static inline void bitmap_dir_entry_to_be(Qcow2BitmapDirEntry *entry) { cpu_to_be64s(&entry->bitmap_table_offset); cpu_to_be32s(&entry->bitmap_table_size); cpu_to_be32s(&entry->flags); cpu_to_be16s(&entry->name_size); cpu_to_be32s(&entry->extra_data_size); }
static void correct_endian_ret_submit(struct usbip_header_ret_submit *pdu, int send) { if (send) { cpu_to_be32s(&pdu->status); cpu_to_be32s(&pdu->actual_length); cpu_to_be32s(&pdu->start_frame); cpu_to_be32s(&pdu->error_count); } else { be32_to_cpus(&pdu->status); be32_to_cpus(&pdu->actual_length); be32_to_cpus(&pdu->start_frame); be32_to_cpus(&pdu->error_count); } }
static void correct_endian_ret_unlink(struct usbip_header_ret_unlink *pdu, int send) { if (send) cpu_to_be32s(&pdu->status); else be32_to_cpus(&pdu->status); }
static void correct_endian_cmd_submit(struct usbip_header_cmd_submit *pdu, int send) { if (send) { pdu->transfer_flags = cpu_to_be32(pdu->transfer_flags); cpu_to_be32s(&pdu->transfer_buffer_length); cpu_to_be32s(&pdu->start_frame); cpu_to_be32s(&pdu->number_of_packets); cpu_to_be32s(&pdu->interval); } else { pdu->transfer_flags = be32_to_cpu(pdu->transfer_flags); be32_to_cpus(&pdu->transfer_buffer_length); be32_to_cpus(&pdu->start_frame); be32_to_cpus(&pdu->number_of_packets); be32_to_cpus(&pdu->interval); } }
static int qcrypto_block_luks_create(QCryptoBlock *block, QCryptoBlockCreateOptions *options, QCryptoBlockInitFunc initfunc, QCryptoBlockWriteFunc writefunc, void *opaque, Error **errp) { QCryptoBlockLUKS *luks; QCryptoBlockCreateOptionsLUKS luks_opts; Error *local_err = NULL; uint8_t *masterkey = NULL; uint8_t *slotkey = NULL; uint8_t *splitkey = NULL; size_t splitkeylen = 0; size_t i; QCryptoCipher *cipher = NULL; QCryptoIVGen *ivgen = NULL; char *password; const char *cipher_alg; const char *cipher_mode; const char *ivgen_alg; const char *ivgen_hash_alg = NULL; const char *hash_alg; char *cipher_mode_spec = NULL; QCryptoCipherAlgorithm ivcipheralg = 0; uint64_t iters; memcpy(&luks_opts, &options->u.luks, sizeof(luks_opts)); if (!luks_opts.has_iter_time) { luks_opts.iter_time = 2000; } if (!luks_opts.has_cipher_alg) { luks_opts.cipher_alg = QCRYPTO_CIPHER_ALG_AES_256; } if (!luks_opts.has_cipher_mode) { luks_opts.cipher_mode = QCRYPTO_CIPHER_MODE_XTS; } if (!luks_opts.has_ivgen_alg) { luks_opts.ivgen_alg = QCRYPTO_IVGEN_ALG_PLAIN64; } if (!luks_opts.has_hash_alg) { luks_opts.hash_alg = QCRYPTO_HASH_ALG_SHA256; } if (luks_opts.ivgen_alg == QCRYPTO_IVGEN_ALG_ESSIV) { if (!luks_opts.has_ivgen_hash_alg) { luks_opts.ivgen_hash_alg = QCRYPTO_HASH_ALG_SHA256; luks_opts.has_ivgen_hash_alg = true; } } /* Note we're allowing ivgen_hash_alg to be set even for * non-essiv iv generators that don't need a hash. It will * be silently ignored, for compatibility with dm-crypt */ if (!options->u.luks.key_secret) { error_setg(errp, "Parameter 'key-secret' is required for cipher"); return -1; } password = qcrypto_secret_lookup_as_utf8(luks_opts.key_secret, errp); if (!password) { return -1; } luks = g_new0(QCryptoBlockLUKS, 1); block->opaque = luks; memcpy(luks->header.magic, qcrypto_block_luks_magic, QCRYPTO_BLOCK_LUKS_MAGIC_LEN); /* We populate the header in native endianness initially and * then convert everything to big endian just before writing * it out to disk */ luks->header.version = QCRYPTO_BLOCK_LUKS_VERSION; qcrypto_block_luks_uuid_gen(luks->header.uuid); cipher_alg = qcrypto_block_luks_cipher_alg_lookup(luks_opts.cipher_alg, errp); if (!cipher_alg) { goto error; } cipher_mode = QCryptoCipherMode_lookup[luks_opts.cipher_mode]; ivgen_alg = QCryptoIVGenAlgorithm_lookup[luks_opts.ivgen_alg]; if (luks_opts.has_ivgen_hash_alg) { ivgen_hash_alg = QCryptoHashAlgorithm_lookup[luks_opts.ivgen_hash_alg]; cipher_mode_spec = g_strdup_printf("%s-%s:%s", cipher_mode, ivgen_alg, ivgen_hash_alg); } else { cipher_mode_spec = g_strdup_printf("%s-%s", cipher_mode, ivgen_alg); } hash_alg = QCryptoHashAlgorithm_lookup[luks_opts.hash_alg]; if (strlen(cipher_alg) >= QCRYPTO_BLOCK_LUKS_CIPHER_NAME_LEN) { error_setg(errp, "Cipher name '%s' is too long for LUKS header", cipher_alg); goto error; } if (strlen(cipher_mode_spec) >= QCRYPTO_BLOCK_LUKS_CIPHER_MODE_LEN) { error_setg(errp, "Cipher mode '%s' is too long for LUKS header", cipher_mode_spec); goto error; } if (strlen(hash_alg) >= QCRYPTO_BLOCK_LUKS_HASH_SPEC_LEN) { error_setg(errp, "Hash name '%s' is too long for LUKS header", hash_alg); goto error; } if (luks_opts.ivgen_alg == QCRYPTO_IVGEN_ALG_ESSIV) { ivcipheralg = qcrypto_block_luks_essiv_cipher(luks_opts.cipher_alg, luks_opts.ivgen_hash_alg, &local_err); if (local_err) { error_propagate(errp, local_err); goto error; } } else { ivcipheralg = luks_opts.cipher_alg; } strcpy(luks->header.cipher_name, cipher_alg); strcpy(luks->header.cipher_mode, cipher_mode_spec); strcpy(luks->header.hash_spec, hash_alg); luks->header.key_bytes = qcrypto_cipher_get_key_len(luks_opts.cipher_alg); if (luks_opts.cipher_mode == QCRYPTO_CIPHER_MODE_XTS) { luks->header.key_bytes *= 2; } /* Generate the salt used for hashing the master key * with PBKDF later */ if (qcrypto_random_bytes(luks->header.master_key_salt, QCRYPTO_BLOCK_LUKS_SALT_LEN, errp) < 0) { goto error; } /* Generate random master key */ masterkey = g_new0(uint8_t, luks->header.key_bytes); if (qcrypto_random_bytes(masterkey, luks->header.key_bytes, errp) < 0) { goto error; } /* Setup the block device payload encryption objects */ block->cipher = qcrypto_cipher_new(luks_opts.cipher_alg, luks_opts.cipher_mode, masterkey, luks->header.key_bytes, errp); if (!block->cipher) { goto error; } block->kdfhash = luks_opts.hash_alg; block->niv = qcrypto_cipher_get_iv_len(luks_opts.cipher_alg, luks_opts.cipher_mode); block->ivgen = qcrypto_ivgen_new(luks_opts.ivgen_alg, ivcipheralg, luks_opts.ivgen_hash_alg, masterkey, luks->header.key_bytes, errp); if (!block->ivgen) { goto error; } /* Determine how many iterations we need to hash the master * key, in order to have 1 second of compute time used */ iters = qcrypto_pbkdf2_count_iters(luks_opts.hash_alg, masterkey, luks->header.key_bytes, luks->header.master_key_salt, QCRYPTO_BLOCK_LUKS_SALT_LEN, QCRYPTO_BLOCK_LUKS_DIGEST_LEN, &local_err); if (local_err) { error_propagate(errp, local_err); goto error; } if (iters > (ULLONG_MAX / luks_opts.iter_time)) { error_setg_errno(errp, ERANGE, "PBKDF iterations %llu too large to scale", (unsigned long long)iters); goto error; } /* iter_time was in millis, but count_iters reported for secs */ iters = iters * luks_opts.iter_time / 1000; /* Why /= 8 ? That matches cryptsetup, but there's no * explanation why they chose /= 8... Probably so that * if all 8 keyslots are active we only spend 1 second * in total time to check all keys */ iters /= 8; if (iters > UINT32_MAX) { error_setg_errno(errp, ERANGE, "PBKDF iterations %llu larger than %u", (unsigned long long)iters, UINT32_MAX); goto error; } iters = MAX(iters, QCRYPTO_BLOCK_LUKS_MIN_MASTER_KEY_ITERS); luks->header.master_key_iterations = iters; /* Hash the master key, saving the result in the LUKS * header. This hash is used when opening the encrypted * device to verify that the user password unlocked a * valid master key */ if (qcrypto_pbkdf2(luks_opts.hash_alg, masterkey, luks->header.key_bytes, luks->header.master_key_salt, QCRYPTO_BLOCK_LUKS_SALT_LEN, luks->header.master_key_iterations, luks->header.master_key_digest, QCRYPTO_BLOCK_LUKS_DIGEST_LEN, errp) < 0) { goto error; } /* Although LUKS has multiple key slots, we're just going * to use the first key slot */ splitkeylen = luks->header.key_bytes * QCRYPTO_BLOCK_LUKS_STRIPES; for (i = 0; i < QCRYPTO_BLOCK_LUKS_NUM_KEY_SLOTS; i++) { luks->header.key_slots[i].active = i == 0 ? QCRYPTO_BLOCK_LUKS_KEY_SLOT_ENABLED : QCRYPTO_BLOCK_LUKS_KEY_SLOT_DISABLED; luks->header.key_slots[i].stripes = QCRYPTO_BLOCK_LUKS_STRIPES; /* This calculation doesn't match that shown in the spec, * but instead follows the cryptsetup implementation. */ luks->header.key_slots[i].key_offset = (QCRYPTO_BLOCK_LUKS_KEY_SLOT_OFFSET / QCRYPTO_BLOCK_LUKS_SECTOR_SIZE) + (ROUND_UP(DIV_ROUND_UP(splitkeylen, QCRYPTO_BLOCK_LUKS_SECTOR_SIZE), (QCRYPTO_BLOCK_LUKS_KEY_SLOT_OFFSET / QCRYPTO_BLOCK_LUKS_SECTOR_SIZE)) * i); } if (qcrypto_random_bytes(luks->header.key_slots[0].salt, QCRYPTO_BLOCK_LUKS_SALT_LEN, errp) < 0) { goto error; } /* Again we determine how many iterations are required to * hash the user password while consuming 1 second of compute * time */ iters = qcrypto_pbkdf2_count_iters(luks_opts.hash_alg, (uint8_t *)password, strlen(password), luks->header.key_slots[0].salt, QCRYPTO_BLOCK_LUKS_SALT_LEN, luks->header.key_bytes, &local_err); if (local_err) { error_propagate(errp, local_err); goto error; } if (iters > (ULLONG_MAX / luks_opts.iter_time)) { error_setg_errno(errp, ERANGE, "PBKDF iterations %llu too large to scale", (unsigned long long)iters); goto error; } /* iter_time was in millis, but count_iters reported for secs */ iters = iters * luks_opts.iter_time / 1000; if (iters > UINT32_MAX) { error_setg_errno(errp, ERANGE, "PBKDF iterations %llu larger than %u", (unsigned long long)iters, UINT32_MAX); goto error; } luks->header.key_slots[0].iterations = MAX(iters, QCRYPTO_BLOCK_LUKS_MIN_SLOT_KEY_ITERS); /* Generate a key that we'll use to encrypt the master * key, from the user's password */ slotkey = g_new0(uint8_t, luks->header.key_bytes); if (qcrypto_pbkdf2(luks_opts.hash_alg, (uint8_t *)password, strlen(password), luks->header.key_slots[0].salt, QCRYPTO_BLOCK_LUKS_SALT_LEN, luks->header.key_slots[0].iterations, slotkey, luks->header.key_bytes, errp) < 0) { goto error; } /* Setup the encryption objects needed to encrypt the * master key material */ cipher = qcrypto_cipher_new(luks_opts.cipher_alg, luks_opts.cipher_mode, slotkey, luks->header.key_bytes, errp); if (!cipher) { goto error; } ivgen = qcrypto_ivgen_new(luks_opts.ivgen_alg, ivcipheralg, luks_opts.ivgen_hash_alg, slotkey, luks->header.key_bytes, errp); if (!ivgen) { goto error; } /* Before storing the master key, we need to vastly * increase its size, as protection against forensic * disk data recovery */ splitkey = g_new0(uint8_t, splitkeylen); if (qcrypto_afsplit_encode(luks_opts.hash_alg, luks->header.key_bytes, luks->header.key_slots[0].stripes, masterkey, splitkey, errp) < 0) { goto error; } /* Now we encrypt the split master key with the key generated * from the user's password, before storing it */ if (qcrypto_block_encrypt_helper(cipher, block->niv, ivgen, QCRYPTO_BLOCK_LUKS_SECTOR_SIZE, 0, splitkey, splitkeylen, errp) < 0) { goto error; } /* The total size of the LUKS headers is the partition header + key * slot headers, rounded up to the nearest sector, combined with * the size of each master key material region, also rounded up * to the nearest sector */ luks->header.payload_offset = (QCRYPTO_BLOCK_LUKS_KEY_SLOT_OFFSET / QCRYPTO_BLOCK_LUKS_SECTOR_SIZE) + (ROUND_UP(DIV_ROUND_UP(splitkeylen, QCRYPTO_BLOCK_LUKS_SECTOR_SIZE), (QCRYPTO_BLOCK_LUKS_KEY_SLOT_OFFSET / QCRYPTO_BLOCK_LUKS_SECTOR_SIZE)) * QCRYPTO_BLOCK_LUKS_NUM_KEY_SLOTS); block->payload_offset = luks->header.payload_offset * QCRYPTO_BLOCK_LUKS_SECTOR_SIZE; /* Reserve header space to match payload offset */ initfunc(block, block->payload_offset, opaque, &local_err); if (local_err) { error_propagate(errp, local_err); goto error; } /* Everything on disk uses Big Endian, so flip header fields * before writing them */ cpu_to_be16s(&luks->header.version); cpu_to_be32s(&luks->header.payload_offset); cpu_to_be32s(&luks->header.key_bytes); cpu_to_be32s(&luks->header.master_key_iterations); for (i = 0; i < QCRYPTO_BLOCK_LUKS_NUM_KEY_SLOTS; i++) { cpu_to_be32s(&luks->header.key_slots[i].active); cpu_to_be32s(&luks->header.key_slots[i].iterations); cpu_to_be32s(&luks->header.key_slots[i].key_offset); cpu_to_be32s(&luks->header.key_slots[i].stripes); } /* Write out the partition header and key slot headers */ writefunc(block, 0, (const uint8_t *)&luks->header, sizeof(luks->header), opaque, &local_err); /* Delay checking local_err until we've byte-swapped */ /* Byte swap the header back to native, in case we need * to read it again later */ be16_to_cpus(&luks->header.version); be32_to_cpus(&luks->header.payload_offset); be32_to_cpus(&luks->header.key_bytes); be32_to_cpus(&luks->header.master_key_iterations); for (i = 0; i < QCRYPTO_BLOCK_LUKS_NUM_KEY_SLOTS; i++) { be32_to_cpus(&luks->header.key_slots[i].active); be32_to_cpus(&luks->header.key_slots[i].iterations); be32_to_cpus(&luks->header.key_slots[i].key_offset); be32_to_cpus(&luks->header.key_slots[i].stripes); } if (local_err) { error_propagate(errp, local_err); goto error; } /* Write out the master key material, starting at the * sector immediately following the partition header. */ if (writefunc(block, luks->header.key_slots[0].key_offset * QCRYPTO_BLOCK_LUKS_SECTOR_SIZE, splitkey, splitkeylen, opaque, errp) != splitkeylen) { goto error; } luks->cipher_alg = luks_opts.cipher_alg; luks->cipher_mode = luks_opts.cipher_mode; luks->ivgen_alg = luks_opts.ivgen_alg; luks->ivgen_hash_alg = luks_opts.ivgen_hash_alg; luks->hash_alg = luks_opts.hash_alg; memset(masterkey, 0, luks->header.key_bytes); g_free(masterkey); memset(slotkey, 0, luks->header.key_bytes); g_free(slotkey); g_free(splitkey); g_free(password); g_free(cipher_mode_spec); qcrypto_ivgen_free(ivgen); qcrypto_cipher_free(cipher); return 0; error: if (masterkey) { memset(masterkey, 0, luks->header.key_bytes); } g_free(masterkey); if (slotkey) { memset(slotkey, 0, luks->header.key_bytes); } g_free(slotkey); g_free(splitkey); g_free(password); g_free(cipher_mode_spec); qcrypto_ivgen_free(ivgen); qcrypto_cipher_free(cipher); g_free(luks); return -1; }