/*- * SPDX-License-Identifier: BSD-2-Clause * * Copyright (c) 2012 Andrey V. Elsukov * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. * IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT, * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT * NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF * THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "g_part_if.h" FEATURE(geom_part_ldm, "GEOM partitioning class for LDM support"); SYSCTL_DECL(_kern_geom_part); static SYSCTL_NODE(_kern_geom_part, OID_AUTO, ldm, CTLFLAG_RW | CTLFLAG_MPSAFE, 0, "GEOM_PART_LDM Logical Disk Manager"); static u_int ldm_debug = 0; SYSCTL_UINT(_kern_geom_part_ldm, OID_AUTO, debug, CTLFLAG_RWTUN, &ldm_debug, 0, "Debug level"); /* * This allows access to mirrored LDM volumes. Since we do not * doing mirroring here, it is not enabled by default. */ static u_int show_mirrors = 0; SYSCTL_UINT(_kern_geom_part_ldm, OID_AUTO, show_mirrors, CTLFLAG_RWTUN, &show_mirrors, 0, "Show mirrored volumes"); #define LDM_DEBUG(lvl, fmt, ...) do { \ if (ldm_debug >= (lvl)) { \ printf("GEOM_PART: " fmt "\n", __VA_ARGS__); \ } \ } while (0) #define LDM_DUMP(buf, size) do { \ if (ldm_debug > 1) { \ hexdump(buf, size, NULL, 0); \ } \ } while (0) /* * There are internal representations of LDM structures. * * We do not keep all fields of on-disk structures, only most useful. * All numbers in an on-disk structures are in big-endian format. */ /* * Private header is 512 bytes long. There are three copies on each disk. * Offset and sizes are in sectors. Location of each copy: * - the first offset is relative to the disk start; * - the second and third offset are relative to the LDM database start. * * On a disk partitioned with GPT, the LDM has not first private header. */ #define LDM_PH_MBRINDEX 0 #define LDM_PH_GPTINDEX 2 static const uint64_t ldm_ph_off[] = {6, 1856, 2047}; #define LDM_VERSION_2K 0x2000b #define LDM_VERSION_VISTA 0x2000c #define LDM_PH_VERSION_OFF 0x00c #define LDM_PH_DISKGUID_OFF 0x030 #define LDM_PH_DGGUID_OFF 0x0b0 #define LDM_PH_DGNAME_OFF 0x0f0 #define LDM_PH_START_OFF 0x11b #define LDM_PH_SIZE_OFF 0x123 #define LDM_PH_DB_OFF 0x12b #define LDM_PH_DBSIZE_OFF 0x133 #define LDM_PH_TH1_OFF 0x13b #define LDM_PH_TH2_OFF 0x143 #define LDM_PH_CONFSIZE_OFF 0x153 #define LDM_PH_LOGSIZE_OFF 0x15b #define LDM_PH_SIGN "PRIVHEAD" struct ldm_privhdr { struct uuid disk_guid; struct uuid dg_guid; u_char dg_name[32]; uint64_t start; /* logical disk start */ uint64_t size; /* logical disk size */ uint64_t db_offset; /* LDM database start */ #define LDM_DB_SIZE 2048 uint64_t db_size; /* LDM database size */ #define LDM_TH_COUNT 2 uint64_t th_offset[LDM_TH_COUNT]; /* TOC header offsets */ uint64_t conf_size; /* configuration size */ uint64_t log_size; /* size of log */ }; /* * Table of contents header is 512 bytes long. * There are two identical copies at offsets from the private header. * Offsets are relative to the LDM database start. */ #define LDM_TH_SIGN "TOCBLOCK" #define LDM_TH_NAME1 "config" #define LDM_TH_NAME2 "log" #define LDM_TH_NAME1_OFF 0x024 #define LDM_TH_CONF_OFF 0x02e #define LDM_TH_CONFSIZE_OFF 0x036 #define LDM_TH_NAME2_OFF 0x046 #define LDM_TH_LOG_OFF 0x050 #define LDM_TH_LOGSIZE_OFF 0x058 struct ldm_tochdr { uint64_t conf_offset; /* configuration offset */ uint64_t log_offset; /* log offset */ }; /* * LDM database header is 512 bytes long. */ #define LDM_VMDB_SIGN "VMDB" #define LDM_DB_LASTSEQ_OFF 0x004 #define LDM_DB_SIZE_OFF 0x008 #define LDM_DB_STATUS_OFF 0x010 #define LDM_DB_VERSION_OFF 0x012 #define LDM_DB_DGNAME_OFF 0x016 #define LDM_DB_DGGUID_OFF 0x035 struct ldm_vmdbhdr { uint32_t last_seq; /* sequence number of last VBLK */ uint32_t size; /* size of VBLK */ }; /* * The LDM database configuration section contains VMDB header and * many VBLKs. Each VBLK represents a disk group, disk partition, * component or volume. * * The most interesting for us are volumes, they are represents * partitions in the GEOM_PART meaning. But volume VBLK does not * contain all information needed to create GEOM provider. And we * should get this information from the related VBLK. This is how * VBLK releated: * Volumes <- Components <- Partitions -> Disks * * One volume can contain several components. In this case LDM * does mirroring of volume data to each component. * * Also each component can contain several partitions (spanned or * striped volumes). */ struct ldm_component { uint64_t id; /* object id */ uint64_t vol_id; /* parent volume object id */ int count; LIST_HEAD(, ldm_partition) partitions; LIST_ENTRY(ldm_component) entry; }; struct ldm_volume { uint64_t id; /* object id */ uint64_t size; /* volume size */ uint8_t number; /* used for ordering */ uint8_t part_type; /* partition type */ int count; LIST_HEAD(, ldm_component) components; LIST_ENTRY(ldm_volume) entry; }; struct ldm_disk { uint64_t id; /* object id */ struct uuid guid; /* disk guid */ LIST_ENTRY(ldm_disk) entry; }; #if 0 struct ldm_disk_group { uint64_t id; /* object id */ struct uuid guid; /* disk group guid */ u_char name[32]; /* disk group name */ LIST_ENTRY(ldm_disk_group) entry; }; #endif struct ldm_partition { uint64_t id; /* object id */ uint64_t disk_id; /* disk object id */ uint64_t comp_id; /* parent component object id */ uint64_t start; /* offset relative to disk start */ uint64_t offset; /* offset for spanned volumes */ uint64_t size; /* partition size */ LIST_ENTRY(ldm_partition) entry; }; /* * Each VBLK is 128 bytes long and has standard 16 bytes header. * Some of VBLK's fields are fixed size, but others has variable size. * Fields with variable size are prefixed with one byte length marker. * Some fields are strings and also can have fixed size and variable. * Strings with fixed size are NULL-terminated, others are not. * All VBLKs have same several first fields: * Offset Size Description * ---------------+---------------+-------------------------- * 0x00 16 standard VBLK header * 0x10 2 update status * 0x13 1 VBLK type * 0x18 PS object id * 0x18+ PN object name * * o Offset 0x18+ means '0x18 + length of all variable-width fields' * o 'P' in size column means 'prefixed' (variable-width), * 'S' - string, 'N' - number. */ #define LDM_VBLK_SIGN "VBLK" #define LDM_VBLK_SEQ_OFF 0x04 #define LDM_VBLK_GROUP_OFF 0x08 #define LDM_VBLK_INDEX_OFF 0x0c #define LDM_VBLK_COUNT_OFF 0x0e #define LDM_VBLK_TYPE_OFF 0x13 #define LDM_VBLK_OID_OFF 0x18 struct ldm_vblkhdr { uint32_t seq; /* sequence number */ uint32_t group; /* group number */ uint16_t index; /* index in the group */ uint16_t count; /* number of entries in the group */ }; #define LDM_VBLK_T_COMPONENT 0x32 #define LDM_VBLK_T_PARTITION 0x33 #define LDM_VBLK_T_DISK 0x34 #define LDM_VBLK_T_DISKGROUP 0x35 #define LDM_VBLK_T_DISK4 0x44 #define LDM_VBLK_T_DISKGROUP4 0x45 #define LDM_VBLK_T_VOLUME 0x51 struct ldm_vblk { uint8_t type; /* VBLK type */ union { uint64_t id; struct ldm_volume vol; struct ldm_component comp; struct ldm_disk disk; struct ldm_partition part; #if 0 struct ldm_disk_group disk_group; #endif } u; LIST_ENTRY(ldm_vblk) entry; }; /* * Some VBLKs contains a bit more data than can fit into 128 bytes. These * VBLKs are called eXtended VBLK. Before parsing, the data from these VBLK * should be placed into continuous memory buffer. We can determine xVBLK * by the count field in the standard VBLK header (count > 1). */ struct ldm_xvblk { uint32_t group; /* xVBLK group number */ uint32_t size; /* the total size of xVBLK */ uint8_t map; /* bitmask of currently saved VBLKs */ u_char *data; /* xVBLK data */ LIST_ENTRY(ldm_xvblk) entry; }; /* The internal representation of LDM database. */ struct ldm_db { struct ldm_privhdr ph; /* private header */ struct ldm_tochdr th; /* TOC header */ struct ldm_vmdbhdr dh; /* VMDB header */ LIST_HEAD(, ldm_volume) volumes; LIST_HEAD(, ldm_disk) disks; LIST_HEAD(, ldm_vblk) vblks; LIST_HEAD(, ldm_xvblk) xvblks; }; static struct uuid gpt_uuid_ms_ldm_metadata = GPT_ENT_TYPE_MS_LDM_METADATA; struct g_part_ldm_table { struct g_part_table base; uint64_t db_offset; int is_gpt; }; struct g_part_ldm_entry { struct g_part_entry base; uint8_t type; }; static int g_part_ldm_add(struct g_part_table *, struct g_part_entry *, struct g_part_parms *); static int g_part_ldm_bootcode(struct g_part_table *, struct g_part_parms *); static int g_part_ldm_create(struct g_part_table *, struct g_part_parms *); static int g_part_ldm_destroy(struct g_part_table *, struct g_part_parms *); static void g_part_ldm_dumpconf(struct g_part_table *, struct g_part_entry *, struct sbuf *, const char *); static int g_part_ldm_dumpto(struct g_part_table *, struct g_part_entry *); static int g_part_ldm_modify(struct g_part_table *, struct g_part_entry *, struct g_part_parms *); static const char *g_part_ldm_name(struct g_part_table *, struct g_part_entry *, char *, size_t); static int g_part_ldm_probe(struct g_part_table *, struct g_consumer *); static int g_part_ldm_read(struct g_part_table *, struct g_consumer *); static const char *g_part_ldm_type(struct g_part_table *, struct g_part_entry *, char *, size_t); static int g_part_ldm_write(struct g_part_table *, struct g_consumer *); static kobj_method_t g_part_ldm_methods[] = { KOBJMETHOD(g_part_add, g_part_ldm_add), KOBJMETHOD(g_part_bootcode, g_part_ldm_bootcode), KOBJMETHOD(g_part_create, g_part_ldm_create), KOBJMETHOD(g_part_destroy, g_part_ldm_destroy), KOBJMETHOD(g_part_dumpconf, g_part_ldm_dumpconf), KOBJMETHOD(g_part_dumpto, g_part_ldm_dumpto), KOBJMETHOD(g_part_modify, g_part_ldm_modify), KOBJMETHOD(g_part_name, g_part_ldm_name), KOBJMETHOD(g_part_probe, g_part_ldm_probe), KOBJMETHOD(g_part_read, g_part_ldm_read), KOBJMETHOD(g_part_type, g_part_ldm_type), KOBJMETHOD(g_part_write, g_part_ldm_write), { 0, 0 } }; static struct g_part_scheme g_part_ldm_scheme = { "LDM", g_part_ldm_methods, sizeof(struct g_part_ldm_table), .gps_entrysz = sizeof(struct g_part_ldm_entry) }; G_PART_SCHEME_DECLARE(g_part_ldm); MODULE_VERSION(geom_part_ldm, 0); static struct g_part_ldm_alias { u_char typ; int alias; } ldm_alias_match[] = { { DOSPTYP_386BSD, G_PART_ALIAS_FREEBSD }, { DOSPTYP_FAT32, G_PART_ALIAS_MS_FAT32 }, { DOSPTYP_FAT32LBA, G_PART_ALIAS_MS_FAT32LBA }, { DOSPTYP_LDM, G_PART_ALIAS_MS_LDM_DATA }, { DOSPTYP_LINLVM, G_PART_ALIAS_LINUX_LVM }, { DOSPTYP_LINRAID, G_PART_ALIAS_LINUX_RAID }, { DOSPTYP_LINSWP, G_PART_ALIAS_LINUX_SWAP }, { DOSPTYP_LINUX, G_PART_ALIAS_LINUX_DATA }, { DOSPTYP_NTFS, G_PART_ALIAS_MS_NTFS }, }; static u_char* ldm_privhdr_read(struct g_consumer *cp, uint64_t off, int *error) { struct g_provider *pp; u_char *buf; pp = cp->provider; buf = g_read_data(cp, off, pp->sectorsize, error); if (buf == NULL) return (NULL); if (memcmp(buf, LDM_PH_SIGN, strlen(LDM_PH_SIGN)) != 0) { LDM_DEBUG(1, "%s: invalid LDM private header signature", pp->name); g_free(buf); buf = NULL; *error = EINVAL; } return (buf); } static int ldm_privhdr_parse(struct g_consumer *cp, struct ldm_privhdr *hdr, const u_char *buf) { uint32_t version; int error; memset(hdr, 0, sizeof(*hdr)); version = be32dec(buf + LDM_PH_VERSION_OFF); if (version != LDM_VERSION_2K && version != LDM_VERSION_VISTA) { LDM_DEBUG(0, "%s: unsupported LDM version %u.%u", cp->provider->name, version >> 16, version & 0xFFFF); return (ENXIO); } error = parse_uuid(buf + LDM_PH_DISKGUID_OFF, &hdr->disk_guid); if (error != 0) return (error); error = parse_uuid(buf + LDM_PH_DGGUID_OFF, &hdr->dg_guid); if (error != 0) return (error); strncpy(hdr->dg_name, buf + LDM_PH_DGNAME_OFF, sizeof(hdr->dg_name)); hdr->start = be64dec(buf + LDM_PH_START_OFF); hdr->size = be64dec(buf + LDM_PH_SIZE_OFF); hdr->db_offset = be64dec(buf + LDM_PH_DB_OFF); hdr->db_size = be64dec(buf + LDM_PH_DBSIZE_OFF); hdr->th_offset[0] = be64dec(buf + LDM_PH_TH1_OFF); hdr->th_offset[1] = be64dec(buf + LDM_PH_TH2_OFF); hdr->conf_size = be64dec(buf + LDM_PH_CONFSIZE_OFF); hdr->log_size = be64dec(buf + LDM_PH_LOGSIZE_OFF); return (0); } static int ldm_privhdr_check(struct ldm_db *db, struct g_consumer *cp, int is_gpt) { struct g_consumer *cp2; struct g_provider *pp; struct ldm_privhdr hdr; uint64_t offset, last; int error, found, i; u_char *buf; pp = cp->provider; if (is_gpt) { /* * The last LBA is used in several checks below, for the * GPT case it should be calculated relative to the whole * disk. */ cp2 = LIST_FIRST(&pp->geom->consumer); last = cp2->provider->mediasize / cp2->provider->sectorsize - 1; } else last = pp->mediasize / pp->sectorsize - 1; for (found = 0, i = is_gpt; i < nitems(ldm_ph_off); i++) { offset = ldm_ph_off[i]; /* * In the GPT case consumer is attached to the LDM metadata * partition and we don't need add db_offset. */ if (!is_gpt) offset += db->ph.db_offset; if (i == LDM_PH_MBRINDEX) { /* * Prepare to errors and setup new base offset * to read backup private headers. Assume that LDM * database is in the last 1Mbyte area. */ db->ph.db_offset = last - LDM_DB_SIZE; } buf = ldm_privhdr_read(cp, offset * pp->sectorsize, &error); if (buf == NULL) { LDM_DEBUG(1, "%s: failed to read private header " "%d at LBA %ju", pp->name, i, (uintmax_t)offset); continue; } error = ldm_privhdr_parse(cp, &hdr, buf); if (error != 0) { LDM_DEBUG(1, "%s: failed to parse private " "header %d", pp->name, i); LDM_DUMP(buf, pp->sectorsize); g_free(buf); continue; } g_free(buf); if (hdr.start > last || hdr.start + hdr.size - 1 > last || (hdr.start + hdr.size - 1 > hdr.db_offset && !is_gpt) || hdr.db_size != LDM_DB_SIZE || hdr.db_offset + LDM_DB_SIZE - 1 > last || hdr.th_offset[0] >= LDM_DB_SIZE || hdr.th_offset[1] >= LDM_DB_SIZE || hdr.conf_size + hdr.log_size >= LDM_DB_SIZE) { LDM_DEBUG(1, "%s: invalid values in the " "private header %d", pp->name, i); LDM_DEBUG(2, "%s: start: %jd, size: %jd, " "db_offset: %jd, db_size: %jd, th_offset0: %jd, " "th_offset1: %jd, conf_size: %jd, log_size: %jd, " "last: %jd", pp->name, hdr.start, hdr.size, hdr.db_offset, hdr.db_size, hdr.th_offset[0], hdr.th_offset[1], hdr.conf_size, hdr.log_size, last); continue; } if (found != 0 && memcmp(&db->ph, &hdr, sizeof(hdr)) != 0) { LDM_DEBUG(0, "%s: private headers are not equal", pp->name); if (i > 1) { /* * We have different headers in the LDM. * We can not trust this metadata. */ LDM_DEBUG(0, "%s: refuse LDM metadata", pp->name); return (EINVAL); } /* * We already have read primary private header * and it differs from this backup one. * Prefer the backup header and save it. */ found = 0; } if (found == 0) memcpy(&db->ph, &hdr, sizeof(hdr)); found = 1; } if (found == 0) { LDM_DEBUG(1, "%s: valid LDM private header not found", pp->name); return (ENXIO); } return (0); } static int ldm_gpt_check(struct ldm_db *db, struct g_consumer *cp) { struct g_part_table *gpt; struct g_part_entry *e; struct g_consumer *cp2; int error; cp2 = LIST_NEXT(cp, consumer); g_topology_lock(); gpt = cp->provider->geom->softc; error = 0; LIST_FOREACH(e, &gpt->gpt_entry, gpe_entry) { if (cp->provider == e->gpe_pp) { /* ms-ldm-metadata partition */ if (e->gpe_start != db->ph.db_offset || e->gpe_end != db->ph.db_offset + LDM_DB_SIZE - 1) error++; } else if (cp2->provider == e->gpe_pp) { /* ms-ldm-data partition */ if (e->gpe_start != db->ph.start || e->gpe_end != db->ph.start + db->ph.size - 1) error++; } if (error != 0) { LDM_DEBUG(0, "%s: GPT partition %d boundaries " "do not match with the LDM metadata", e->gpe_pp->name, e->gpe_index); error = ENXIO; break; } } g_topology_unlock(); return (error); } static int ldm_tochdr_check(struct ldm_db *db, struct g_consumer *cp) { struct g_provider *pp; struct ldm_tochdr hdr; uint64_t offset, conf_size, log_size; int error, found, i; u_char *buf; pp = cp->provider; for (i = 0, found = 0; i < LDM_TH_COUNT; i++) { offset = db->ph.db_offset + db->ph.th_offset[i]; buf = g_read_data(cp, offset * pp->sectorsize, pp->sectorsize, &error); if (buf == NULL) { LDM_DEBUG(1, "%s: failed to read TOC header " "at LBA %ju", pp->name, (uintmax_t)offset); continue; } if (memcmp(buf, LDM_TH_SIGN, strlen(LDM_TH_SIGN)) != 0 || memcmp(buf + LDM_TH_NAME1_OFF, LDM_TH_NAME1, strlen(LDM_TH_NAME1)) != 0 || memcmp(buf + LDM_TH_NAME2_OFF, LDM_TH_NAME2, strlen(LDM_TH_NAME2)) != 0) { LDM_DEBUG(1, "%s: failed to parse TOC header " "at LBA %ju", pp->name, (uintmax_t)offset); LDM_DUMP(buf, pp->sectorsize); g_free(buf); continue; } hdr.conf_offset = be64dec(buf + LDM_TH_CONF_OFF); hdr.log_offset = be64dec(buf + LDM_TH_LOG_OFF); conf_size = be64dec(buf + LDM_TH_CONFSIZE_OFF); log_size = be64dec(buf + LDM_TH_LOGSIZE_OFF); if (conf_size != db->ph.conf_size || hdr.conf_offset + conf_size >= LDM_DB_SIZE || log_size != db->ph.log_size || hdr.log_offset + log_size >= LDM_DB_SIZE) { LDM_DEBUG(1, "%s: invalid values in the " "TOC header at LBA %ju", pp->name, (uintmax_t)offset); LDM_DUMP(buf, pp->sectorsize); g_free(buf); continue; } g_free(buf); if (found == 0) memcpy(&db->th, &hdr, sizeof(hdr)); found = 1; } if (found == 0) { LDM_DEBUG(0, "%s: valid LDM TOC header not found.", pp->name); return (ENXIO); } return (0); } static int ldm_vmdbhdr_check(struct ldm_db *db, struct g_consumer *cp) { struct g_provider *pp; struct uuid dg_guid; uint64_t offset; uint32_t version; int error; u_char *buf; pp = cp->provider; offset = db->ph.db_offset + db->th.conf_offset; buf = g_read_data(cp, offset * pp->sectorsize, pp->sectorsize, &error); if (buf == NULL) { LDM_DEBUG(0, "%s: failed to read VMDB header at " "LBA %ju", pp->name, (uintmax_t)offset); return (error); } if (memcmp(buf, LDM_VMDB_SIGN, strlen(LDM_VMDB_SIGN)) != 0) { g_free(buf); LDM_DEBUG(0, "%s: failed to parse VMDB header at " "LBA %ju", pp->name, (uintmax_t)offset); return (ENXIO); } /* Check version. */ version = be32dec(buf + LDM_DB_VERSION_OFF); if (version != 0x4000A) { g_free(buf); LDM_DEBUG(0, "%s: unsupported VMDB version %u.%u", pp->name, version >> 16, version & 0xFFFF); return (ENXIO); } /* * Check VMDB update status: * 1 - in a consistent state; * 2 - in a creation phase; * 3 - in a deletion phase; */ if (be16dec(buf + LDM_DB_STATUS_OFF) != 1) { g_free(buf); LDM_DEBUG(0, "%s: VMDB is not in a consistent state", pp->name); return (ENXIO); } db->dh.last_seq = be32dec(buf + LDM_DB_LASTSEQ_OFF); db->dh.size = be32dec(buf + LDM_DB_SIZE_OFF); error = parse_uuid(buf + LDM_DB_DGGUID_OFF, &dg_guid); /* Compare disk group name and guid from VMDB and private headers */ if (error != 0 || db->dh.size == 0 || pp->sectorsize % db->dh.size != 0 || strncmp(buf + LDM_DB_DGNAME_OFF, db->ph.dg_name, 31) != 0 || memcmp(&dg_guid, &db->ph.dg_guid, sizeof(dg_guid)) != 0 || db->dh.size * db->dh.last_seq > db->ph.conf_size * pp->sectorsize) { LDM_DEBUG(0, "%s: invalid values in the VMDB header", pp->name); LDM_DUMP(buf, pp->sectorsize); g_free(buf); return (EINVAL); } g_free(buf); return (0); } static int ldm_xvblk_handle(struct ldm_db *db, struct ldm_vblkhdr *vh, const u_char *p) { struct ldm_xvblk *blk; size_t size; size = db->dh.size - 16; LIST_FOREACH(blk, &db->xvblks, entry) if (blk->group == vh->group) break; if (blk == NULL) { blk = g_malloc(sizeof(*blk), M_WAITOK | M_ZERO); blk->group = vh->group; blk->size = size * vh->count + 16; blk->data = g_malloc(blk->size, M_WAITOK | M_ZERO); blk->map = 0xFF << vh->count; LIST_INSERT_HEAD(&db->xvblks, blk, entry); } if ((blk->map & (1 << vh->index)) != 0) { /* Block with given index has been already saved. */ return (EINVAL); } /* Copy the data block to the place related to index. */ memcpy(blk->data + size * vh->index + 16, p + 16, size); blk->map |= 1 << vh->index; return (0); } /* Read the variable-width numeric field and return new offset */ static int ldm_vnum_get(const u_char *buf, int offset, uint64_t *result, size_t range) { uint64_t num; uint8_t len; len = buf[offset++]; if (len > sizeof(uint64_t) || len + offset >= range) return (-1); for (num = 0; len > 0; len--) num = (num << 8) | buf[offset++]; *result = num; return (offset); } /* Read the variable-width string and return new offset */ static int ldm_vstr_get(const u_char *buf, int offset, u_char *result, size_t maxlen, size_t range) { uint8_t len; len = buf[offset++]; if (len >= maxlen || len + offset >= range) return (-1); memcpy(result, buf + offset, len); result[len] = '\0'; return (offset + len); } /* Just skip the variable-width variable and return new offset */ static int ldm_vparm_skip(const u_char *buf, int offset, size_t range) { uint8_t len; len = buf[offset++]; if (offset + len >= range) return (-1); return (offset + len); } static int ldm_vblk_handle(struct ldm_db *db, const u_char *p, size_t size) { struct ldm_vblk *blk; struct ldm_volume *volume, *last; const char *errstr; u_char vstr[64]; int error, offset; blk = g_malloc(sizeof(*blk), M_WAITOK | M_ZERO); blk->type = p[LDM_VBLK_TYPE_OFF]; offset = ldm_vnum_get(p, LDM_VBLK_OID_OFF, &blk->u.id, size); if (offset < 0) { errstr = "object id"; goto fail; } offset = ldm_vstr_get(p, offset, vstr, sizeof(vstr), size); if (offset < 0) { errstr = "object name"; goto fail; } switch (blk->type) { /* * Component VBLK fields: * Offset Size Description * ------------+-------+------------------------ * 0x18+ PS volume state * 0x18+5 PN component children count * 0x1D+16 PN parent's volume object id * 0x2D+1 PN stripe size */ case LDM_VBLK_T_COMPONENT: offset = ldm_vparm_skip(p, offset, size); if (offset < 0) { errstr = "volume state"; goto fail; } offset = ldm_vparm_skip(p, offset + 5, size); if (offset < 0) { errstr = "children count"; goto fail; } offset = ldm_vnum_get(p, offset + 16, &blk->u.comp.vol_id, size); if (offset < 0) { errstr = "volume id"; goto fail; } break; /* * Partition VBLK fields: * Offset Size Description * ------------+-------+------------------------ * 0x18+12 8 partition start offset * 0x18+20 8 volume offset * 0x18+28 PN partition size * 0x34+ PN parent's component object id * 0x34+ PN disk's object id */ case LDM_VBLK_T_PARTITION: if (offset + 28 >= size) { errstr = "too small buffer"; goto fail; } blk->u.part.start = be64dec(p + offset + 12); blk->u.part.offset = be64dec(p + offset + 20); offset = ldm_vnum_get(p, offset + 28, &blk->u.part.size, size); if (offset < 0) { errstr = "partition size"; goto fail; } offset = ldm_vnum_get(p, offset, &blk->u.part.comp_id, size); if (offset < 0) { errstr = "component id"; goto fail; } offset = ldm_vnum_get(p, offset, &blk->u.part.disk_id, size); if (offset < 0) { errstr = "disk id"; goto fail; } break; /* * Disk VBLK fields: * Offset Size Description * ------------+-------+------------------------ * 0x18+ PS disk GUID */ case LDM_VBLK_T_DISK: errstr = "disk guid"; offset = ldm_vstr_get(p, offset, vstr, sizeof(vstr), size); if (offset < 0) goto fail; error = parse_uuid(vstr, &blk->u.disk.guid); if (error != 0) goto fail; LIST_INSERT_HEAD(&db->disks, &blk->u.disk, entry); break; /* * Disk group VBLK fields: * Offset Size Description * ------------+-------+------------------------ * 0x18+ PS disk group GUID */ case LDM_VBLK_T_DISKGROUP: #if 0 strncpy(blk->u.disk_group.name, vstr, sizeof(blk->u.disk_group.name)); offset = ldm_vstr_get(p, offset, vstr, sizeof(vstr), size); if (offset < 0) { errstr = "disk group guid"; goto fail; } error = parse_uuid(name, &blk->u.disk_group.guid); if (error != 0) { errstr = "disk group guid"; goto fail; } LIST_INSERT_HEAD(&db->groups, &blk->u.disk_group, entry); #endif break; /* * Disk VBLK fields: * Offset Size Description * ------------+-------+------------------------ * 0x18+ 16 disk GUID */ case LDM_VBLK_T_DISK4: be_uuid_dec(p + offset, &blk->u.disk.guid); LIST_INSERT_HEAD(&db->disks, &blk->u.disk, entry); break; /* * Disk group VBLK fields: * Offset Size Description * ------------+-------+------------------------ * 0x18+ 16 disk GUID */ case LDM_VBLK_T_DISKGROUP4: #if 0 strncpy(blk->u.disk_group.name, vstr, sizeof(blk->u.disk_group.name)); be_uuid_dec(p + offset, &blk->u.disk.guid); LIST_INSERT_HEAD(&db->groups, &blk->u.disk_group, entry); #endif break; /* * Volume VBLK fields: * Offset Size Description * ------------+-------+------------------------ * 0x18+ PS volume type * 0x18+ PS unknown * 0x18+ 14(S) volume state * 0x18+16 1 volume number * 0x18+21 PN volume children count * 0x2D+16 PN volume size * 0x3D+4 1 partition type */ case LDM_VBLK_T_VOLUME: offset = ldm_vparm_skip(p, offset, size); if (offset < 0) { errstr = "volume type"; goto fail; } offset = ldm_vparm_skip(p, offset, size); if (offset < 0) { errstr = "unknown param"; goto fail; } if (offset + 21 >= size) { errstr = "too small buffer"; goto fail; } blk->u.vol.number = p[offset + 16]; offset = ldm_vparm_skip(p, offset + 21, size); if (offset < 0) { errstr = "children count"; goto fail; } offset = ldm_vnum_get(p, offset + 16, &blk->u.vol.size, size); if (offset < 0) { errstr = "volume size"; goto fail; } if (offset + 4 >= size) { errstr = "too small buffer"; goto fail; } blk->u.vol.part_type = p[offset + 4]; /* keep volumes ordered by volume number */ last = NULL; LIST_FOREACH(volume, &db->volumes, entry) { if (volume->number > blk->u.vol.number) break; last = volume; } if (last != NULL) LIST_INSERT_AFTER(last, &blk->u.vol, entry); else LIST_INSERT_HEAD(&db->volumes, &blk->u.vol, entry); break; default: LDM_DEBUG(1, "unknown VBLK type 0x%02x\n", blk->type); LDM_DUMP(p, size); } LIST_INSERT_HEAD(&db->vblks, blk, entry); return (0); fail: LDM_DEBUG(0, "failed to parse '%s' in VBLK of type 0x%02x\n", errstr, blk->type); LDM_DUMP(p, size); g_free(blk); return (EINVAL); } static void ldm_vmdb_free(struct ldm_db *db) { struct ldm_vblk *vblk; struct ldm_xvblk *xvblk; while (!LIST_EMPTY(&db->xvblks)) { xvblk = LIST_FIRST(&db->xvblks); LIST_REMOVE(xvblk, entry); g_free(xvblk->data); g_free(xvblk); } while (!LIST_EMPTY(&db->vblks)) { vblk = LIST_FIRST(&db->vblks); LIST_REMOVE(vblk, entry); g_free(vblk); } } static int ldm_vmdb_parse(struct ldm_db *db, struct g_consumer *cp) { struct g_provider *pp; struct ldm_vblk *vblk; struct ldm_xvblk *xvblk; struct ldm_volume *volume; struct ldm_component *comp; struct ldm_vblkhdr vh; u_char *buf, *p; size_t size, n, sectors; uint64_t offset; int error; pp = cp->provider; size = howmany(db->dh.last_seq * db->dh.size, pp->sectorsize); size -= 1; /* one sector takes vmdb header */ for (n = 0; n < size; n += maxphys / pp->sectorsize) { offset = db->ph.db_offset + db->th.conf_offset + n + 1; sectors = (size - n) > (maxphys / pp->sectorsize) ? maxphys / pp->sectorsize : size - n; /* read VBLKs */ buf = g_read_data(cp, offset * pp->sectorsize, sectors * pp->sectorsize, &error); if (buf == NULL) { LDM_DEBUG(0, "%s: failed to read VBLK\n", pp->name); goto fail; } for (p = buf; p < buf + sectors * pp->sectorsize; p += db->dh.size) { if (memcmp(p, LDM_VBLK_SIGN, strlen(LDM_VBLK_SIGN)) != 0) { LDM_DEBUG(0, "%s: no VBLK signature\n", pp->name); LDM_DUMP(p, db->dh.size); goto fail; } vh.seq = be32dec(p + LDM_VBLK_SEQ_OFF); vh.group = be32dec(p + LDM_VBLK_GROUP_OFF); /* skip empty blocks */ if (vh.seq == 0 || vh.group == 0) continue; vh.index = be16dec(p + LDM_VBLK_INDEX_OFF); vh.count = be16dec(p + LDM_VBLK_COUNT_OFF); if (vh.count == 0 || vh.count > 4 || vh.seq > db->dh.last_seq) { LDM_DEBUG(0, "%s: invalid values " "in the VBLK header\n", pp->name); LDM_DUMP(p, db->dh.size); goto fail; } if (vh.count > 1) { error = ldm_xvblk_handle(db, &vh, p); if (error != 0) { LDM_DEBUG(0, "%s: xVBLK " "is corrupted\n", pp->name); LDM_DUMP(p, db->dh.size); goto fail; } continue; } if (be16dec(p + 16) != 0) LDM_DEBUG(1, "%s: VBLK update" " status is %u\n", pp->name, be16dec(p + 16)); error = ldm_vblk_handle(db, p, db->dh.size); if (error != 0) goto fail; } g_free(buf); buf = NULL; } /* Parse xVBLKs */ while (!LIST_EMPTY(&db->xvblks)) { xvblk = LIST_FIRST(&db->xvblks); if (xvblk->map == 0xFF) { error = ldm_vblk_handle(db, xvblk->data, xvblk->size); if (error != 0) goto fail; } else { LDM_DEBUG(0, "%s: incomplete or corrupt " "xVBLK found\n", pp->name); goto fail; } LIST_REMOVE(xvblk, entry); g_free(xvblk->data); g_free(xvblk); } /* construct all VBLKs relations */ LIST_FOREACH(volume, &db->volumes, entry) { LIST_FOREACH(vblk, &db->vblks, entry) if (vblk->type == LDM_VBLK_T_COMPONENT && vblk->u.comp.vol_id == volume->id) { LIST_INSERT_HEAD(&volume->components, &vblk->u.comp, entry); volume->count++; } LIST_FOREACH(comp, &volume->components, entry) LIST_FOREACH(vblk, &db->vblks, entry) if (vblk->type == LDM_VBLK_T_PARTITION && vblk->u.part.comp_id == comp->id) { LIST_INSERT_HEAD(&comp->partitions, &vblk->u.part, entry); comp->count++; } } return (0); fail: ldm_vmdb_free(db); g_free(buf); return (ENXIO); } static int g_part_ldm_add(struct g_part_table *basetable, struct g_part_entry *baseentry, struct g_part_parms *gpp) { return (ENOSYS); } static int g_part_ldm_bootcode(struct g_part_table *basetable, struct g_part_parms *gpp) { return (ENOSYS); } static int g_part_ldm_create(struct g_part_table *basetable, struct g_part_parms *gpp) { return (ENOSYS); } static int g_part_ldm_destroy(struct g_part_table *basetable, struct g_part_parms *gpp) { struct g_part_ldm_table *table; struct g_provider *pp; table = (struct g_part_ldm_table *)basetable; /* * To destroy LDM on a disk partitioned with GPT we should delete * ms-ldm-metadata partition, but we can't do this via standard * GEOM_PART method. */ if (table->is_gpt) return (ENOSYS); pp = LIST_FIRST(&basetable->gpt_gp->consumer)->provider; /* * To destroy LDM we should wipe MBR, first private header and * backup private headers. */ basetable->gpt_smhead = (1 << ldm_ph_off[0]) | 1; /* * Don't touch last backup private header when LDM database is * not located in the last 1MByte area. * XXX: can't remove all blocks. */ if (table->db_offset + LDM_DB_SIZE == pp->mediasize / pp->sectorsize) basetable->gpt_smtail = 1; return (0); } static void g_part_ldm_dumpconf(struct g_part_table *basetable, struct g_part_entry *baseentry, struct sbuf *sb, const char *indent) { struct g_part_ldm_entry *entry; entry = (struct g_part_ldm_entry *)baseentry; if (indent == NULL) { /* conftxt: libdisk compatibility */ sbuf_printf(sb, " xs LDM xt %u", entry->type); } else if (entry != NULL) { /* confxml: partition entry information */ sbuf_printf(sb, "%s%u\n", indent, entry->type); } else { /* confxml: scheme information */ } } static int g_part_ldm_dumpto(struct g_part_table *table, struct g_part_entry *baseentry) { return (0); } static int g_part_ldm_modify(struct g_part_table *basetable, struct g_part_entry *baseentry, struct g_part_parms *gpp) { return (ENOSYS); } static const char * g_part_ldm_name(struct g_part_table *table, struct g_part_entry *baseentry, char *buf, size_t bufsz) { snprintf(buf, bufsz, "s%d", baseentry->gpe_index); return (buf); } static int ldm_gpt_probe(struct g_part_table *basetable, struct g_consumer *cp) { struct g_part_ldm_table *table; struct g_part_table *gpt; struct g_part_entry *entry; struct g_consumer *cp2; struct gpt_ent *part; u_char *buf; int error; /* * XXX: We use some knowledge about GEOM_PART_GPT internal * structures, but it is easier than parse GPT by himself. */ g_topology_lock(); gpt = cp->provider->geom->softc; LIST_FOREACH(entry, &gpt->gpt_entry, gpe_entry) { part = (struct gpt_ent *)(entry + 1); /* Search ms-ldm-metadata partition */ if (memcmp(&part->ent_type, &gpt_uuid_ms_ldm_metadata, sizeof(struct uuid)) != 0 || entry->gpe_end - entry->gpe_start < LDM_DB_SIZE - 1) continue; /* Create new consumer and attach it to metadata partition */ cp2 = g_new_consumer(cp->geom); error = g_attach(cp2, entry->gpe_pp); if (error != 0) { g_destroy_consumer(cp2); g_topology_unlock(); return (ENXIO); } error = g_access(cp2, 1, 0, 0); if (error != 0) { g_detach(cp2); g_destroy_consumer(cp2); g_topology_unlock(); return (ENXIO); } g_topology_unlock(); LDM_DEBUG(2, "%s: LDM metadata partition %s found in the GPT", cp->provider->name, cp2->provider->name); /* Read the LDM private header */ buf = ldm_privhdr_read(cp2, ldm_ph_off[LDM_PH_GPTINDEX] * cp2->provider->sectorsize, &error); if (buf != NULL) { table = (struct g_part_ldm_table *)basetable; table->is_gpt = 1; g_free(buf); return (G_PART_PROBE_PRI_HIGH); } /* second consumer is no longer needed. */ g_topology_lock(); g_access(cp2, -1, 0, 0); g_detach(cp2); g_destroy_consumer(cp2); break; } g_topology_unlock(); return (ENXIO); } static int g_part_ldm_probe(struct g_part_table *basetable, struct g_consumer *cp) { struct g_provider *pp; u_char *buf, type[64]; int error, idx; pp = cp->provider; if (pp->sectorsize != 512) return (ENXIO); error = g_getattr("PART::scheme", cp, &type); if (error == 0 && strcmp(type, "GPT") == 0) { if (g_getattr("PART::type", cp, &type) != 0 || strcmp(type, "ms-ldm-data") != 0) return (ENXIO); error = ldm_gpt_probe(basetable, cp); return (error); } if (basetable->gpt_depth != 0) return (ENXIO); /* LDM has 1M metadata area */ if (pp->mediasize <= 1024 * 1024) return (ENOSPC); /* Check that there's a MBR */ buf = g_read_data(cp, 0, pp->sectorsize, &error); if (buf == NULL) return (error); if (le16dec(buf + DOSMAGICOFFSET) != DOSMAGIC) { g_free(buf); return (ENXIO); } error = ENXIO; /* Check that we have LDM partitions in the MBR */ for (idx = 0; idx < NDOSPART && error != 0; idx++) { if (buf[DOSPARTOFF + idx * DOSPARTSIZE + 4] == DOSPTYP_LDM) error = 0; } g_free(buf); if (error == 0) { LDM_DEBUG(2, "%s: LDM data partitions found in MBR", pp->name); /* Read the LDM private header */ buf = ldm_privhdr_read(cp, ldm_ph_off[LDM_PH_MBRINDEX] * pp->sectorsize, &error); if (buf == NULL) return (error); g_free(buf); return (G_PART_PROBE_PRI_HIGH); } return (error); } static int g_part_ldm_read(struct g_part_table *basetable, struct g_consumer *cp) { struct g_part_ldm_table *table; struct g_part_ldm_entry *entry; struct g_consumer *cp2; struct ldm_component *comp; struct ldm_partition *part; struct ldm_volume *vol; struct ldm_disk *disk; struct ldm_db db; int error, index, skipped; table = (struct g_part_ldm_table *)basetable; memset(&db, 0, sizeof(db)); cp2 = cp; /* ms-ldm-data */ if (table->is_gpt) cp = LIST_FIRST(&cp->geom->consumer); /* ms-ldm-metadata */ /* Read and parse LDM private headers. */ error = ldm_privhdr_check(&db, cp, table->is_gpt); if (error != 0) goto gpt_cleanup; basetable->gpt_first = table->is_gpt ? 0: db.ph.start; basetable->gpt_last = basetable->gpt_first + db.ph.size - 1; table->db_offset = db.ph.db_offset; /* Make additional checks for GPT */ if (table->is_gpt) { error = ldm_gpt_check(&db, cp); if (error != 0) goto gpt_cleanup; /* * Now we should reset database offset to zero, because our * consumer cp is attached to the ms-ldm-metadata partition * and we don't need add db_offset to read from it. */ db.ph.db_offset = 0; } /* Read and parse LDM TOC headers. */ error = ldm_tochdr_check(&db, cp); if (error != 0) goto gpt_cleanup; /* Read and parse LDM VMDB header. */ error = ldm_vmdbhdr_check(&db, cp); if (error != 0) goto gpt_cleanup; error = ldm_vmdb_parse(&db, cp); /* * For the GPT case we must detach and destroy * second consumer before return. */ gpt_cleanup: if (table->is_gpt) { g_topology_lock(); g_access(cp, -1, 0, 0); g_detach(cp); g_destroy_consumer(cp); g_topology_unlock(); cp = cp2; } if (error != 0) return (error); /* Search current disk in the disk list. */ LIST_FOREACH(disk, &db.disks, entry) if (memcmp(&disk->guid, &db.ph.disk_guid, sizeof(struct uuid)) == 0) break; if (disk == NULL) { LDM_DEBUG(1, "%s: no LDM volumes on this disk", cp->provider->name); ldm_vmdb_free(&db); return (ENXIO); } index = 1; LIST_FOREACH(vol, &db.volumes, entry) { LIST_FOREACH(comp, &vol->components, entry) { /* Skip volumes from different disks. */ part = LIST_FIRST(&comp->partitions); if (part->disk_id != disk->id) continue; skipped = 0; /* We don't support spanned and striped volumes. */ if (comp->count > 1 || part->offset != 0) { LDM_DEBUG(1, "%s: LDM volume component " "%ju has %u partitions. Skipped", cp->provider->name, (uintmax_t)comp->id, comp->count); skipped = 1; } /* * Allow mirrored volumes only when they are explicitly * allowed with kern.geom.part.ldm.show_mirrors=1. */ if (vol->count > 1 && show_mirrors == 0) { LDM_DEBUG(1, "%s: LDM volume %ju has %u " "components. Skipped", cp->provider->name, (uintmax_t)vol->id, vol->count); skipped = 1; } entry = (struct g_part_ldm_entry *)g_part_new_entry( basetable, index++, basetable->gpt_first + part->start, basetable->gpt_first + part->start + part->size - 1); /* * Mark skipped partition as ms-ldm-data partition. * We do not support them, but it is better to show * that we have something there, than just show * free space. */ if (skipped == 0) entry->type = vol->part_type; else entry->type = DOSPTYP_LDM; LDM_DEBUG(1, "%s: new volume id: %ju, start: %ju," " end: %ju, type: 0x%02x\n", cp->provider->name, (uintmax_t)part->id,(uintmax_t)part->start + basetable->gpt_first, (uintmax_t)part->start + part->size + basetable->gpt_first - 1, vol->part_type); } } ldm_vmdb_free(&db); return (error); } static const char * g_part_ldm_type(struct g_part_table *basetable, struct g_part_entry *baseentry, char *buf, size_t bufsz) { struct g_part_ldm_entry *entry; int i; entry = (struct g_part_ldm_entry *)baseentry; for (i = 0; i < nitems(ldm_alias_match); i++) { if (ldm_alias_match[i].typ == entry->type) return (g_part_alias_name(ldm_alias_match[i].alias)); } snprintf(buf, bufsz, "!%d", entry->type); return (buf); } static int g_part_ldm_write(struct g_part_table *basetable, struct g_consumer *cp) { return (ENOSYS); }