/* * TCRYPT (TrueCrypt-compatible) and VeraCrypt volume handling * * Copyright (C) 2012-2020 Red Hat, Inc. All rights reserved. * Copyright (C) 2012-2020 Milan Broz * * This file is free software; you can redistribute it and/or * modify it under the terms of the GNU Lesser General Public * License as published by the Free Software Foundation; either * version 2.1 of the License, or (at your option) any later version. * * This file 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 * Lesser General Public License for more details. * * You should have received a copy of the GNU Lesser General Public * License along with this file; if not, write to the Free Software * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA. */ #include #include #include #include #include #include "libcryptsetup.h" #include "tcrypt.h" #include "internal.h" /* TCRYPT PBKDF variants */ static const struct { unsigned int legacy:1; unsigned int veracrypt:1; const char *name; const char *hash; unsigned int iterations; uint32_t veracrypt_pim_const; uint32_t veracrypt_pim_mult; } tcrypt_kdf[] = { { 0, 0, "pbkdf2", "ripemd160", 2000, 0, 0 }, { 0, 0, "pbkdf2", "ripemd160", 1000, 0, 0 }, { 0, 0, "pbkdf2", "sha512", 1000, 0, 0 }, { 0, 0, "pbkdf2", "whirlpool", 1000, 0, 0 }, { 1, 0, "pbkdf2", "sha1", 2000, 0, 0 }, { 0, 1, "pbkdf2", "sha512", 500000, 15000, 1000 }, { 0, 1, "pbkdf2", "whirlpool", 500000, 15000, 1000 }, { 0, 1, "pbkdf2", "sha256", 500000, 15000, 1000 }, // VeraCrypt 1.0f { 0, 1, "pbkdf2", "sha256", 200000, 0, 2048 }, // boot only { 0, 1, "pbkdf2", "ripemd160", 655331, 15000, 1000 }, { 0, 1, "pbkdf2", "ripemd160", 327661, 0, 2048 }, // boot only { 0, 1, "pbkdf2", "stribog512",500000, 15000, 1000 }, // { 0, 1, "pbkdf2", "stribog512",200000, 0, 2048 }, // boot only { 0, 0, NULL, NULL, 0, 0, 0 } }; struct tcrypt_alg { const char *name; unsigned int key_size; unsigned int iv_size; unsigned int key_offset; unsigned int iv_offset; /* or tweak key offset */ unsigned int key_extra_size; }; struct tcrypt_algs { unsigned int legacy:1; unsigned int chain_count; unsigned int chain_key_size; const char *long_name; const char *mode; struct tcrypt_alg cipher[3]; }; /* TCRYPT cipher variants */ static struct tcrypt_algs tcrypt_cipher[] = { /* XTS mode */ {0,1,64,"aes","xts-plain64", {{"aes", 64,16,0,32,0}}}, {0,1,64,"serpent","xts-plain64", {{"serpent",64,16,0,32,0}}}, {0,1,64,"twofish","xts-plain64", {{"twofish",64,16,0,32,0}}}, {0,2,128,"twofish-aes","xts-plain64", {{"twofish",64,16, 0,64,0}, {"aes", 64,16,32,96,0}}}, {0,3,192,"serpent-twofish-aes","xts-plain64", {{"serpent",64,16, 0, 96,0}, {"twofish",64,16,32,128,0}, {"aes", 64,16,64,160,0}}}, {0,2,128,"aes-serpent","xts-plain64", {{"aes", 64,16, 0,64,0}, {"serpent",64,16,32,96,0}}}, {0,3,192,"aes-twofish-serpent","xts-plain64", {{"aes", 64,16, 0, 96,0}, {"twofish",64,16,32,128,0}, {"serpent",64,16,64,160,0}}}, {0,2,128,"serpent-twofish","xts-plain64", {{"serpent",64,16, 0,64,0}, {"twofish",64,16,32,96,0}}}, {0,1,64,"camellia","xts-plain64", {{"camellia", 64,16,0,32,0}}}, {0,1,64,"kuznyechik","xts-plain64", {{"kuznyechik", 64,16,0,32,0}}}, {0,2,128,"kuznyechik-camellia","xts-plain64", {{"kuznyechik",64,16, 0,64,0}, {"camellia", 64,16,32,96,0}}}, {0,2,128,"twofish-kuznyechik","xts-plain64", {{"twofish", 64,16, 0,64,0}, {"kuznyechik",64,16,32,96,0}}}, {0,2,128,"serpent-camellia","xts-plain64", {{"serpent", 64,16, 0,64,0}, {"camellia", 64,16,32,96,0}}}, {0,2,128,"aes-kuznyechik","xts-plain64", {{"aes", 64,16, 0,64,0}, {"kuznyechik",64,16,32,96,0}}}, {0,3,192,"camellia-serpent-kuznyechik","xts-plain64", {{"camellia", 64,16, 0, 96,0}, {"serpent", 64,16,32,128,0}, {"kuznyechik",64,16,64,160,0}}}, /* LRW mode */ {0,1,48,"aes","lrw-benbi", {{"aes", 48,16,32,0,0}}}, {0,1,48,"serpent","lrw-benbi", {{"serpent",48,16,32,0,0}}}, {0,1,48,"twofish","lrw-benbi", {{"twofish",48,16,32,0,0}}}, {0,2,96,"twofish-aes","lrw-benbi", {{"twofish",48,16,32,0,0}, {"aes", 48,16,64,0,0}}}, {0,3,144,"serpent-twofish-aes","lrw-benbi", {{"serpent",48,16,32,0,0}, {"twofish",48,16,64,0,0}, {"aes", 48,16,96,0,0}}}, {0,2,96,"aes-serpent","lrw-benbi", {{"aes", 48,16,32,0,0}, {"serpent",48,16,64,0,0}}}, {0,3,144,"aes-twofish-serpent","lrw-benbi", {{"aes", 48,16,32,0,0}, {"twofish",48,16,64,0,0}, {"serpent",48,16,96,0,0}}}, {0,2,96,"serpent-twofish", "lrw-benbi", {{"serpent",48,16,32,0,0}, {"twofish",48,16,64,0,0}}}, /* Kernel LRW block size is fixed to 16 bytes for GF(2^128) * thus cannot be used with blowfish where block is 8 bytes. * There also no GF(2^64) support. {1,1,64,"blowfish_le","lrw-benbi", {{"blowfish_le",64,8,32,0,0}}}, {1,2,112,"blowfish_le-aes","lrw-benbi", {{"blowfish_le",64, 8,32,0,0}, {"aes", 48,16,88,0,0}}}, {1,3,160,"serpent-blowfish_le-aes","lrw-benbi", {{"serpent", 48,16, 32,0,0}, {"blowfish_le",64, 8, 64,0,0}, {"aes", 48,16,120,0,0}}},*/ /* * CBC + "outer" CBC (both with whitening) * chain_key_size: alg_keys_bytes + IV_seed_bytes + whitening_bytes */ {1,1,32+16+16,"aes","cbc-tcw", {{"aes", 32,16,32,0,32}}}, {1,1,32+16+16,"serpent","cbc-tcw", {{"serpent",32,16,32,0,32}}}, {1,1,32+16+16,"twofish","cbc-tcw", {{"twofish",32,16,32,0,32}}}, {1,2,64+16+16,"twofish-aes","cbci-tcrypt", {{"twofish",32,16,32,0,0}, {"aes", 32,16,64,0,32}}}, {1,3,96+16+16,"serpent-twofish-aes","cbci-tcrypt", {{"serpent",32,16,32,0,0}, {"twofish",32,16,64,0,0}, {"aes", 32,16,96,0,32}}}, {1,2,64+16+16,"aes-serpent","cbci-tcrypt", {{"aes", 32,16,32,0,0}, {"serpent",32,16,64,0,32}}}, {1,3,96+16+16,"aes-twofish-serpent", "cbci-tcrypt", {{"aes", 32,16,32,0,0}, {"twofish",32,16,64,0,0}, {"serpent",32,16,96,0,32}}}, {1,2,64+16+16,"serpent-twofish", "cbci-tcrypt", {{"serpent",32,16,32,0,0}, {"twofish",32,16,64,0,32}}}, {1,1,16+8+16,"cast5","cbc-tcw", {{"cast5", 16,8,32,0,24}}}, {1,1,24+8+16,"des3_ede","cbc-tcw", {{"des3_ede",24,8,32,0,24}}}, {1,1,56+8+16,"blowfish_le","cbc-tcrypt", {{"blowfish_le",56,8,32,0,24}}}, {1,2,88+16+16,"blowfish_le-aes","cbc-tcrypt", {{"blowfish_le",56, 8,32,0,0}, {"aes", 32,16,88,0,32}}}, {1,3,120+16+16,"serpent-blowfish_le-aes","cbc-tcrypt", {{"serpent", 32,16, 32,0,0}, {"blowfish_le",56, 8, 64,0,0}, {"aes", 32,16,120,0,32}}}, {} }; static int TCRYPT_hdr_from_disk(struct crypt_device *cd, struct tcrypt_phdr *hdr, struct crypt_params_tcrypt *params, int kdf_index, int cipher_index) { uint32_t crc32; size_t size; /* Check CRC32 of header */ size = TCRYPT_HDR_LEN - sizeof(hdr->d.keys) - sizeof(hdr->d.header_crc32); crc32 = crypt_crc32(~0, (unsigned char*)&hdr->d, size) ^ ~0; if (be16_to_cpu(hdr->d.version) > 3 && crc32 != be32_to_cpu(hdr->d.header_crc32)) { log_dbg(cd, "TCRYPT header CRC32 mismatch."); return -EINVAL; } /* Check CRC32 of keys */ crc32 = crypt_crc32(~0, (unsigned char*)hdr->d.keys, sizeof(hdr->d.keys)) ^ ~0; if (crc32 != be32_to_cpu(hdr->d.keys_crc32)) { log_dbg(cd, "TCRYPT keys CRC32 mismatch."); return -EINVAL; } /* Convert header to cpu format */ hdr->d.version = be16_to_cpu(hdr->d.version); hdr->d.version_tc = be16_to_cpu(hdr->d.version_tc); hdr->d.keys_crc32 = be32_to_cpu(hdr->d.keys_crc32); hdr->d.hidden_volume_size = be64_to_cpu(hdr->d.hidden_volume_size); hdr->d.volume_size = be64_to_cpu(hdr->d.volume_size); hdr->d.mk_offset = be64_to_cpu(hdr->d.mk_offset); if (!hdr->d.mk_offset) hdr->d.mk_offset = 512; hdr->d.mk_size = be64_to_cpu(hdr->d.mk_size); hdr->d.flags = be32_to_cpu(hdr->d.flags); hdr->d.sector_size = be32_to_cpu(hdr->d.sector_size); if (!hdr->d.sector_size) hdr->d.sector_size = 512; hdr->d.header_crc32 = be32_to_cpu(hdr->d.header_crc32); /* Set params */ params->passphrase = NULL; params->passphrase_size = 0; params->hash_name = tcrypt_kdf[kdf_index].hash; params->key_size = tcrypt_cipher[cipher_index].chain_key_size; params->cipher = tcrypt_cipher[cipher_index].long_name; params->mode = tcrypt_cipher[cipher_index].mode; return 0; } /* * Kernel implements just big-endian version of blowfish, hack it here */ static void TCRYPT_swab_le(char *buf) { uint32_t *l = (uint32_t*)&buf[0]; uint32_t *r = (uint32_t*)&buf[4]; *l = swab32(*l); *r = swab32(*r); } static int decrypt_blowfish_le_cbc(struct tcrypt_alg *alg, const char *key, char *buf) { int bs = alg->iv_size; char iv[bs], iv_old[bs]; struct crypt_cipher *cipher = NULL; int i, j, r; assert(bs == 2*sizeof(uint32_t)); r = crypt_cipher_init(&cipher, "blowfish", "ecb", &key[alg->key_offset], alg->key_size); if (r < 0) return r; memcpy(iv, &key[alg->iv_offset], alg->iv_size); for (i = 0; i < TCRYPT_HDR_LEN; i += bs) { memcpy(iv_old, &buf[i], bs); TCRYPT_swab_le(&buf[i]); r = crypt_cipher_decrypt(cipher, &buf[i], &buf[i], bs, NULL, 0); TCRYPT_swab_le(&buf[i]); if (r < 0) break; for (j = 0; j < bs; j++) buf[i + j] ^= iv[j]; memcpy(iv, iv_old, bs); } crypt_cipher_destroy(cipher); crypt_safe_memzero(iv, bs); crypt_safe_memzero(iv_old, bs); return r; } static void TCRYPT_remove_whitening(char *buf, const char *key) { int j; for (j = 0; j < TCRYPT_HDR_LEN; j++) buf[j] ^= key[j % 8]; } static void TCRYPT_copy_key(struct tcrypt_alg *alg, const char *mode, char *out_key, const char *key) { int ks2; if (!strncmp(mode, "xts", 3)) { ks2 = alg->key_size / 2; memcpy(out_key, &key[alg->key_offset], ks2); memcpy(&out_key[ks2], &key[alg->iv_offset], ks2); } else if (!strncmp(mode, "lrw", 3)) { ks2 = alg->key_size - TCRYPT_LRW_IKEY_LEN; memcpy(out_key, &key[alg->key_offset], ks2); memcpy(&out_key[ks2], key, TCRYPT_LRW_IKEY_LEN); } else if (!strncmp(mode, "cbc", 3)) { memcpy(out_key, &key[alg->key_offset], alg->key_size); /* IV + whitening */ memcpy(&out_key[alg->key_size], &key[alg->iv_offset], alg->key_extra_size); } } static int TCRYPT_decrypt_hdr_one(struct tcrypt_alg *alg, const char *mode, const char *key,struct tcrypt_phdr *hdr) { char backend_key[TCRYPT_HDR_KEY_LEN]; char iv[TCRYPT_HDR_IV_LEN] = {}; char mode_name[MAX_CIPHER_LEN + 1]; struct crypt_cipher *cipher; char *c, *buf = (char*)&hdr->e; int r; /* Remove IV if present */ mode_name[MAX_CIPHER_LEN] = '\0'; strncpy(mode_name, mode, MAX_CIPHER_LEN); c = strchr(mode_name, '-'); if (c) *c = '\0'; if (!strncmp(mode, "lrw", 3)) iv[alg->iv_size - 1] = 1; else if (!strncmp(mode, "cbc", 3)) { TCRYPT_remove_whitening(buf, &key[8]); if (!strcmp(alg->name, "blowfish_le")) return decrypt_blowfish_le_cbc(alg, key, buf); memcpy(iv, &key[alg->iv_offset], alg->iv_size); } TCRYPT_copy_key(alg, mode, backend_key, key); r = crypt_cipher_init(&cipher, alg->name, mode_name, backend_key, alg->key_size); if (!r) { r = crypt_cipher_decrypt(cipher, buf, buf, TCRYPT_HDR_LEN, iv, alg->iv_size); crypt_cipher_destroy(cipher); } crypt_safe_memzero(backend_key, sizeof(backend_key)); crypt_safe_memzero(iv, TCRYPT_HDR_IV_LEN); return r; } /* * For chained ciphers and CBC mode we need "outer" decryption. * Backend doesn't provide this, so implement it here directly using ECB. */ static int TCRYPT_decrypt_cbci(struct tcrypt_algs *ciphers, const char *key, struct tcrypt_phdr *hdr) { struct crypt_cipher *cipher[ciphers->chain_count]; unsigned int bs = ciphers->cipher[0].iv_size; char *buf = (char*)&hdr->e, iv[bs], iv_old[bs]; unsigned int i, j; int r = -EINVAL; TCRYPT_remove_whitening(buf, &key[8]); memcpy(iv, &key[ciphers->cipher[0].iv_offset], bs); /* Initialize all ciphers in chain in ECB mode */ for (j = 0; j < ciphers->chain_count; j++) cipher[j] = NULL; for (j = 0; j < ciphers->chain_count; j++) { r = crypt_cipher_init(&cipher[j], ciphers->cipher[j].name, "ecb", &key[ciphers->cipher[j].key_offset], ciphers->cipher[j].key_size); if (r < 0) goto out; } /* Implements CBC with chained ciphers in loop inside */ for (i = 0; i < TCRYPT_HDR_LEN; i += bs) { memcpy(iv_old, &buf[i], bs); for (j = ciphers->chain_count; j > 0; j--) { r = crypt_cipher_decrypt(cipher[j - 1], &buf[i], &buf[i], bs, NULL, 0); if (r < 0) goto out; } for (j = 0; j < bs; j++) buf[i + j] ^= iv[j]; memcpy(iv, iv_old, bs); } out: for (j = 0; j < ciphers->chain_count; j++) if (cipher[j]) crypt_cipher_destroy(cipher[j]); crypt_safe_memzero(iv, bs); crypt_safe_memzero(iv_old, bs); return r; } static int TCRYPT_decrypt_hdr(struct crypt_device *cd, struct tcrypt_phdr *hdr, const char *key, uint32_t flags) { struct tcrypt_phdr hdr2; int i, j, r = -EINVAL; for (i = 0; tcrypt_cipher[i].chain_count; i++) { if (!(flags & CRYPT_TCRYPT_LEGACY_MODES) && tcrypt_cipher[i].legacy) continue; log_dbg(cd, "TCRYPT: trying cipher %s-%s", tcrypt_cipher[i].long_name, tcrypt_cipher[i].mode); memcpy(&hdr2.e, &hdr->e, TCRYPT_HDR_LEN); if (!strncmp(tcrypt_cipher[i].mode, "cbci", 4)) r = TCRYPT_decrypt_cbci(&tcrypt_cipher[i], key, &hdr2); else for (j = tcrypt_cipher[i].chain_count - 1; j >= 0 ; j--) { if (!tcrypt_cipher[i].cipher[j].name) continue; r = TCRYPT_decrypt_hdr_one(&tcrypt_cipher[i].cipher[j], tcrypt_cipher[i].mode, key, &hdr2); if (r < 0) break; } if (r < 0) { log_dbg(cd, "TCRYPT: returned error %d, skipped.", r); if (r == -ENOTSUP) break; r = -ENOENT; continue; } if (!strncmp(hdr2.d.magic, TCRYPT_HDR_MAGIC, TCRYPT_HDR_MAGIC_LEN)) { log_dbg(cd, "TCRYPT: Signature magic detected."); memcpy(&hdr->e, &hdr2.e, TCRYPT_HDR_LEN); r = i; break; } if ((flags & CRYPT_TCRYPT_VERA_MODES) && !strncmp(hdr2.d.magic, VCRYPT_HDR_MAGIC, TCRYPT_HDR_MAGIC_LEN)) { log_dbg(cd, "TCRYPT: Signature magic detected (Veracrypt)."); memcpy(&hdr->e, &hdr2.e, TCRYPT_HDR_LEN); r = i; break; } r = -EPERM; } crypt_safe_memzero(&hdr2, sizeof(hdr2)); return r; } static int TCRYPT_pool_keyfile(struct crypt_device *cd, unsigned char pool[VCRYPT_KEY_POOL_LEN], const char *keyfile, int keyfiles_pool_length) { unsigned char *data; int i, j, fd, data_size, r = -EIO; uint32_t crc; log_dbg(cd, "TCRYPT: using keyfile %s.", keyfile); data = malloc(TCRYPT_KEYFILE_LEN); if (!data) return -ENOMEM; memset(data, 0, TCRYPT_KEYFILE_LEN); fd = open(keyfile, O_RDONLY); if (fd < 0) { log_err(cd, _("Failed to open key file.")); goto out; } data_size = read_buffer(fd, data, TCRYPT_KEYFILE_LEN); close(fd); if (data_size < 0) { log_err(cd, _("Error reading keyfile %s."), keyfile); goto out; } for (i = 0, j = 0, crc = ~0U; i < data_size; i++) { crc = crypt_crc32(crc, &data[i], 1); pool[j++] += (unsigned char)(crc >> 24); pool[j++] += (unsigned char)(crc >> 16); pool[j++] += (unsigned char)(crc >> 8); pool[j++] += (unsigned char)(crc); j %= keyfiles_pool_length; } r = 0; out: crypt_safe_memzero(&crc, sizeof(crc)); crypt_safe_memzero(data, TCRYPT_KEYFILE_LEN); free(data); return r; } static int TCRYPT_init_hdr(struct crypt_device *cd, struct tcrypt_phdr *hdr, struct crypt_params_tcrypt *params) { unsigned char pwd[VCRYPT_KEY_POOL_LEN] = {}; size_t passphrase_size, max_passphrase_size; char *key; unsigned int i, skipped = 0, iterations; int r = -EPERM, keyfiles_pool_length; if (posix_memalign((void*)&key, crypt_getpagesize(), TCRYPT_HDR_KEY_LEN)) return -ENOMEM; if (params->flags & CRYPT_TCRYPT_VERA_MODES && params->passphrase_size > TCRYPT_KEY_POOL_LEN) { /* Really. Keyfile pool length depends on passphrase size in Veracrypt. */ max_passphrase_size = VCRYPT_KEY_POOL_LEN; keyfiles_pool_length = VCRYPT_KEY_POOL_LEN; } else { max_passphrase_size = TCRYPT_KEY_POOL_LEN; keyfiles_pool_length = TCRYPT_KEY_POOL_LEN; } if (params->keyfiles_count) passphrase_size = max_passphrase_size; else passphrase_size = params->passphrase_size; if (params->passphrase_size > max_passphrase_size) { log_err(cd, _("Maximum TCRYPT passphrase length (%zu) exceeded."), max_passphrase_size); goto out; } /* Calculate pool content from keyfiles */ for (i = 0; i < params->keyfiles_count; i++) { r = TCRYPT_pool_keyfile(cd, pwd, params->keyfiles[i], keyfiles_pool_length); if (r < 0) goto out; } /* If provided password, combine it with pool */ for (i = 0; i < params->passphrase_size; i++) pwd[i] += params->passphrase[i]; for (i = 0; tcrypt_kdf[i].name; i++) { if (!(params->flags & CRYPT_TCRYPT_LEGACY_MODES) && tcrypt_kdf[i].legacy) continue; if (!(params->flags & CRYPT_TCRYPT_VERA_MODES) && tcrypt_kdf[i].veracrypt) continue; if ((params->flags & CRYPT_TCRYPT_VERA_MODES) && params->veracrypt_pim) { /* Do not try TrueCrypt modes if we have PIM value */ if (!tcrypt_kdf[i].veracrypt) continue; /* adjust iterations to given PIM cmdline parameter */ iterations = tcrypt_kdf[i].veracrypt_pim_const + (tcrypt_kdf[i].veracrypt_pim_mult * params->veracrypt_pim); } else iterations = tcrypt_kdf[i].iterations; /* Derive header key */ log_dbg(cd, "TCRYPT: trying KDF: %s-%s-%d%s.", tcrypt_kdf[i].name, tcrypt_kdf[i].hash, tcrypt_kdf[i].iterations, params->veracrypt_pim && tcrypt_kdf[i].veracrypt ? "-PIM" : ""); r = crypt_pbkdf(tcrypt_kdf[i].name, tcrypt_kdf[i].hash, (char*)pwd, passphrase_size, hdr->salt, TCRYPT_HDR_SALT_LEN, key, TCRYPT_HDR_KEY_LEN, iterations, 0, 0); if (r < 0) { log_verbose(cd, _("PBKDF2 hash algorithm %s not available, skipping."), tcrypt_kdf[i].hash); continue; } /* Decrypt header */ r = TCRYPT_decrypt_hdr(cd, hdr, key, params->flags); if (r == -ENOENT) { skipped++; r = -EPERM; } if (r != -EPERM) break; } if ((r < 0 && r != -EPERM && skipped && skipped == i) || r == -ENOTSUP) { log_err(cd, _("Required kernel crypto interface not available.")); #ifdef ENABLE_AF_ALG log_err(cd, _("Ensure you have algif_skcipher kernel module loaded.")); #endif } if (r < 0) goto out; r = TCRYPT_hdr_from_disk(cd, hdr, params, i, r); if (!r) { log_dbg(cd, "TCRYPT: Magic: %s, Header version: %d, req. %d, sector %d" ", mk_offset %" PRIu64 ", hidden_size %" PRIu64 ", volume size %" PRIu64, tcrypt_kdf[i].veracrypt ? VCRYPT_HDR_MAGIC : TCRYPT_HDR_MAGIC, (int)hdr->d.version, (int)hdr->d.version_tc, (int)hdr->d.sector_size, hdr->d.mk_offset, hdr->d.hidden_volume_size, hdr->d.volume_size); log_dbg(cd, "TCRYPT: Header cipher %s-%s, key size %zu", params->cipher, params->mode, params->key_size); } out: crypt_safe_memzero(pwd, TCRYPT_KEY_POOL_LEN); if (key) crypt_safe_memzero(key, TCRYPT_HDR_KEY_LEN); free(key); return r; } int TCRYPT_read_phdr(struct crypt_device *cd, struct tcrypt_phdr *hdr, struct crypt_params_tcrypt *params) { struct device *base_device = NULL, *device = crypt_metadata_device(cd); ssize_t hdr_size = sizeof(struct tcrypt_phdr); char *base_device_path; int devfd, r; assert(sizeof(struct tcrypt_phdr) == 512); log_dbg(cd, "Reading TCRYPT header of size %zu bytes from device %s.", hdr_size, device_path(device)); if (params->flags & CRYPT_TCRYPT_SYSTEM_HEADER && crypt_dev_is_partition(device_path(device))) { base_device_path = crypt_get_base_device(device_path(device)); log_dbg(cd, "Reading TCRYPT system header from device %s.", base_device_path ?: "?"); if (!base_device_path) return -EINVAL; r = device_alloc(cd, &base_device, base_device_path); free(base_device_path); if (r < 0) return r; devfd = device_open(cd, base_device, O_RDONLY); } else devfd = device_open(cd, device, O_RDONLY); if (devfd < 0) { device_free(cd, base_device); log_err(cd, _("Cannot open device %s."), device_path(device)); return -EINVAL; } r = -EIO; if (params->flags & CRYPT_TCRYPT_SYSTEM_HEADER) { if (read_lseek_blockwise(devfd, device_block_size(cd, device), device_alignment(device), hdr, hdr_size, TCRYPT_HDR_SYSTEM_OFFSET) == hdr_size) { r = TCRYPT_init_hdr(cd, hdr, params); } } else if (params->flags & CRYPT_TCRYPT_HIDDEN_HEADER) { if (params->flags & CRYPT_TCRYPT_BACKUP_HEADER) { if (read_lseek_blockwise(devfd, device_block_size(cd, device), device_alignment(device), hdr, hdr_size, TCRYPT_HDR_HIDDEN_OFFSET_BCK) == hdr_size) r = TCRYPT_init_hdr(cd, hdr, params); } else { if (read_lseek_blockwise(devfd, device_block_size(cd, device), device_alignment(device), hdr, hdr_size, TCRYPT_HDR_HIDDEN_OFFSET) == hdr_size) r = TCRYPT_init_hdr(cd, hdr, params); if (r && read_lseek_blockwise(devfd, device_block_size(cd, device), device_alignment(device), hdr, hdr_size, TCRYPT_HDR_HIDDEN_OFFSET_OLD) == hdr_size) r = TCRYPT_init_hdr(cd, hdr, params); } } else if (params->flags & CRYPT_TCRYPT_BACKUP_HEADER) { if (read_lseek_blockwise(devfd, device_block_size(cd, device), device_alignment(device), hdr, hdr_size, TCRYPT_HDR_OFFSET_BCK) == hdr_size) r = TCRYPT_init_hdr(cd, hdr, params); } else if (read_lseek_blockwise(devfd, device_block_size(cd, device), device_alignment(device), hdr, hdr_size, 0) == hdr_size) r = TCRYPT_init_hdr(cd, hdr, params); device_free(cd, base_device); if (r < 0) memset(hdr, 0, sizeof (*hdr)); return r; } static struct tcrypt_algs *TCRYPT_get_algs(const char *cipher, const char *mode) { int i; if (!cipher || !mode) return NULL; for (i = 0; tcrypt_cipher[i].chain_count; i++) if (!strcmp(tcrypt_cipher[i].long_name, cipher) && !strcmp(tcrypt_cipher[i].mode, mode)) return &tcrypt_cipher[i]; return NULL; } int TCRYPT_activate(struct crypt_device *cd, const char *name, struct tcrypt_phdr *hdr, struct crypt_params_tcrypt *params, uint32_t flags) { char dm_name[PATH_MAX], dm_dev_name[PATH_MAX], cipher_spec[MAX_CIPHER_LEN*2+1]; char *part_path; unsigned int i; int r; uint32_t req_flags, dmc_flags; struct tcrypt_algs *algs; enum devcheck device_check; uint64_t offset = crypt_get_data_offset(cd); struct volume_key *vk = NULL; struct device *ptr_dev = crypt_data_device(cd), *device = NULL, *part_device = NULL; struct crypt_dm_active_device dmd = { .flags = flags }; if (!hdr->d.version) { log_dbg(cd, "TCRYPT: this function is not supported without encrypted header load."); return -ENOTSUP; } if (hdr->d.sector_size && hdr->d.sector_size != SECTOR_SIZE) { log_err(cd, _("Activation is not supported for %d sector size."), hdr->d.sector_size); return -ENOTSUP; } if (strstr(params->mode, "-tcrypt")) { log_err(cd, _("Kernel does not support activation for this TCRYPT legacy mode.")); return -ENOTSUP; } if (strstr(params->mode, "-tcw")) req_flags = DM_TCW_SUPPORTED; else req_flags = DM_PLAIN64_SUPPORTED; algs = TCRYPT_get_algs(params->cipher, params->mode); if (!algs) return -EINVAL; if (hdr->d.sector_size == 0) return -EINVAL; if (params->flags & CRYPT_TCRYPT_SYSTEM_HEADER) dmd.size = 0; else if (params->flags & CRYPT_TCRYPT_HIDDEN_HEADER) dmd.size = hdr->d.hidden_volume_size / hdr->d.sector_size; else dmd.size = hdr->d.volume_size / hdr->d.sector_size; if (dmd.flags & CRYPT_ACTIVATE_SHARED) device_check = DEV_OK; else device_check = DEV_EXCL; if ((params->flags & CRYPT_TCRYPT_SYSTEM_HEADER) && !crypt_dev_is_partition(device_path(crypt_data_device(cd)))) { part_path = crypt_get_partition_device(device_path(crypt_data_device(cd)), crypt_get_data_offset(cd), dmd.size); if (part_path) { if (!device_alloc(cd, &part_device, part_path)) { log_verbose(cd, _("Activating TCRYPT system encryption for partition %s."), part_path); ptr_dev = part_device; offset = 0; } free(part_path); } else /* * System encryption use the whole device mapping, there can * be active partitions. */ device_check = DEV_OK; } r = device_block_adjust(cd, ptr_dev, device_check, offset, &dmd.size, &dmd.flags); if (r) goto out; /* From here, key size for every cipher must be the same */ vk = crypt_alloc_volume_key(algs->cipher[0].key_size + algs->cipher[0].key_extra_size, NULL); if (!vk) { r = -ENOMEM; goto out; } for (i = algs->chain_count; i > 0; i--) { if (i == 1) { dm_name[sizeof(dm_name)-1] = '\0'; strncpy(dm_name, name, sizeof(dm_name)-1); dmd.flags = flags; } else { snprintf(dm_name, sizeof(dm_name), "%s_%d", name, i-1); dmd.flags = flags | CRYPT_ACTIVATE_PRIVATE; } TCRYPT_copy_key(&algs->cipher[i-1], algs->mode, vk->key, hdr->d.keys); if (algs->chain_count != i) { snprintf(dm_dev_name, sizeof(dm_dev_name), "%s/%s_%d", dm_get_dir(), name, i); r = device_alloc(cd, &device, dm_dev_name); if (r) break; ptr_dev = device; offset = 0; } r = snprintf(cipher_spec, sizeof(cipher_spec), "%s-%s", algs->cipher[i-1].name, algs->mode); if (r < 0 || (size_t)r >= sizeof(cipher_spec)) { r = -ENOMEM; break; } r = dm_crypt_target_set(&dmd.segment, 0, dmd.size, ptr_dev, vk, cipher_spec, crypt_get_iv_offset(cd), offset, crypt_get_integrity(cd), crypt_get_integrity_tag_size(cd), crypt_get_sector_size(cd)); if (r) break; log_dbg(cd, "Trying to activate TCRYPT device %s using cipher %s.", dm_name, dmd.segment.u.crypt.cipher); r = dm_create_device(cd, dm_name, CRYPT_TCRYPT, &dmd); dm_targets_free(cd, &dmd); device_free(cd, device); device = NULL; if (r) break; } if (r < 0 && (dm_flags(cd, DM_CRYPT, &dmc_flags) || ((dmc_flags & req_flags) != req_flags))) { log_err(cd, _("Kernel does not support TCRYPT compatible mapping.")); r = -ENOTSUP; } out: crypt_free_volume_key(vk); device_free(cd, device); device_free(cd, part_device); return r; } static int TCRYPT_remove_one(struct crypt_device *cd, const char *name, const char *base_uuid, int index, uint32_t flags) { struct crypt_dm_active_device dmd; char dm_name[PATH_MAX]; int r; if (snprintf(dm_name, sizeof(dm_name), "%s_%d", name, index) < 0) return -ENOMEM; r = dm_status_device(cd, dm_name); if (r < 0) return r; r = dm_query_device(cd, dm_name, DM_ACTIVE_UUID, &dmd); if (!r && !strncmp(dmd.uuid, base_uuid, strlen(base_uuid))) r = dm_remove_device(cd, dm_name, flags); free(CONST_CAST(void*)dmd.uuid); return r; } int TCRYPT_deactivate(struct crypt_device *cd, const char *name, uint32_t flags) { struct crypt_dm_active_device dmd; int r; r = dm_query_device(cd, name, DM_ACTIVE_UUID, &dmd); if (r < 0) return r; if (!dmd.uuid) return -EINVAL; r = dm_remove_device(cd, name, flags); if (r < 0) goto out; r = TCRYPT_remove_one(cd, name, dmd.uuid, 1, flags); if (r < 0) goto out; r = TCRYPT_remove_one(cd, name, dmd.uuid, 2, flags); out: free(CONST_CAST(void*)dmd.uuid); return (r == -ENODEV) ? 0 : r; } static int TCRYPT_status_one(struct crypt_device *cd, const char *name, const char *base_uuid, int index, size_t *key_size, char *cipher, struct tcrypt_phdr *tcrypt_hdr, struct device **device) { struct crypt_dm_active_device dmd; struct dm_target *tgt = &dmd.segment; char dm_name[PATH_MAX], *c; int r; if (snprintf(dm_name, sizeof(dm_name), "%s_%d", name, index) < 0) return -ENOMEM; r = dm_status_device(cd, dm_name); if (r < 0) return r; r = dm_query_device(cd, dm_name, DM_ACTIVE_DEVICE | DM_ACTIVE_UUID | DM_ACTIVE_CRYPT_CIPHER | DM_ACTIVE_CRYPT_KEYSIZE, &dmd); if (r < 0) return r; if (!single_segment(&dmd) || tgt->type != DM_CRYPT) { r = -ENOTSUP; goto out; } r = 0; if (!strncmp(dmd.uuid, base_uuid, strlen(base_uuid))) { if ((c = strchr(tgt->u.crypt.cipher, '-'))) *c = '\0'; strcat(cipher, "-"); strncat(cipher, tgt->u.crypt.cipher, MAX_CIPHER_LEN); *key_size += tgt->u.crypt.vk->keylength; tcrypt_hdr->d.mk_offset = tgt->u.crypt.offset * SECTOR_SIZE; device_free(cd, *device); MOVE_REF(*device, tgt->data_device); } else r = -ENODEV; out: dm_targets_free(cd, &dmd); free(CONST_CAST(void*)dmd.uuid); return r; } int TCRYPT_init_by_name(struct crypt_device *cd, const char *name, const char *uuid, const struct dm_target *tgt, struct device **device, struct crypt_params_tcrypt *tcrypt_params, struct tcrypt_phdr *tcrypt_hdr) { struct tcrypt_algs *algs; char cipher[MAX_CIPHER_LEN * 4], mode[MAX_CIPHER_LEN+1], *tmp; size_t key_size; int r; memset(tcrypt_params, 0, sizeof(*tcrypt_params)); memset(tcrypt_hdr, 0, sizeof(*tcrypt_hdr)); tcrypt_hdr->d.sector_size = SECTOR_SIZE; tcrypt_hdr->d.mk_offset = tgt->u.crypt.offset * SECTOR_SIZE; strncpy(cipher, tgt->u.crypt.cipher, MAX_CIPHER_LEN); tmp = strchr(cipher, '-'); if (!tmp) return -EINVAL; *tmp = '\0'; mode[MAX_CIPHER_LEN] = '\0'; strncpy(mode, ++tmp, MAX_CIPHER_LEN); key_size = tgt->u.crypt.vk->keylength; r = TCRYPT_status_one(cd, name, uuid, 1, &key_size, cipher, tcrypt_hdr, device); if (!r) r = TCRYPT_status_one(cd, name, uuid, 2, &key_size, cipher, tcrypt_hdr, device); if (r < 0 && r != -ENODEV) return r; algs = TCRYPT_get_algs(cipher, mode); if (!algs || key_size != algs->chain_key_size) return -EINVAL; tcrypt_params->key_size = algs->chain_key_size; tcrypt_params->cipher = algs->long_name; tcrypt_params->mode = algs->mode; return 0; } uint64_t TCRYPT_get_data_offset(struct crypt_device *cd, struct tcrypt_phdr *hdr, struct crypt_params_tcrypt *params) { uint64_t size; /* No real header loaded, initialized by active device */ if (!hdr->d.version) goto hdr_offset; /* Mapping through whole device, not partition! */ if (params->flags & CRYPT_TCRYPT_SYSTEM_HEADER) { if (crypt_dev_is_partition(device_path(crypt_metadata_device(cd)))) return 0; goto hdr_offset; } if (params->mode && !strncmp(params->mode, "xts", 3)) { if (hdr->d.version < 3) return 1; if (params->flags & CRYPT_TCRYPT_HIDDEN_HEADER) { if (hdr->d.version > 3) return (hdr->d.mk_offset / hdr->d.sector_size); if (device_size(crypt_metadata_device(cd), &size) < 0) return 0; return (size - hdr->d.hidden_volume_size + (TCRYPT_HDR_HIDDEN_OFFSET_OLD)) / hdr->d.sector_size; } goto hdr_offset; } if (params->flags & CRYPT_TCRYPT_HIDDEN_HEADER) { if (device_size(crypt_metadata_device(cd), &size) < 0) return 0; return (size - hdr->d.hidden_volume_size + (TCRYPT_HDR_HIDDEN_OFFSET_OLD)) / hdr->d.sector_size; } hdr_offset: return hdr->d.mk_offset / hdr->d.sector_size; } uint64_t TCRYPT_get_iv_offset(struct crypt_device *cd, struct tcrypt_phdr *hdr, struct crypt_params_tcrypt *params) { uint64_t iv_offset; if (params->mode && !strncmp(params->mode, "xts", 3)) iv_offset = TCRYPT_get_data_offset(cd, hdr, params); else if (params->mode && !strncmp(params->mode, "lrw", 3)) iv_offset = 0; else iv_offset = hdr->d.mk_offset / hdr->d.sector_size; if (params->flags & CRYPT_TCRYPT_SYSTEM_HEADER) iv_offset += crypt_dev_partition_offset(device_path(crypt_metadata_device(cd))); return iv_offset; } int TCRYPT_get_volume_key(struct crypt_device *cd, struct tcrypt_phdr *hdr, struct crypt_params_tcrypt *params, struct volume_key **vk) { struct tcrypt_algs *algs; unsigned int i, key_index; if (!hdr->d.version) { log_err(cd, _("This function is not supported without TCRYPT header load.")); return -ENOTSUP; } algs = TCRYPT_get_algs(params->cipher, params->mode); if (!algs) return -EINVAL; *vk = crypt_alloc_volume_key(params->key_size, NULL); if (!*vk) return -ENOMEM; for (i = 0, key_index = 0; i < algs->chain_count; i++) { TCRYPT_copy_key(&algs->cipher[i], algs->mode, &(*vk)->key[key_index], hdr->d.keys); key_index += algs->cipher[i].key_size; } return 0; } int TCRYPT_dump(struct crypt_device *cd, struct tcrypt_phdr *hdr, struct crypt_params_tcrypt *params) { log_std(cd, "%s header information for %s\n", hdr->d.magic[0] == 'T' ? "TCRYPT" : "VERACRYPT", device_path(crypt_metadata_device(cd))); if (hdr->d.version) { log_std(cd, "Version: \t%d\n", hdr->d.version); log_std(cd, "Driver req.:\t%x.%x\n", hdr->d.version_tc >> 8, hdr->d.version_tc & 0xFF); log_std(cd, "Sector size:\t%" PRIu32 "\n", hdr->d.sector_size); log_std(cd, "MK offset:\t%" PRIu64 "\n", hdr->d.mk_offset); log_std(cd, "PBKDF2 hash:\t%s\n", params->hash_name); } log_std(cd, "Cipher chain:\t%s\n", params->cipher); log_std(cd, "Cipher mode:\t%s\n", params->mode); log_std(cd, "MK bits: \t%zu\n", params->key_size * 8); return 0; }