimage_"))) { log_error("Unable to merge non-mirror image %s/%s", vg->name, image_lv->name); return 0; } *p = '\0'; /* lv_name is now that of top-level RAID */ if (image_lv->status & LVM_WRITE) { log_error("%s/%s is not read-only - refusing to merge", vg->name, image_lv->name); return 0; } if (!(lvl = find_lv_in_vg(vg, lv_name))) { log_error("Unable to find containing RAID array for %s/%s", vg->name, image_lv->name); return 0; } lv = lvl->lv; seg = first_seg(lv); for (s = 0; s < seg->area_count; s++) { if (seg_lv(seg, s) == image_lv) { meta_lv = seg_metalv(seg, s); } } if (!meta_lv) return_0; if (!deactivate_lv(vg->cmd, meta_lv)) { log_error("Failed to deactivate %s", meta_lv->name); return 0; } if (!deactivate_lv(vg->cmd, image_lv)) { log_error("Failed to deactivate %s/%s before merging", vg->name, image_lv->name); return 0; } lv_set_hidden(image_lv); image_lv->status |= (lv->status & LVM_WRITE); image_lv->status |= RAID_IMAGE; if (!vg_write(vg)) { log_error("Failed to write changes to %s in %s", lv->name, vg->name); return 0; } if (!suspend_lv(vg->cmd, lv)) { log_error("Failed to suspend %s/%s before committing changes", vg->name, lv->name); return 0; } if (!vg_commit(vg)) { log_error("Failed to commit changes to %s in %s", lv->name, vg->name); return 0; } if (!resume_lv(vg->cmd, lv)) { log_error("Failed to resume %s/%s after committing changes", vg->name, lv->name); return 0; } log_print_unless_silent("%s/%s successfully merged back into %s/%s", vg->name, image_lv->name, vg->name, lv->name); return 1; } static int _convert_mirror_to_raid1(struct logical_volume *lv, const struct segment_type *new_segtype) { uint32_t s; struct lv_segment *seg = first_seg(lv); struct lv_list lvl_array[seg->area_count], *lvl; struct dm_list meta_lvs; struct lv_segment_area *meta_areas; dm_list_init(&meta_lvs); if (!_raid_in_sync(lv)) { log_error("Unable to convert %s/%s while it is not in-sync", lv->vg->name, lv->name); return 0; } meta_areas = dm_pool_zalloc(lv->vg->vgmem, lv_mirror_count(lv) * sizeof(*meta_areas)); if (!meta_areas) { log_error("Failed to allocate memory"); return 0; } for (s = 0; s < seg->area_count; s++) { log_debug("Allocating new metadata LV for %s", seg_lv(seg, s)->name); if (!_alloc_rmeta_for_lv(seg_lv(seg, s), &(lvl_array[s].lv))) { log_error("Failed to allocate metadata LV for %s in %s", seg_lv(seg, s)->name, lv->name); return 0; } dm_list_add(&meta_lvs, &(lvl_array[s].list)); } log_debug("Clearing newly allocated metadata LVs"); if (!_clear_lvs(&meta_lvs)) { log_error("Failed to initialize metadata LVs"); return 0; } if (seg->log_lv) { log_debug("Removing mirror log, %s", seg->log_lv->name); if (!remove_mirror_log(lv->vg->cmd, lv, NULL, 0)) { log_error("Failed to remove mirror log"); return 0; } } seg->meta_areas = meta_areas; s = 0; dm_list_iterate_items(lvl, &meta_lvs) { log_debug("Adding %s to %s", lvl->lv->name, lv->name); /* Images are known to be in-sync */ lvl->lv->status &= ~LV_REBUILD; first_seg(lvl->lv)->status &= ~LV_REBUILD; lv_set_hidden(lvl->lv); if (!set_lv_segment_area_lv(seg, s, lvl->lv, 0, lvl->lv->status)) { log_error("Failed to add %s to %s", lvl->lv->name, lv->name); return 0; } s++; } for (s = 0; s < seg->area_count; s++) { char *new_name; new_name = dm_pool_zalloc(lv->vg->vgmem, strlen(lv->name) + strlen("_rimage_XXn")); if (!new_name) { log_error("Failed to rename mirror images"); return 0; } sprintf(new_name, "%s_rimage_%u", lv->name, s); log_debug("Renaming %s to %s", seg_lv(seg, s)->name, new_name); seg_lv(seg, s)->name = new_name; seg_lv(seg, s)->status &= ~MIRROR_IMAGE; seg_lv(seg, s)->status |= RAID_IMAGE; } init_mirror_in_sync(1); log_debug("Setting new segtype for %s", lv->name); seg->segtype = new_segtype; lv->status &= ~MIRRORED; lv->status |= RAID; seg->status |= RAID; if (!vg_write(lv->vg)) { log_error("Failed to write changes to %s in %s", lv->name, lv->vg->name); return 0; } if (!suspend_lv(lv->vg->cmd, lv)) { log_error("Failed to suspend %s/%s before committing changes", lv->vg->name, lv->name); return 0; } if (!vg_commit(lv->vg)) { log_error("Failed to commit changes to %s in %s", lv->name, lv->vg->name); return 0; } if (!resume_lv(lv->vg->cmd, lv)) { log_error("Failed to resume %s/%s after committing changes", lv->vg->name, lv->name); return 0; } return 1; } /* * lv_raid_reshape * @lv * @new_segtype * * Convert an LV from one RAID type (or 'mirror' segtype) to another. * * Returns: 1 on success, 0 on failure */ int lv_raid_reshape(struct logical_volume *lv, const struct segment_type *new_segtype) { struct lv_segment *seg = first_seg(lv); if (!new_segtype) { log_error(INTERNAL_ERROR "New segtype not specified"); return 0; } if (!strcmp(seg->segtype->name, "mirror") && (!strcmp(new_segtype->name, "raid1"))) return _convert_mirror_to_raid1(lv, new_segtype); log_error("Converting the segment type for %s/%s from %s to %s" " is not yet supported.", lv->vg->name, lv->name, seg->segtype->name, new_segtype->name); return 0; } /* * lv_raid_replace * @lv * @replace_pvs * @allocatable_pvs * * Replace the specified PVs. */ int lv_raid_replace(struct logical_volume *lv, struct dm_list *remove_pvs, struct dm_list *allocate_pvs) { uint32_t s, sd, match_count = 0; struct dm_list old_meta_lvs, old_data_lvs; struct dm_list new_meta_lvs, new_data_lvs; struct lv_segment *raid_seg = first_seg(lv); struct lv_list *lvl; char *tmp_names[raid_seg->area_count * 2]; dm_list_init(&old_meta_lvs); dm_list_init(&old_data_lvs); dm_list_init(&new_meta_lvs); dm_list_init(&new_data_lvs); /* * How many sub-LVs are being removed? */ for (s = 0; s < raid_seg->area_count; s++) { if ((seg_type(raid_seg, s) == AREA_UNASSIGNED) || (seg_metatype(raid_seg, s) == AREA_UNASSIGNED)) { log_error("Unable to replace RAID images while the " "array has unassigned areas"); return 0; } if (_lv_is_on_pvs(seg_lv(raid_seg, s), remove_pvs) || _lv_is_on_pvs(seg_metalv(raid_seg, s), remove_pvs)) match_count++; } if (!match_count) { log_verbose("%s/%s does not contain devices specified" " for replacement", lv->vg->name, lv->name); return 1; } else if (match_count == raid_seg->area_count) { log_error("Unable to remove all PVs from %s/%s at once.", lv->vg->name, lv->name); return 0; } else if (raid_seg->segtype->parity_devs && (match_count > raid_seg->segtype->parity_devs)) { log_error("Unable to replace more than %u PVs from (%s) %s/%s", raid_seg->segtype->parity_devs, raid_seg->segtype->name, lv->vg->name, lv->name); return 0; } else if (!strcmp(raid_seg->segtype->name, "raid10")) { uint32_t i, rebuilds_per_group = 0; /* FIXME: We only support 2-way mirrors in RAID10 currently */ uint32_t copies = 2; for (i = 0; i < raid_seg->area_count * copies; i++) { s = i % raid_seg->area_count; if (!(i % copies)) rebuilds_per_group = 0; if (_lv_is_on_pvs(seg_lv(raid_seg, s), remove_pvs) || _lv_is_on_pvs(seg_metalv(raid_seg, s), remove_pvs)) rebuilds_per_group++; if (rebuilds_per_group >= copies) { log_error("Unable to replace all the devices " "in a RAID10 mirror group."); return 0; } } } /* * Allocate the new image components first * - This makes it easy to avoid all currently used devs * - We can immediately tell if there is enough space * * - We need to change the LV names when we insert them. */ try_again: if (!_alloc_image_components(lv, allocate_pvs, match_count, &new_meta_lvs, &new_data_lvs)) { log_error("Failed to allocate replacement images for %s/%s", lv->vg->name, lv->name); /* * If this is a repair, then try to * do better than all-or-nothing */ if (match_count > 1) { log_error("Attempting replacement of %u devices" " instead of %u", match_count - 1, match_count); match_count--; /* * Since we are replacing some but not all of the bad * devices, we must set partial_activation */ lv->vg->cmd->partial_activation = 1; goto try_again; } return 0; } /* * Remove the old images * - If we did this before the allocate, we wouldn't have to rename * the allocated images, but it'd be much harder to avoid the right * PVs during allocation. */ if (!_raid_extract_images(lv, raid_seg->area_count - match_count, remove_pvs, 0, &old_meta_lvs, &old_data_lvs)) { log_error("Failed to remove the specified images from %s/%s", lv->vg->name, lv->name); return 0; } /* * Skip metadata operation normally done to clear the metadata sub-LVs. * * The LV_REBUILD flag is set on the new sub-LVs, * so they will be rebuilt and we don't need to clear the metadata dev. */ for (s = 0; s < raid_seg->area_count; s++) { tmp_names[s] = NULL; sd = s + raid_seg->area_count; tmp_names[sd] = NULL; if ((seg_type(raid_seg, s) == AREA_UNASSIGNED) && (seg_metatype(raid_seg, s) == AREA_UNASSIGNED)) { /* Adjust the new metadata LV name */ lvl = dm_list_item(dm_list_first(&new_meta_lvs), struct lv_list); dm_list_del(&lvl->list); tmp_names[s] = dm_pool_alloc(lv->vg->vgmem, strlen(lvl->lv->name) + 1); if (!tmp_names[s]) return_0; if (dm_snprintf(tmp_names[s], strlen(lvl->lv->name) + 1, "%s_rmeta_%u", lv->name, s) < 0) return_0; if (!set_lv_segment_area_lv(raid_seg, s, lvl->lv, 0, lvl->lv->status)) { log_error("Failed to add %s to %s", lvl->lv->name, lv->name); return 0; } lv_set_hidden(lvl->lv); /* Adjust the new data LV name */ lvl = dm_list_item(dm_list_first(&new_data_lvs), struct lv_list); dm_list_del(&lvl->list); tmp_names[sd] = dm_pool_alloc(lv->vg->vgmem, strlen(lvl->lv->name) + 1); if (!tmp_names[sd]) return_0; if (dm_snprintf(tmp_names[sd], strlen(lvl->lv->name) + 1, "%s_rimage_%u", lv->name, s) < 0) return_0; if (!set_lv_segment_area_lv(raid_seg, s, lvl->lv, 0, lvl->lv->status)) { log_error("Failed to add %s to %s", lvl->lv->name, lv->name); return 0; } lv_set_hidden(lvl->lv); } } if (!vg_write(lv->vg)) { log_error("Failed to write changes to %s in %s", lv->name, lv->vg->name); return 0; } if (!suspend_lv_origin(lv->vg->cmd, lv)) { log_error("Failed to suspend %s/%s before committing changes", lv->vg->name, lv->name); return 0; } if (!vg_commit(lv->vg)) { log_error("Failed to commit changes to %s in %s", lv->name, lv->vg->name); return 0; } if (!resume_lv_origin(lv->vg->cmd, lv)) { log_error("Failed to resume %s/%s after committing changes", lv->vg->name, lv->name); return 0; } dm_list_iterate_items(lvl, &old_meta_lvs) { if (!deactivate_lv(lv->vg->cmd, lvl->lv)) return_0; if (!lv_remove(lvl->lv)) return_0; } dm_list_iterate_items(lvl, &old_data_lvs) { if (!deactivate_lv(lv->vg->cmd, lvl->lv)) return_0; if (!lv_remove(lvl->lv)) return_0; } /* Update new sub-LVs to correct name and clear REBUILD flag */ for (s = 0; s < raid_seg->area_count; s++) { sd = s + raid_seg->area_count; if (tmp_names[s] && tmp_names[sd]) { seg_metalv(raid_seg, s)->name = tmp_names[s]; seg_lv(raid_seg, s)->name = tmp_names[sd]; seg_metalv(raid_seg, s)->status &= ~LV_REBUILD; seg_lv(raid_seg, s)->status &= ~LV_REBUILD; } } if (!vg_write(lv->vg)) { log_error("Failed to write changes to %s in %s", lv->name, lv->vg->name); return 0; } if (!suspend_lv_origin(lv->vg->cmd, lv)) { log_error("Failed to suspend %s/%s before committing changes", lv->vg->name, lv->name); return 0; } if (!vg_commit(lv->vg)) { log_error("Failed to commit changes to %s in %s", lv->name, lv->vg->name); return 0; } if (!resume_lv_origin(lv->vg->cmd, lv)) { log_error("Failed to resume %s/%s after committing changes", lv->vg->name, lv->name); return 0; } return 1; }