/* lvm.c - module to read Logical Volumes. */ /* * GRUB -- GRand Unified Bootloader * Copyright (C) 2006,2007,2008 Free Software Foundation, Inc. * * GRUB is free software: you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation, either version 3 of the License, or * (at your option) any later version. * * GRUB is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with GRUB. If not, see . */ #include #include #include #include #include #include static struct grub_lvm_vg *vg_list; static int lv_count; /* Go the string STR and return the number after STR. *P will point at the number. In case STR is not found, *P will be NULL and the return value will be 0. */ static int grub_lvm_getvalue (char **p, char *str) { *p = grub_strstr (*p, str); if (! *p) return 0; *p += grub_strlen (str); return grub_strtoul (*p, NULL, 10); } static int grub_lvm_iterate (int (*hook) (const char *name)) { struct grub_lvm_vg *vg; for (vg = vg_list; vg; vg = vg->next) { struct grub_lvm_lv *lv; if (vg->lvs) for (lv = vg->lvs; lv; lv = lv->next) if (hook (lv->name)) return 1; } return 0; } #ifdef GRUB_UTIL static grub_disk_memberlist_t grub_lvm_memberlist (grub_disk_t disk) { struct grub_lvm_lv *lv = disk->data; grub_disk_memberlist_t list = NULL, tmp; struct grub_lvm_pv *pv; if (lv->vg->pvs) for (pv = lv->vg->pvs; pv; pv = pv->next) { tmp = grub_malloc (sizeof (*tmp)); tmp->disk = pv->disk; tmp->next = list; list = tmp; } return list; } #endif static grub_err_t grub_lvm_open (const char *name, grub_disk_t disk) { struct grub_lvm_vg *vg; struct grub_lvm_lv *lv = NULL; for (vg = vg_list; vg; vg = vg->next) { if (vg->lvs) for (lv = vg->lvs; lv; lv = lv->next) if (! grub_strcmp (lv->name, name)) break; if (lv) break; } if (! lv) return grub_error (GRUB_ERR_UNKNOWN_DEVICE, "Unknown device"); disk->has_partitions = 0; disk->id = lv->number; disk->data = lv; disk->total_sectors = lv->size; return 0; } static void grub_lvm_close (grub_disk_t disk __attribute ((unused))) { return; } static grub_err_t grub_lvm_read (grub_disk_t disk, grub_disk_addr_t sector, grub_size_t size, char *buf) { grub_err_t err = 0; struct grub_lvm_lv *lv = disk->data; struct grub_lvm_vg *vg = lv->vg; struct grub_lvm_segment *seg = lv->segments; struct grub_lvm_pv *pv; grub_uint64_t offset; grub_uint64_t extent; unsigned int i; extent = grub_divmod64 (sector, vg->extent_size, NULL); /* Find the right segment. */ for (i = 0; i < lv->segment_count; i++) { if ((seg->start_extent <= extent) && ((seg->start_extent + seg->extent_count) > extent)) { break; } seg++; } if (seg->stripe_count == 1) { /* This segment is linear, so that's easy. We just need to find out the offset in the physical volume and read SIZE bytes from that. */ struct grub_lvm_stripe *stripe = seg->stripes; grub_uint64_t seg_offset; /* Offset of the segment in PV device. */ pv = stripe->pv; seg_offset = ((grub_uint64_t) stripe->start * (grub_uint64_t) vg->extent_size) + pv->start; offset = sector - ((grub_uint64_t) seg->start_extent * (grub_uint64_t) vg->extent_size) + seg_offset; } else { /* This is a striped segment. We have to find the right PV similar to RAID0. */ struct grub_lvm_stripe *stripe = seg->stripes; grub_uint32_t a, b; grub_uint64_t seg_offset; /* Offset of the segment in PV device. */ unsigned int stripenr; offset = sector - ((grub_uint64_t) seg->start_extent * (grub_uint64_t) vg->extent_size); a = grub_divmod64 (offset, seg->stripe_size, NULL); grub_divmod64 (a, seg->stripe_count, &stripenr); a = grub_divmod64 (offset, seg->stripe_size * seg->stripe_count, NULL); grub_divmod64 (offset, seg->stripe_size, &b); offset = a * seg->stripe_size + b; stripe += stripenr; pv = stripe->pv; seg_offset = ((grub_uint64_t) stripe->start * (grub_uint64_t) vg->extent_size) + pv->start; offset += seg_offset; } /* Check whether we actually know the physical volume we want to read from. */ if (pv->disk) err = grub_disk_read (pv->disk, offset, 0, size << GRUB_DISK_SECTOR_BITS, buf); else err = grub_error (GRUB_ERR_UNKNOWN_DEVICE, "Physical volume %s not found", pv->name); return err; } static grub_err_t grub_lvm_write (grub_disk_t disk __attribute ((unused)), grub_disk_addr_t sector __attribute ((unused)), grub_size_t size __attribute ((unused)), const char *buf __attribute ((unused))) { return GRUB_ERR_NOT_IMPLEMENTED_YET; } static int grub_lvm_scan_device (const char *name) { grub_err_t err; grub_disk_t disk; grub_uint64_t da_offset, da_size, mda_offset, mda_size; char buf[GRUB_LVM_LABEL_SIZE]; char vg_id[GRUB_LVM_ID_STRLEN+1]; char pv_id[GRUB_LVM_ID_STRLEN+1]; char *metadatabuf, *p, *q, *vgname; struct grub_lvm_label_header *lh = (struct grub_lvm_label_header *) buf; struct grub_lvm_pv_header *pvh; struct grub_lvm_disk_locn *dlocn; struct grub_lvm_mda_header *mdah; struct grub_lvm_raw_locn *rlocn; unsigned int i, j, vgname_len; struct grub_lvm_vg *vg; struct grub_lvm_pv *pv; disk = grub_disk_open (name); if (!disk) return 0; /* Search for label. */ for (i = 0; i < GRUB_LVM_LABEL_SCAN_SECTORS; i++) { err = grub_disk_read (disk, i, 0, sizeof(buf), buf); if (err) goto fail; if ((! grub_strncmp ((char *)lh->id, GRUB_LVM_LABEL_ID, sizeof (lh->id))) && (! grub_strncmp ((char *)lh->type, GRUB_LVM_LVM2_LABEL, sizeof (lh->type)))) break; } /* Return if we didn't find a label. */ if (i == GRUB_LVM_LABEL_SCAN_SECTORS) goto fail; pvh = (struct grub_lvm_pv_header *) (buf + grub_le_to_cpu32(lh->offset_xl)); for (i = 0, j = 0; i < GRUB_LVM_ID_LEN; i++) { pv_id[j++] = pvh->pv_uuid[i]; if ((i != 1) && (i != 29) && (i % 4 == 1)) pv_id[j++] = '-'; } pv_id[j] = '\0'; dlocn = pvh->disk_areas_xl; da_offset = grub_le_to_cpu64 (dlocn->offset); da_size = grub_le_to_cpu64 (dlocn->size); dlocn++; /* Is it possible to have multiple data/metadata areas? I haven't seen devices that have it. */ if (dlocn->offset) { grub_error (GRUB_ERR_NOT_IMPLEMENTED_YET, "We don't support multiple data areas"); goto fail; } dlocn++; mda_offset = grub_le_to_cpu64 (dlocn->offset); mda_size = grub_le_to_cpu64 (dlocn->size); dlocn++; if (dlocn->offset) { grub_error (GRUB_ERR_NOT_IMPLEMENTED_YET, "We don't support multiple metadata areas"); goto fail; } metadatabuf = grub_malloc (mda_size); if (! metadatabuf) goto fail; err = grub_disk_read (disk, 0, mda_offset, mda_size, metadatabuf); if (err) goto fail2; mdah = (struct grub_lvm_mda_header *) metadatabuf; if ((grub_strncmp ((char *)mdah->magic, GRUB_LVM_FMTT_MAGIC, sizeof (mdah->magic))) || (grub_le_to_cpu32 (mdah->version) != GRUB_LVM_FMTT_VERSION)) { grub_error (GRUB_ERR_NOT_IMPLEMENTED_YET, "Unknown metadata header"); goto fail2; } rlocn = mdah->raw_locns; p = q = metadatabuf + grub_le_to_cpu64 (rlocn->offset); while (*q != ' ' && q < metadatabuf + mda_size) q++; if (q == metadatabuf + mda_size) goto fail2; vgname_len = q - p; vgname = grub_malloc (vgname_len + 1); if (!vgname) goto fail2; grub_memcpy (vgname, p, vgname_len); vgname[vgname_len] = '\0'; p = grub_strstr (q, "id = \""); if (p == NULL) goto fail3; p += sizeof ("id = \"") - 1; grub_memcpy (vg_id, p, GRUB_LVM_ID_STRLEN); vg_id[GRUB_LVM_ID_STRLEN] = '\0'; for (vg = vg_list; vg; vg = vg->next) { if (! grub_memcmp(vg_id, vg->id, GRUB_LVM_ID_STRLEN)) break; } if (! vg) { /* First time we see this volume group. We've to create the whole volume group structure. */ vg = grub_malloc (sizeof (*vg)); if (! vg) goto fail3; vg->name = vgname; grub_memcpy (vg->id, vg_id, GRUB_LVM_ID_STRLEN+1); vg->extent_size = grub_lvm_getvalue (&p, "extent_size = "); if (p == NULL) goto fail4; vg->lvs = NULL; vg->pvs = NULL; vg->next = vg_list; vg_list = vg; p = grub_strstr (p, "physical_volumes {"); if (p) { p += sizeof ("physical_volumes {") - 1; /* Add all the pvs to the volume group. */ while (1) { int s; while (grub_isspace (*p)) p++; if (*p == '}') break; pv = grub_malloc (sizeof (*pv)); q = p; while (*q != ' ') q++; s = q - p; pv->name = grub_malloc (s + 1); grub_memcpy (pv->name, p, s); pv->name[s] = '\0'; p = grub_strstr (p, "id = \"") + sizeof("id = \"") - 1; if (p == NULL) goto pvs_fail; grub_memcpy (pv->id, p, GRUB_LVM_ID_STRLEN); pv->id[GRUB_LVM_ID_STRLEN] = '\0'; pv->start = grub_lvm_getvalue (&p, "pe_start = "); if (p == NULL) goto pvs_fail; pv->disk = NULL; pv->next = vg->pvs; vg->pvs = pv; p = grub_strchr (p, '}') + 1; continue; pvs_fail: grub_free (pv->name); grub_free (pv); goto fail4; } } p = grub_strstr (p, "logical_volumes"); if (p) { p += 18; /* And add all the lvs to the volume group. */ while (1) { int s; struct grub_lvm_lv *lv; struct grub_lvm_segment *seg; while (grub_isspace (*p)) p++; if (*p == '}') break; lv = grub_malloc (sizeof (*lv)); q = p; while (*q != ' ') q++; s = q - p; lv->name = grub_malloc (vgname_len + 1 + s + 1); grub_memcpy (lv->name, vgname, vgname_len); lv->name[vgname_len] = '-'; grub_memcpy (lv->name + vgname_len + 1, p, s); lv->name[vgname_len + 1 + s] = '\0'; lv->size = 0; lv->segment_count = grub_lvm_getvalue (&p, "segment_count = "); if (p == NULL) goto lvs_fail; lv->segments = grub_malloc (sizeof (*seg) * lv->segment_count); seg = lv->segments; for (i = 0; i < lv->segment_count; i++) { struct grub_lvm_stripe *stripe; p = grub_strstr (p, "segment"); if (p == NULL) goto lvs_segment_fail; seg->start_extent = grub_lvm_getvalue (&p, "start_extent = "); if (p == NULL) goto lvs_segment_fail; seg->extent_count = grub_lvm_getvalue (&p, "extent_count = "); if (p == NULL) goto lvs_segment_fail; seg->stripe_count = grub_lvm_getvalue (&p, "stripe_count = "); if (p == NULL) goto lvs_segment_fail; lv->size += seg->extent_count * vg->extent_size; if (seg->stripe_count != 1) seg->stripe_size = grub_lvm_getvalue (&p, "stripe_size = "); seg->stripes = grub_malloc (sizeof (*stripe) * seg->stripe_count); stripe = seg->stripes; p = grub_strstr (p, "stripes = ["); if (p == NULL) goto lvs_segment_fail2; p += sizeof("stripes = [") - 1; for (j = 0; j < seg->stripe_count; j++) { char *pvname; p = grub_strchr (p, '"'); if (p == NULL) continue; q = ++p; while (*q != '"') q++; s = q - p; pvname = grub_malloc (s + 1); if (pvname == NULL) goto lvs_segment_fail2; grub_memcpy (pvname, p, s); pvname[s] = '\0'; if (vg->pvs) for (pv = vg->pvs; pv; pv = pv->next) { if (! grub_strcmp (pvname, pv->name)) { stripe->pv = pv; break; } } grub_free(pvname); stripe->start = grub_lvm_getvalue (&p, ","); if (p == NULL) continue; stripe++; } seg++; continue; lvs_segment_fail2: grub_free (seg->stripes); lvs_segment_fail: goto fail4; } lv->number = lv_count++; lv->vg = vg; lv->next = vg->lvs; vg->lvs = lv; p = grub_strchr (p, '}'); if (p == NULL) goto lvs_fail; p += 3; continue; lvs_fail: grub_free (lv->name); grub_free (lv); goto fail4; } } } else { grub_free (vgname); } /* Match the device we are currently reading from with the right PV. */ if (vg->pvs) for (pv = vg->pvs; pv; pv = pv->next) { if (! grub_memcmp (pv->id, pv_id, GRUB_LVM_ID_STRLEN)) { pv->disk = grub_disk_open (name); break; } } goto fail2; /* Failure path. */ fail4: grub_free (vg); fail3: grub_free (vgname); /* Normal exit path. */ fail2: grub_free (metadatabuf); fail: grub_disk_close (disk); return 0; } static struct grub_disk_dev grub_lvm_dev = { .name = "lvm", .id = GRUB_DISK_DEVICE_LVM_ID, .iterate = grub_lvm_iterate, .open = grub_lvm_open, .close = grub_lvm_close, .read = grub_lvm_read, .write = grub_lvm_write, #ifdef GRUB_UTIL .memberlist = grub_lvm_memberlist, #endif .next = 0 }; GRUB_MOD_INIT(lvm) { grub_device_iterate (&grub_lvm_scan_device); grub_disk_dev_register (&grub_lvm_dev); } GRUB_MOD_FINI(lvm) { grub_disk_dev_unregister (&grub_lvm_dev); /* FIXME: free the lvm list. */ }