/* * LUKS - Linux Unified Key Setup v2, LUKS2 header format code * * Copyright (C) 2015-2023 Red Hat, Inc. All rights reserved. * Copyright (C) 2015-2023 Milan Broz * * This program is free software; you can redistribute it and/or * modify it under the terms of the GNU General Public License * as published by the Free Software Foundation; either version 2 * of the License, or (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA. */ #include "luks2_internal.h" #include struct area { uint64_t offset; uint64_t length; }; static size_t get_area_size(size_t keylength) { /* for now it is AF_split_sectors */ return size_round_up(keylength * 4000, 4096); } static size_t get_min_offset(struct luks2_hdr *hdr) { return 2 * hdr->hdr_size; } static size_t get_max_offset(struct luks2_hdr *hdr) { return LUKS2_hdr_and_areas_size(hdr); } int LUKS2_find_area_max_gap(struct crypt_device *cd, struct luks2_hdr *hdr, uint64_t *area_offset, uint64_t *area_length) { struct area areas[LUKS2_KEYSLOTS_MAX], sorted_areas[LUKS2_KEYSLOTS_MAX+1] = {}; int i, j, k, area_i; size_t valid_offset, offset, length; /* fill area offset + length table */ for (i = 0; i < LUKS2_KEYSLOTS_MAX; i++) { if (!LUKS2_keyslot_area(hdr, i, &areas[i].offset, &areas[i].length)) continue; areas[i].length = 0; areas[i].offset = 0; } /* sort table */ k = 0; /* index in sorted table */ for (i = 0; i < LUKS2_KEYSLOTS_MAX; i++) { offset = get_max_offset(hdr) ?: UINT64_MAX; area_i = -1; /* search for the smallest offset in table */ for (j = 0; j < LUKS2_KEYSLOTS_MAX; j++) if (areas[j].offset && areas[j].offset <= offset) { area_i = j; offset = areas[j].offset; } if (area_i >= 0) { sorted_areas[k].length = areas[area_i].length; sorted_areas[k].offset = areas[area_i].offset; areas[area_i].length = 0; areas[area_i].offset = 0; k++; } } sorted_areas[LUKS2_KEYSLOTS_MAX].offset = get_max_offset(hdr); sorted_areas[LUKS2_KEYSLOTS_MAX].length = 1; /* search for the gap we can use */ length = valid_offset = 0; offset = get_min_offset(hdr); for (i = 0; i < LUKS2_KEYSLOTS_MAX+1; i++) { /* skip empty */ if (sorted_areas[i].offset == 0 || sorted_areas[i].length == 0) continue; /* found bigger gap than the last one */ if ((offset < sorted_areas[i].offset) && (sorted_areas[i].offset - offset) > length) { length = sorted_areas[i].offset - offset; valid_offset = offset; } /* move beyond allocated area */ offset = sorted_areas[i].offset + sorted_areas[i].length; } /* this search 'algorithm' does not work with unaligned areas */ assert(length == size_round_up(length, 4096)); assert(valid_offset == size_round_up(valid_offset, 4096)); if (!length) { log_dbg(cd, "Not enough space in header keyslot area."); return -EINVAL; } log_dbg(cd, "Found largest free area %zu -> %zu", valid_offset, length + valid_offset); *area_offset = valid_offset; *area_length = length; return 0; } int LUKS2_find_area_gap(struct crypt_device *cd, struct luks2_hdr *hdr, size_t keylength, uint64_t *area_offset, uint64_t *area_length) { struct area areas[LUKS2_KEYSLOTS_MAX], sorted_areas[LUKS2_KEYSLOTS_MAX] = {}; int i, j, k, area_i; size_t offset, length; /* fill area offset + length table */ for (i = 0; i < LUKS2_KEYSLOTS_MAX; i++) { if (!LUKS2_keyslot_area(hdr, i, &areas[i].offset, &areas[i].length)) continue; areas[i].length = 0; areas[i].offset = 0; } /* sort table */ k = 0; /* index in sorted table */ for (i = 0; i < LUKS2_KEYSLOTS_MAX; i++) { offset = get_max_offset(hdr) ?: UINT64_MAX; area_i = -1; /* search for the smallest offset in table */ for (j = 0; j < LUKS2_KEYSLOTS_MAX; j++) if (areas[j].offset && areas[j].offset <= offset) { area_i = j; offset = areas[j].offset; } if (area_i >= 0) { sorted_areas[k].length = areas[area_i].length; sorted_areas[k].offset = areas[area_i].offset; areas[area_i].length = 0; areas[area_i].offset = 0; k++; } } /* search for the gap we can use */ offset = get_min_offset(hdr); length = get_area_size(keylength); for (i = 0; i < LUKS2_KEYSLOTS_MAX; i++) { /* skip empty */ if (sorted_areas[i].offset == 0 || sorted_areas[i].length == 0) continue; /* enough space before the used area */ if ((offset < sorted_areas[i].offset) && ((offset + length) <= sorted_areas[i].offset)) break; /* both offset and length are already aligned to 4096 bytes */ offset = sorted_areas[i].offset + sorted_areas[i].length; } if ((offset + length) > get_max_offset(hdr)) { log_dbg(cd, "Not enough space in header keyslot area."); return -EINVAL; } log_dbg(cd, "Found area %zu -> %zu", offset, length + offset); if (area_offset) *area_offset = offset; if (area_length) *area_length = length; return 0; } int LUKS2_check_metadata_area_size(uint64_t metadata_size) { /* see LUKS2_HDR2_OFFSETS */ return (metadata_size != 0x004000 && metadata_size != 0x008000 && metadata_size != 0x010000 && metadata_size != 0x020000 && metadata_size != 0x040000 && metadata_size != 0x080000 && metadata_size != 0x100000 && metadata_size != 0x200000 && metadata_size != 0x400000); } int LUKS2_check_keyslots_area_size(uint64_t keyslots_size) { return (MISALIGNED_4K(keyslots_size) || keyslots_size > LUKS2_MAX_KEYSLOTS_SIZE); } int LUKS2_generate_hdr( struct crypt_device *cd, struct luks2_hdr *hdr, const struct volume_key *vk, const char *cipherName, const char *cipherMode, const char *integrity, const char *uuid, unsigned int sector_size, /* in bytes */ uint64_t data_offset, /* in bytes */ uint64_t align_offset, /* in bytes */ uint64_t required_alignment, uint64_t metadata_size, uint64_t keyslots_size) { struct json_object *jobj_segment, *jobj_integrity, *jobj_keyslots, *jobj_segments, *jobj_config; char cipher[128]; uuid_t partitionUuid; int r, digest; uint64_t mdev_size; if (!metadata_size) metadata_size = LUKS2_HDR_16K_LEN; hdr->hdr_size = metadata_size; if (data_offset && data_offset < get_min_offset(hdr)) { log_err(cd, _("Requested data offset is too small.")); return -EINVAL; } /* Increase keyslot size according to data offset */ if (!keyslots_size && data_offset) keyslots_size = data_offset - get_min_offset(hdr); /* keyslots size has to be 4 KiB aligned */ keyslots_size -= (keyslots_size % 4096); if (keyslots_size > LUKS2_MAX_KEYSLOTS_SIZE) keyslots_size = LUKS2_MAX_KEYSLOTS_SIZE; if (!keyslots_size) { assert(LUKS2_DEFAULT_HDR_SIZE > 2 * LUKS2_HDR_OFFSET_MAX); keyslots_size = LUKS2_DEFAULT_HDR_SIZE - get_min_offset(hdr); /* Decrease keyslots_size due to metadata device being too small */ if (!device_size(crypt_metadata_device(cd), &mdev_size) && ((keyslots_size + get_min_offset(hdr)) > mdev_size) && device_fallocate(crypt_metadata_device(cd), keyslots_size + get_min_offset(hdr)) && (get_min_offset(hdr) <= mdev_size)) keyslots_size = mdev_size - get_min_offset(hdr); } /* Decrease keyslots_size if we have smaller data_offset */ if (data_offset && (keyslots_size + get_min_offset(hdr)) > data_offset) { keyslots_size = data_offset - get_min_offset(hdr); log_dbg(cd, "Decreasing keyslot area size to %" PRIu64 " bytes due to the requested data offset %" PRIu64 " bytes.", keyslots_size, data_offset); } /* Data offset has priority */ if (!data_offset && required_alignment) { data_offset = size_round_up(get_min_offset(hdr) + keyslots_size, (size_t)required_alignment); data_offset += align_offset; } log_dbg(cd, "Formatting LUKS2 with JSON metadata area %" PRIu64 " bytes and keyslots area %" PRIu64 " bytes.", metadata_size - LUKS2_HDR_BIN_LEN, keyslots_size); if (keyslots_size < (LUKS2_HDR_OFFSET_MAX - 2*LUKS2_HDR_16K_LEN)) log_std(cd, _("WARNING: keyslots area (%" PRIu64 " bytes) is very small," " available LUKS2 keyslot count is very limited.\n"), keyslots_size); hdr->seqid = 1; hdr->version = 2; memset(hdr->label, 0, LUKS2_LABEL_L); strcpy(hdr->checksum_alg, "sha256"); crypt_random_get(cd, (char*)hdr->salt1, LUKS2_SALT_L, CRYPT_RND_SALT); crypt_random_get(cd, (char*)hdr->salt2, LUKS2_SALT_L, CRYPT_RND_SALT); if (uuid && uuid_parse(uuid, partitionUuid) == -1) { log_err(cd, _("Wrong LUKS UUID format provided.")); return -EINVAL; } if (!uuid) uuid_generate(partitionUuid); uuid_unparse(partitionUuid, hdr->uuid); if (*cipherMode != '\0') r = snprintf(cipher, sizeof(cipher), "%s-%s", cipherName, cipherMode); else r = snprintf(cipher, sizeof(cipher), "%s", cipherName); if (r < 0 || (size_t)r >= sizeof(cipher)) return -EINVAL; hdr->jobj = json_object_new_object(); jobj_keyslots = json_object_new_object(); json_object_object_add(hdr->jobj, "keyslots", jobj_keyslots); json_object_object_add(hdr->jobj, "tokens", json_object_new_object()); jobj_segments = json_object_new_object(); json_object_object_add(hdr->jobj, "segments", jobj_segments); json_object_object_add(hdr->jobj, "digests", json_object_new_object()); jobj_config = json_object_new_object(); json_object_object_add(hdr->jobj, "config", jobj_config); digest = LUKS2_digest_create(cd, "pbkdf2", hdr, vk); if (digest < 0) goto err; if (LUKS2_digest_segment_assign(cd, hdr, 0, digest, 1, 0) < 0) goto err; jobj_segment = json_segment_create_crypt(data_offset, 0, NULL, cipher, sector_size, 0); if (!jobj_segment) goto err; if (integrity) { jobj_integrity = json_object_new_object(); json_object_object_add(jobj_integrity, "type", json_object_new_string(integrity)); json_object_object_add(jobj_integrity, "journal_encryption", json_object_new_string("none")); json_object_object_add(jobj_integrity, "journal_integrity", json_object_new_string("none")); json_object_object_add(jobj_segment, "integrity", jobj_integrity); } json_object_object_add_by_uint(jobj_segments, 0, jobj_segment); json_object_object_add(jobj_config, "json_size", crypt_jobj_new_uint64(metadata_size - LUKS2_HDR_BIN_LEN)); json_object_object_add(jobj_config, "keyslots_size", crypt_jobj_new_uint64(keyslots_size)); JSON_DBG(cd, hdr->jobj, "Header JSON:"); return 0; err: json_object_put(hdr->jobj); hdr->jobj = NULL; return -EINVAL; } int LUKS2_wipe_header_areas(struct crypt_device *cd, struct luks2_hdr *hdr, bool detached_header) { int r; uint64_t offset, length; size_t wipe_block; /* Wipe complete header, keyslots and padding areas with zeroes. */ offset = 0; length = LUKS2_get_data_offset(hdr) * SECTOR_SIZE; wipe_block = 1024 * 1024; if (LUKS2_hdr_validate(cd, hdr->jobj, hdr->hdr_size - LUKS2_HDR_BIN_LEN)) return -EINVAL; /* On detached header wipe at least the first 4k */ if (detached_header) { length = 4096; wipe_block = 4096; } r = device_check_size(cd, crypt_metadata_device(cd), length, 1); if (r) return r; log_dbg(cd, "Wiping LUKS areas (0x%06" PRIx64 " - 0x%06" PRIx64") with zeroes.", offset, length + offset); r = crypt_wipe_device(cd, crypt_metadata_device(cd), CRYPT_WIPE_ZERO, offset, length, wipe_block, NULL, NULL); if (r < 0) return r; /* Wipe keyslot area */ wipe_block = 1024 * 1024; offset = get_min_offset(hdr); length = LUKS2_keyslots_size(hdr); log_dbg(cd, "Wiping keyslots area (0x%06" PRIx64 " - 0x%06" PRIx64") with random data.", offset, length + offset); return crypt_wipe_device(cd, crypt_metadata_device(cd), CRYPT_WIPE_RANDOM, offset, length, wipe_block, NULL, NULL); } int LUKS2_set_keyslots_size(struct luks2_hdr *hdr, uint64_t data_offset) { json_object *jobj_config; uint64_t keyslots_size; if (data_offset < get_min_offset(hdr)) return 1; keyslots_size = data_offset - get_min_offset(hdr); /* keep keyslots_size reasonable for custom data alignments */ if (keyslots_size > LUKS2_MAX_KEYSLOTS_SIZE) keyslots_size = LUKS2_MAX_KEYSLOTS_SIZE; /* keyslots size has to be 4 KiB aligned */ keyslots_size -= (keyslots_size % 4096); if (!json_object_object_get_ex(hdr->jobj, "config", &jobj_config)) return 1; json_object_object_add(jobj_config, "keyslots_size", crypt_jobj_new_uint64(keyslots_size)); return 0; }