/* * Copyright (C) 2002-2004 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 */ #include "base/memory/zalloc.h" #include "lib/misc/lib.h" #include "lib/format_text/format-text.h" #include "layout.h" #include "lib/label/label.h" #include "lib/mm/xlate.h" #include "lib/cache/lvmcache.h" #include #include static int _text_can_handle(struct labeller *l __attribute__((unused)), void *buf, uint64_t sector __attribute__((unused))) { struct label_header *lh = (struct label_header *) buf; if (!memcmp(lh->type, LVM2_LABEL, sizeof(lh->type))) return 1; return 0; } struct _dl_setup_baton { struct disk_locn *pvh_dlocn_xl; struct device *dev; }; static int _da_setup(struct disk_locn *da, void *baton) { struct _dl_setup_baton *p = baton; p->pvh_dlocn_xl->offset = xlate64(da->offset); p->pvh_dlocn_xl->size = xlate64(da->size); p->pvh_dlocn_xl++; return 1; } static int _ba_setup(struct disk_locn *ba, void *baton) { return _da_setup(ba, baton); } static int _mda_setup(struct metadata_area *mda, void *baton) { struct _dl_setup_baton *p = baton; struct mda_context *mdac = (struct mda_context *) mda->metadata_locn; if (mdac->area.dev != p->dev) return 1; p->pvh_dlocn_xl->offset = xlate64(mdac->area.start); p->pvh_dlocn_xl->size = xlate64(mdac->area.size); p->pvh_dlocn_xl++; return 1; } static int _dl_null_termination(void *baton) { struct _dl_setup_baton *p = baton; p->pvh_dlocn_xl->offset = xlate64(UINT64_C(0)); p->pvh_dlocn_xl->size = xlate64(UINT64_C(0)); p->pvh_dlocn_xl++; return 1; } static int _text_write(struct label *label, void *buf) { struct label_header *lh = (struct label_header *) buf; struct pv_header *pvhdr; struct pv_header_extension *pvhdr_ext; struct lvmcache_info *info; struct _dl_setup_baton baton; char buffer[64] __attribute__((aligned(8))); int ba1, da1, mda1, mda2; /* * PV header base */ /* FIXME Move to where label is created */ memcpy(label->type, LVM2_LABEL, sizeof(label->type)); memcpy(lh->type, LVM2_LABEL, sizeof(lh->type)); pvhdr = (struct pv_header *) ((char *) buf + xlate32(lh->offset_xl)); info = (struct lvmcache_info *) label->info; pvhdr->device_size_xl = xlate64(lvmcache_device_size(info)); memcpy(pvhdr->pv_uuid, &lvmcache_device(info)->pvid, sizeof(struct id)); if (!id_write_format((const struct id *)pvhdr->pv_uuid, buffer, sizeof(buffer))) { stack; buffer[0] = '\0'; } baton.dev = lvmcache_device(info); baton.pvh_dlocn_xl = &pvhdr->disk_areas_xl[0]; /* List of data areas (holding PEs) */ lvmcache_foreach_da(info, _da_setup, &baton); _dl_null_termination(&baton); /* List of metadata area header locations */ lvmcache_foreach_mda(info, _mda_setup, &baton); _dl_null_termination(&baton); /* * PV header extension */ pvhdr_ext = (struct pv_header_extension *) ((char *) baton.pvh_dlocn_xl); pvhdr_ext->version = xlate32(PV_HEADER_EXTENSION_VSN); pvhdr_ext->flags = xlate32(lvmcache_ext_flags(info)); /* List of bootloader area locations */ baton.pvh_dlocn_xl = &pvhdr_ext->bootloader_areas_xl[0]; lvmcache_foreach_ba(info, _ba_setup, &baton); _dl_null_termination(&baton); /* Create debug message with ba, da and mda locations */ ba1 = (xlate64(pvhdr_ext->bootloader_areas_xl[0].offset) || xlate64(pvhdr_ext->bootloader_areas_xl[0].size)) ? 0 : -1; da1 = (xlate64(pvhdr->disk_areas_xl[0].offset) || xlate64(pvhdr->disk_areas_xl[0].size)) ? 0 : -1; mda1 = da1 + 2; mda2 = mda1 + 1; if (!xlate64(pvhdr->disk_areas_xl[mda1].offset) && !xlate64(pvhdr->disk_areas_xl[mda1].size)) mda1 = mda2 = 0; else if (!xlate64(pvhdr->disk_areas_xl[mda2].offset) && !xlate64(pvhdr->disk_areas_xl[mda2].size)) mda2 = 0; log_debug_metadata("%s: Preparing PV label header %s size " FMTu64 " with" "%s%.*" PRIu64 "%s%.*" PRIu64 "%s" "%s%.*" PRIu64 "%s%.*" PRIu64 "%s" "%s%.*" PRIu64 "%s%.*" PRIu64 "%s" "%s%.*" PRIu64 "%s%.*" PRIu64 "%s", dev_name(lvmcache_device(info)), buffer, lvmcache_device_size(info), (ba1 > -1) ? " ba1 (" : "", (ba1 > -1) ? 1 : 0, (ba1 > -1) ? xlate64(pvhdr_ext->bootloader_areas_xl[ba1].offset) >> SECTOR_SHIFT : 0, (ba1 > -1) ? "s, " : "", (ba1 > -1) ? 1 : 0, (ba1 > -1) ? xlate64(pvhdr_ext->bootloader_areas_xl[ba1].size) >> SECTOR_SHIFT : 0, (ba1 > -1) ? "s)" : "", (da1 > -1) ? " da1 (" : "", (da1 > -1) ? 1 : 0, (da1 > -1) ? xlate64(pvhdr->disk_areas_xl[da1].offset) >> SECTOR_SHIFT : 0, (da1 > -1) ? "s, " : "", (da1 > -1) ? 1 : 0, (da1 > -1) ? xlate64(pvhdr->disk_areas_xl[da1].size) >> SECTOR_SHIFT : 0, (da1 > -1) ? "s)" : "", mda1 ? " mda1 (" : "", mda1 ? 1 : 0, mda1 ? xlate64(pvhdr->disk_areas_xl[mda1].offset) >> SECTOR_SHIFT : 0, mda1 ? "s, " : "", mda1 ? 1 : 0, mda1 ? xlate64(pvhdr->disk_areas_xl[mda1].size) >> SECTOR_SHIFT : 0, mda1 ? "s)" : "", mda2 ? " mda2 (" : "", mda2 ? 1 : 0, mda2 ? xlate64(pvhdr->disk_areas_xl[mda2].offset) >> SECTOR_SHIFT : 0, mda2 ? "s, " : "", mda2 ? 1 : 0, mda2 ? xlate64(pvhdr->disk_areas_xl[mda2].size) >> SECTOR_SHIFT : 0, mda2 ? "s)" : ""); if (da1 < 0) { log_error(INTERNAL_ERROR "%s label header currently requires " "a data area.", dev_name(lvmcache_device(info))); return 0; } return 1; } int add_da(struct dm_pool *mem, struct dm_list *das, uint64_t start, uint64_t size) { struct data_area_list *dal; if (!mem) { if (!(dal = malloc(sizeof(*dal)))) { log_error("struct data_area_list allocation failed"); return 0; } } else { if (!(dal = dm_pool_alloc(mem, sizeof(*dal)))) { log_error("struct data_area_list allocation failed"); return 0; } } dal->disk_locn.offset = start; dal->disk_locn.size = size; dm_list_add(das, &dal->list); return 1; } void del_das(struct dm_list *das) { struct dm_list *dah, *tmp; struct data_area_list *da; dm_list_iterate_safe(dah, tmp, das) { da = dm_list_item(dah, struct data_area_list); dm_list_del(&da->list); free(da); } } int add_ba(struct dm_pool *mem, struct dm_list *eas, uint64_t start, uint64_t size) { return add_da(mem, eas, start, size); } void del_bas(struct dm_list *bas) { del_das(bas); } int add_mda(const struct format_type *fmt, struct dm_pool *mem, struct dm_list *mdas, struct device *dev, uint64_t start, uint64_t size, unsigned ignored, struct metadata_area **mda_new) { struct metadata_area *mdal, *mda; struct mda_lists *mda_lists = (struct mda_lists *) fmt->private; struct mda_context *mdac, *mdac2; if (!mem) { if (!(mdal = malloc(sizeof(struct metadata_area)))) { log_error("struct mda_list allocation failed"); return 0; } if (!(mdac = malloc(sizeof(struct mda_context)))) { log_error("struct mda_context allocation failed"); free(mdal); return 0; } } else { if (!(mdal = dm_pool_alloc(mem, sizeof(struct metadata_area)))) { log_error("struct mda_list allocation failed"); return 0; } if (!(mdac = dm_pool_alloc(mem, sizeof(struct mda_context)))) { log_error("struct mda_context allocation failed"); return 0; } } mdal->ops = mda_lists->raw_ops; mdal->metadata_locn = mdac; mdac->area.dev = dev; mdac->area.start = start; mdac->area.size = size; mdac->free_sectors = UINT64_C(0); memset(&mdac->rlocn, 0, sizeof(mdac->rlocn)); /* Set MDA_PRIMARY only if this is the first metadata area on this device. */ mdal->status = MDA_PRIMARY; dm_list_iterate_items(mda, mdas) { mdac2 = mda->metadata_locn; if (mdac2->area.dev == dev) { mdal->status = 0; break; } } mda_set_ignored(mdal, ignored); dm_list_add(mdas, &mdal->list); if (mda_new) *mda_new = mdal; return 1; } void del_mdas(struct dm_list *mdas) { struct dm_list *mdah, *tmp; struct metadata_area *mda; dm_list_iterate_safe(mdah, tmp, mdas) { mda = dm_list_item(mdah, struct metadata_area); free(mda->metadata_locn); dm_list_del(&mda->list); free(mda); } } static int _text_initialise_label(struct labeller *l __attribute__((unused)), struct label *label) { memcpy(label->type, LVM2_LABEL, sizeof(label->type)); return 1; } static int _read_mda_header_and_metadata(const struct format_type *fmt, struct metadata_area *mda, struct lvmcache_vgsummary *vgsummary, uint32_t *bad_fields) { struct mda_context *mdac = (struct mda_context *) mda->metadata_locn; struct mda_header *mdah; int retries = 0; retry: if (!(mdah = raw_read_mda_header(fmt, &mdac->area, (mda->mda_num == 1), 0, bad_fields))) { log_warn("WARNING: bad metadata header on %s at %llu.", dev_name(mdac->area.dev), (unsigned long long)mdac->area.start); mda->header_start = mdac->area.start; *bad_fields |= BAD_MDA_HEADER; return 0; } mda->header_start = mdah->start; mda_set_ignored(mda, rlocn_is_ignored(mdah->raw_locns)); if (mda_is_ignored(mda)) { log_debug_metadata("Ignoring mda on device %s at offset " FMTu64, dev_name(mdac->area.dev), mdac->area.start); vgsummary->mda_ignored = 1; return 1; } if (!read_metadata_location_summary(fmt, mda, mdah, mda_is_primary(mda), &mdac->area, vgsummary, &mdac->free_sectors)) { if (vgsummary->zero_offset) return 1; /* * This code is used by label_scan to get a summary of the * VG metadata that will be properly read later by vg_read. * The initial read of this device during label_scan * populates bcache with the first 128K of data from the * device. That block of data contains the mda_header * (at 4k) but will often not include the metadata text, * which is often located further into the metadata area * (beyond the 128K block saved in bcache.) * So read_metadata_location_summary will usually get the * mda_header from bcache which was read initially, and * then it will often need to do a new disk read to get * the actual metadata text that the mda_header points to. * Since there is no locking around label_scan, it's * possible (but very rare) that the entire metadata area * can be rewritten by other commands between the time that * this command read the mda_header and the time that it * reads the metadata text. This means the expected metadata * text isn't found, and an error is returned here. * To handle this, invalidate all data in bcache for this * device and reread the mda_header and metadata text back to * back, so inconsistency is less likely (without locking * there's no guarantee, e.g. if the command is blocked * somehow between the two reads.) */ if (!retries) { log_print_unless_silent("Retrying metadata scan."); retries++; dev_invalidate(mdac->area.dev); goto retry; } log_warn("WARNING: bad metadata text on %s in mda%d", dev_name(mdac->area.dev), mda->mda_num); *bad_fields |= BAD_MDA_TEXT; return 0; } return 1; } /* * Used by label_scan to get a summary of the VG that exists on this PV. This * summary is stored in lvmcache vginfo/info/info->mdas and is used later by * vg_read which needs to know which PVs to read for a given VG name, and where * the metadata is at for those PVs. */ static int _text_read(struct cmd_context *cmd, struct labeller *labeller, struct device *dev, void *label_buf, uint64_t label_sector, int *is_duplicate) { struct lvmcache_vgsummary vgsummary; char pvid[ID_LEN + 1] __attribute__((aligned(8))) = { 0 }; char vgid[ID_LEN + 1] __attribute__((aligned(8))) = { 0 }; struct lvmcache_info *info; const struct format_type *fmt = labeller->fmt; struct label_header *lh = (struct label_header *) label_buf; struct pv_header *pvhdr; struct pv_header_extension *pvhdr_ext; struct metadata_area *mda = NULL; struct metadata_area *mda1 = NULL; struct metadata_area *mda2 = NULL; struct disk_locn *dlocn_xl; uint64_t offset; uint32_t ext_version; uint32_t bad_fields; int mda_count = 0; int good_mda_count = 0; int bad_mda_count = 0; int rv1, rv2; /* * PV header base */ pvhdr = (struct pv_header *) ((char *) label_buf + xlate32(lh->offset_xl)); memcpy(pvid, &pvhdr->pv_uuid, ID_LEN); strncpy(vgid, FMT_TEXT_ORPHAN_VG_NAME, ID_LEN); /* * FIXME: stop adding the device to lvmcache initially as an orphan * (and then moving it later) and instead just add it when we know the * VG. * * If another device with this same PVID has already been seen, * lvmcache_add will put this device in the duplicates list in lvmcache * and return NULL. At the end of label_scan, the duplicate devs are * compared, and if another dev is preferred for this PV, then the * existing dev is removed from lvmcache and _text_read is called again * for this dev, and lvmcache_add will add it. * * Other reasons for lvmcache_add to return NULL are internal errors. */ if (!(info = lvmcache_add(cmd, labeller, pvid, dev, label_sector, vgid, vgid, 0, is_duplicate))) return_0; lvmcache_set_device_size(info, xlate64(pvhdr->device_size_xl)); lvmcache_del_das(info); lvmcache_del_mdas(info); lvmcache_del_bas(info); /* Data areas holding the PEs */ dlocn_xl = pvhdr->disk_areas_xl; while ((offset = xlate64(dlocn_xl->offset))) { lvmcache_add_da(info, offset, xlate64(dlocn_xl->size)); dlocn_xl++; } dlocn_xl++; /* Metadata areas */ while ((offset = xlate64(dlocn_xl->offset))) { /* * This just calls add_mda() above, replacing info with info->mdas. */ lvmcache_add_mda(info, dev, offset, xlate64(dlocn_xl->size), 0, &mda); dlocn_xl++; mda_count++; if (mda_count == 1) { mda1 = mda; mda1->mda_num = 1; } else if (mda_count == 2) { mda2 = mda; mda2->mda_num = 2; } } dlocn_xl++; /* * PV header extension */ pvhdr_ext = (struct pv_header_extension *) ((char *) dlocn_xl); if (!(ext_version = xlate32(pvhdr_ext->version))) goto scan_mdas; if (ext_version != PV_HEADER_EXTENSION_VSN) log_debug_metadata("Found pv_header_extension version " FMTu32 " on %s", ext_version, dev_name(dev)); /* Extension version */ lvmcache_set_ext_version(info, xlate32(pvhdr_ext->version)); /* Extension flags */ lvmcache_set_ext_flags(info, xlate32(pvhdr_ext->flags)); /* Bootloader areas */ dlocn_xl = pvhdr_ext->bootloader_areas_xl; while ((offset = xlate64(dlocn_xl->offset))) { lvmcache_add_ba(info, offset, xlate64(dlocn_xl->size)); dlocn_xl++; } scan_mdas: if (!mda_count) { log_debug_metadata("Scanning %s found no mdas.", dev_name(dev)); return 1; } /* * Track which devs have bad metadata so repair can find them (even if * this dev also has good metadata that we are able to use). * * When bad metadata is seen, the unusable mda struct is removed from * lvmcache info->mdas. This means that vg_read and vg_write will skip * the bad mda not try to read or write the bad metadata. The bad mdas * are saved in a separate bad_mdas list in lvmcache so that repair can * find them to repair. */ if (mda1) { log_debug_metadata("Scanning %s mda1 summary.", dev_name(dev)); memset(&vgsummary, 0, sizeof(vgsummary)); dm_list_init(&vgsummary.pvsummaries); bad_fields = 0; vgsummary.mda_num = 1; rv1 = _read_mda_header_and_metadata(fmt, mda1, &vgsummary, &bad_fields); if (rv1 && !vgsummary.zero_offset && !vgsummary.mda_ignored) { if (!lvmcache_update_vgname_and_id(cmd, info, &vgsummary)) { /* I believe this is only an internal error. */ dm_list_del(&mda1->list); /* Are there other cases besides mismatch and internal error? */ if (vgsummary.mismatch) { log_warn("WARNING: Scanning %s mda1 found mismatch with other metadata.", dev_name(dev)); bad_fields |= BAD_MDA_MISMATCH; } else { log_warn("WARNING: Scanning %s mda1 failed to save internal summary.", dev_name(dev)); bad_fields |= BAD_MDA_INTERNAL; } mda1->bad_fields = bad_fields; lvmcache_save_bad_mda(info, mda1); mda1 = NULL; bad_mda_count++; } else { /* The normal success path */ log_debug("Found metadata seqno %u in mda1 on %s", vgsummary.seqno, dev_name(dev)); good_mda_count++; } } if (!rv1) { /* * Remove the bad mda from normal mda list so it's not * used by vg_read/vg_write, but keep track of it in * lvmcache for repair. */ log_warn("WARNING: scanning %s mda1 failed to read metadata summary.", dev_name(dev)); log_warn("WARNING: repair VG metadata on %s with vgck --updatemetadata.", dev_name(dev)); dm_list_del(&mda1->list); mda1->bad_fields = bad_fields; lvmcache_save_bad_mda(info, mda1); mda1 = NULL; bad_mda_count++; } } if (mda2) { log_debug_metadata("Scanning %s mda2 summary.", dev_name(dev)); memset(&vgsummary, 0, sizeof(vgsummary)); dm_list_init(&vgsummary.pvsummaries); bad_fields = 0; vgsummary.mda_num = 2; rv2 = _read_mda_header_and_metadata(fmt, mda2, &vgsummary, &bad_fields); if (rv2 && !vgsummary.zero_offset && !vgsummary.mda_ignored) { if (!lvmcache_update_vgname_and_id(cmd, info, &vgsummary)) { dm_list_del(&mda2->list); /* Are there other cases besides mismatch and internal error? */ if (vgsummary.mismatch) { log_warn("WARNING: Scanning %s mda2 found mismatch with other metadata.", dev_name(dev)); bad_fields |= BAD_MDA_MISMATCH; } else { log_warn("WARNING: Scanning %s mda2 failed to save internal summary.", dev_name(dev)); bad_fields |= BAD_MDA_INTERNAL; } mda2->bad_fields = bad_fields; lvmcache_save_bad_mda(info, mda2); mda2 = NULL; bad_mda_count++; } else { /* The normal success path */ log_debug("Found metadata seqno %u in mda2 on %s", vgsummary.seqno, dev_name(dev)); good_mda_count++; } } if (!rv2) { /* * Remove the bad mda from normal mda list so it's not * used by vg_read/vg_write, but keep track of it in * lvmcache for repair. */ log_warn("WARNING: scanning %s mda2 failed to read metadata summary.", dev_name(dev)); log_warn("WARNING: repair VG metadata on %s with vgck --updatemetadata.", dev_name(dev)); dm_list_del(&mda2->list); mda2->bad_fields = bad_fields; lvmcache_save_bad_mda(info, mda2); mda2 = NULL; bad_mda_count++; } } if (good_mda_count) return 1; if (bad_mda_count) return 0; /* no metadata in the mdas */ return 1; } static void _text_destroy_label(struct labeller *l __attribute__((unused)), struct label *label) { struct lvmcache_info *info = (struct lvmcache_info *) label->info; lvmcache_del_mdas(info); lvmcache_del_das(info); lvmcache_del_bas(info); } static void _fmt_text_destroy(struct labeller *l) { free(l); } static const struct label_ops _text_ops = { .can_handle = _text_can_handle, .write = _text_write, .read = _text_read, .initialise_label = _text_initialise_label, .destroy_label = _text_destroy_label, .destroy = _fmt_text_destroy, }; struct labeller *text_labeller_create(const struct format_type *fmt) { struct labeller *l; if (!(l = zalloc(sizeof(*l)))) { log_error("Couldn't allocate labeller object."); return NULL; } l->ops = &_text_ops; l->fmt = fmt; return l; }