/* * Copyright (C) 2001-2004 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., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA */ /* * Translates between disk and in-core formats. */ #include "lib.h" #include "disk-rep.h" #include "lvm-string.h" #include "toolcontext.h" #include "segtype.h" #include "pv_alloc.h" #include "display.h" #include "metadata.h" #include static int _check_vg_name(const char *name) { return strlen(name) < NAME_LEN; } /* * Extracts the last part of a path. */ static char *_create_lv_name(struct dm_pool *mem, const char *full_name) { const char *ptr = strrchr(full_name, '/'); if (!ptr) ptr = full_name; else ptr++; return dm_pool_strdup(mem, ptr); } int import_pv(const struct format_type *fmt, struct dm_pool *mem, struct device *dev, struct volume_group *vg, struct physical_volume *pv, struct pv_disk *pvd, struct vg_disk *vgd) { uint64_t size; memset(pv, 0, sizeof(*pv)); memcpy(&pv->id, pvd->pv_uuid, ID_LEN); pv->dev = dev; if (!*pvd->vg_name) pv->vg_name = fmt->orphan_vg_name; else if (!(pv->vg_name = dm_pool_strdup(mem, (char *)pvd->vg_name))) { log_error("Volume Group name allocation failed."); return 0; } memcpy(&pv->vgid, vgd->vg_uuid, sizeof(vg->id)); /* Store system_id from first PV if PV belongs to a VG */ if (vg && !*vg->lvm1_system_id) strncpy(vg->lvm1_system_id, (char *)pvd->system_id, NAME_LEN); if (vg && strncmp(vg->lvm1_system_id, (char *)pvd->system_id, sizeof(pvd->system_id))) log_very_verbose("System ID %s on %s differs from %s for " "volume group", pvd->system_id, pv_dev_name(pv), vg->lvm1_system_id); /* * If exported, we still need to flag in pv->status too because * we don't always have a struct volume_group when we need this. */ if (pvd->pv_status & VG_EXPORTED) pv->status |= EXPORTED_VG; if (pvd->pv_allocatable) pv->status |= ALLOCATABLE_PV; pv->size = pvd->pv_size; pv->pe_size = pvd->pe_size; pv->pe_start = pvd->pe_start; pv->pe_count = pvd->pe_total; pv->pe_alloc_count = 0; pv->pe_align = 0; pv->is_labelled = 0; /* format1 PVs have no label */ pv->label_sector = 0; /* Fix up pv size if missing or impossibly large */ if (!pv->size || pv->size > (1ULL << 62)) { if (!dev_get_size(dev, &pv->size)) { log_error("%s: Couldn't get size.", pv_dev_name(pv)); return 0; } log_verbose("Fixing up missing format1 size (%s) " "for PV %s", display_size(fmt->cmd, pv->size), pv_dev_name(pv)); if (vg) { size = pv->pe_count * (uint64_t) vg->extent_size + pv->pe_start; if (size > pv->size) log_warn("WARNING: Physical Volume %s is too " "large for underlying device", pv_dev_name(pv)); } } dm_list_init(&pv->tags); dm_list_init(&pv->segments); if (!alloc_pv_segment_whole_pv(mem, pv)) return_0; return 1; } int generate_lvm1_system_id(struct cmd_context *cmd, char *s, const char *prefix) { if (dm_snprintf(s, NAME_LEN, "%s%s%lu", prefix, cmd->hostname, time(NULL)) < 0) { log_error("Generated LVM1 format system_id too long"); return 0; } return 1; } int export_pv(struct cmd_context *cmd, struct dm_pool *mem __attribute__((unused)), struct volume_group *vg, struct pv_disk *pvd, struct physical_volume *pv) { memset(pvd, 0, sizeof(*pvd)); pvd->id[0] = 'H'; pvd->id[1] = 'M'; pvd->version = 1; memcpy(pvd->pv_uuid, pv->id.uuid, ID_LEN); if (pv->vg_name && !is_orphan(pv) && !(pv->status & UNLABELLED_PV)) { if (!_check_vg_name(pv->vg_name)) return_0; strncpy((char *)pvd->vg_name, pv->vg_name, sizeof(pvd->vg_name)); } /* Preserve existing system_id if it exists */ if (vg && vg->lvm1_system_id && *vg->lvm1_system_id) strncpy((char *)pvd->system_id, vg->lvm1_system_id, sizeof(pvd->system_id)); else if (vg && vg->system_id && *vg->system_id) strncpy((char *)pvd->system_id, vg->system_id, sizeof(pvd->system_id)); /* Is VG already exported or being exported? */ if (vg && vg_is_exported(vg)) { /* Does system_id need setting? */ if (!vg->lvm1_system_id || !*vg->lvm1_system_id || strncmp(vg->lvm1_system_id, EXPORTED_TAG, sizeof(EXPORTED_TAG) - 1)) { if (!generate_lvm1_system_id(cmd, (char *)pvd->system_id, EXPORTED_TAG)) return_0; } if (strlen((char *)pvd->vg_name) + sizeof(EXPORTED_TAG) > sizeof(pvd->vg_name)) { log_error("Volume group name %s too long to export", pvd->vg_name); return 0; } strcat((char *)pvd->vg_name, EXPORTED_TAG); } /* Is VG being imported? */ if (vg && !vg_is_exported(vg) && vg->lvm1_system_id && *vg->lvm1_system_id && !strncmp(vg->lvm1_system_id, EXPORTED_TAG, sizeof(EXPORTED_TAG) - 1)) { if (!generate_lvm1_system_id(cmd, (char *)pvd->system_id, IMPORTED_TAG)) return_0; } /* Generate system_id if PV is in VG */ if (!pvd->system_id[0]) if (!generate_lvm1_system_id(cmd, (char *)pvd->system_id, "")) return_0; /* Update internal system_id if we changed it */ if (vg && vg->lvm1_system_id && (!*vg->lvm1_system_id || strncmp(vg->lvm1_system_id, (char *)pvd->system_id, sizeof(pvd->system_id)))) strncpy(vg->lvm1_system_id, (char *)pvd->system_id, NAME_LEN); //pvd->pv_major = MAJOR(pv->dev); if (pv->status & ALLOCATABLE_PV) pvd->pv_allocatable = PV_ALLOCATABLE; pvd->pv_size = pv->size; pvd->lv_cur = 0; /* this is set when exporting the lv list */ if (vg) pvd->pe_size = vg->extent_size; else pvd->pe_size = pv->pe_size; pvd->pe_total = pv->pe_count; pvd->pe_allocated = pv->pe_alloc_count; pvd->pe_start = pv->pe_start; return 1; } int import_vg(struct dm_pool *mem, struct volume_group *vg, struct disk_list *dl) { struct vg_disk *vgd = &dl->vgd; memcpy(vg->id.uuid, vgd->vg_uuid, ID_LEN); if (!_check_vg_name((char *)dl->pvd.vg_name)) return_0; if (!(vg->name = dm_pool_strdup(mem, (char *)dl->pvd.vg_name))) return_0; if (!(vg->lvm1_system_id = dm_pool_zalloc(mem, NAME_LEN + 1))) return_0; if (vgd->vg_status & VG_EXPORTED) vg->status |= EXPORTED_VG; if (vgd->vg_status & VG_EXTENDABLE) vg->status |= RESIZEABLE_VG; if (vgd->vg_access & VG_READ) vg->status |= LVM_READ; if (vgd->vg_access & VG_WRITE) vg->status |= LVM_WRITE; if (vgd->vg_access & VG_CLUSTERED) vg->status |= CLUSTERED; if (vgd->vg_access & VG_SHARED) vg->status |= SHARED; vg->extent_size = vgd->pe_size; vg->extent_count = vgd->pe_total; vg->free_count = vgd->pe_total; vg->max_lv = vgd->lv_max; vg->max_pv = vgd->pv_max; vg->alloc = ALLOC_NORMAL; return 1; } int export_vg(struct vg_disk *vgd, struct volume_group *vg) { memset(vgd, 0, sizeof(*vgd)); memcpy(vgd->vg_uuid, vg->id.uuid, ID_LEN); if (vg->status & LVM_READ) vgd->vg_access |= VG_READ; if (vg->status & LVM_WRITE) vgd->vg_access |= VG_WRITE; if (vg_is_clustered(vg)) vgd->vg_access |= VG_CLUSTERED; if (vg->status & SHARED) vgd->vg_access |= VG_SHARED; if (vg_is_exported(vg)) vgd->vg_status |= VG_EXPORTED; if (vg_is_resizeable(vg)) vgd->vg_status |= VG_EXTENDABLE; vgd->lv_max = vg->max_lv; vgd->lv_cur = vg_visible_lvs(vg) + snapshot_count(vg); vgd->pv_max = vg->max_pv; vgd->pv_cur = vg->pv_count; vgd->pe_size = vg->extent_size; vgd->pe_total = vg->extent_count; vgd->pe_allocated = vg->extent_count - vg->free_count; return 1; } int import_lv(struct cmd_context *cmd, struct dm_pool *mem, struct logical_volume *lv, struct lv_disk *lvd) { if (!(lv->name = _create_lv_name(mem, (char *)lvd->lv_name))) return_0; lv->status |= VISIBLE_LV; if (lvd->lv_status & LV_SPINDOWN) lv->status |= SPINDOWN_LV; if (lvd->lv_status & LV_PERSISTENT_MINOR) { lv->status |= FIXED_MINOR; lv->minor = MINOR(lvd->lv_dev); lv->major = MAJOR(lvd->lv_dev); } else { lv->major = -1; lv->minor = -1; } if (lvd->lv_access & LV_READ) lv->status |= LVM_READ; if (lvd->lv_access & LV_WRITE) lv->status |= LVM_WRITE; if (lvd->lv_badblock) lv->status |= BADBLOCK_ON; /* Drop the unused LV_STRICT here */ if (lvd->lv_allocation & LV_CONTIGUOUS) lv->alloc = ALLOC_CONTIGUOUS; else lv->alloc = ALLOC_NORMAL; if (!lvd->lv_read_ahead) lv->read_ahead = cmd->default_settings.read_ahead; else lv->read_ahead = lvd->lv_read_ahead; lv->size = lvd->lv_size; lv->le_count = lvd->lv_allocated_le; return 1; } static void _export_lv(struct lv_disk *lvd, struct volume_group *vg, struct logical_volume *lv, const char *dev_dir) { memset(lvd, 0, sizeof(*lvd)); snprintf((char *)lvd->lv_name, sizeof(lvd->lv_name), "%s%s/%s", dev_dir, vg->name, lv->name); (void) dm_strncpy((char *)lvd->vg_name, vg->name, sizeof(lvd->vg_name)); if (lv->status & LVM_READ) lvd->lv_access |= LV_READ; if (lv->status & LVM_WRITE) lvd->lv_access |= LV_WRITE; if (lv->status & SPINDOWN_LV) lvd->lv_status |= LV_SPINDOWN; if (lv->status & FIXED_MINOR) { lvd->lv_status |= LV_PERSISTENT_MINOR; lvd->lv_dev = MKDEV(lv->major, lv->minor); } else { lvd->lv_dev = MKDEV(LVM_BLK_MAJOR, lvnum_from_lvid(&lv->lvid)); } if (lv->read_ahead == DM_READ_AHEAD_AUTO || lv->read_ahead == DM_READ_AHEAD_NONE) lvd->lv_read_ahead = 0; else lvd->lv_read_ahead = lv->read_ahead; lvd->lv_stripes = dm_list_item(lv->segments.n, struct lv_segment)->area_count; lvd->lv_stripesize = dm_list_item(lv->segments.n, struct lv_segment)->stripe_size; lvd->lv_size = lv->size; lvd->lv_allocated_le = lv->le_count; if (lv->status & BADBLOCK_ON) lvd->lv_badblock = LV_BADBLOCK_ON; if (lv->alloc == ALLOC_CONTIGUOUS) lvd->lv_allocation |= LV_CONTIGUOUS; } int export_extents(struct disk_list *dl, uint32_t lv_num, struct logical_volume *lv, struct physical_volume *pv) { struct pe_disk *ped; struct lv_segment *seg; uint32_t pe, s; dm_list_iterate_items(seg, &lv->segments) { for (s = 0; s < seg->area_count; s++) { if (!(seg->segtype->flags & SEG_FORMAT1_SUPPORT)) { log_error("Segment type %s in LV %s: " "unsupported by format1", seg->segtype->name, lv->name); return 0; } if (seg_type(seg, s) != AREA_PV) { log_error("Non-PV stripe found in LV %s: " "unsupported by format1", lv->name); return 0; } if (seg_pv(seg, s) != pv) continue; /* not our pv */ for (pe = 0; pe < (seg->len / seg->area_count); pe++) { ped = &dl->extents[pe + seg_pe(seg, s)]; ped->lv_num = lv_num; ped->le_num = (seg->le / seg->area_count) + pe + s * (lv->le_count / seg->area_count); } } } return 1; } int import_pvs(const struct format_type *fmt, struct dm_pool *mem, struct volume_group *vg, struct dm_list *pvds) { struct disk_list *dl; struct pv_list *pvl; vg->pv_count = 0; dm_list_iterate_items(dl, pvds) { if (!(pvl = dm_pool_zalloc(mem, sizeof(*pvl))) || !(pvl->pv = dm_pool_alloc(mem, sizeof(*pvl->pv)))) return_0; if (!import_pv(fmt, mem, dl->dev, vg, pvl->pv, &dl->pvd, &dl->vgd)) return_0; pvl->pv->fmt = fmt; add_pvl_to_vgs(vg, pvl); } return 1; } static struct logical_volume *_add_lv(struct dm_pool *mem, struct volume_group *vg, struct lv_disk *lvd) { struct logical_volume *lv; if (!(lv = alloc_lv(mem))) return_NULL; lvid_from_lvnum(&lv->lvid, &vg->id, lvd->lv_number); if (!import_lv(vg->cmd, mem, lv, lvd)) goto_bad; if (!link_lv_to_vg(vg, lv)) goto_bad; return lv; bad: dm_pool_free(mem, lv); return NULL; } int import_lvs(struct dm_pool *mem, struct volume_group *vg, struct dm_list *pvds) { struct disk_list *dl; struct lvd_list *ll; struct lv_disk *lvd; dm_list_iterate_items(dl, pvds) { dm_list_iterate_items(ll, &dl->lvds) { lvd = &ll->lvd; if (!find_lv(vg, (char *)lvd->lv_name) && !_add_lv(mem, vg, lvd)) return_0; } } return 1; } /* FIXME: tidy */ int export_lvs(struct disk_list *dl, struct volume_group *vg, struct physical_volume *pv, const char *dev_dir) { int r = 0; struct lv_list *ll; struct lvd_list *lvdl; size_t len; uint32_t lv_num; struct dm_hash_table *lvd_hash; if (!_check_vg_name(vg->name)) return_0; if (!(lvd_hash = dm_hash_create(32))) return_0; /* * setup the pv's extents array */ len = sizeof(struct pe_disk) * dl->pvd.pe_total; if (!(dl->extents = dm_pool_zalloc(dl->mem, len))) goto_out; dm_list_iterate_items(ll, &vg->lvs) { if (ll->lv->status & SNAPSHOT) continue; if (!(lvdl = dm_pool_alloc(dl->mem, sizeof(*lvdl)))) goto_out; _export_lv(&lvdl->lvd, vg, ll->lv, dev_dir); lv_num = lvnum_from_lvid(&ll->lv->lvid); lvdl->lvd.lv_number = lv_num; if (!dm_hash_insert(lvd_hash, ll->lv->name, &lvdl->lvd)) goto_out; if (!export_extents(dl, lv_num + 1, ll->lv, pv)) goto_out; if (lv_is_origin(ll->lv)) lvdl->lvd.lv_access |= LV_SNAPSHOT_ORG; if (lv_is_cow(ll->lv)) { lvdl->lvd.lv_access |= LV_SNAPSHOT; lvdl->lvd.lv_chunk_size = ll->lv->snapshot->chunk_size; lvdl->lvd.lv_snapshot_minor = lvnum_from_lvid(&ll->lv->snapshot->origin->lvid); } dm_list_add(&dl->lvds, &lvdl->list); dl->pvd.lv_cur++; } r = 1; out: dm_hash_destroy(lvd_hash); return r; } /* * FIXME: More inefficient code. */ int import_snapshots(struct dm_pool *mem __attribute__((unused)), struct volume_group *vg, struct dm_list *pvds) { struct logical_volume *lvs[MAX_LV] = { 0 }; struct disk_list *dl; struct lvd_list *ll; struct lv_disk *lvd; int lvnum; struct logical_volume *org, *cow; /* build an index of lv numbers */ dm_list_iterate_items(dl, pvds) { dm_list_iterate_items(ll, &dl->lvds) { lvd = &ll->lvd; lvnum = lvd->lv_number; if (lvnum >= MAX_LV) { log_error("Logical volume number " "out of bounds."); return 0; } if (!lvs[lvnum] && !(lvs[lvnum] = find_lv(vg, (char *)lvd->lv_name))) { log_error("Couldn't find logical volume '%s'.", lvd->lv_name); return 0; } } } /* * Now iterate through yet again adding the snapshots. */ dm_list_iterate_items(dl, pvds) { dm_list_iterate_items(ll, &dl->lvds) { lvd = &ll->lvd; if (!(lvd->lv_access & LV_SNAPSHOT)) continue; lvnum = lvd->lv_number; cow = lvs[lvnum]; if (!(org = lvs[lvd->lv_snapshot_minor])) { log_error("Couldn't find origin logical volume " "for snapshot '%s'.", lvd->lv_name); return 0; } /* we may have already added this snapshot */ if (lv_is_cow(cow)) continue; /* insert the snapshot */ if (!vg_add_snapshot(org, cow, NULL, org->le_count, lvd->lv_chunk_size)) { log_error("Couldn't add snapshot."); return 0; } } } return 1; } int export_uuids(struct disk_list *dl, struct volume_group *vg) { struct uuid_list *ul; struct pv_list *pvl; dm_list_iterate_items(pvl, &vg->pvs) { if (!(ul = dm_pool_alloc(dl->mem, sizeof(*ul)))) return_0; memset(ul->uuid, 0, sizeof(ul->uuid)); memcpy(ul->uuid, pvl->pv->id.uuid, ID_LEN); dm_list_add(&dl->uuids, &ul->list); } return 1; } /* * This calculates the nasty pv_number field * used by LVM1. */ void export_numbers(struct dm_list *pvds, struct volume_group *vg __attribute__((unused))) { struct disk_list *dl; int pv_num = 1; dm_list_iterate_items(dl, pvds) dl->pvd.pv_number = pv_num++; } /* * Calculate vg_disk->pv_act. */ void export_pv_act(struct dm_list *pvds) { struct disk_list *dl; int act = 0; dm_list_iterate_items(dl, pvds) if (dl->pvd.pv_status & PV_ACTIVE) act++; dm_list_iterate_items(dl, pvds) dl->vgd.pv_act = act; } int export_vg_number(struct format_instance *fid, struct dm_list *pvds, const char *vg_name, struct dev_filter *filter) { struct disk_list *dl; int vg_num; if (!get_free_vg_number(fid, filter, vg_name, &vg_num)) return_0; dm_list_iterate_items(dl, pvds) dl->vgd.vg_number = vg_num; return 1; }