/* * Copyright (C) 2003 Sistina Software, Inc. All rights reserved. * Copyright (C) 2004-2006 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 "pv_alloc.h" #include "toolcontext.h" #include "locking.h" #include "defaults.h" #include "lvmcache.h" #include "lvmetad.h" #include "display.h" #include "label.h" #include "archiver.h" #include "lvm-signal.h" static struct pv_segment *_alloc_pv_segment(struct dm_pool *mem, struct physical_volume *pv, uint32_t pe, uint32_t len, struct lv_segment *lvseg, uint32_t lv_area) { struct pv_segment *peg; if (!(peg = dm_pool_zalloc(mem, sizeof(*peg)))) { log_error("pv_segment allocation failed"); return NULL; } peg->pv = pv; peg->pe = pe; peg->len = len; peg->lvseg = lvseg; peg->lv_area = lv_area; dm_list_init(&peg->list); return peg; } int alloc_pv_segment_whole_pv(struct dm_pool *mem, struct physical_volume *pv) { struct pv_segment *peg; if (!pv->pe_count) return 1; /* FIXME Cope with holes in PVs */ if (!(peg = _alloc_pv_segment(mem, pv, 0, pv->pe_count, NULL, 0))) return_0; dm_list_add(&pv->segments, &peg->list); return 1; } int peg_dup(struct dm_pool *mem, struct dm_list *peg_new, struct dm_list *peg_old) { struct pv_segment *peg, *pego; dm_list_init(peg_new); dm_list_iterate_items(pego, peg_old) { if (!(peg = _alloc_pv_segment(mem, pego->pv, pego->pe, pego->len, pego->lvseg, pego->lv_area))) return_0; dm_list_add(peg_new, &peg->list); } return 1; } /* Find segment at a given physical extent in a PV */ static struct pv_segment *find_peg_by_pe(const struct physical_volume *pv, uint32_t pe) { struct pv_segment *pvseg; /* search backwards to optimise mostly used last segment split */ dm_list_iterate_back_items(pvseg, &pv->segments) if (pe >= pvseg->pe && pe < pvseg->pe + pvseg->len) return pvseg; return NULL; } /* * Split peg at given extent. * Second part is always not allocated to a LV and returned. */ static struct pv_segment *_pv_split_segment(struct dm_pool *mem, struct physical_volume *pv, struct pv_segment *peg, uint32_t pe) { struct pv_segment *peg_new; if (!(peg_new = _alloc_pv_segment(mem, peg->pv, pe, peg->len + peg->pe - pe, NULL, 0))) return_NULL; peg->len = peg->len - peg_new->len; dm_list_add_h(&peg->list, &peg_new->list); if (peg->lvseg) { peg->pv->pe_alloc_count -= peg_new->len; peg->lvseg->lv->vg->free_count += peg_new->len; } return peg_new; } /* * Ensure there is a PV segment boundary at the given extent. */ int pv_split_segment(struct dm_pool *mem, struct physical_volume *pv, uint32_t pe, struct pv_segment **pvseg_allocated) { struct pv_segment *pvseg, *pvseg_new = NULL; if (pe == pv->pe_count) goto out; if (!(pvseg = find_peg_by_pe(pv, pe))) { log_error("Segment with extent %" PRIu32 " in PV %s not found", pe, pv_dev_name(pv)); return 0; } /* This is a peg start already */ if (pe == pvseg->pe) { pvseg_new = pvseg; goto out; } if (!(pvseg_new = _pv_split_segment(mem, pv, pvseg, pe))) return_0; out: if (pvseg_allocated) *pvseg_allocated = pvseg_new; return 1; } static struct pv_segment null_pv_segment = { .pv = NULL, .pe = 0, }; struct pv_segment *assign_peg_to_lvseg(struct physical_volume *pv, uint32_t pe, uint32_t area_len, struct lv_segment *seg, uint32_t area_num) { struct pv_segment *peg = NULL; /* Missing format1 PV */ if (!pv) return &null_pv_segment; if (!pv_split_segment(seg->lv->vg->vgmem, pv, pe, &peg) || !pv_split_segment(seg->lv->vg->vgmem, pv, pe + area_len, NULL)) return_NULL; if (!peg) { log_error("Missing PV segment on %s at %u.", pv_dev_name(pv), pe); return NULL; } peg->lvseg = seg; peg->lv_area = area_num; peg->pv->pe_alloc_count += area_len; peg->lvseg->lv->vg->free_count -= area_len; return peg; } int discard_pv_segment(struct pv_segment *peg, uint32_t discard_area_reduction) { uint64_t discard_offset_sectors; uint64_t pe_start = peg->pv->pe_start; char uuid[64] __attribute__((aligned(8))); if (!peg->lvseg) { log_error("discard_pv_segment with unallocated segment: " "%s PE %" PRIu32, pv_dev_name(peg->pv), peg->pe); return 0; } /* * Only issue discards if enabled in lvm.conf and both * the device and kernel (>= 2.6.35) supports discards. */ if (!find_config_tree_bool(peg->pv->fmt->cmd, devices_issue_discards_CFG, NULL)) return 1; /* Missing PV? */ if (is_missing_pv(peg->pv) || !peg->pv->dev) { if (!id_write_format(&peg->pv->id, uuid, sizeof(uuid))) return_0; log_verbose("Skipping discard on missing device with uuid %s.", uuid); return 1; } if (!dev_discard_max_bytes(peg->pv->fmt->cmd->dev_types, peg->pv->dev) || !dev_discard_granularity(peg->pv->fmt->cmd->dev_types, peg->pv->dev)) return 1; discard_offset_sectors = (peg->pe + peg->lvseg->area_len - discard_area_reduction) * (uint64_t) peg->pv->vg->extent_size + pe_start; if (!discard_offset_sectors) { /* * pe_start=0 and the PV's first extent contains the label. * Must skip past the first extent. */ discard_offset_sectors = peg->pv->vg->extent_size; discard_area_reduction--; } log_debug_alloc("Discarding %" PRIu32 " extents offset %" PRIu64 " sectors on %s.", discard_area_reduction, discard_offset_sectors, dev_name(peg->pv->dev)); if (discard_area_reduction && !dev_discard_blocks(peg->pv->dev, discard_offset_sectors << SECTOR_SHIFT, discard_area_reduction * (uint64_t) peg->pv->vg->extent_size * SECTOR_SIZE)) return_0; return 1; } static int _merge_free_pv_segment(struct pv_segment *peg) { struct dm_list *l; struct pv_segment *merge_peg; if (peg->lvseg) { log_error(INTERNAL_ERROR "_merge_free_pv_seg called on a" " segment that is not free."); return 0; } /* * FIXME: * Should we free the list element once it is deleted * from the list? I think not. It is likely part of * a mempool. */ /* Attempt to merge with Free space before */ if ((l = dm_list_prev(&peg->pv->segments, &peg->list))) { merge_peg = dm_list_item(l, struct pv_segment); if (!merge_peg->lvseg) { merge_peg->len += peg->len; dm_list_del(&peg->list); peg = merge_peg; } } /* Attempt to merge with Free space after */ if ((l = dm_list_next(&peg->pv->segments, &peg->list))) { merge_peg = dm_list_item(l, struct pv_segment); if (!merge_peg->lvseg) { peg->len += merge_peg->len; dm_list_del(&merge_peg->list); } } return 1; } /* * release_pv_segment * @peg * @area_reduction * * WARNING: When release_pv_segment is called, the freed space may be * merged into the 'pv_segment's before and after it in the * list if they are also free. Thus, any iterators of the * 'pv->segments' list that call this function must be aware * that the list can change in a way that is unsafe even for * *_safe iterators. Restart the iterator in these cases. * * Returns: 1 on success, 0 on failure */ int release_pv_segment(struct pv_segment *peg, uint32_t area_reduction) { struct dm_list *l; struct pv_segment *merge_peg; if (!peg->lvseg) { log_error("release_pv_segment with unallocated segment: " "%s PE %" PRIu32, pv_dev_name(peg->pv), peg->pe); return 0; } if (peg->lvseg->area_len == area_reduction) { peg->pv->pe_alloc_count -= area_reduction; peg->lvseg->lv->vg->free_count += area_reduction; peg->lvseg = NULL; peg->lv_area = 0; return _merge_free_pv_segment(peg); } if (!pv_split_segment(peg->lvseg->lv->vg->vgmem, peg->pv, peg->pe + peg->lvseg->area_len - area_reduction, NULL)) return_0; /* The segment after 'peg' now holds free space, try to merge it */ if ((l = dm_list_next(&peg->pv->segments, &peg->list))) { merge_peg = dm_list_item(l, struct pv_segment); return _merge_free_pv_segment(merge_peg); } return 1; } /* * Only for use by lv_segment merging routines. */ void merge_pv_segments(struct pv_segment *peg1, struct pv_segment *peg2) { peg1->len += peg2->len; dm_list_del(&peg2->list); } /* * Calculate the overlap, in extents, between a struct pv_segment and * a struct pe_range. */ static uint32_t _overlap_pe(const struct pv_segment *pvseg, const struct pe_range *per) { uint32_t start; uint32_t end; start = max(pvseg->pe, per->start); end = min(pvseg->pe + pvseg->len, per->start + per->count); if (end < start) return 0; else return end - start; } /* * Returns: number of free PEs in a struct pv_list */ uint32_t pv_list_extents_free(const struct dm_list *pvh) { struct pv_list *pvl; struct pe_range *per; uint32_t extents = 0; struct pv_segment *pvseg; dm_list_iterate_items(pvl, pvh) { if (!pvl->pe_ranges) { log_warn(INTERNAL_ERROR "WARNING: PV %s is without initialized PE ranges.", dev_name(pvl->pv->dev)); continue; } dm_list_iterate_items(per, pvl->pe_ranges) { dm_list_iterate_items(pvseg, &pvl->pv->segments) { if (!pvseg_is_allocated(pvseg)) extents += _overlap_pe(pvseg, per); } } } return extents; } /* * Check all pv_segments in VG for consistency */ int check_pv_segments(struct volume_group *vg) { struct physical_volume *pv; struct pv_list *pvl; struct pv_segment *peg; unsigned s, segno; uint32_t start_pe, alloced; uint32_t pv_count = 0, free_count = 0, extent_count = 0; int ret = 1; dm_list_iterate_items(pvl, &vg->pvs) { pv = pvl->pv; segno = 0; start_pe = 0; alloced = 0; pv_count++; dm_list_iterate_items(peg, &pv->segments) { s = peg->lv_area; /* FIXME Remove this next line eventually */ log_debug_alloc("%s %u: %6u %6u: %s(%u:%u)", pv_dev_name(pv), segno++, peg->pe, peg->len, peg->lvseg ? peg->lvseg->lv->name : "NULL", peg->lvseg ? peg->lvseg->le : 0, s); /* FIXME Add details here on failure instead */ if (start_pe != peg->pe) { log_error("Gap in pvsegs: %u, %u", start_pe, peg->pe); ret = 0; } if (peg->lvseg) { if (seg_type(peg->lvseg, s) != AREA_PV) { log_error("Wrong lvseg area type"); ret = 0; } if (seg_pvseg(peg->lvseg, s) != peg) { log_error("Inconsistent pvseg pointers"); ret = 0; } if (peg->lvseg->area_len != peg->len) { log_error("Inconsistent length: %u %u", peg->len, peg->lvseg->area_len); ret = 0; } alloced += peg->len; } start_pe += peg->len; } if (start_pe != pv->pe_count) { log_error("PV segment pe_count mismatch: %u != %u", start_pe, pv->pe_count); ret = 0; } if (alloced != pv->pe_alloc_count) { log_error("PV segment pe_alloc_count mismatch: " "%u != %u", alloced, pv->pe_alloc_count); ret = 0; } extent_count += start_pe; free_count += (start_pe - alloced); } if (pv_count != vg->pv_count) { log_error("PV segment VG pv_count mismatch: %u != %u", pv_count, vg->pv_count); ret = 0; } if (free_count != vg->free_count) { log_error("PV segment VG free_count mismatch: %u != %u", free_count, vg->free_count); ret = 0; } if (extent_count != vg->extent_count) { log_error("PV segment VG extent_count mismatch: %u != %u", extent_count, vg->extent_count); ret = 0; } return ret; } static int _reduce_pv(struct physical_volume *pv, struct volume_group *vg, uint32_t old_pe_count, uint32_t new_pe_count) { struct pv_segment *peg, *pegt; if (new_pe_count < pv->pe_alloc_count) { log_error("%s: cannot resize to %" PRIu32 " extents " "as %" PRIu32 " are allocated.", pv_dev_name(pv), new_pe_count, pv->pe_alloc_count); return 0; } /* Check PEs to be removed are not already allocated */ dm_list_iterate_items(peg, &pv->segments) { if (peg->pe + peg->len <= new_pe_count) continue; if (peg->lvseg) { log_error("%s: cannot resize to %" PRIu32 " extents as " "later ones are allocated.", pv_dev_name(pv), new_pe_count); return 0; } } if (!pv_split_segment(vg->vgmem, pv, new_pe_count, NULL)) return_0; dm_list_iterate_items_safe(peg, pegt, &pv->segments) { if (peg->pe + peg->len > new_pe_count) dm_list_del(&peg->list); } pv->pe_count = new_pe_count; vg->extent_count -= (old_pe_count - new_pe_count); vg->free_count -= (old_pe_count - new_pe_count); return 1; } static int _extend_pv(struct physical_volume *pv, struct volume_group *vg, uint32_t old_pe_count, uint32_t new_pe_count) { struct pv_segment *peg; if ((uint64_t) new_pe_count * pv->pe_size > pv->size ) { log_error("%s: cannot resize to %" PRIu32 " extents as there " "is only room for %" PRIu64 ".", pv_dev_name(pv), new_pe_count, pv->size / pv->pe_size); return 0; } if (!(peg = _alloc_pv_segment(pv->fmt->cmd->mem, pv, old_pe_count, new_pe_count - old_pe_count, NULL, 0))) return_0; dm_list_add(&pv->segments, &peg->list); pv->pe_count = new_pe_count; vg->extent_count += (new_pe_count - old_pe_count); vg->free_count += (new_pe_count - old_pe_count); return 1; } /* * Resize a PV in a VG, adding or removing segments as needed. * New size must fit within pv->size. */ static int pv_resize(struct physical_volume *pv, struct volume_group *vg, uint64_t size) { uint32_t old_pe_count, new_pe_count = 0; if (size < pv_min_size()) { log_error("Size must exceed minimum of %" PRIu64 " sectors on PV %s.", pv_min_size(), pv_dev_name(pv)); return 0; } if (size < pv_pe_start(pv)) { log_error("Size must exceed physical extent start " "of %" PRIu64 " sectors on PV %s.", pv_pe_start(pv), pv_dev_name(pv)); } old_pe_count = pv->pe_count; if (!pv->fmt->ops->pv_resize(pv->fmt, pv, vg, size)) { log_error("Format specific resize of PV %s failed.", pv_dev_name(pv)); return 0; } /* pv->pe_count is 0 now! We need to recalculate! */ /* If there's a VG, calculate new PE count value. */ /* Don't do for orphan VG */ if (vg && !is_orphan_vg(vg->name)) { /* FIXME: Maybe PE calculation should go into pv->fmt->resize? (like it is for pv->fmt->setup) */ if (!(new_pe_count = pv_size(pv) / vg->extent_size)) { log_error("Size must leave space for at least one physical " "extent of %" PRIu32 " sectors on PV %s.", pv_pe_size(pv), pv_dev_name(pv)); return 0; } if (new_pe_count == old_pe_count) { pv->pe_count = old_pe_count; log_verbose("No change to size of physical volume %s.", pv_dev_name(pv)); return 1; } log_verbose("Resizing physical volume %s from %" PRIu32 " to %" PRIu32 " extents.", pv_dev_name(pv), pv->pe_count, new_pe_count); if (new_pe_count > old_pe_count) return _extend_pv(pv, vg, old_pe_count, new_pe_count); else return _reduce_pv(pv, vg, old_pe_count, new_pe_count); } return 1; } int pv_resize_single(struct cmd_context *cmd, struct volume_group *vg, struct physical_volume *pv, const uint64_t new_size) { uint64_t size = 0; int r = 0; const char *pv_name = pv_dev_name(pv); const char *vg_name = pv->vg_name; int vg_needs_pv_write = 0; if (!archive(vg)) goto out; if (!(pv->fmt->features & FMT_RESIZE_PV)) { log_error("Physical volume %s format does not support resizing.", pv_name); goto out; } /* Get new size */ if (!dev_get_size(pv_dev(pv), &size)) { log_error("%s: Couldn't get size.", pv_name); goto out; } if (new_size) { if (new_size > size) log_warn("WARNING: %s: Overriding real size. " "You could lose data.", pv_name); log_verbose("%s: Pretending size is %" PRIu64 " not %" PRIu64 " sectors.", pv_name, new_size, pv_size(pv)); size = new_size; } log_verbose("Resizing volume \"%s\" to %" PRIu64 " sectors.", pv_name, size); if (!pv_resize(pv, vg, size)) goto_out; log_verbose("Updating physical volume \"%s\"", pv_name); /* Write PV label only if this an orphan PV or it has 2nd mda. */ if ((is_orphan_vg(vg_name) || (vg_needs_pv_write = (fid_get_mda_indexed(vg->fid, (const char *) &pv->id, ID_LEN, 1) != NULL))) && !pv_write(cmd, pv, 1)) { log_error("Failed to store physical volume \"%s\"", pv_name); goto out; } if (!is_orphan_vg(vg_name)) { if (!vg_write(vg) || !vg_commit(vg)) { log_error("Failed to store physical volume \"%s\" in " "volume group \"%s\"", pv_name, vg_name); goto out; } backup(vg); } log_print_unless_silent("Physical volume \"%s\" changed", pv_name); r = 1; out: if (!r && vg_needs_pv_write) log_error("Use pvcreate and vgcfgrestore " "to repair from archived metadata."); return r; } const char _really_wipe[] = "Really WIPE LABELS from physical volume \"%s\" of volume group \"%s\" [y/n]? "; /* * Decide whether it is "safe" to wipe the labels on this device. * 0 indicates we may not. */ static int pvremove_check(struct cmd_context *cmd, const char *name, unsigned force_count, unsigned prompt, struct dm_list *pvslist) { struct device *dev; struct label *label; struct pv_list *pvl; struct physical_volume *pv = NULL; int r = 0; /* FIXME Check partition type is LVM unless --force is given */ if (!(dev = dev_cache_get(name, cmd->filter))) { log_error("Device %s not found", name); return 0; } /* Is there a pv here already? */ /* If not, this is an error unless you used -f. */ if (!label_read(dev, &label, 0)) { if (force_count) return 1; log_error("No PV label found on %s.", name); return 0; } dm_list_iterate_items(pvl, pvslist) if (pvl->pv->dev == dev) pv = pvl->pv; if (!pv) { log_error(INTERNAL_ERROR "Physical Volume %s has a label," " but is neither in a VG nor orphan.", name); goto out; /* better safe than sorry */ } if (is_orphan(pv)) { r = 1; goto out; } /* we must have -ff to overwrite a non orphan */ if (force_count < 2) { log_error("PV %s belongs to Volume Group %s so please use vgreduce first.", name, pv_vg_name(pv)); log_error("(If you are certain you need pvremove, then confirm by using --force twice.)"); goto out; } /* prompt */ if (!prompt && yes_no_prompt("Really WIPE LABELS from physical volume \"%s\" " "of volume group \"%s\" [y/n]? ", name, pv_vg_name(pv)) == 'n') { log_error("%s: physical volume label not removed", name); goto out; } if (force_count) { log_warn("WARNING: Wiping physical volume label from " "%s%s%s%s", name, !is_orphan(pv) ? " of volume group \"" : "", pv_vg_name(pv), !is_orphan(pv) ? "\"" : ""); } r = 1; out: return r; } int pvremove_single(struct cmd_context *cmd, const char *pv_name, void *handle __attribute__((unused)), unsigned force_count, unsigned prompt, struct dm_list *pvslist) { struct device *dev; struct lvmcache_info *info; int r = 0; if (!pvremove_check(cmd, pv_name, force_count, prompt, pvslist)) goto out; if (!(dev = dev_cache_get(pv_name, cmd->filter))) { log_error("%s: Couldn't find device. Check your filters?", pv_name); goto out; } info = lvmcache_info_from_pvid(dev->pvid, 0); if (!dev_test_excl(dev)) { /* FIXME Detect whether device-mapper is still using the device */ log_error("Can't open %s exclusively - not removing. " "Mounted filesystem?", dev_name(dev)); goto out; } /* Wipe existing label(s) */ if (!label_remove(dev)) { log_error("Failed to wipe existing label(s) on %s", pv_name); goto out; } if (info) lvmcache_del(info); if (!lvmetad_pv_gone_by_dev(dev, NULL)) goto_out; log_print_unless_silent("Labels on physical volume \"%s\" successfully wiped", pv_name); r = 1; out: return r; } int pvremove_many(struct cmd_context *cmd, struct dm_list *pv_names, unsigned force_count, unsigned prompt) { int ret = 1; struct dm_list *pvslist = NULL; struct pv_list *pvl; const struct dm_str_list *pv_name; if (!lock_vol(cmd, VG_ORPHANS, LCK_VG_WRITE, NULL)) { log_error("Can't get lock for orphan PVs"); return 0; } lvmcache_seed_infos_from_lvmetad(cmd); if (!(pvslist = get_pvs(cmd))) { ret = 0; goto_out; } dm_list_iterate_items(pv_name, pv_names) { if (!pvremove_single(cmd, pv_name->str, NULL, force_count, prompt, pvslist)) { stack; ret = 0; } if (sigint_caught()) { ret = 0; goto_out; } } out: unlock_vg(cmd, VG_ORPHANS); if (pvslist) dm_list_iterate_items(pvl, pvslist) free_pv_fid(pvl->pv); return ret; } int pvcreate_single(struct cmd_context *cmd, const char *pv_name, struct pvcreate_params *pp) { int r = 0; if (!lock_vol(cmd, VG_ORPHANS, LCK_VG_WRITE, NULL)) { log_error("Can't get lock for orphan PVs"); return 0; } if (!(pvcreate_vol(cmd, pv_name, pp, 1))) goto_out; r = 1; out: unlock_vg(cmd, VG_ORPHANS); return r; }