/* * Copyright (C) 2007 Karel Zak * Copyright (C) 2012 Davidlohr Bueso * * GUID Partition Table (GPT) support. Based on UEFI Specs 2.3.1 * Chapter 5: GUID Partition Table (GPT) Disk Layout (Jun 27th, 2012). * Some ideas and inspiration from GNU parted and gptfdisk. */ #include #include #include #include #include #include #include #include #include #include #include #include #include "fdiskP.h" #include "crc32.h" #include "blkdev.h" #include "bitops.h" #include "strutils.h" #include "all-io.h" #include "pt-mbr.h" #include "encode.h" /** * SECTION: gpt * @title: UEFI GPT * @short_description: specific functionality */ #define GPT_HEADER_SIGNATURE 0x5452415020494645LL /* EFI PART */ #define GPT_HEADER_REVISION_V1_02 0x00010200 #define GPT_HEADER_REVISION_V1_00 0x00010000 #define GPT_HEADER_REVISION_V0_99 0x00009900 #define GPT_HEADER_MINSZ 92 /* bytes */ #define GPT_PMBR_LBA 0 #define GPT_MBR_PROTECTIVE 1 #define GPT_MBR_HYBRID 2 #define GPT_PRIMARY_PARTITION_TABLE_LBA 0x00000001ULL #define EFI_PMBR_OSTYPE 0xEE #define MSDOS_MBR_SIGNATURE 0xAA55 #define GPT_PART_NAME_LEN (72 / sizeof(uint16_t)) #define GPT_NPARTITIONS FDISK_GPT_NPARTITIONS_DEFAULT /* Globally unique identifier */ struct gpt_guid { uint32_t time_low; uint16_t time_mid; uint16_t time_hi_and_version; uint8_t clock_seq_hi; uint8_t clock_seq_low; uint8_t node[6]; }; /* only checking that the GUID is 0 is enough to verify an empty partition. */ #define GPT_UNUSED_ENTRY_GUID \ ((struct gpt_guid) { 0x00000000, 0x0000, 0x0000, 0x00, 0x00, \ { 0x00, 0x00, 0x00, 0x00, 0x00, 0x00 }}) /* Linux native partition type */ #define GPT_DEFAULT_ENTRY_TYPE "0FC63DAF-8483-4772-8E79-3D69D8477DE4" /* * Attribute bits */ enum { /* UEFI specific */ GPT_ATTRBIT_REQ = 0, GPT_ATTRBIT_NOBLOCK = 1, GPT_ATTRBIT_LEGACY = 2, /* GUID specific (range 48..64)*/ GPT_ATTRBIT_GUID_FIRST = 48, GPT_ATTRBIT_GUID_COUNT = 16 }; #define GPT_ATTRSTR_REQ "RequiredPartition" #define GPT_ATTRSTR_REQ_TYPO "RequiredPartiton" #define GPT_ATTRSTR_NOBLOCK "NoBlockIOProtocol" #define GPT_ATTRSTR_LEGACY "LegacyBIOSBootable" /* The GPT Partition entry array contains an array of GPT entries. */ struct gpt_entry { struct gpt_guid type; /* purpose and type of the partition */ struct gpt_guid partition_guid; uint64_t lba_start; uint64_t lba_end; uint64_t attrs; uint16_t name[GPT_PART_NAME_LEN]; } __attribute__ ((packed)); /* GPT header */ struct gpt_header { uint64_t signature; /* header identification */ uint32_t revision; /* header version */ uint32_t size; /* in bytes */ uint32_t crc32; /* header CRC checksum */ uint32_t reserved1; /* must be 0 */ uint64_t my_lba; /* LBA of block that contains this struct (LBA 1) */ uint64_t alternative_lba; /* backup GPT header */ uint64_t first_usable_lba; /* first usable logical block for partitions */ uint64_t last_usable_lba; /* last usable logical block for partitions */ struct gpt_guid disk_guid; /* unique disk identifier */ uint64_t partition_entry_lba; /* LBA of start of partition entries array */ uint32_t npartition_entries; /* total partition entries - normally 128 */ uint32_t sizeof_partition_entry; /* bytes for each GUID pt */ uint32_t partition_entry_array_crc32; /* partition CRC checksum */ uint8_t reserved2[512 - 92]; /* must all be 0 */ } __attribute__ ((packed)); struct gpt_record { uint8_t boot_indicator; /* unused by EFI, set to 0x80 for bootable */ uint8_t start_head; /* unused by EFI, pt start in CHS */ uint8_t start_sector; /* unused by EFI, pt start in CHS */ uint8_t start_track; uint8_t os_type; /* EFI and legacy non-EFI OS types */ uint8_t end_head; /* unused by EFI, pt end in CHS */ uint8_t end_sector; /* unused by EFI, pt end in CHS */ uint8_t end_track; /* unused by EFI, pt end in CHS */ uint32_t starting_lba; /* used by EFI - start addr of the on disk pt */ uint32_t size_in_lba; /* used by EFI - size of pt in LBA */ } __attribute__ ((packed)); /* Protected MBR and legacy MBR share same structure */ struct gpt_legacy_mbr { uint8_t boot_code[440]; uint32_t unique_mbr_signature; uint16_t unknown; struct gpt_record partition_record[4]; uint16_t signature; } __attribute__ ((packed)); /* * Here be dragons! * See: http://en.wikipedia.org/wiki/GUID_Partition_Table#Partition_type_GUIDs */ #define DEF_GUID(_u, _n) \ { \ .typestr = (_u), \ .name = (_n), \ } static struct fdisk_parttype gpt_parttypes[] = { #include "pt-gpt-partnames.h" }; static const struct fdisk_shortcut gpt_parttype_cuts[] = { { .shortcut = "L", .alias = "linux", .data = "0FC63DAF-8483-4772-8E79-3D69D8477DE4" }, /* Linux */ { .shortcut = "S", .alias = "swap", .data = "0657FD6D-A4AB-43C4-84E5-0933C84B4F4F" }, /* Swap */ { .shortcut = "H", .alias = "home", .data = "933AC7E1-2EB4-4F13-B844-0E14E2AEF915" }, /* Home */ { .shortcut = "U", .alias = "uefi", .data = "C12A7328-F81F-11D2-BA4B-00A0C93EC93B" }, /* UEFI system */ { .shortcut = "R", .alias = "raid", .data = "A19D880F-05FC-4D3B-A006-743F0F84911E" }, /* Linux RAID */ { .shortcut = "V", .alias = "lvm", .data = "E6D6D379-F507-44C2-A23C-238F2A3DF928" } /* LVM */ }; #define alignment_required(_x) ((_x)->grain != (_x)->sector_size) /* gpt_entry macros */ #define gpt_partition_start(_e) le64_to_cpu((_e)->lba_start) #define gpt_partition_end(_e) le64_to_cpu((_e)->lba_end) /* * in-memory fdisk GPT stuff */ struct fdisk_gpt_label { struct fdisk_label head; /* generic part */ /* gpt specific part */ struct gpt_header *pheader; /* primary header */ struct gpt_header *bheader; /* backup header */ unsigned char *ents; /* entries (partitions) */ unsigned int no_relocate :1, /* do not fix backup location */ minimize :1; }; static void gpt_deinit(struct fdisk_label *lb); static inline struct fdisk_gpt_label *self_label(struct fdisk_context *cxt) { return (struct fdisk_gpt_label *) cxt->label; } /* * Returns the partition length, or 0 if end is before beginning. */ static uint64_t gpt_partition_size(const struct gpt_entry *e) { uint64_t start = gpt_partition_start(e); uint64_t end = gpt_partition_end(e); return start > end ? 0 : end - start + 1ULL; } /* prints UUID in the real byte order! */ static void gpt_debug_uuid(const char *mesg, struct gpt_guid *guid) { const unsigned char *uuid = (unsigned char *) guid; fprintf(stderr, "%s: " "%02x%02x%02x%02x-%02x%02x-%02x%02x-%02x%02x-%02x%02x%02x%02x%02x%02x\n", mesg, uuid[0], uuid[1], uuid[2], uuid[3], uuid[4], uuid[5], uuid[6], uuid[7], uuid[8], uuid[9], uuid[10], uuid[11], uuid[12], uuid[13], uuid[14],uuid[15]); } /* * UUID is traditionally 16 byte big-endian array, except Intel EFI * specification where the UUID is a structure of little-endian fields. */ static void swap_efi_guid(struct gpt_guid *uid) { uid->time_low = swab32(uid->time_low); uid->time_mid = swab16(uid->time_mid); uid->time_hi_and_version = swab16(uid->time_hi_and_version); } static int string_to_guid(const char *in, struct gpt_guid *guid) { if (uuid_parse(in, (unsigned char *) guid)) { /* BE */ DBG(GPT, ul_debug("failed to parse GUID: %s", in)); return -EINVAL; } swap_efi_guid(guid); /* LE */ return 0; } static char *guid_to_string(const struct gpt_guid *guid, char *out) { struct gpt_guid u = *guid; /* LE */ swap_efi_guid(&u); /* BE */ uuid_unparse_upper((unsigned char *) &u, out); return out; } static struct fdisk_parttype *gpt_partition_parttype( struct fdisk_context *cxt, const struct gpt_entry *e) { struct fdisk_parttype *t; char str[UUID_STR_LEN]; struct gpt_guid guid = e->type; guid_to_string(&guid, str); t = fdisk_label_get_parttype_from_string(cxt->label, str); return t ? : fdisk_new_unknown_parttype(0, str); } static void gpt_entry_set_type(struct gpt_entry *e, struct gpt_guid *uuid) { e->type = *uuid; DBG(GPT, gpt_debug_uuid("new type", uuid)); } static int gpt_entry_set_name(struct gpt_entry *e, char *str) { uint16_t name[GPT_PART_NAME_LEN] = { 0 }; size_t i, mblen = 0; uint8_t *in = (uint8_t *) str; for (i = 0; *in && i < GPT_PART_NAME_LEN; in++) { if (!mblen) { if (!(*in & 0x80)) { name[i++] = *in; } else if ((*in & 0xE0) == 0xC0) { mblen = 1; name[i] = (uint16_t)(*in & 0x1F) << (mblen *6); } else if ((*in & 0xF0) == 0xE0) { mblen = 2; name[i] = (uint16_t)(*in & 0x0F) << (mblen *6); } else { /* broken UTF-8 or code point greater than U+FFFF */ return -EILSEQ; } } else { /* incomplete UTF-8 sequence */ if ((*in & 0xC0) != 0x80) return -EILSEQ; name[i] |= (uint16_t)(*in & 0x3F) << (--mblen *6); if (!mblen) { /* check for code points reserved for surrogate pairs*/ if ((name[i] & 0xF800) == 0xD800) return -EILSEQ; i++; } } } for (i = 0; i < GPT_PART_NAME_LEN; i++) e->name[i] = cpu_to_le16(name[i]); return (int)((char *) in - str); } static int gpt_entry_set_uuid(struct gpt_entry *e, char *str) { struct gpt_guid uuid; int rc; rc = string_to_guid(str, &uuid); if (rc) return rc; e->partition_guid = uuid; return 0; } static inline int gpt_entry_is_used(const struct gpt_entry *e) { return memcmp(&e->type, &GPT_UNUSED_ENTRY_GUID, sizeof(struct gpt_guid)) != 0; } static const char *gpt_get_header_revstr(struct gpt_header *header) { if (!header) goto unknown; switch (le32_to_cpu(header->revision)) { case GPT_HEADER_REVISION_V1_02: return "1.2"; case GPT_HEADER_REVISION_V1_00: return "1.0"; case GPT_HEADER_REVISION_V0_99: return "0.99"; default: goto unknown; } unknown: return "unknown"; } static inline unsigned char *gpt_get_entry_ptr(struct fdisk_gpt_label *gpt, size_t i) { return gpt->ents + le32_to_cpu(gpt->pheader->sizeof_partition_entry) * i; } static inline struct gpt_entry *gpt_get_entry(struct fdisk_gpt_label *gpt, size_t i) { return (struct gpt_entry *) gpt_get_entry_ptr(gpt, i); } static inline struct gpt_entry *gpt_zeroize_entry(struct fdisk_gpt_label *gpt, size_t i) { return (struct gpt_entry *) memset(gpt_get_entry_ptr(gpt, i), 0, le32_to_cpu(gpt->pheader->sizeof_partition_entry)); } /* Use to access array of entries, for() loops, etc. But don't use when * you directly do something with GPT header, then use uint32_t. */ static inline size_t gpt_get_nentries(struct fdisk_gpt_label *gpt) { return (size_t) le32_to_cpu(gpt->pheader->npartition_entries); } /* calculate size of entries array in bytes for specified number of entries */ static inline int gpt_calculate_sizeof_entries( struct gpt_header *hdr, uint32_t nents, size_t *sz) { uint32_t esz = hdr ? le32_to_cpu(hdr->sizeof_partition_entry) : sizeof(struct gpt_entry); if (nents == 0 || esz == 0 || SIZE_MAX/esz < nents) { DBG(GPT, ul_debug("entries array size check failed")); return -ERANGE; } *sz = (size_t) nents * esz; return 0; } /* calculate size of entries array in sectors for specified number of entries */ static inline int gpt_calculate_sectorsof_entries( struct gpt_header *hdr, uint32_t nents, uint64_t *sz, struct fdisk_context *cxt) { size_t esz = 0; int rc = gpt_calculate_sizeof_entries(hdr, nents, &esz); /* in bytes */ if (rc == 0) *sz = (esz + cxt->sector_size - 1) / cxt->sector_size; return rc; } /* calculate alternative (backup) entries array offset from primary header */ static inline int gpt_calculate_alternative_entries_lba( struct gpt_header *hdr, uint32_t nents, uint64_t *sz, struct fdisk_context *cxt) { uint64_t esects = 0; int rc = gpt_calculate_sectorsof_entries(hdr, nents, &esects, cxt); if (rc) return rc; if (cxt->total_sectors < 1ULL + esects) return -ENOSPC; *sz = cxt->total_sectors - 1ULL - esects; return 0; } static inline int gpt_calculate_last_lba( struct gpt_header *hdr, uint32_t nents, uint64_t *sz, struct fdisk_context *cxt) { uint64_t esects = 0; int rc = gpt_calculate_sectorsof_entries(hdr, nents, &esects, cxt); if (rc) return rc; if (cxt->total_sectors < 2ULL + esects) return -ENOSPC; *sz = cxt->total_sectors - 2ULL - esects; return 0; } static inline int gpt_calculate_first_lba( struct gpt_header *hdr, uint32_t nents, uint64_t *sz, struct fdisk_context *cxt) { uint64_t esects = 0; int rc = gpt_calculate_sectorsof_entries(hdr, nents, &esects, cxt); if (rc == 0) *sz = esects + 2ULL; return rc; } /* the current size of entries array in bytes */ static inline int gpt_sizeof_entries(struct gpt_header *hdr, size_t *sz) { return gpt_calculate_sizeof_entries(hdr, le32_to_cpu(hdr->npartition_entries), sz); } static char *gpt_get_header_id(struct gpt_header *header) { char str[UUID_STR_LEN]; struct gpt_guid guid = header->disk_guid; guid_to_string(&guid, str); return strdup(str); } /* * Builds a clean new valid protective MBR - will wipe out any existing data. * Returns 0 on success, otherwise < 0 on error. */ static int gpt_mknew_pmbr(struct fdisk_context *cxt) { struct gpt_legacy_mbr *pmbr = NULL; int rc; if (!cxt || !cxt->firstsector) return -ENOSYS; if (fdisk_has_protected_bootbits(cxt)) rc = fdisk_init_firstsector_buffer(cxt, 0, MBR_PT_BOOTBITS_SIZE); else rc = fdisk_init_firstsector_buffer(cxt, 0, 0); if (rc) return rc; pmbr = (struct gpt_legacy_mbr *) cxt->firstsector; memset(pmbr->partition_record, 0, sizeof(pmbr->partition_record)); pmbr->signature = cpu_to_le16(MSDOS_MBR_SIGNATURE); pmbr->partition_record[0].os_type = EFI_PMBR_OSTYPE; pmbr->partition_record[0].start_sector = 2; pmbr->partition_record[0].end_head = 0xFF; pmbr->partition_record[0].end_sector = 0xFF; pmbr->partition_record[0].end_track = 0xFF; pmbr->partition_record[0].starting_lba = cpu_to_le32(1); pmbr->partition_record[0].size_in_lba = cpu_to_le32((uint32_t) min( cxt->total_sectors - 1ULL, 0xFFFFFFFFULL) ); return 0; } /* Move backup header to the end of the device */ static int gpt_fix_alternative_lba(struct fdisk_context *cxt, struct fdisk_gpt_label *gpt) { struct gpt_header *p, *b; uint64_t x = 0, orig; size_t nents; int rc; if (!cxt) return -EINVAL; p = gpt->pheader; /* primary */ b = gpt->bheader; /* backup */ nents = le32_to_cpu(p->npartition_entries); orig = le64_to_cpu(p->alternative_lba); /* reference from primary to backup */ p->alternative_lba = cpu_to_le64(cxt->total_sectors - 1ULL); /* reference from backup to primary */ b->alternative_lba = p->my_lba; b->my_lba = p->alternative_lba; /* fix backup partitions array address */ rc = gpt_calculate_alternative_entries_lba(p, nents, &x, cxt); if (rc) goto failed; b->partition_entry_lba = cpu_to_le64(x); /* update last usable LBA */ rc = gpt_calculate_last_lba(p, nents, &x, cxt); if (rc) goto failed; p->last_usable_lba = cpu_to_le64(x); b->last_usable_lba = cpu_to_le64(x); DBG(GPT, ul_debug("Alternative-LBA updated from %"PRIu64" to %"PRIu64, orig, le64_to_cpu(p->alternative_lba))); return 0; failed: DBG(GPT, ul_debug("failed to fix alternative-LBA [rc=%d]", rc)); return rc; } static uint64_t gpt_calculate_minimal_size(struct fdisk_context *cxt, struct fdisk_gpt_label *gpt) { size_t i; uint64_t x = 0, total = 0; struct gpt_header *hdr; assert(cxt); assert(gpt); assert(gpt->pheader); assert(gpt->ents); hdr = gpt->pheader; /* LBA behind the last partition */ for (i = 0; i < gpt_get_nentries(gpt); i++) { struct gpt_entry *e = gpt_get_entry(gpt, i); if (gpt_entry_is_used(e)) { uint64_t end = gpt_partition_end(e); if (end > x) x = end; } } total = x + 1; /* the current last LBA usable for partitions */ gpt_calculate_last_lba(hdr, le32_to_cpu(hdr->npartition_entries), &x, cxt); /* size of all stuff at the end of the device */ total += cxt->total_sectors - x; DBG(GPT, ul_debug("minimal device is %"PRIu64, total)); return total; } static int gpt_possible_minimize(struct fdisk_context *cxt, struct fdisk_gpt_label *gpt) { struct gpt_header *hdr = gpt->pheader; uint64_t total = gpt_calculate_minimal_size(cxt, gpt); return le64_to_cpu(hdr->alternative_lba) > (total - 1ULL); } /* move backup header behind the last partition */ static int gpt_minimize_alternative_lba(struct fdisk_context *cxt, struct fdisk_gpt_label *gpt) { uint64_t total = gpt_calculate_minimal_size(cxt, gpt); uint64_t orig = cxt->total_sectors; int rc; /* Let's temporary change size of the device to recalculate backup header */ cxt->total_sectors = total; rc = gpt_fix_alternative_lba(cxt, gpt); if (rc) return rc; cxt->total_sectors = orig; fdisk_label_set_changed(cxt->label, 1); return 0; } /* some universal differences between the headers */ static void gpt_mknew_header_common(struct fdisk_context *cxt, struct gpt_header *header, uint64_t lba) { if (!cxt || !header) return; header->my_lba = cpu_to_le64(lba); if (lba == GPT_PRIMARY_PARTITION_TABLE_LBA) { /* primary */ header->alternative_lba = cpu_to_le64(cxt->total_sectors - 1ULL); header->partition_entry_lba = cpu_to_le64(2ULL); } else { /* backup */ uint64_t x = 0; gpt_calculate_alternative_entries_lba(header, le32_to_cpu(header->npartition_entries), &x, cxt); header->alternative_lba = cpu_to_le64(GPT_PRIMARY_PARTITION_TABLE_LBA); header->partition_entry_lba = cpu_to_le64(x); } } /* * Builds a new GPT header (at sector lba) from a backup header2. * If building a primary header, then backup is the secondary, and vice versa. * * Always pass a new (zeroized) header to build upon as we don't * explicitly zero-set some values such as CRCs and reserved. * * Returns 0 on success, otherwise < 0 on error. */ static int gpt_mknew_header_from_bkp(struct fdisk_context *cxt, struct gpt_header *header, uint64_t lba, struct gpt_header *header2) { if (!cxt || !header || !header2) return -ENOSYS; header->signature = header2->signature; header->revision = header2->revision; header->size = header2->size; header->npartition_entries = header2->npartition_entries; header->sizeof_partition_entry = header2->sizeof_partition_entry; header->first_usable_lba = header2->first_usable_lba; header->last_usable_lba = header2->last_usable_lba; memcpy(&header->disk_guid, &header2->disk_guid, sizeof(header2->disk_guid)); gpt_mknew_header_common(cxt, header, lba); return 0; } static struct gpt_header *gpt_copy_header(struct fdisk_context *cxt, struct gpt_header *src) { struct gpt_header *res; if (!cxt || !src) return NULL; assert(cxt->sector_size >= sizeof(struct gpt_header)); res = calloc(1, cxt->sector_size); if (!res) { fdisk_warn(cxt, _("failed to allocate GPT header")); return NULL; } res->my_lba = src->alternative_lba; res->alternative_lba = src->my_lba; res->signature = src->signature; res->revision = src->revision; res->size = src->size; res->npartition_entries = src->npartition_entries; res->sizeof_partition_entry = src->sizeof_partition_entry; res->first_usable_lba = src->first_usable_lba; res->last_usable_lba = src->last_usable_lba; memcpy(&res->disk_guid, &src->disk_guid, sizeof(src->disk_guid)); if (res->my_lba == GPT_PRIMARY_PARTITION_TABLE_LBA) res->partition_entry_lba = cpu_to_le64(2ULL); else { uint64_t esz = (uint64_t) le32_to_cpu(src->npartition_entries) * sizeof(struct gpt_entry); uint64_t esects = (esz + cxt->sector_size - 1) / cxt->sector_size; res->partition_entry_lba = cpu_to_le64(cxt->total_sectors - 1ULL - esects); } return res; } static int get_script_u64(struct fdisk_context *cxt, uint64_t *num, const char *name) { const char *str; int pwr = 0, rc = 0; assert(cxt); *num = 0; if (!cxt->script) return 1; str = fdisk_script_get_header(cxt->script, name); if (!str) return 1; rc = parse_size(str, (uintmax_t *) num, &pwr); if (rc < 0) return rc; if (pwr) *num /= cxt->sector_size; return 0; } static int count_first_last_lba(struct fdisk_context *cxt, uint64_t *first, uint64_t *last) { int rc = 0; uint64_t flba = 0, llba = 0; assert(cxt); assert(first); assert(last); *first = *last = 0; /* UEFI default */ rc = gpt_calculate_last_lba(NULL, GPT_NPARTITIONS, &llba, cxt); if (rc == 0) gpt_calculate_first_lba(NULL, GPT_NPARTITIONS, &flba, cxt); if (rc) return rc; /* script default */ if (cxt->script) { rc = get_script_u64(cxt, first, "first-lba"); if (rc < 0) return rc; DBG(GPT, ul_debug("FirstLBA: script=%"PRIu64", uefi=%"PRIu64", topology=%ju.", *first, flba, (uintmax_t)cxt->first_lba)); if (rc == 0 && (*first < flba || *first > llba)) { fdisk_warnx(cxt, _("First LBA specified by script is out of range.")); return -ERANGE; } rc = get_script_u64(cxt, last, "last-lba"); if (rc < 0) return rc; DBG(GPT, ul_debug("LastLBA: script=%"PRIu64", uefi=%"PRIu64", topology=%ju.", *last, llba, (uintmax_t)cxt->last_lba)); if (rc == 0 && (*last > llba || *last < flba)) { fdisk_warnx(cxt, _("Last LBA specified by script is out of range.")); return -ERANGE; } } if (!*last) *last = llba; /* default by topology */ if (!*first) *first = flba < cxt->first_lba && cxt->first_lba < *last ? cxt->first_lba : flba; return 0; } /* * Builds a clean new GPT header (currently under revision 1.0). * * Always pass a new (zeroized) header to build upon as we don't * explicitly zero-set some values such as CRCs and reserved. * * Returns 0 on success, otherwise < 0 on error. */ static int gpt_mknew_header(struct fdisk_context *cxt, struct gpt_header *header, uint64_t lba) { uint64_t first, last; int has_id = 0, rc; if (!cxt || !header) return -ENOSYS; header->signature = cpu_to_le64(GPT_HEADER_SIGNATURE); header->revision = cpu_to_le32(GPT_HEADER_REVISION_V1_00); /* According to EFI standard it's valid to count all the first * sector into header size, but some tools may have a problem * to accept it, so use the header without the zeroed area. * This does not have any impact to CRC, etc. --kzak Jan-2015 */ header->size = cpu_to_le32(sizeof(struct gpt_header) - sizeof(header->reserved2)); /* * 128 partitions are the default. It can go beyond that, but * we're creating a de facto header here, so no funny business. */ header->npartition_entries = cpu_to_le32(GPT_NPARTITIONS); header->sizeof_partition_entry = cpu_to_le32(sizeof(struct gpt_entry)); rc = count_first_last_lba(cxt, &first, &last); if (rc) return rc; header->first_usable_lba = cpu_to_le64(first); header->last_usable_lba = cpu_to_le64(last); gpt_mknew_header_common(cxt, header, lba); if (cxt->script) { const char *id = fdisk_script_get_header(cxt->script, "label-id"); struct gpt_guid guid = header->disk_guid; if (id && string_to_guid(id, &guid) == 0) has_id = 1; header->disk_guid = guid; } if (!has_id) { struct gpt_guid guid; uuid_generate_random((unsigned char *) &header->disk_guid); guid = header->disk_guid; swap_efi_guid(&guid); } return 0; } /* * Checks if there is a valid protective MBR partition table. * Returns 0 if it is invalid or failure. Otherwise, return * GPT_MBR_PROTECTIVE or GPT_MBR_HYBRID, depending on the detection. */ static int valid_pmbr(struct fdisk_context *cxt) { int i, part = 0, ret = 0; /* invalid by default */ struct gpt_legacy_mbr *pmbr = NULL; if (!cxt->firstsector) goto done; pmbr = (struct gpt_legacy_mbr *) cxt->firstsector; if (le16_to_cpu(pmbr->signature) != MSDOS_MBR_SIGNATURE) goto done; /* seems like a valid MBR was found, check DOS primary partitions */ for (i = 0; i < 4; i++) { if (pmbr->partition_record[i].os_type == EFI_PMBR_OSTYPE) { /* * Ok, we at least know that there's a protective MBR, * now check if there are other partition types for * hybrid MBR. */ part = i; ret = GPT_MBR_PROTECTIVE; break; } } if (ret != GPT_MBR_PROTECTIVE) goto done; for (i = 0 ; i < 4; i++) { if ((pmbr->partition_record[i].os_type != EFI_PMBR_OSTYPE) && (pmbr->partition_record[i].os_type != 0x00)) { ret = GPT_MBR_HYBRID; goto done; } } /* LBA of the GPT partition header */ if (pmbr->partition_record[part].starting_lba != cpu_to_le32(GPT_PRIMARY_PARTITION_TABLE_LBA)) goto done; /* * Protective MBRs take up the lesser of the whole disk * or 2 TiB (32bit LBA), ignoring the rest of the disk. * Some partitioning programs, nonetheless, choose to set * the size to the maximum 32-bit limitation, disregarding * the disk size. * * Hybrid MBRs do not necessarily comply with this. * * Consider a bad value here to be a warning to support dd-ing * an image from a smaller disk to a bigger disk. */ if (ret == GPT_MBR_PROTECTIVE) { uint64_t sz_lba = (uint64_t) le32_to_cpu(pmbr->partition_record[part].size_in_lba); if (sz_lba != cxt->total_sectors - 1ULL && sz_lba != 0xFFFFFFFFULL) { fdisk_warnx(cxt, _("GPT PMBR size mismatch (%"PRIu64" != %"PRIu64") " "will be corrected by write."), sz_lba, cxt->total_sectors - 1ULL); /* Note that gpt_write_pmbr() overwrites PMBR, but we want to keep it valid already * in memory too to disable warnings when valid_pmbr() called next time */ pmbr->partition_record[part].size_in_lba = cpu_to_le32((uint32_t) min( cxt->total_sectors - 1ULL, 0xFFFFFFFFULL) ); fdisk_label_set_changed(cxt->label, 1); } } done: DBG(GPT, ul_debug("PMBR type: %s", ret == GPT_MBR_PROTECTIVE ? "protective" : ret == GPT_MBR_HYBRID ? "hybrid" : "???" )); return ret; } static uint64_t last_lba(struct fdisk_context *cxt) { struct stat s; uint64_t sectors = 0; memset(&s, 0, sizeof(s)); if (fstat(cxt->dev_fd, &s) == -1) { fdisk_warn(cxt, _("gpt: stat() failed")); return 0; } if (S_ISBLK(s.st_mode)) sectors = cxt->total_sectors - 1ULL; else if (S_ISREG(s.st_mode)) sectors = ((uint64_t) s.st_size / (uint64_t) cxt->sector_size) - 1ULL; else fdisk_warnx(cxt, _("gpt: cannot handle files with mode %o"), s.st_mode); DBG(GPT, ul_debug("last LBA: %"PRIu64"", sectors)); return sectors; } static ssize_t read_lba(struct fdisk_context *cxt, uint64_t lba, void *buffer, const size_t bytes) { off_t offset = lba * cxt->sector_size; if (lseek(cxt->dev_fd, offset, SEEK_SET) == (off_t) -1) return -1; return (size_t)read(cxt->dev_fd, buffer, bytes) != bytes; } /* Returns the GPT entry array */ static unsigned char *gpt_read_entries(struct fdisk_context *cxt, struct gpt_header *header) { size_t sz = 0; ssize_t ssz; unsigned char *ret = NULL; off_t offset; assert(cxt); assert(header); if (gpt_sizeof_entries(header, &sz)) return NULL; if (sz > (size_t) SSIZE_MAX) { DBG(GPT, ul_debug("entries array too large to read()")); return NULL; } ret = calloc(1, sz); if (!ret) return NULL; offset = (off_t) le64_to_cpu(header->partition_entry_lba) * cxt->sector_size; if (offset != lseek(cxt->dev_fd, offset, SEEK_SET)) goto fail; ssz = read(cxt->dev_fd, ret, sz); if (ssz < 0 || (size_t) ssz != sz) goto fail; return ret; fail: free(ret); return NULL; } static inline uint32_t count_crc32(const unsigned char *buf, size_t len, size_t ex_off, size_t ex_len) { return (ul_crc32_exclude_offset(~0L, buf, len, ex_off, ex_len) ^ ~0L); } static inline uint32_t gpt_header_count_crc32(struct gpt_header *header) { return count_crc32((unsigned char *) header, /* buffer */ le32_to_cpu(header->size), /* size of buffer */ offsetof(struct gpt_header, crc32), /* exclude */ sizeof(header->crc32)); /* size of excluded area */ } static inline uint32_t gpt_entryarr_count_crc32(struct gpt_header *header, unsigned char *ents) { size_t arysz = 0; if (gpt_sizeof_entries(header, &arysz)) return 0; return count_crc32(ents, arysz, 0, 0); } /* * Recompute header and partition array 32bit CRC checksums. * This function does not fail - if there's corruption, then it * will be reported when checksumming it again (ie: probing or verify). */ static void gpt_recompute_crc(struct gpt_header *header, unsigned char *ents) { if (!header) return; header->partition_entry_array_crc32 = cpu_to_le32( gpt_entryarr_count_crc32(header, ents) ); header->crc32 = cpu_to_le32( gpt_header_count_crc32(header) ); } /* * Compute the 32bit CRC checksum of the partition table header. * Returns 1 if it is valid, otherwise 0. */ static int gpt_check_header_crc(struct gpt_header *header, unsigned char *ents) { uint32_t orgcrc = le32_to_cpu(header->crc32), crc = gpt_header_count_crc32(header); if (crc == orgcrc) return 1; /* * If we have checksum mismatch it may be due to stale data, like a * partition being added or deleted. Recompute the CRC again and make * sure this is not the case. */ if (ents) { gpt_recompute_crc(header, ents); return gpt_header_count_crc32(header) == orgcrc; } return 0; } /* * It initializes the partition entry array. * Returns 1 if the checksum is valid, otherwise 0. */ static int gpt_check_entryarr_crc(struct gpt_header *header, unsigned char *ents) { if (!header || !ents) return 0; return gpt_entryarr_count_crc32(header, ents) == le32_to_cpu(header->partition_entry_array_crc32); } static int gpt_check_lba_sanity(struct fdisk_context *cxt, struct gpt_header *header) { int ret = 0; uint64_t lu, fu, lastlba = last_lba(cxt); fu = le64_to_cpu(header->first_usable_lba); lu = le64_to_cpu(header->last_usable_lba); /* check if first and last usable LBA make sense */ if (lu < fu) { DBG(GPT, ul_debug("error: header last LBA is before first LBA")); goto done; } /* check if first and last usable LBAs with the disk's last LBA */ if (fu > lastlba || lu > lastlba) { DBG(GPT, ul_debug("error: header LBAs are after the disk's last LBA (%ju..%ju)", (uintmax_t) fu, (uintmax_t) lu)); goto done; } /* the header has to be outside usable range */ if (fu < GPT_PRIMARY_PARTITION_TABLE_LBA && GPT_PRIMARY_PARTITION_TABLE_LBA < lu) { DBG(GPT, ul_debug("error: header outside of usable range")); goto done; } ret = 1; /* sane */ done: return ret; } /* Check if there is a valid header signature */ static int gpt_check_signature(struct gpt_header *header) { return header->signature == cpu_to_le64(GPT_HEADER_SIGNATURE); } /* * Return the specified GPT Header, or NULL upon failure/invalid. * Note that all tests must pass to ensure a valid header, * we do not rely on only testing the signature for a valid probe. */ static struct gpt_header *gpt_read_header(struct fdisk_context *cxt, uint64_t lba, unsigned char **_ents) { struct gpt_header *header = NULL; unsigned char *ents = NULL; uint32_t hsz; if (!cxt) return NULL; /* always allocate all sector, the area after GPT header * has to be fill by zeros */ assert(cxt->sector_size >= sizeof(struct gpt_header)); header = calloc(1, cxt->sector_size); if (!header) return NULL; /* read and verify header */ if (read_lba(cxt, lba, header, cxt->sector_size) != 0) goto invalid; if (!gpt_check_signature(header)) goto invalid; /* make sure header size is between 92 and sector size bytes */ hsz = le32_to_cpu(header->size); if (hsz < GPT_HEADER_MINSZ || hsz > cxt->sector_size) goto invalid; if (!gpt_check_header_crc(header, NULL)) goto invalid; /* read and verify entries */ ents = gpt_read_entries(cxt, header); if (!ents) goto invalid; if (!gpt_check_entryarr_crc(header, ents)) goto invalid; if (!gpt_check_lba_sanity(cxt, header)) goto invalid; /* valid header must be at MyLBA */ if (le64_to_cpu(header->my_lba) != lba) goto invalid; if (_ents) *_ents = ents; else free(ents); DBG(GPT, ul_debug("found valid header on LBA %"PRIu64"", lba)); return header; invalid: free(header); free(ents); DBG(GPT, ul_debug("read header on LBA %"PRIu64" failed", lba)); return NULL; } static int gpt_locate_disklabel(struct fdisk_context *cxt, int n, const char **name, uint64_t *offset, size_t *size) { struct fdisk_gpt_label *gpt; assert(cxt); *name = NULL; *offset = 0; *size = 0; switch (n) { case 0: *name = "PMBR"; *offset = 0; *size = 512; break; case 1: *name = _("GPT Header"); *offset = (uint64_t) GPT_PRIMARY_PARTITION_TABLE_LBA * cxt->sector_size; *size = sizeof(struct gpt_header); break; case 2: *name = _("GPT Entries"); gpt = self_label(cxt); *offset = (uint64_t) le64_to_cpu(gpt->pheader->partition_entry_lba) * cxt->sector_size; return gpt_sizeof_entries(gpt->pheader, size); default: return 1; /* no more chunks */ } return 0; } static int gpt_get_disklabel_item(struct fdisk_context *cxt, struct fdisk_labelitem *item) { struct gpt_header *h; int rc = 0; assert(cxt); assert(cxt->label); assert(fdisk_is_label(cxt, GPT)); h = self_label(cxt)->pheader; switch (item->id) { case GPT_LABELITEM_ID: item->name = _("Disk identifier"); item->type = 's'; item->data.str = gpt_get_header_id(h); if (!item->data.str) rc = -ENOMEM; break; case GPT_LABELITEM_FIRSTLBA: item->name = _("First LBA"); item->type = 'j'; item->data.num64 = le64_to_cpu(h->first_usable_lba); break; case GPT_LABELITEM_LASTLBA: item->name = _("Last LBA"); item->type = 'j'; item->data.num64 = le64_to_cpu(h->last_usable_lba); break; case GPT_LABELITEM_ALTLBA: /* TRANSLATORS: The LBA (Logical Block Address) of the backup GPT header. */ item->name = _("Alternative LBA"); item->type = 'j'; item->data.num64 = le64_to_cpu(h->alternative_lba); break; case GPT_LABELITEM_ENTRIESLBA: /* TRANSLATORS: The start of the array of partition entries. */ item->name = _("Partition entries LBA"); item->type = 'j'; item->data.num64 = le64_to_cpu(h->partition_entry_lba); break; case GPT_LABELITEM_ENTRIESALLOC: item->name = _("Allocated partition entries"); item->type = 'j'; item->data.num64 = le32_to_cpu(h->npartition_entries); break; default: if (item->id < __FDISK_NLABELITEMS) rc = 1; /* unsupported generic item */ else rc = 2; /* out of range */ break; } return rc; } /* * Returns the number of partitions that are in use. */ static size_t partitions_in_use(struct fdisk_gpt_label *gpt) { size_t i, used = 0; assert(gpt); assert(gpt->pheader); assert(gpt->ents); for (i = 0; i < gpt_get_nentries(gpt); i++) { struct gpt_entry *e = gpt_get_entry(gpt, i); if (gpt_entry_is_used(e)) used++; } return used; } /* * Check if a partition is too big for the disk (sectors). * Returns the faulting partition number, otherwise 0. */ static uint32_t check_too_big_partitions(struct fdisk_gpt_label *gpt, uint64_t sectors) { size_t i; assert(gpt); assert(gpt->pheader); assert(gpt->ents); for (i = 0; i < gpt_get_nentries(gpt); i++) { struct gpt_entry *e = gpt_get_entry(gpt, i); if (!gpt_entry_is_used(e)) continue; if (gpt_partition_end(e) >= sectors) return i + 1; } return 0; } /* * Check if a partition ends before it begins * Returns the faulting partition number, otherwise 0. */ static uint32_t check_start_after_end_partitions(struct fdisk_gpt_label *gpt) { size_t i; assert(gpt); assert(gpt->pheader); assert(gpt->ents); for (i = 0; i < gpt_get_nentries(gpt); i++) { struct gpt_entry *e = gpt_get_entry(gpt, i); if (!gpt_entry_is_used(e)) continue; if (gpt_partition_start(e) > gpt_partition_end(e)) return i + 1; } return 0; } /* * Check if partition e1 overlaps with partition e2. */ static inline int partition_overlap(struct gpt_entry *e1, struct gpt_entry *e2) { uint64_t start1 = gpt_partition_start(e1); uint64_t end1 = gpt_partition_end(e1); uint64_t start2 = gpt_partition_start(e2); uint64_t end2 = gpt_partition_end(e2); return (start1 && start2 && (start1 <= end2) != (end1 < start2)); } /* * Find any partitions that overlap. */ static uint32_t check_overlap_partitions(struct fdisk_gpt_label *gpt) { size_t i, j; assert(gpt); assert(gpt->pheader); assert(gpt->ents); for (i = 0; i < gpt_get_nentries(gpt); i++) for (j = 0; j < i; j++) { struct gpt_entry *ei = gpt_get_entry(gpt, i); struct gpt_entry *ej = gpt_get_entry(gpt, j); if (!gpt_entry_is_used(ei) || !gpt_entry_is_used(ej)) continue; if (partition_overlap(ei, ej)) { DBG(GPT, ul_debug("partitions overlap detected [%zu vs. %zu]", i, j)); return i + 1; } } return 0; } /* * Find the first available block after the starting point; returns 0 if * there are no available blocks left, or error. From gdisk. */ static uint64_t find_first_available(struct fdisk_gpt_label *gpt, uint64_t start) { int first_moved = 0; uint64_t first; uint64_t fu, lu; assert(gpt); assert(gpt->pheader); assert(gpt->ents); fu = le64_to_cpu(gpt->pheader->first_usable_lba); lu = le64_to_cpu(gpt->pheader->last_usable_lba); /* * Begin from the specified starting point or from the first usable * LBA, whichever is greater... */ first = start < fu ? fu : start; /* * Now search through all partitions; if first is within an * existing partition, move it to the next sector after that * partition and repeat. If first was moved, set firstMoved * flag; repeat until firstMoved is not set, so as to catch * cases where partitions are out of sequential order.... */ do { size_t i; first_moved = 0; for (i = 0; i < gpt_get_nentries(gpt); i++) { struct gpt_entry *e = gpt_get_entry(gpt, i); if (!gpt_entry_is_used(e)) continue; if (first < gpt_partition_start(e)) continue; if (first <= gpt_partition_end(e)) { first = gpt_partition_end(e) + 1; first_moved = 1; } } } while (first_moved == 1); if (first > lu) first = 0; return first; } /* Returns last available sector in the free space pointed to by start. From gdisk. */ static uint64_t find_last_free(struct fdisk_gpt_label *gpt, uint64_t start) { size_t i; uint64_t nearest_start; assert(gpt); assert(gpt->pheader); assert(gpt->ents); nearest_start = le64_to_cpu(gpt->pheader->last_usable_lba); for (i = 0; i < gpt_get_nentries(gpt); i++) { struct gpt_entry *e = gpt_get_entry(gpt, i); uint64_t ps = gpt_partition_start(e); if (nearest_start > ps && ps > start) nearest_start = ps - 1ULL; } return nearest_start; } /* Returns the last free sector on the disk. From gdisk. */ static uint64_t find_last_free_sector(struct fdisk_gpt_label *gpt) { int last_moved; uint64_t last = 0; assert(gpt); assert(gpt->pheader); assert(gpt->ents); /* start by assuming the last usable LBA is available */ last = le64_to_cpu(gpt->pheader->last_usable_lba); do { size_t i; last_moved = 0; for (i = 0; i < gpt_get_nentries(gpt); i++) { struct gpt_entry *e = gpt_get_entry(gpt, i); if (last >= gpt_partition_start(e) && last <= gpt_partition_end(e)) { last = gpt_partition_start(e) - 1ULL; last_moved = 1; } } } while (last_moved == 1); return last; } /* * Finds the first available sector in the largest block of unallocated * space on the disk. Returns 0 if there are no available blocks left. * From gdisk. */ static uint64_t find_first_in_largest(struct fdisk_gpt_label *gpt) { uint64_t start = 0, first_sect, last_sect; uint64_t segment_size, selected_size = 0, selected_segment = 0; assert(gpt); assert(gpt->pheader); assert(gpt->ents); do { first_sect = find_first_available(gpt, start); if (first_sect != 0) { last_sect = find_last_free(gpt, first_sect); segment_size = last_sect - first_sect + 1ULL; if (segment_size > selected_size) { selected_size = segment_size; selected_segment = first_sect; } start = last_sect + 1ULL; } } while (first_sect != 0); return selected_segment; } /* * Find the total number of free sectors, the number of segments in which * they reside, and the size of the largest of those segments. From gdisk. */ static uint64_t get_free_sectors(struct fdisk_context *cxt, struct fdisk_gpt_label *gpt, uint32_t *nsegments, uint64_t *largest_segment) { uint32_t num = 0; uint64_t first_sect, last_sect; uint64_t largest_seg = 0, segment_sz; uint64_t totfound = 0, start = 0; /* starting point for each search */ if (!cxt->total_sectors) goto done; assert(gpt); assert(gpt->pheader); assert(gpt->ents); do { first_sect = find_first_available(gpt, start); if (first_sect) { last_sect = find_last_free(gpt, first_sect); segment_sz = last_sect - first_sect + 1; if (segment_sz > largest_seg) largest_seg = segment_sz; totfound += segment_sz; num++; start = last_sect + 1ULL; } } while (first_sect); done: if (nsegments) *nsegments = num; if (largest_segment) *largest_segment = largest_seg; return totfound; } static int gpt_probe_label(struct fdisk_context *cxt) { int mbr_type; struct fdisk_gpt_label *gpt; assert(cxt); assert(cxt->label); assert(fdisk_is_label(cxt, GPT)); gpt = self_label(cxt); /* TODO: it would be nice to support scenario when GPT headers are OK, * but PMBR is corrupt */ mbr_type = valid_pmbr(cxt); if (!mbr_type) goto failed; /* primary header */ gpt->pheader = gpt_read_header(cxt, GPT_PRIMARY_PARTITION_TABLE_LBA, &gpt->ents); if (gpt->pheader) /* primary OK, try backup from alternative LBA */ gpt->bheader = gpt_read_header(cxt, le64_to_cpu(gpt->pheader->alternative_lba), NULL); else /* primary corrupted -- try last LBA */ gpt->bheader = gpt_read_header(cxt, last_lba(cxt), &gpt->ents); if (!gpt->pheader && !gpt->bheader) goto failed; /* primary OK, backup corrupted -- recovery */ if (gpt->pheader && !gpt->bheader) { fdisk_warnx(cxt, _("The backup GPT table is corrupt, but the " "primary appears OK, so that will be used.")); gpt->bheader = gpt_copy_header(cxt, gpt->pheader); if (!gpt->bheader) goto failed; gpt_recompute_crc(gpt->bheader, gpt->ents); fdisk_label_set_changed(cxt->label, 1); /* primary corrupted, backup OK -- recovery */ } else if (!gpt->pheader && gpt->bheader) { fdisk_warnx(cxt, _("The primary GPT table is corrupt, but the " "backup appears OK, so that will be used.")); gpt->pheader = gpt_copy_header(cxt, gpt->bheader); if (!gpt->pheader) goto failed; gpt_recompute_crc(gpt->pheader, gpt->ents); fdisk_label_set_changed(cxt->label, 1); } /* The headers make be correct, but Backup do not have to be on the end * of the device (due to device resize, etc.). Let's fix this issue. */ if (gpt->minimize == 0 && (le64_to_cpu(gpt->pheader->alternative_lba) > cxt->total_sectors || le64_to_cpu(gpt->pheader->alternative_lba) < cxt->total_sectors - 1ULL)) { if (gpt->no_relocate || fdisk_is_readonly(cxt)) fdisk_warnx(cxt, _("The backup GPT table is not on the end of the device.")); else { fdisk_warnx(cxt, _("The backup GPT table is not on the end of the device. " "This problem will be corrected by write.")); if (gpt_fix_alternative_lba(cxt, gpt) != 0) fdisk_warnx(cxt, _("Failed to recalculate backup GPT table location")); gpt_recompute_crc(gpt->bheader, gpt->ents); gpt_recompute_crc(gpt->pheader, gpt->ents); fdisk_label_set_changed(cxt->label, 1); } } if (gpt->minimize && gpt_possible_minimize(cxt, gpt)) fdisk_label_set_changed(cxt->label, 1); cxt->label->nparts_max = gpt_get_nentries(gpt); cxt->label->nparts_cur = partitions_in_use(gpt); return 1; failed: DBG(GPT, ul_debug("probe failed")); gpt_deinit(cxt->label); return 0; } static char *encode_to_utf8(unsigned char *src, size_t count) { unsigned char *dest; size_t len = (count * 3 / 2) + 1; dest = calloc(1, len); if (!dest) return NULL; ul_encode_to_utf8(UL_ENCODE_UTF16LE, dest, len, src, count); return (char *) dest; } static int gpt_entry_attrs_to_string(struct gpt_entry *e, char **res) { unsigned int n, count = 0; size_t l; char *bits, *p; uint64_t attrs; assert(e); assert(res); *res = NULL; attrs = e->attrs; if (!attrs) return 0; /* no attributes at all */ bits = (char *) &attrs; /* Note that sizeof() is correct here, we need separators between * the strings so also count \0 is correct */ *res = calloc(1, sizeof(GPT_ATTRSTR_NOBLOCK) + sizeof(GPT_ATTRSTR_REQ) + sizeof(GPT_ATTRSTR_LEGACY) + sizeof("GUID:") + (GPT_ATTRBIT_GUID_COUNT * 3)); if (!*res) return -errno; p = *res; if (isset(bits, GPT_ATTRBIT_REQ)) { memcpy(p, GPT_ATTRSTR_REQ, (l = sizeof(GPT_ATTRSTR_REQ))); p += l - 1; } if (isset(bits, GPT_ATTRBIT_NOBLOCK)) { if (p != *res) *p++ = ' '; memcpy(p, GPT_ATTRSTR_NOBLOCK, (l = sizeof(GPT_ATTRSTR_NOBLOCK))); p += l - 1; } if (isset(bits, GPT_ATTRBIT_LEGACY)) { if (p != *res) *p++ = ' '; memcpy(p, GPT_ATTRSTR_LEGACY, (l = sizeof(GPT_ATTRSTR_LEGACY))); p += l - 1; } for (n = GPT_ATTRBIT_GUID_FIRST; n < GPT_ATTRBIT_GUID_FIRST + GPT_ATTRBIT_GUID_COUNT; n++) { if (!isset(bits, n)) continue; if (!count) { if (p != *res) *p++ = ' '; p += sprintf(p, "GUID:%u", n); } else p += sprintf(p, ",%u", n); count++; } return 0; } static int gpt_entry_attrs_from_string( struct fdisk_context *cxt, struct gpt_entry *e, const char *str) { const char *p = str; uint64_t attrs = 0; char *bits; assert(e); assert(p); DBG(GPT, ul_debug("parsing string attributes '%s'", p)); bits = (char *) &attrs; while (p && *p) { int bit = -1; while (isblank(*p)) p++; if (!*p) break; DBG(GPT, ul_debug(" item '%s'", p)); if (strncmp(p, GPT_ATTRSTR_REQ, sizeof(GPT_ATTRSTR_REQ) - 1) == 0) { bit = GPT_ATTRBIT_REQ; p += sizeof(GPT_ATTRSTR_REQ) - 1; } else if (strncmp(p, GPT_ATTRSTR_REQ_TYPO, sizeof(GPT_ATTRSTR_REQ_TYPO) - 1) == 0) { bit = GPT_ATTRBIT_REQ; p += sizeof(GPT_ATTRSTR_REQ_TYPO) - 1; } else if (strncmp(p, GPT_ATTRSTR_LEGACY, sizeof(GPT_ATTRSTR_LEGACY) - 1) == 0) { bit = GPT_ATTRBIT_LEGACY; p += sizeof(GPT_ATTRSTR_LEGACY) - 1; } else if (strncmp(p, GPT_ATTRSTR_NOBLOCK, sizeof(GPT_ATTRSTR_NOBLOCK) - 1) == 0) { bit = GPT_ATTRBIT_NOBLOCK; p += sizeof(GPT_ATTRSTR_NOBLOCK) - 1; /* GUID: as well as */ } else if (isdigit((unsigned char) *p) || (strncmp(p, "GUID:", 5) == 0 && isdigit((unsigned char) *(p + 5)))) { char *end = NULL; if (*p == 'G') p += 5; errno = 0; bit = strtol(p, &end, 0); if (errno || !end || end == str || bit < GPT_ATTRBIT_GUID_FIRST || bit >= GPT_ATTRBIT_GUID_FIRST + GPT_ATTRBIT_GUID_COUNT) bit = -1; else p = end; } if (bit < 0) { fdisk_warnx(cxt, _("unsupported GPT attribute bit '%s'"), p); return -EINVAL; } if (*p && *p != ',' && !isblank(*p)) { fdisk_warnx(cxt, _("failed to parse GPT attribute string '%s'"), str); return -EINVAL; } setbit(bits, bit); while (isblank(*p)) p++; if (*p == ',') p++; } e->attrs = attrs; return 0; } static int gpt_get_partition(struct fdisk_context *cxt, size_t n, struct fdisk_partition *pa) { struct fdisk_gpt_label *gpt; struct gpt_entry *e; char u_str[UUID_STR_LEN]; int rc = 0; struct gpt_guid guid; assert(cxt); assert(cxt->label); assert(fdisk_is_label(cxt, GPT)); gpt = self_label(cxt); if (n >= gpt_get_nentries(gpt)) return -EINVAL; gpt = self_label(cxt); e = gpt_get_entry(gpt, n); pa->used = gpt_entry_is_used(e) || gpt_partition_start(e); if (!pa->used) return 0; pa->start = gpt_partition_start(e); pa->size = gpt_partition_size(e); pa->type = gpt_partition_parttype(cxt, e); guid = e->partition_guid; if (guid_to_string(&guid, u_str)) { pa->uuid = strdup(u_str); if (!pa->uuid) { rc = -errno; goto done; } } else pa->uuid = NULL; rc = gpt_entry_attrs_to_string(e, &pa->attrs); if (rc) goto done; pa->name = encode_to_utf8((unsigned char *)e->name, sizeof(e->name)); return 0; done: fdisk_reset_partition(pa); return rc; } static int gpt_set_partition(struct fdisk_context *cxt, size_t n, struct fdisk_partition *pa) { struct fdisk_gpt_label *gpt; struct gpt_entry *e; int rc = 0; uint64_t start, end; assert(cxt); assert(cxt->label); assert(fdisk_is_label(cxt, GPT)); gpt = self_label(cxt); if (n >= gpt_get_nentries(gpt)) return -EINVAL; FDISK_INIT_UNDEF(start); FDISK_INIT_UNDEF(end); gpt = self_label(cxt); e = gpt_get_entry(gpt, n); if (pa->uuid) { char new_u[UUID_STR_LEN], old_u[UUID_STR_LEN]; struct gpt_guid guid; guid = e->partition_guid; guid_to_string(&guid, old_u); rc = gpt_entry_set_uuid(e, pa->uuid); if (rc) return rc; guid = e->partition_guid; guid_to_string(&guid, new_u); fdisk_info(cxt, _("Partition UUID changed from %s to %s."), old_u, new_u); } if (pa->name) { int len; char *old = encode_to_utf8((unsigned char *)e->name, sizeof(e->name)); len = gpt_entry_set_name(e, pa->name); if (len < 0) fdisk_warn(cxt, _("Failed to translate partition name, name not changed.")); else fdisk_info(cxt, _("Partition name changed from '%s' to '%.*s'."), old, len, pa->name); free(old); } if (pa->type && pa->type->typestr) { struct gpt_guid typeid; rc = string_to_guid(pa->type->typestr, &typeid); if (rc) return rc; gpt_entry_set_type(e, &typeid); } if (pa->attrs) { rc = gpt_entry_attrs_from_string(cxt, e, pa->attrs); if (rc) return rc; } if (fdisk_partition_has_start(pa)) start = pa->start; if (fdisk_partition_has_size(pa) || fdisk_partition_has_start(pa)) { uint64_t xstart = fdisk_partition_has_start(pa) ? pa->start : gpt_partition_start(e); uint64_t xsize = fdisk_partition_has_size(pa) ? pa->size : gpt_partition_size(e); end = xstart + xsize - 1ULL; } if (!FDISK_IS_UNDEF(start)) { if (start < le64_to_cpu(gpt->pheader->first_usable_lba)) { fdisk_warnx(cxt, _("The start of the partition understeps FirstUsableLBA.")); return -EINVAL; } e->lba_start = cpu_to_le64(start); } if (!FDISK_IS_UNDEF(end)) { if (end > le64_to_cpu(gpt->pheader->last_usable_lba)) { fdisk_warnx(cxt, _("The end of the partition oversteps LastUsableLBA.")); return -EINVAL; } e->lba_end = cpu_to_le64(end); } gpt_recompute_crc(gpt->pheader, gpt->ents); gpt_recompute_crc(gpt->bheader, gpt->ents); fdisk_label_set_changed(cxt->label, 1); return rc; } static int gpt_write(struct fdisk_context *cxt, off_t offset, void *buf, size_t count) { if (offset != lseek(cxt->dev_fd, offset, SEEK_SET)) return -errno; if (write_all(cxt->dev_fd, buf, count)) return -errno; fsync(cxt->dev_fd); DBG(GPT, ul_debug(" write OK [offset=%zu, size=%zu]", (size_t) offset, count)); return 0; } /* * Write partitions. * Returns 0 on success, or corresponding error otherwise. */ static int gpt_write_partitions(struct fdisk_context *cxt, struct gpt_header *header, unsigned char *ents) { size_t esz = 0; int rc; rc = gpt_sizeof_entries(header, &esz); if (rc) return rc; return gpt_write(cxt, (off_t) le64_to_cpu(header->partition_entry_lba) * cxt->sector_size, ents, esz); } /* * Write a GPT header to a specified LBA. * * We read all sector, so we have to write all sector back * to the device -- never ever rely on sizeof(struct gpt_header)! * * Returns 0 on success, or corresponding error otherwise. */ static int gpt_write_header(struct fdisk_context *cxt, struct gpt_header *header, uint64_t lba) { return gpt_write(cxt, lba * cxt->sector_size, header, cxt->sector_size); } /* * Write the protective MBR. * Returns 0 on success, or corresponding error otherwise. */ static int gpt_write_pmbr(struct fdisk_context *cxt) { struct gpt_legacy_mbr *pmbr; assert(cxt); assert(cxt->firstsector); DBG(GPT, ul_debug("(over)writing PMBR")); pmbr = (struct gpt_legacy_mbr *) cxt->firstsector; /* zero out the legacy partitions */ memset(pmbr->partition_record, 0, sizeof(pmbr->partition_record)); pmbr->signature = cpu_to_le16(MSDOS_MBR_SIGNATURE); pmbr->partition_record[0].os_type = EFI_PMBR_OSTYPE; pmbr->partition_record[0].start_sector = 2; pmbr->partition_record[0].end_head = 0xFF; pmbr->partition_record[0].end_sector = 0xFF; pmbr->partition_record[0].end_track = 0xFF; pmbr->partition_record[0].starting_lba = cpu_to_le32(1); /* * Set size_in_lba to the size of the disk minus one. If the size of the disk * is too large to be represented by a 32bit LBA (2Tb), set it to 0xFFFFFFFF. */ if (cxt->total_sectors - 1ULL > 0xFFFFFFFFULL) pmbr->partition_record[0].size_in_lba = cpu_to_le32(0xFFFFFFFF); else pmbr->partition_record[0].size_in_lba = cpu_to_le32((uint32_t) (cxt->total_sectors - 1ULL)); /* pMBR covers the first sector (LBA) of the disk */ return gpt_write(cxt, GPT_PMBR_LBA * cxt->sector_size, pmbr, cxt->sector_size); } /* * Writes in-memory GPT and pMBR data to disk. * Returns 0 if successful write, otherwise, a corresponding error. * Any indication of error will abort the operation. */ static int gpt_write_disklabel(struct fdisk_context *cxt) { struct fdisk_gpt_label *gpt; int mbr_type; assert(cxt); assert(cxt->label); assert(fdisk_is_label(cxt, GPT)); DBG(GPT, ul_debug("writing...")); gpt = self_label(cxt); mbr_type = valid_pmbr(cxt); /* check that disk is big enough to handle the backup header */ if (le64_to_cpu(gpt->pheader->alternative_lba) > cxt->total_sectors) goto err0; /* check that the backup header is properly placed */ if (le64_to_cpu(gpt->pheader->alternative_lba) < cxt->total_sectors - 1ULL) goto err0; if (check_overlap_partitions(gpt)) goto err0; if (gpt->minimize) gpt_minimize_alternative_lba(cxt, gpt); /* recompute CRCs for both headers */ gpt_recompute_crc(gpt->pheader, gpt->ents); gpt_recompute_crc(gpt->bheader, gpt->ents); /* * UEFI requires writing in this specific order: * 1) backup partition tables * 2) backup GPT header * 3) primary partition tables * 4) primary GPT header * 5) protective MBR * * If any write fails, we abort the rest. */ if (gpt_write_partitions(cxt, gpt->bheader, gpt->ents) != 0) goto err1; if (gpt_write_header(cxt, gpt->bheader, le64_to_cpu(gpt->pheader->alternative_lba)) != 0) goto err1; if (gpt_write_partitions(cxt, gpt->pheader, gpt->ents) != 0) goto err1; if (gpt_write_header(cxt, gpt->pheader, GPT_PRIMARY_PARTITION_TABLE_LBA) != 0) goto err1; if (mbr_type == GPT_MBR_HYBRID) fdisk_warnx(cxt, _("The device contains hybrid MBR -- writing GPT only.")); else if (gpt_write_pmbr(cxt) != 0) goto err1; DBG(GPT, ul_debug("...write success")); return 0; err0: DBG(GPT, ul_debug("...write failed: incorrect input")); errno = EINVAL; return -EINVAL; err1: DBG(GPT, ul_debug("...write failed: %m")); return -errno; } /* * Verify data integrity and report any found problems for: * - primary and backup header validations * - partition validations */ static int gpt_verify_disklabel(struct fdisk_context *cxt) { int nerror = 0; unsigned int ptnum; struct fdisk_gpt_label *gpt; assert(cxt); assert(cxt->label); assert(fdisk_is_label(cxt, GPT)); gpt = self_label(cxt); if (!gpt) return -EINVAL; if (!gpt->bheader) { nerror++; fdisk_warnx(cxt, _("Disk does not contain a valid backup header.")); } if (!gpt_check_header_crc(gpt->pheader, gpt->ents)) { nerror++; fdisk_warnx(cxt, _("Invalid primary header CRC checksum.")); } if (gpt->bheader && !gpt_check_header_crc(gpt->bheader, gpt->ents)) { nerror++; fdisk_warnx(cxt, _("Invalid backup header CRC checksum.")); } if (!gpt_check_entryarr_crc(gpt->pheader, gpt->ents)) { nerror++; fdisk_warnx(cxt, _("Invalid partition entry checksum.")); } if (!gpt_check_lba_sanity(cxt, gpt->pheader)) { nerror++; fdisk_warnx(cxt, _("Invalid primary header LBA sanity checks.")); } if (gpt->bheader && !gpt_check_lba_sanity(cxt, gpt->bheader)) { nerror++; fdisk_warnx(cxt, _("Invalid backup header LBA sanity checks.")); } if (le64_to_cpu(gpt->pheader->my_lba) != GPT_PRIMARY_PARTITION_TABLE_LBA) { nerror++; fdisk_warnx(cxt, _("MyLBA mismatch with real position at primary header.")); } if (gpt->bheader && le64_to_cpu(gpt->bheader->my_lba) != last_lba(cxt)) { nerror++; fdisk_warnx(cxt, _("MyLBA mismatch with real position at backup header.")); } if (le64_to_cpu(gpt->pheader->alternative_lba) >= cxt->total_sectors) { nerror++; fdisk_warnx(cxt, _("Disk is too small to hold all data.")); } /* * if the GPT is the primary table, check the alternateLBA * to see if it is a valid GPT */ if (gpt->bheader && (le64_to_cpu(gpt->pheader->my_lba) != le64_to_cpu(gpt->bheader->alternative_lba))) { nerror++; fdisk_warnx(cxt, _("Primary and backup header mismatch.")); } ptnum = check_overlap_partitions(gpt); if (ptnum) { nerror++; fdisk_warnx(cxt, _("Partition %u overlaps with partition %u."), ptnum, ptnum+1); } ptnum = check_too_big_partitions(gpt, cxt->total_sectors); if (ptnum) { nerror++; fdisk_warnx(cxt, _("Partition %u is too big for the disk."), ptnum); } ptnum = check_start_after_end_partitions(gpt); if (ptnum) { nerror++; fdisk_warnx(cxt, _("Partition %u ends before it starts."), ptnum); } if (!nerror) { /* yay :-) */ uint32_t nsegments = 0; uint64_t free_sectors = 0, largest_segment = 0; char *strsz = NULL; fdisk_info(cxt, _("No errors detected.")); fdisk_info(cxt, _("Header version: %s"), gpt_get_header_revstr(gpt->pheader)); fdisk_info(cxt, _("Using %zu out of %zu partitions."), partitions_in_use(gpt), gpt_get_nentries(gpt)); free_sectors = get_free_sectors(cxt, gpt, &nsegments, &largest_segment); if (largest_segment) strsz = size_to_human_string(SIZE_SUFFIX_SPACE | SIZE_SUFFIX_3LETTER, largest_segment * cxt->sector_size); fdisk_info(cxt, P_("A total of %ju free sectors is available in %u segment.", "A total of %ju free sectors is available in %u segments " "(the largest is %s).", nsegments), free_sectors, nsegments, strsz); free(strsz); } else fdisk_warnx(cxt, P_("%d error detected.", "%d errors detected.", nerror), nerror); return nerror; } /* Delete a single GPT partition, specified by partnum. */ static int gpt_delete_partition(struct fdisk_context *cxt, size_t partnum) { struct fdisk_gpt_label *gpt; assert(cxt); assert(cxt->label); assert(fdisk_is_label(cxt, GPT)); gpt = self_label(cxt); if (partnum >= cxt->label->nparts_max) return -EINVAL; if (!gpt_entry_is_used(gpt_get_entry(gpt, partnum))) return -EINVAL; /* hasta la vista, baby! */ gpt_zeroize_entry(gpt, partnum); gpt_recompute_crc(gpt->pheader, gpt->ents); gpt_recompute_crc(gpt->bheader, gpt->ents); cxt->label->nparts_cur--; fdisk_label_set_changed(cxt->label, 1); return 0; } /* Performs logical checks to add a new partition entry */ static int gpt_add_partition( struct fdisk_context *cxt, struct fdisk_partition *pa, size_t *partno) { uint64_t user_f, user_l; /* user input ranges for first and last sectors */ uint64_t disk_f, disk_l; /* first and last available sector ranges on device*/ uint64_t dflt_f, dflt_l; /* largest segment (default) */ struct gpt_guid typeid; struct fdisk_gpt_label *gpt; struct gpt_header *pheader; struct gpt_entry *e; struct fdisk_ask *ask = NULL; size_t partnum; int rc; assert(cxt); assert(cxt->label); assert(fdisk_is_label(cxt, GPT)); gpt = self_label(cxt); assert(gpt); assert(gpt->pheader); assert(gpt->ents); pheader = gpt->pheader; rc = fdisk_partition_next_partno(pa, cxt, &partnum); if (rc) { DBG(GPT, ul_debug("failed to get next partno")); return rc; } assert(partnum < gpt_get_nentries(gpt)); if (gpt_entry_is_used(gpt_get_entry(gpt, partnum))) { fdisk_warnx(cxt, _("Partition %zu is already defined. " "Delete it before re-adding it."), partnum +1); return -ERANGE; } if (gpt_get_nentries(gpt) == partitions_in_use(gpt)) { fdisk_warnx(cxt, _("All partitions are already in use.")); return -ENOSPC; } if (!get_free_sectors(cxt, gpt, NULL, NULL)) { fdisk_warnx(cxt, _("No free sectors available.")); return -ENOSPC; } rc = string_to_guid(pa && pa->type && pa->type->typestr ? pa->type->typestr: GPT_DEFAULT_ENTRY_TYPE, &typeid); if (rc) return rc; disk_f = find_first_available(gpt, le64_to_cpu(pheader->first_usable_lba)); e = gpt_get_entry(gpt, 0); /* if first sector no explicitly defined then ignore small gaps before * the first partition */ if ((!pa || !fdisk_partition_has_start(pa)) && gpt_entry_is_used(e) && disk_f < gpt_partition_start(e)) { do { uint64_t x; DBG(GPT, ul_debug("testing first sector %"PRIu64"", disk_f)); disk_f = find_first_available(gpt, disk_f); if (!disk_f) break; x = find_last_free(gpt, disk_f); if (x - disk_f >= cxt->grain / cxt->sector_size) break; DBG(GPT, ul_debug("first sector %"PRIu64" addresses to small space, continue...", disk_f)); disk_f = x + 1ULL; } while(1); if (disk_f == 0) disk_f = find_first_available(gpt, le64_to_cpu(pheader->first_usable_lba)); } e = NULL; disk_l = find_last_free_sector(gpt); /* the default is the largest free space */ dflt_f = find_first_in_largest(gpt); dflt_l = find_last_free(gpt, dflt_f); /* align the default in range */ dflt_f = fdisk_align_lba_in_range(cxt, dflt_f, dflt_f, dflt_l); /* first sector */ if (pa && pa->start_follow_default) { user_f = dflt_f; } else if (pa && fdisk_partition_has_start(pa)) { DBG(GPT, ul_debug("first sector defined: %ju", (uintmax_t)pa->start)); if (pa->start != find_first_available(gpt, pa->start)) { fdisk_warnx(cxt, _("Sector %ju already used."), (uintmax_t)pa->start); return -ERANGE; } user_f = pa->start; } else { /* ask by dialog */ for (;;) { if (!ask) ask = fdisk_new_ask(); else fdisk_reset_ask(ask); if (!ask) return -ENOMEM; /* First sector */ fdisk_ask_set_query(ask, _("First sector")); fdisk_ask_set_type(ask, FDISK_ASKTYPE_NUMBER); fdisk_ask_number_set_low(ask, disk_f); /* minimal */ fdisk_ask_number_set_default(ask, dflt_f); /* default */ fdisk_ask_number_set_high(ask, disk_l); /* maximal */ rc = fdisk_do_ask(cxt, ask); if (rc) goto done; user_f = fdisk_ask_number_get_result(ask); if (user_f != find_first_available(gpt, user_f)) { fdisk_warnx(cxt, _("Sector %ju already used."), user_f); continue; } break; } } /* Last sector */ dflt_l = find_last_free(gpt, user_f); if (pa && pa->end_follow_default) { user_l = dflt_l; } else if (pa && fdisk_partition_has_size(pa)) { user_l = user_f + pa->size - 1; DBG(GPT, ul_debug("size defined: %ju, end: %"PRIu64" (last possible: %"PRIu64")", (uintmax_t)pa->size, user_l, dflt_l)); if (user_l != dflt_l && !pa->size_explicit && alignment_required(cxt) && user_l - user_f > (cxt->grain / fdisk_get_sector_size(cxt))) { user_l = fdisk_align_lba_in_range(cxt, user_l, user_f, dflt_l); if (user_l > user_f) user_l -= 1ULL; } } else { for (;;) { if (!ask) ask = fdisk_new_ask(); else fdisk_reset_ask(ask); if (!ask) return -ENOMEM; fdisk_ask_set_query(ask, _("Last sector, +/-sectors or +/-size{K,M,G,T,P}")); fdisk_ask_set_type(ask, FDISK_ASKTYPE_OFFSET); fdisk_ask_number_set_low(ask, user_f); /* minimal */ fdisk_ask_number_set_default(ask, dflt_l); /* default */ fdisk_ask_number_set_high(ask, dflt_l); /* maximal */ fdisk_ask_number_set_base(ask, user_f); /* base for relative input */ fdisk_ask_number_set_unit(ask, cxt->sector_size); fdisk_ask_number_set_wrap_negative(ask, 1); /* wrap negative around high */ rc = fdisk_do_ask(cxt, ask); if (rc) goto done; user_l = fdisk_ask_number_get_result(ask); if (fdisk_ask_number_is_relative(ask)) { user_l = fdisk_align_lba_in_range(cxt, user_l, user_f, dflt_l); if (user_l > user_f) user_l -= 1ULL; } if (user_l >= user_f && user_l <= disk_l) break; fdisk_warnx(cxt, _("Value out of range.")); } } if (user_f > user_l || partnum >= cxt->label->nparts_max) { fdisk_warnx(cxt, _("Could not create partition %zu"), partnum + 1); rc = -EINVAL; goto done; } /* Be paranoid and check against on-disk setting rather than against libfdisk cxt */ if (user_l > le64_to_cpu(pheader->last_usable_lba)) { fdisk_warnx(cxt, _("The last usable GPT sector is %ju, but %ju is requested."), le64_to_cpu(pheader->last_usable_lba), user_l); rc = -EINVAL; goto done; } if (user_f < le64_to_cpu(pheader->first_usable_lba)) { fdisk_warnx(cxt, _("The first usable GPT sector is %ju, but %ju is requested."), le64_to_cpu(pheader->first_usable_lba), user_f); rc = -EINVAL; goto done; } assert(!FDISK_IS_UNDEF(user_l)); assert(!FDISK_IS_UNDEF(user_f)); assert(partnum < gpt_get_nentries(gpt)); e = gpt_get_entry(gpt, partnum); e->lba_end = cpu_to_le64(user_l); e->lba_start = cpu_to_le64(user_f); gpt_entry_set_type(e, &typeid); if (pa && pa->uuid) { /* Sometimes it's necessary to create a copy of the PT and * reuse already defined UUID */ rc = gpt_entry_set_uuid(e, pa->uuid); if (rc) goto done; } else { /* Any time a new partition entry is created a new GUID must be * generated for that partition, and every partition is guaranteed * to have a unique GUID. */ struct gpt_guid guid; uuid_generate_random((unsigned char *) &e->partition_guid); guid = e->partition_guid; swap_efi_guid(&guid); } if (pa && pa->name && *pa->name) gpt_entry_set_name(e, pa->name); if (pa && pa->attrs) gpt_entry_attrs_from_string(cxt, e, pa->attrs); DBG(GPT, ul_debug("new partition: partno=%zu, start=%"PRIu64", end=%"PRIu64", size=%"PRIu64"", partnum, gpt_partition_start(e), gpt_partition_end(e), gpt_partition_size(e))); gpt_recompute_crc(gpt->pheader, gpt->ents); gpt_recompute_crc(gpt->bheader, gpt->ents); /* report result */ { struct fdisk_parttype *t; cxt->label->nparts_cur++; fdisk_label_set_changed(cxt->label, 1); t = gpt_partition_parttype(cxt, e); fdisk_info_new_partition(cxt, partnum + 1, user_f, user_l, t); fdisk_unref_parttype(t); } rc = 0; if (partno) *partno = partnum; done: fdisk_unref_ask(ask); return rc; } /* * Create a new GPT disklabel - destroys any previous data. */ static int gpt_create_disklabel(struct fdisk_context *cxt) { int rc = 0; size_t esz = 0; char str[UUID_STR_LEN]; struct fdisk_gpt_label *gpt; struct gpt_guid guid; assert(cxt); assert(cxt->label); assert(fdisk_is_label(cxt, GPT)); gpt = self_label(cxt); /* label private stuff has to be empty, see gpt_deinit() */ assert(gpt->pheader == NULL); assert(gpt->bheader == NULL); /* * When no header, entries or pmbr is set, we're probably * dealing with a new, empty disk - so always allocate memory * to deal with the data structures whatever the case is. */ rc = gpt_mknew_pmbr(cxt); if (rc < 0) goto done; assert(cxt->sector_size >= sizeof(struct gpt_header)); /* primary */ gpt->pheader = calloc(1, cxt->sector_size); if (!gpt->pheader) { rc = -ENOMEM; goto done; } rc = gpt_mknew_header(cxt, gpt->pheader, GPT_PRIMARY_PARTITION_TABLE_LBA); if (rc < 0) goto done; /* backup ("copy" primary) */ gpt->bheader = calloc(1, cxt->sector_size); if (!gpt->bheader) { rc = -ENOMEM; goto done; } rc = gpt_mknew_header_from_bkp(cxt, gpt->bheader, last_lba(cxt), gpt->pheader); if (rc < 0) goto done; rc = gpt_sizeof_entries(gpt->pheader, &esz); if (rc) goto done; gpt->ents = calloc(1, esz); if (!gpt->ents) { rc = -ENOMEM; goto done; } gpt_recompute_crc(gpt->pheader, gpt->ents); gpt_recompute_crc(gpt->bheader, gpt->ents); cxt->label->nparts_max = gpt_get_nentries(gpt); cxt->label->nparts_cur = 0; guid = gpt->pheader->disk_guid; guid_to_string(&guid, str); fdisk_label_set_changed(cxt->label, 1); fdisk_info(cxt, _("Created a new GPT disklabel (GUID: %s)."), str); done: return rc; } static int gpt_set_disklabel_id(struct fdisk_context *cxt, const char *str) { struct fdisk_gpt_label *gpt; struct gpt_guid uuid; char *old, *new; int rc; assert(cxt); assert(cxt->label); assert(fdisk_is_label(cxt, GPT)); gpt = self_label(cxt); if (!str) { char *buf = NULL; if (fdisk_ask_string(cxt, _("Enter new disk UUID (in 8-4-4-4-12 format)"), &buf)) return -EINVAL; rc = string_to_guid(buf, &uuid); free(buf); } else rc = string_to_guid(str, &uuid); if (rc) { fdisk_warnx(cxt, _("Failed to parse your UUID.")); return rc; } old = gpt_get_header_id(gpt->pheader); gpt->pheader->disk_guid = uuid; gpt->bheader->disk_guid = uuid; gpt_recompute_crc(gpt->pheader, gpt->ents); gpt_recompute_crc(gpt->bheader, gpt->ents); new = gpt_get_header_id(gpt->pheader); fdisk_info(cxt, _("Disk identifier changed from %s to %s."), old, new); free(old); free(new); fdisk_label_set_changed(cxt->label, 1); return 0; } static int gpt_check_table_overlap(struct fdisk_context *cxt, uint64_t first_usable, uint64_t last_usable) { struct fdisk_gpt_label *gpt = self_label(cxt); size_t i; int rc = 0; /* First check if there's enough room for the table. last_lba may have wrapped */ if (first_usable > cxt->total_sectors || /* far too little space */ last_usable > cxt->total_sectors || /* wrapped */ first_usable > last_usable) { /* too little space */ fdisk_warnx(cxt, _("Not enough space for new partition table!")); return -ENOSPC; } /* check that all partitions fit in the remaining space */ for (i = 0; i < gpt_get_nentries(gpt); i++) { struct gpt_entry *e = gpt_get_entry(gpt, i); if (!gpt_entry_is_used(e)) continue; if (gpt_partition_start(e) < first_usable) { fdisk_warnx(cxt, _("Partition #%zu out of range (minimal start is %"PRIu64" sectors)"), i + 1, first_usable); rc = -EINVAL; } if (gpt_partition_end(e) > last_usable) { fdisk_warnx(cxt, _("Partition #%zu out of range (maximal end is %"PRIu64" sectors)"), i + 1, last_usable - 1ULL); rc = -EINVAL; } } return rc; } /** * fdisk_gpt_set_npartitions: * @cxt: context * @nents: number of wanted entries * * Elarge GPT entries array if possible. The function check if an existing * partition does not overlap the entries array area. If yes, then it report * warning and returns -EINVAL. * * Returns: 0 on success, < 0 on error. * Since: 2.29 */ int fdisk_gpt_set_npartitions(struct fdisk_context *cxt, uint32_t nents) { struct fdisk_gpt_label *gpt; size_t new_size = 0; uint32_t old_nents; uint64_t first_usable = 0ULL, last_usable = 0ULL; int rc; assert(cxt); assert(cxt->label); if (!fdisk_is_label(cxt, GPT)) return -EINVAL; gpt = self_label(cxt); old_nents = le32_to_cpu(gpt->pheader->npartition_entries); if (old_nents == nents) return 0; /* do nothing, say nothing */ /* calculate the size (bytes) of the entries array */ rc = gpt_calculate_sizeof_entries(gpt->pheader, nents, &new_size); if (rc) { uint32_t entry_size = le32_to_cpu(gpt->pheader->sizeof_partition_entry); if (entry_size == 0) fdisk_warnx(cxt, _("The partition entry size is zero.")); else fdisk_warnx(cxt, _("The number of the partition has to be smaller than %zu."), UINT32_MAX / entry_size); return rc; } rc = gpt_calculate_first_lba(gpt->pheader, nents, &first_usable, cxt); if (rc == 0) rc = gpt_calculate_last_lba(gpt->pheader, nents, &last_usable, cxt); if (rc) return rc; /* if expanding the table, first check that everything fits, * then allocate more memory and zero. */ if (nents > old_nents) { unsigned char *ents; size_t old_size = 0; rc = gpt_calculate_sizeof_entries(gpt->pheader, old_nents, &old_size); if (rc == 0) rc = gpt_check_table_overlap(cxt, first_usable, last_usable); if (rc) return rc; ents = realloc(gpt->ents, new_size); if (!ents) { fdisk_warnx(cxt, _("Cannot allocate memory!")); return -ENOMEM; } memset(ents + old_size, 0, new_size - old_size); gpt->ents = ents; } /* everything's ok, apply the new size */ gpt->pheader->npartition_entries = cpu_to_le32(nents); gpt->bheader->npartition_entries = cpu_to_le32(nents); /* usable LBA addresses will have changed */ fdisk_set_first_lba(cxt, first_usable); fdisk_set_last_lba(cxt, last_usable); gpt->pheader->first_usable_lba = cpu_to_le64(first_usable); gpt->bheader->first_usable_lba = cpu_to_le64(first_usable); gpt->pheader->last_usable_lba = cpu_to_le64(last_usable); gpt->bheader->last_usable_lba = cpu_to_le64(last_usable); /* The backup header must be recalculated */ gpt_mknew_header_common(cxt, gpt->bheader, le64_to_cpu(gpt->pheader->alternative_lba)); /* CRCs will have changed */ gpt_recompute_crc(gpt->pheader, gpt->ents); gpt_recompute_crc(gpt->bheader, gpt->ents); /* update library info */ cxt->label->nparts_max = gpt_get_nentries(gpt); fdisk_info(cxt, _("Partition table length changed from %"PRIu32" to %"PRIu64"."), old_nents, nents); fdisk_label_set_changed(cxt->label, 1); return 0; } static int gpt_part_is_used(struct fdisk_context *cxt, size_t i) { struct fdisk_gpt_label *gpt; struct gpt_entry *e; assert(cxt); assert(cxt->label); assert(fdisk_is_label(cxt, GPT)); gpt = self_label(cxt); if (i >= gpt_get_nentries(gpt)) return 0; e = gpt_get_entry(gpt, i); return gpt_entry_is_used(e) || gpt_partition_start(e); } /** * fdisk_gpt_is_hybrid: * @cxt: context * * The regular GPT contains PMBR (dummy protective MBR) where the protective * MBR does not address any partitions. * * Hybrid GPT contains regular MBR where this partition table addresses the * same partitions as GPT. It's recommended to not use hybrid GPT due to MBR * limits. * * The libfdisk does not provide functionality to sync GPT and MBR, you have to * directly access and modify (P)MBR (see fdisk_new_nested_context()). * * Returns: 1 if partition table detected as hybrid otherwise return 0 */ int fdisk_gpt_is_hybrid(struct fdisk_context *cxt) { assert(cxt); return valid_pmbr(cxt) == GPT_MBR_HYBRID; } /** * fdisk_gpt_get_partition_attrs: * @cxt: context * @partnum: partition number * @attrs: GPT partition attributes * * Sets @attrs for the given partition * * Returns: 0 on success, <0 on error. */ int fdisk_gpt_get_partition_attrs( struct fdisk_context *cxt, size_t partnum, uint64_t *attrs) { struct fdisk_gpt_label *gpt; assert(cxt); assert(cxt->label); if (!fdisk_is_label(cxt, GPT)) return -EINVAL; gpt = self_label(cxt); if (partnum >= gpt_get_nentries(gpt)) return -EINVAL; *attrs = le64_to_cpu(gpt_get_entry(gpt, partnum)->attrs); return 0; } /** * fdisk_gpt_set_partition_attrs: * @cxt: context * @partnum: partition number * @attrs: GPT partition attributes * * Sets the GPT partition attributes field to @attrs. * * Returns: 0 on success, <0 on error. */ int fdisk_gpt_set_partition_attrs( struct fdisk_context *cxt, size_t partnum, uint64_t attrs) { struct fdisk_gpt_label *gpt; assert(cxt); assert(cxt->label); if (!fdisk_is_label(cxt, GPT)) return -EINVAL; DBG(GPT, ul_debug("entry attributes change requested partno=%zu", partnum)); gpt = self_label(cxt); if (partnum >= gpt_get_nentries(gpt)) return -EINVAL; gpt_get_entry(gpt, partnum)->attrs = cpu_to_le64(attrs); fdisk_info(cxt, _("The attributes on partition %zu changed to 0x%016" PRIx64 "."), partnum + 1, attrs); gpt_recompute_crc(gpt->pheader, gpt->ents); gpt_recompute_crc(gpt->bheader, gpt->ents); fdisk_label_set_changed(cxt->label, 1); return 0; } static int gpt_toggle_partition_flag( struct fdisk_context *cxt, size_t i, unsigned long flag) { struct fdisk_gpt_label *gpt; struct gpt_entry *e; uint64_t attrs; uintmax_t tmp; char *bits; const char *name = NULL; int bit = -1, rc; assert(cxt); assert(cxt->label); assert(fdisk_is_label(cxt, GPT)); DBG(GPT, ul_debug("entry attribute change requested partno=%zu", i)); gpt = self_label(cxt); if (i >= gpt_get_nentries(gpt)) return -EINVAL; e = gpt_get_entry(gpt, i); attrs = e->attrs; bits = (char *) &attrs; switch (flag) { case GPT_FLAG_REQUIRED: bit = GPT_ATTRBIT_REQ; name = GPT_ATTRSTR_REQ; break; case GPT_FLAG_NOBLOCK: bit = GPT_ATTRBIT_NOBLOCK; name = GPT_ATTRSTR_NOBLOCK; break; case GPT_FLAG_LEGACYBOOT: bit = GPT_ATTRBIT_LEGACY; name = GPT_ATTRSTR_LEGACY; break; case GPT_FLAG_GUIDSPECIFIC: rc = fdisk_ask_number(cxt, 48, 48, 63, _("Enter GUID specific bit"), &tmp); if (rc) return rc; bit = tmp; break; default: /* already specified PT_FLAG_GUIDSPECIFIC bit */ if (flag >= 48 && flag <= 63) { bit = flag; flag = GPT_FLAG_GUIDSPECIFIC; } break; } if (bit < 0) { fdisk_warnx(cxt, _("failed to toggle unsupported bit %lu"), flag); return -EINVAL; } if (!isset(bits, bit)) setbit(bits, bit); else clrbit(bits, bit); e->attrs = attrs; if (flag == GPT_FLAG_GUIDSPECIFIC) fdisk_info(cxt, isset(bits, bit) ? _("The GUID specific bit %d on partition %zu is enabled now.") : _("The GUID specific bit %d on partition %zu is disabled now."), bit, i + 1); else fdisk_info(cxt, isset(bits, bit) ? _("The %s flag on partition %zu is enabled now.") : _("The %s flag on partition %zu is disabled now."), name, i + 1); gpt_recompute_crc(gpt->pheader, gpt->ents); gpt_recompute_crc(gpt->bheader, gpt->ents); fdisk_label_set_changed(cxt->label, 1); return 0; } static int gpt_entry_cmp_start(const void *a, const void *b) { const struct gpt_entry *ae = (const struct gpt_entry *) a, *be = (const struct gpt_entry *) b; int au = gpt_entry_is_used(ae), bu = gpt_entry_is_used(be); if (!au && !bu) return 0; if (!au) return 1; if (!bu) return -1; return cmp_numbers(gpt_partition_start(ae), gpt_partition_start(be)); } /* sort partition by start sector */ static int gpt_reorder(struct fdisk_context *cxt) { struct fdisk_gpt_label *gpt; size_t i, nparts, mess; assert(cxt); assert(cxt->label); assert(fdisk_is_label(cxt, GPT)); gpt = self_label(cxt); nparts = gpt_get_nentries(gpt); for (i = 0, mess = 0; mess == 0 && i + 1 < nparts; i++) mess = gpt_entry_cmp_start( (const void *) gpt_get_entry(gpt, i), (const void *) gpt_get_entry(gpt, i + 1)) > 0; if (!mess) { fdisk_info(cxt, _("Nothing to do. Ordering is correct already.")); return 1; } qsort(gpt->ents, nparts, sizeof(struct gpt_entry), gpt_entry_cmp_start); gpt_recompute_crc(gpt->pheader, gpt->ents); gpt_recompute_crc(gpt->bheader, gpt->ents); fdisk_label_set_changed(cxt->label, 1); return 0; } static int gpt_reset_alignment(struct fdisk_context *cxt) { struct fdisk_gpt_label *gpt; struct gpt_header *h; assert(cxt); assert(cxt->label); assert(fdisk_is_label(cxt, GPT)); gpt = self_label(cxt); h = gpt ? gpt->pheader : NULL; if (h) { /* always follow existing table */ cxt->first_lba = le64_to_cpu(h->first_usable_lba); cxt->last_lba = le64_to_cpu(h->last_usable_lba); } else { /* estimate ranges for GPT */ uint64_t first, last; count_first_last_lba(cxt, &first, &last); if (cxt->first_lba < first) cxt->first_lba = first; if (cxt->last_lba > last) cxt->last_lba = last; } return 0; } /* * Deinitialize fdisk-specific variables */ static void gpt_deinit(struct fdisk_label *lb) { struct fdisk_gpt_label *gpt = (struct fdisk_gpt_label *) lb; if (!gpt) return; free(gpt->ents); free(gpt->pheader); free(gpt->bheader); gpt->ents = NULL; gpt->pheader = NULL; gpt->bheader = NULL; } static const struct fdisk_label_operations gpt_operations = { .probe = gpt_probe_label, .write = gpt_write_disklabel, .verify = gpt_verify_disklabel, .create = gpt_create_disklabel, .locate = gpt_locate_disklabel, .get_item = gpt_get_disklabel_item, .set_id = gpt_set_disklabel_id, .get_part = gpt_get_partition, .set_part = gpt_set_partition, .add_part = gpt_add_partition, .del_part = gpt_delete_partition, .reorder = gpt_reorder, .part_is_used = gpt_part_is_used, .part_toggle_flag = gpt_toggle_partition_flag, .deinit = gpt_deinit, .reset_alignment = gpt_reset_alignment }; static const struct fdisk_field gpt_fields[] = { /* basic */ { FDISK_FIELD_DEVICE, N_("Device"), 10, 0 }, { FDISK_FIELD_START, N_("Start"), 5, FDISK_FIELDFL_NUMBER }, { FDISK_FIELD_END, N_("End"), 5, FDISK_FIELDFL_NUMBER }, { FDISK_FIELD_SECTORS, N_("Sectors"), 5, FDISK_FIELDFL_NUMBER }, { FDISK_FIELD_SIZE, N_("Size"), 5, FDISK_FIELDFL_NUMBER | FDISK_FIELDFL_EYECANDY }, { FDISK_FIELD_TYPE, N_("Type"), 0.1, FDISK_FIELDFL_EYECANDY }, /* expert */ { FDISK_FIELD_TYPEID, N_("Type-UUID"), 36, FDISK_FIELDFL_DETAIL }, { FDISK_FIELD_UUID, N_("UUID"), 36, FDISK_FIELDFL_DETAIL }, { FDISK_FIELD_NAME, N_("Name"), 0.2, FDISK_FIELDFL_DETAIL }, { FDISK_FIELD_ATTR, N_("Attrs"), 0, FDISK_FIELDFL_DETAIL } }; /* * allocates GPT in-memory stuff */ struct fdisk_label *fdisk_new_gpt_label(struct fdisk_context *cxt __attribute__ ((__unused__))) { struct fdisk_label *lb; struct fdisk_gpt_label *gpt; gpt = calloc(1, sizeof(*gpt)); if (!gpt) return NULL; /* initialize generic part of the driver */ lb = (struct fdisk_label *) gpt; lb->name = "gpt"; lb->id = FDISK_DISKLABEL_GPT; lb->op = &gpt_operations; lb->parttypes = gpt_parttypes; lb->nparttypes = ARRAY_SIZE(gpt_parttypes); lb->parttype_cuts = gpt_parttype_cuts; lb->nparttype_cuts = ARRAY_SIZE(gpt_parttype_cuts); lb->fields = gpt_fields; lb->nfields = ARRAY_SIZE(gpt_fields); return lb; } /** * fdisk_gpt_disable_relocation * @lb: label * @disable: 0 or 1 * * Disable automatic backup header relocation to the end of the device. The * header position is recalculated during libfdisk probing stage by * fdisk_assign_device() and later written by fdisk_write_disklabel(), so you * need to call it before fdisk_assign_device(). * * Since: 2.36 */ void fdisk_gpt_disable_relocation(struct fdisk_label *lb, int disable) { struct fdisk_gpt_label *gpt = (struct fdisk_gpt_label *) lb; assert(gpt); gpt->no_relocate = disable ? 1 : 0; } /** * fdisk_gpt_enable_minimize * @lb: label * @enable: 0 or 1 * * Force libfdisk to write backup header to behind last partition. The * header position is recalculated on fdisk_write_disklabel(). * * Since: 2.36 */ void fdisk_gpt_enable_minimize(struct fdisk_label *lb, int enable) { struct fdisk_gpt_label *gpt = (struct fdisk_gpt_label *) lb; assert(gpt); gpt->minimize = enable ? 1 : 0; } #ifdef TEST_PROGRAM static int test_getattr(struct fdisk_test *ts, int argc, char *argv[]) { const char *disk = argv[1]; size_t part = strtoul(argv[2], NULL, 0) - 1; struct fdisk_context *cxt; uint64_t atters = 0; cxt = fdisk_new_context(); fdisk_assign_device(cxt, disk, 1); if (!fdisk_is_label(cxt, GPT)) return EXIT_FAILURE; if (fdisk_gpt_get_partition_attrs(cxt, part, &atters)) return EXIT_FAILURE; printf("%s: 0x%016" PRIx64 "\n", argv[2], atters); fdisk_unref_context(cxt); return 0; } static int test_setattr(struct fdisk_test *ts, int argc, char *argv[]) { const char *disk = argv[1]; size_t part = strtoul(argv[2], NULL, 0) - 1; uint64_t atters = strtoull(argv[3], NULL, 0); struct fdisk_context *cxt; cxt = fdisk_new_context(); fdisk_assign_device(cxt, disk, 0); if (!fdisk_is_label(cxt, GPT)) return EXIT_FAILURE; if (fdisk_gpt_set_partition_attrs(cxt, part, atters)) return EXIT_FAILURE; if (fdisk_write_disklabel(cxt)) return EXIT_FAILURE; fdisk_unref_context(cxt); return 0; } int main(int argc, char *argv[]) { struct fdisk_test tss[] = { { "--getattr", test_getattr, " print attributes" }, { "--setattr", test_setattr, " set attributes" }, { NULL } }; return fdisk_run_test(tss, argc, argv); } #endif