/* * BITLK (BitLocker-compatible) volume handling * * Copyright (C) 2019-2023 Red Hat, Inc. All rights reserved. * Copyright (C) 2019-2023 Milan Broz * Copyright (C) 2019-2023 Vojtech Trefny * * 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 "bitlk.h" #include "internal.h" #define BITLK_BOOTCODE_V1 "\xeb\x52\x90" #define BITLK_BOOTCODE_V2 "\xeb\x58\x90" #define BITLK_SIGNATURE "-FVE-FS-" #define BITLK_SIGNATURE_TOGO "MSWIN4.1" #define BITLK_HEADER_METADATA_OFFSET 160 #define BITLK_HEADER_METADATA_OFFSET_TOGO 424 /* FVE metadata header is split into two parts */ #define BITLK_FVE_METADATA_BLOCK_HEADER_LEN 64 #define BITLK_FVE_METADATA_HEADER_LEN 48 #define BITLK_FVE_METADATA_HEADERS_LEN BITLK_FVE_METADATA_BLOCK_HEADER_LEN + BITLK_FVE_METADATA_HEADER_LEN /* total size of the FVE area (64 KiB) */ #define BITLK_FVE_METADATA_SIZE 64 * 1024 #define BITLK_ENTRY_HEADER_LEN 8 #define BITLK_VMK_HEADER_LEN 28 #define BITLK_OPEN_KEY_METADATA_LEN 12 #define BITLK_RECOVERY_KEY_LEN 55 #define BITLK_RECOVERY_PARTS 8 #define BITLK_RECOVERY_PART_LEN 6 #define BITLK_BEK_FILE_HEADER_LEN 48 #define BITLK_STARTUP_KEY_HEADER_LEN 24 #define BITLK_KDF_HASH "sha256" #define BITLK_KDF_ITERATION_COUNT 0x100000 /* maximum number of segments for the DM device */ #define MAX_BITLK_SEGMENTS 10 /* January 1, 1970 as MS file time */ #define EPOCH_AS_FILETIME 116444736000000000 #define HUNDREDS_OF_NANOSECONDS 10000000 /* not available in older version of libuuid */ #ifndef UUID_STR_LEN #define UUID_STR_LEN 37 #endif /* known types of GUIDs from the BITLK superblock */ const uint8_t BITLK_GUID_NORMAL[16] = { 0x3b, 0xd6, 0x67, 0x49, 0x29, 0x2e, 0xd8, 0x4a, 0x83, 0x99, 0xf6, 0xa3, 0x39, 0xe3, 0xd0, 0x01 }; const uint8_t BITLK_GUID_EOW[16] = { 0x3b, 0x4d, 0xa8, 0x92, 0x80, 0xdd, 0x0e, 0x4d, 0x9e, 0x4e, 0xb1, 0xe3, 0x28, 0x4e, 0xae, 0xd8 }; /* taken from libfdisk gpt.c -- TODO: this is a good candidate for adding to libuuid */ struct bitlk_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]; } __attribute__ ((packed)); static void swap_guid(struct bitlk_guid *guid) { guid->time_low = swab32(guid->time_low); guid->time_mid = swab16(guid->time_mid); guid->time_hi_and_version = swab16(guid->time_hi_and_version); } static void guid_to_string(struct bitlk_guid *guid, char *out) { swap_guid(guid); uuid_unparse((unsigned char *) guid, out); } typedef enum { BITLK_SEGTYPE_CRYPT, BITLK_SEGTYPE_ZERO, } BitlkSegmentType; struct segment { uint64_t offset; uint64_t length; uint64_t iv_offset; BitlkSegmentType type; }; struct bitlk_signature { uint8_t boot_code[3]; uint8_t signature[8]; uint16_t sector_size; } __attribute__ ((packed)); struct bitlk_superblock { struct bitlk_guid guid; uint64_t fve_offset[3]; } __attribute__ ((packed)); struct bitlk_fve_metadata { /* FVE metadata block header */ uint8_t signature[8]; uint16_t fve_size; uint16_t fve_version; uint16_t curr_state; uint16_t next_state; uint64_t volume_size; uint32_t unknown2; uint32_t volume_header_size; uint64_t fve_offset[3]; uint64_t volume_header_offset; /* FVE metadata header */ uint32_t metadata_size; uint32_t metadata_version; uint32_t metadata_header_size; uint32_t metada_size_copy; struct bitlk_guid guid; uint32_t next_nonce; uint16_t encryption; uint16_t unknown3; uint64_t creation_time; } __attribute__ ((packed)); struct bitlk_entry_header_block { uint64_t offset; uint64_t size; } __attribute__ ((packed)); struct bitlk_entry_vmk { struct bitlk_guid guid; uint8_t modified[8]; uint16_t _unknown; uint16_t protection; } __attribute__ ((packed)); struct bitlk_kdf_data { char last_sha256[32]; char initial_sha256[32]; char salt[16]; uint64_t count; }; struct bitlk_bek_header { uint32_t metadata_size; uint32_t metadata_version; uint32_t metadata_header_size; uint32_t metada_size_copy; struct bitlk_guid guid; uint32_t next_nonce; uint16_t encryption; uint16_t unknown; uint64_t creation_time; } __attribute__ ((packed)); static BITLKVMKProtection get_vmk_protection(uint16_t protection) { switch (protection) { case 0x0000: return BITLK_PROTECTION_CLEAR_KEY; case 0x0100: return BITLK_PROTECTION_TPM; case 0x0200: return BITLK_PROTECTION_STARTUP_KEY; case 0x0500: return BITLK_PROTECTION_TPM_PIN; case 0x0800: return BITLK_PROTECTION_RECOVERY_PASSPHRASE; case 0x1000: return BITLK_PROTECTION_SMART_CARD; case 0x2000: return BITLK_PROTECTION_PASSPHRASE; default: return BITLK_PROTECTION_UNKNOWN; } } static const char* get_vmk_protection_string(BITLKVMKProtection protection) { switch (protection) { case BITLK_PROTECTION_CLEAR_KEY: return "VMK protected with clear key"; case BITLK_PROTECTION_TPM: return "VMK protected with TPM"; case BITLK_PROTECTION_STARTUP_KEY: return "VMK protected with startup key"; case BITLK_PROTECTION_TPM_PIN: return "VMK protected with TPM and PIN"; case BITLK_PROTECTION_PASSPHRASE: return "VMK protected with passphrase"; case BITLK_PROTECTION_RECOVERY_PASSPHRASE: return "VMK protected with recovery passphrase"; case BITLK_PROTECTION_SMART_CARD: return "VMK protected with smart card"; default: return "VMK with unknown protection"; } } static const char* get_bitlk_type_string(BITLKEncryptionType type) { switch (type) { case BITLK_ENCRYPTION_TYPE_NORMAL: return "normal"; case BITLK_ENCRYPTION_TYPE_EOW: return "encrypt-on-write"; default: return "unknown"; } } static uint64_t filetime_to_unixtime(uint64_t time) { return (time - EPOCH_AS_FILETIME) / HUNDREDS_OF_NANOSECONDS; } static int parse_vmk_entry(struct crypt_device *cd, uint8_t *data, int start, int end, struct bitlk_vmk **vmk) { uint16_t key_entry_size = 0; uint16_t key_entry_type = 0; uint16_t key_entry_value = 0; size_t key_size = 0; char *string = NULL; const char *key = NULL; struct volume_key *vk = NULL; bool supported = false; int r = 0; /* only passphrase or recovery passphrase vmks are supported (can be used to activate) */ supported = (*vmk)->protection == BITLK_PROTECTION_PASSPHRASE || (*vmk)->protection == BITLK_PROTECTION_RECOVERY_PASSPHRASE || (*vmk)->protection == BITLK_PROTECTION_STARTUP_KEY; while ((end - start) >= (ssize_t)(sizeof(key_entry_size) + sizeof(key_entry_type) + sizeof(key_entry_value))) { /* size of this entry */ memcpy(&key_entry_size, data + start, sizeof(key_entry_size)); key_entry_size = le16_to_cpu(key_entry_size); if (key_entry_size == 0) break; if (key_entry_size > (end - start)) return -EINVAL; /* type and value of this entry */ memcpy(&key_entry_type, data + start + sizeof(key_entry_size), sizeof(key_entry_type)); memcpy(&key_entry_value, data + start + sizeof(key_entry_size) + sizeof(key_entry_type), sizeof(key_entry_value)); key_entry_type = le16_to_cpu(key_entry_type); key_entry_value = le16_to_cpu(key_entry_value); if (key_entry_type != BITLK_ENTRY_TYPE_PROPERTY) { if (supported) { log_err(cd, _("Unexpected metadata entry type '%u' found when parsing supported Volume Master Key."), key_entry_type); return -EINVAL; } else { log_dbg(cd, "Unexpected metadata entry type '%u' found when parsing unsupported VMK.", key_entry_type); } } /* stretch key with salt, skip 4 B (encryption method of the stretch key) */ if (key_entry_value == BITLK_ENTRY_VALUE_STRETCH_KEY) { if ((end - start) < (BITLK_ENTRY_HEADER_LEN + BITLK_SALT_SIZE + 4)) return -EINVAL; memcpy((*vmk)->salt, data + start + BITLK_ENTRY_HEADER_LEN + 4, BITLK_SALT_SIZE); /* AES-CCM encrypted key */ } else if (key_entry_value == BITLK_ENTRY_VALUE_ENCRYPTED_KEY) { if (key_entry_size < (BITLK_ENTRY_HEADER_LEN + BITLK_NONCE_SIZE + BITLK_VMK_MAC_TAG_SIZE)) return -EINVAL; /* nonce */ memcpy((*vmk)->nonce, data + start + BITLK_ENTRY_HEADER_LEN, BITLK_NONCE_SIZE); /* MAC tag */ memcpy((*vmk)->mac_tag, data + start + BITLK_ENTRY_HEADER_LEN + BITLK_NONCE_SIZE, BITLK_VMK_MAC_TAG_SIZE); /* AES-CCM encrypted key */ key_size = key_entry_size - (BITLK_ENTRY_HEADER_LEN + BITLK_NONCE_SIZE + BITLK_VMK_MAC_TAG_SIZE); key = (const char *) data + start + BITLK_ENTRY_HEADER_LEN + BITLK_NONCE_SIZE + BITLK_VMK_MAC_TAG_SIZE; vk = crypt_alloc_volume_key(key_size, key); if (vk == NULL) return -ENOMEM; crypt_volume_key_add_next(&((*vmk)->vk), vk); /* clear key for a partially decrypted volume */ } else if (key_entry_value == BITLK_ENTRY_VALUE_KEY) { /* We currently don't want to support opening a partially decrypted * device so we don't need to store this key. * * key_size = key_entry_size - (BITLK_ENTRY_HEADER_LEN + 4); * key = (const char *) data + start + BITLK_ENTRY_HEADER_LEN + 4; * vk = crypt_alloc_volume_key(key_size, key); * if (vk == NULL) * return -ENOMEM; * crypt_volume_key_add_next(&((*vmk)->vk), vk); */ log_dbg(cd, "Skipping clear key metadata entry."); /* unknown timestamps in recovery protected VMK */ } else if (key_entry_value == BITLK_ENTRY_VALUE_RECOVERY_TIME) { ; } else if (key_entry_value == BITLK_ENTRY_VALUE_STRING) { if (key_entry_size < BITLK_ENTRY_HEADER_LEN) return -EINVAL; string = malloc((key_entry_size - BITLK_ENTRY_HEADER_LEN) * 2 + 1); if (!string) return -ENOMEM; r = crypt_utf16_to_utf8(&string, CONST_CAST(char16_t *)(data + start + BITLK_ENTRY_HEADER_LEN), key_entry_size - BITLK_ENTRY_HEADER_LEN); if (r < 0 || !string) { free(string); log_err(cd, _("Invalid string found when parsing Volume Master Key.")); return -EINVAL; } else if ((*vmk)->name != NULL) { if (supported) { log_err(cd, _("Unexpected string ('%s') found when parsing supported Volume Master Key."), string); free(string); return -EINVAL; } log_dbg(cd, "Unexpected string ('%s') found when parsing unsupported VMK.", string); free(string); string = NULL; } else { /* Assume that strings in VMK are the name of the VMK */ (*vmk)->name = string; string = NULL; } /* no idea what this is, lets hope it's not important */ } else if (key_entry_value == BITLK_ENTRY_VALUE_USE_KEY && (*vmk)->protection == BITLK_PROTECTION_STARTUP_KEY) { ; } else { if (supported) { log_err(cd, _("Unexpected metadata entry value '%u' found when parsing supported Volume Master Key."), key_entry_value); return -EINVAL; } else { log_dbg(cd, "Unexpected metadata entry value '%u' found when parsing unsupported VMK.", key_entry_value); } } start += key_entry_size; } return 0; } void BITLK_bitlk_fvek_free(struct bitlk_fvek *fvek) { if (!fvek) return; crypt_free_volume_key(fvek->vk); free(fvek); } void BITLK_bitlk_vmk_free(struct bitlk_vmk *vmk) { struct bitlk_vmk *vmk_next = NULL; while (vmk) { if (vmk->guid) free(vmk->guid); if (vmk->name) free(vmk->name); crypt_free_volume_key(vmk->vk); vmk_next = vmk->next; free(vmk); vmk = vmk_next; } } void BITLK_bitlk_metadata_free(struct bitlk_metadata *metadata) { if (!metadata) return; free(metadata->guid); if (metadata->description) free(metadata->description); BITLK_bitlk_vmk_free(metadata->vmks); BITLK_bitlk_fvek_free(metadata->fvek); } int BITLK_read_sb(struct crypt_device *cd, struct bitlk_metadata *params) { int devfd; struct device *device = crypt_metadata_device(cd); struct bitlk_signature sig = {}; struct bitlk_superblock sb = {}; struct bitlk_fve_metadata fve = {}; struct bitlk_entry_vmk entry_vmk = {}; uint8_t *fve_entries = NULL; size_t fve_entries_size = 0; uint32_t fve_metadata_size = 0; int fve_offset = 0; char guid_buf[UUID_STR_LEN] = {0}; uint16_t entry_size = 0; uint16_t entry_type = 0; int i = 0; int r = 0; int start = 0; size_t key_size = 0; const char *key = NULL; char *description = NULL; struct bitlk_vmk *vmk = NULL; struct bitlk_vmk *vmk_p = params->vmks; devfd = device_open(cd, crypt_data_device(cd), O_RDONLY); if (devfd < 0) { r = -EINVAL; goto out; } /* read and check the signature */ if (read_lseek_blockwise(devfd, device_block_size(cd, device), device_alignment(device), &sig, sizeof(sig), 0) != sizeof(sig)) { log_dbg(cd, "Failed to read BITLK signature from %s.", device_path(device)); r = -EIO; goto out; } if (memcmp(sig.signature, BITLK_SIGNATURE, sizeof(sig.signature)) == 0) { params->togo = false; fve_offset = BITLK_HEADER_METADATA_OFFSET; } else if (memcmp(sig.signature, BITLK_SIGNATURE_TOGO, sizeof(sig.signature)) == 0) { params->togo = true; fve_offset = BITLK_HEADER_METADATA_OFFSET_TOGO; } else { log_dbg(cd, "Invalid or unknown signature for BITLK device."); r = -EINVAL; goto out; } if (memcmp(sig.boot_code, BITLK_BOOTCODE_V1, sizeof(sig.boot_code)) == 0) { log_err(cd, _("BITLK version 1 is currently not supported.")); r = -ENOTSUP; goto out; } else if (memcmp(sig.boot_code, BITLK_BOOTCODE_V2, sizeof(sig.boot_code)) == 0) ; else { log_err(cd, _("Invalid or unknown boot signature for BITLK device.")); r = -EINVAL; goto out; } params->sector_size = le16_to_cpu(sig.sector_size); if (params->sector_size == 0) { log_dbg(cd, "Got sector size 0, assuming 512."); params->sector_size = SECTOR_SIZE; } if (!(params->sector_size == 512 || params->sector_size == 4096)) { log_err(cd, _("Unsupported sector size %" PRIu16 "."), params->sector_size); r = -EINVAL; goto out; } /* read GUID and FVE metadata offsets */ if (read_lseek_blockwise(devfd, device_block_size(cd, device), device_alignment(device), &sb, sizeof(sb), fve_offset) != sizeof(sb)) { log_err(cd, _("Failed to read BITLK header from %s."), device_path(device)); r = -EINVAL; goto out; } /* get encryption "type" based on the GUID from BITLK superblock */ if (memcmp(&sb.guid, BITLK_GUID_NORMAL, 16) == 0) params->type = BITLK_ENCRYPTION_TYPE_NORMAL; else if (memcmp(&sb.guid, BITLK_GUID_EOW, 16) == 0) params->type = BITLK_ENCRYPTION_TYPE_EOW; else params->type = BITLK_ENCRYPTION_TYPE_UNKNOWN; log_dbg(cd, "BITLK type from GUID: %s.", get_bitlk_type_string(params->type)); for (i = 0; i < 3; i++) params->metadata_offset[i] = le64_to_cpu(sb.fve_offset[i]); log_dbg(cd, "Reading BITLK FVE metadata of size %zu on device %s, offset %" PRIu64 ".", sizeof(fve), device_path(device), params->metadata_offset[0]); /* read FVE metadata from the first metadata area */ if (read_lseek_blockwise(devfd, device_block_size(cd, device), device_alignment(device), &fve, sizeof(fve), params->metadata_offset[0]) != sizeof(fve) || memcmp(fve.signature, BITLK_SIGNATURE, sizeof(fve.signature)) || le16_to_cpu(fve.fve_version) != 2) { log_err(cd, _("Failed to read BITLK FVE metadata from %s."), device_path(device)); r = -EINVAL; goto out; } /* check encryption state for the device */ params->state = true; if (le16_to_cpu(fve.curr_state) != BITLK_STATE_NORMAL || le16_to_cpu(fve.next_state) != BITLK_STATE_NORMAL) { params->state = false; log_dbg(cd, "Unknown/unsupported state detected. Current state: %"PRIu16", next state: %"PRIu16".", le16_to_cpu(fve.curr_state), le16_to_cpu(fve.next_state)); } params->volume_size = le64_to_cpu(fve.volume_size); params->metadata_version = le16_to_cpu(fve.fve_version); switch (le16_to_cpu(fve.encryption)) { /* AES-CBC with Elephant difuser */ case 0x8000: params->key_size = 256; params->cipher = "aes"; params->cipher_mode = "cbc-elephant"; break; case 0x8001: params->key_size = 512; params->cipher = "aes"; params->cipher_mode = "cbc-elephant"; break; /* AES-CBC */ case 0x8002: params->key_size = 128; params->cipher = "aes"; params->cipher_mode = "cbc-eboiv"; break; case 0x8003: params->key_size = 256; params->cipher = "aes"; params->cipher_mode = "cbc-eboiv"; break; /* AES-XTS */ case 0x8004: params->key_size = 256; params->cipher = "aes"; params->cipher_mode = "xts-plain64"; break; case 0x8005: params->key_size = 512; params->cipher = "aes"; params->cipher_mode = "xts-plain64"; break; default: log_err(cd, _("Unknown or unsupported encryption type.")); params->key_size = 0; params->cipher = NULL; params->cipher_mode = NULL; r = -ENOTSUP; goto out; }; /* device GUID */ guid_to_string(&fve.guid, guid_buf); params->guid = strdup(guid_buf); if (!params->guid) { r = -ENOMEM; goto out; } params->creation_time = filetime_to_unixtime(le64_to_cpu(fve.creation_time)); fve_metadata_size = le32_to_cpu(fve.metadata_size); if (fve_metadata_size < (BITLK_FVE_METADATA_HEADER_LEN + sizeof(entry_size) + sizeof(entry_type)) || fve_metadata_size > BITLK_FVE_METADATA_SIZE) { r = -EINVAL; goto out; } fve_entries_size = fve_metadata_size - BITLK_FVE_METADATA_HEADER_LEN; /* read and parse all FVE metadata entries */ fve_entries = malloc(fve_entries_size); if (!fve_entries) { r = -ENOMEM; goto out; } memset(fve_entries, 0, fve_entries_size); log_dbg(cd, "Reading BITLK FVE metadata entries of size %zu on device %s, offset %" PRIu64 ".", fve_entries_size, device_path(device), params->metadata_offset[0] + BITLK_FVE_METADATA_HEADERS_LEN); if (read_lseek_blockwise(devfd, device_block_size(cd, device), device_alignment(device), fve_entries, fve_entries_size, params->metadata_offset[0] + BITLK_FVE_METADATA_HEADERS_LEN) != (ssize_t)fve_entries_size) { log_err(cd, _("Failed to read BITLK metadata entries from %s."), device_path(device)); r = -EINVAL; goto out; } while ((fve_entries_size - start) >= (sizeof(entry_size) + sizeof(entry_type))) { /* size of this entry */ memcpy(&entry_size, fve_entries + start, sizeof(entry_size)); entry_size = le16_to_cpu(entry_size); if (entry_size == 0) break; if (entry_size > (fve_entries_size - start)) { r = -EINVAL; goto out; } /* type of this entry */ memcpy(&entry_type, fve_entries + start + sizeof(entry_size), sizeof(entry_type)); entry_type = le16_to_cpu(entry_type); /* VMK */ if (entry_type == BITLK_ENTRY_TYPE_VMK) { if (entry_size < (BITLK_ENTRY_HEADER_LEN + sizeof(entry_vmk))) { r = -EINVAL; goto out; } /* skip first four variables in the entry (entry size, type, value and version) */ memcpy(&entry_vmk, fve_entries + start + BITLK_ENTRY_HEADER_LEN, sizeof(entry_vmk)); vmk = malloc(sizeof(struct bitlk_vmk)); if (!vmk) { r = -ENOMEM; goto out; } memset(vmk, 0, sizeof(struct bitlk_vmk)); guid_to_string(&entry_vmk.guid, guid_buf); vmk->guid = strdup (guid_buf); vmk->name = NULL; vmk->protection = get_vmk_protection(le16_to_cpu(entry_vmk.protection)); /* more data in another entry list */ r = parse_vmk_entry(cd, fve_entries, start + BITLK_ENTRY_HEADER_LEN + BITLK_VMK_HEADER_LEN, start + entry_size, &vmk); if (r < 0) { BITLK_bitlk_vmk_free(vmk); goto out; } if (params->vmks == NULL) params->vmks = vmk; else vmk_p->next = vmk; vmk_p = vmk; vmk = vmk->next; /* FVEK */ } else if (entry_type == BITLK_ENTRY_TYPE_FVEK && !params->fvek) { if (entry_size < (BITLK_ENTRY_HEADER_LEN + BITLK_NONCE_SIZE + BITLK_VMK_MAC_TAG_SIZE)) { r = -EINVAL; goto out; } params->fvek = malloc(sizeof(struct bitlk_fvek)); if (!params->fvek) { r = -ENOMEM; goto out; } memcpy(params->fvek->nonce, fve_entries + start + BITLK_ENTRY_HEADER_LEN, BITLK_NONCE_SIZE); /* MAC tag */ memcpy(params->fvek->mac_tag, fve_entries + start + BITLK_ENTRY_HEADER_LEN + BITLK_NONCE_SIZE, BITLK_VMK_MAC_TAG_SIZE); /* AES-CCM encrypted key */ key_size = entry_size - (BITLK_ENTRY_HEADER_LEN + BITLK_NONCE_SIZE + BITLK_VMK_MAC_TAG_SIZE); key = (const char *) fve_entries + start + BITLK_ENTRY_HEADER_LEN + BITLK_NONCE_SIZE + BITLK_VMK_MAC_TAG_SIZE; params->fvek->vk = crypt_alloc_volume_key(key_size, key); if (params->fvek->vk == NULL) { r = -ENOMEM; goto out; } /* volume header info (location and size) */ } else if (entry_type == BITLK_ENTRY_TYPE_VOLUME_HEADER) { struct bitlk_entry_header_block entry_header; if ((fve_entries_size - start) < (BITLK_ENTRY_HEADER_LEN + sizeof(entry_header))) { r = -EINVAL; goto out; } memcpy(&entry_header, fve_entries + start + BITLK_ENTRY_HEADER_LEN, sizeof(entry_header)); params->volume_header_offset = le64_to_cpu(entry_header.offset); params->volume_header_size = le64_to_cpu(entry_header.size); /* volume description (utf-16 string) */ } else if (entry_type == BITLK_ENTRY_TYPE_DESCRIPTION && !params->description) { if (entry_size < BITLK_ENTRY_HEADER_LEN) { r = -EINVAL; goto out; } description = malloc((entry_size - BITLK_ENTRY_HEADER_LEN) * 2 + 1); if (!description) { r = -ENOMEM; goto out; } r = crypt_utf16_to_utf8(&description, CONST_CAST(char16_t *)(fve_entries + start + BITLK_ENTRY_HEADER_LEN), entry_size - BITLK_ENTRY_HEADER_LEN); if (r < 0) { free(description); BITLK_bitlk_vmk_free(vmk); log_err(cd, _("Failed to convert BITLK volume description")); goto out; } params->description = description; } start += entry_size; } out: if (fve_entries) free(fve_entries); return r; } int BITLK_dump(struct crypt_device *cd, struct device *device, struct bitlk_metadata *params) { struct volume_key *vk_p; struct bitlk_vmk *vmk_p; int next_id = 0; int i = 0; log_std(cd, "Info for BITLK%s device %s.\n", params->togo ? " To Go" : "", device_path(device)); log_std(cd, "Version: \t%u\n", params->metadata_version); log_std(cd, "GUID: \t%s\n", params->guid); log_std(cd, "Sector size: \t%u [bytes]\n", params->sector_size); log_std(cd, "Volume size: \t%" PRIu64 " [bytes]\n", params->volume_size); log_std(cd, "Created: \t%s", ctime((time_t *)&(params->creation_time))); log_std(cd, "Description: \t%s\n", params->description); log_std(cd, "Cipher name: \t%s\n", params->cipher); log_std(cd, "Cipher mode: \t%s\n", params->cipher_mode); log_std(cd, "Cipher key: \t%u bits\n", params->key_size); log_std(cd, "\n"); log_std(cd, "Keyslots:\n"); vmk_p = params->vmks; while (vmk_p) { log_std(cd, " %d: VMK\n", next_id); if (vmk_p->name != NULL) { log_std(cd, "\tName: \t%s\n", vmk_p->name); } log_std(cd, "\tGUID: \t%s\n", vmk_p->guid); log_std(cd, "\tProtection: \t%s\n", get_vmk_protection_string (vmk_p->protection)); log_std(cd, "\tSalt: \t"); crypt_log_hex(cd, (const char *) vmk_p->salt, 16, "", 0, NULL); log_std(cd, "\n"); vk_p = vmk_p->vk; while (vk_p) { log_std(cd, "\tKey data size:\t%zu [bytes]\n", vk_p->keylength); vk_p = vk_p->next; } vmk_p = vmk_p->next; next_id++; } log_std(cd, " %d: FVEK\n", next_id); log_std(cd, "\tKey data size:\t%zu [bytes]\n", params->fvek->vk->keylength); log_std(cd, "\n"); log_std(cd, "Metadata segments:\n"); for (i = 0; i < 3; i++) { log_std(cd, " %d: FVE metadata area\n", i); log_std(cd, "\tOffset: \t%" PRIu64 " [bytes]\n", params->metadata_offset[i]); log_std(cd, "\tSize: \t%d [bytes]\n", BITLK_FVE_METADATA_SIZE); } log_std(cd, " %d: Volume header\n", i); log_std(cd, "\tOffset: \t%" PRIu64 " [bytes]\n", params->volume_header_offset); log_std(cd, "\tSize: \t%" PRIu64 " [bytes]\n", params->volume_header_size); log_std(cd, "\tCipher: \t%s-%s\n", params->cipher, params->cipher_mode); return 0; } /* check if given passphrase can be a recovery key (has right format) and convert it */ static int get_recovery_key(struct crypt_device *cd, const char *password, size_t passwordLen, struct volume_key **rc_key) { unsigned int i, j = 0; uint16_t parts[BITLK_RECOVERY_PARTS] = {0}; char part_str[BITLK_RECOVERY_PART_LEN + 1] = {0}; long part_num = 0; /* check the passphrase it should be: - 55 characters - 8 groups of 6 divided by '-' - each part is a number dividable by 11 */ if (passwordLen != BITLK_RECOVERY_KEY_LEN) { if (passwordLen == BITLK_RECOVERY_KEY_LEN + 1 && password[passwordLen - 1] == '\n') { /* looks like a recovery key with an extra newline, possibly from a key file */ passwordLen--; log_dbg(cd, "Possible extra EOL stripped from the recovery key."); } else return 0; } for (i = BITLK_RECOVERY_PART_LEN; i < passwordLen; i += BITLK_RECOVERY_PART_LEN + 1) { if (password[i] != '-') return 0; } for (i = 0, j = 0; i < passwordLen; i += BITLK_RECOVERY_PART_LEN + 1, j++) { strncpy(part_str, password + i, BITLK_RECOVERY_PART_LEN); errno = 0; part_num = strtol(part_str, NULL, 10); if ((errno == ERANGE && (part_num == LONG_MAX || part_num == LONG_MIN)) || (errno != 0 && part_num == 0)) return -errno; if (part_num % 11 != 0) return 0; parts[j] = cpu_to_le16(part_num / 11); } *rc_key = crypt_alloc_volume_key(16, (const char*) parts); if (*rc_key == NULL) return -ENOMEM; return 0; } static int parse_external_key_entry(struct crypt_device *cd, const char *data, int start, int end, struct volume_key **vk, const struct bitlk_metadata *params) { uint16_t key_entry_size = 0; uint16_t key_entry_type = 0; uint16_t key_entry_value = 0; size_t key_size = 0; const char *key = NULL; struct bitlk_guid guid; char guid_buf[UUID_STR_LEN] = {0}; while ((end - start) >= (ssize_t)(sizeof(key_entry_size) + sizeof(key_entry_type) + sizeof(key_entry_value))) { /* size of this entry */ memcpy(&key_entry_size, data + start, sizeof(key_entry_size)); key_entry_size = le16_to_cpu(key_entry_size); if (key_entry_size == 0) break; if (key_entry_size > (end - start)) return -EINVAL; /* type and value of this entry */ memcpy(&key_entry_type, data + start + sizeof(key_entry_size), sizeof(key_entry_type)); memcpy(&key_entry_value, data + start + sizeof(key_entry_size) + sizeof(key_entry_type), sizeof(key_entry_value)); key_entry_type = le16_to_cpu(key_entry_type); key_entry_value = le16_to_cpu(key_entry_value); if (key_entry_type != BITLK_ENTRY_TYPE_PROPERTY && key_entry_type != BITLK_ENTRY_TYPE_VOLUME_GUID) { log_err(cd, _("Unexpected metadata entry type '%u' found when parsing external key."), key_entry_type); return -EINVAL; } if (key_entry_value == BITLK_ENTRY_VALUE_KEY) { if (key_entry_size < (BITLK_ENTRY_HEADER_LEN + 4)) return -EINVAL; key_size = key_entry_size - (BITLK_ENTRY_HEADER_LEN + 4); key = (const char *) data + start + BITLK_ENTRY_HEADER_LEN + 4; *vk = crypt_alloc_volume_key(key_size, key); if (*vk == NULL) return -ENOMEM; return 0; /* optional "ExternalKey" string, we can safely ignore it */ } else if (key_entry_value == BITLK_ENTRY_VALUE_STRING) ; /* GUID of the BitLocker device we are trying to open with this key */ else if (key_entry_value == BITLK_ENTRY_VALUE_GUID) { if ((end - start) < (ssize_t)(BITLK_ENTRY_HEADER_LEN + sizeof(struct bitlk_guid))) return -EINVAL; memcpy(&guid, data + start + BITLK_ENTRY_HEADER_LEN, sizeof(struct bitlk_guid)); guid_to_string(&guid, guid_buf); if (strcmp(guid_buf, params->guid) != 0) { log_err(cd, _("BEK file GUID '%s' does not match GUID of the volume."), guid_buf); return -EINVAL; } } else { log_err(cd, _("Unexpected metadata entry value '%u' found when parsing external key."), key_entry_value); return -EINVAL; } start += key_entry_size; } /* if we got here we failed to parse the metadata */ return -EINVAL; } /* check if given passphrase can be a startup key (has right format) and convert it */ static int get_startup_key(struct crypt_device *cd, const char *password, size_t passwordLen, const struct bitlk_vmk *vmk, struct volume_key **su_key, const struct bitlk_metadata *params) { struct bitlk_bek_header bek_header = {0}; char guid_buf[UUID_STR_LEN] = {0}; uint16_t key_entry_size = 0; uint16_t key_entry_type = 0; uint16_t key_entry_value = 0; if (passwordLen < (BITLK_BEK_FILE_HEADER_LEN + sizeof(key_entry_size) + sizeof(key_entry_type) + sizeof(key_entry_value))) return -EPERM; memcpy(&bek_header, password, BITLK_BEK_FILE_HEADER_LEN); /* metadata should contain GUID of the VMK this startup key is used for */ guid_to_string(&bek_header.guid, guid_buf); if (strcmp(guid_buf, vmk->guid) == 0) log_dbg(cd, "Found matching startup key for VMK %s", vmk->guid); else return -EPERM; if (le32_to_cpu(bek_header.metadata_version) != 1) { log_err(cd, _("Unsupported BEK metadata version %" PRIu32), le32_to_cpu(bek_header.metadata_version)); return -ENOTSUP; } if (le32_to_cpu(bek_header.metadata_size) != passwordLen) { log_err(cd, _("Unexpected BEK metadata size %" PRIu32 " does not match BEK file length"), le32_to_cpu(bek_header.metadata_size)); return -EINVAL; } /* we are expecting exactly one metadata entry starting immediately after the header */ memcpy(&key_entry_size, password + BITLK_BEK_FILE_HEADER_LEN, sizeof(key_entry_size)); key_entry_size = le16_to_cpu(key_entry_size); if (key_entry_size < BITLK_ENTRY_HEADER_LEN) { log_dbg(cd, "Unexpected metadata entry size %" PRIu16 " when parsing BEK file", key_entry_size); return -EINVAL; } /* type and value of this entry */ memcpy(&key_entry_type, password + BITLK_BEK_FILE_HEADER_LEN + sizeof(key_entry_size), sizeof(key_entry_type)); memcpy(&key_entry_value, password + BITLK_BEK_FILE_HEADER_LEN + sizeof(key_entry_size) + sizeof(key_entry_type), sizeof(key_entry_value)); key_entry_type = le16_to_cpu(key_entry_type); key_entry_value = le16_to_cpu(key_entry_value); if (key_entry_type == BITLK_ENTRY_TYPE_STARTUP_KEY && key_entry_value == BITLK_ENTRY_VALUE_EXTERNAL_KEY) { return parse_external_key_entry(cd, password, BITLK_BEK_FILE_HEADER_LEN + BITLK_ENTRY_HEADER_LEN + BITLK_STARTUP_KEY_HEADER_LEN, passwordLen, su_key, params); } else { log_err(cd, _("Unexpected metadata entry found when parsing startup key.")); log_dbg(cd, "Entry type: %u, entry value: %u", key_entry_type, key_entry_value); return -EINVAL; } } static int bitlk_kdf(struct crypt_device *cd, const char *password, size_t passwordLen, bool recovery, const uint8_t *salt, struct volume_key **vk) { struct bitlk_kdf_data kdf = {}; struct crypt_hash *hd = NULL; int len = 0; char16_t *utf16Password = NULL; int i = 0; int r = 0; memcpy(kdf.salt, salt, 16); r = crypt_hash_init(&hd, BITLK_KDF_HASH); if (r < 0) return r; len = crypt_hash_size(BITLK_KDF_HASH); if (len < 0) { crypt_hash_destroy(hd); return len; } if (!recovery) { /* passphrase: convert to UTF-16 first, then sha256(sha256(pw)) */ utf16Password = crypt_safe_alloc(sizeof(char16_t) * (passwordLen + 1)); if (!utf16Password) { r = -ENOMEM; goto out; } r = crypt_utf8_to_utf16(&utf16Password, CONST_CAST(char*)password, passwordLen); if (r < 0) goto out; crypt_hash_write(hd, (char*)utf16Password, passwordLen * 2); r = crypt_hash_final(hd, kdf.initial_sha256, len); if (r < 0) goto out; crypt_hash_write(hd, kdf.initial_sha256, len); r = crypt_hash_final(hd, kdf.initial_sha256, len); if (r < 0) goto out; } else { /* recovery passphrase: already converted in #get_recovery_key, now just sha256(rpw) */ crypt_hash_write(hd, password, passwordLen); r = crypt_hash_final(hd, kdf.initial_sha256, len); if (r < 0) goto out; } for (i = 0; i < BITLK_KDF_ITERATION_COUNT; i++) { crypt_hash_write(hd, (const char*) &kdf, sizeof(kdf)); r = crypt_hash_final(hd, kdf.last_sha256, len); if (r < 0) goto out; kdf.count = cpu_to_le64(le64_to_cpu(kdf.count) + 1); } *vk = crypt_alloc_volume_key(len, kdf.last_sha256); out: crypt_safe_free(utf16Password); if (hd) crypt_hash_destroy(hd); return r; } static int decrypt_key(struct crypt_device *cd, struct volume_key **vk, struct volume_key *enc_key, struct volume_key *key, const uint8_t *tag, size_t tag_size, const uint8_t *iv, size_t iv_size, bool is_fvek) { char *outbuf; int r; uint16_t key_size = 0; outbuf = crypt_safe_alloc(enc_key->keylength); if (!outbuf) return -ENOMEM; r = crypt_bitlk_decrypt_key(key->key, key->keylength, enc_key->key, outbuf, enc_key->keylength, (const char*)iv, iv_size, (const char*)tag, tag_size); if (r < 0) { if (r == -ENOTSUP) log_err(cd, _("This operation is not supported.")); goto out; } /* key_data has it's size as part of the metadata */ memcpy(&key_size, outbuf, 2); key_size = le16_to_cpu(key_size); if (enc_key->keylength != key_size) { log_err(cd, _("Unexpected key data size.")); log_dbg(cd, "Expected key data size: %zu, got %" PRIu16 "", enc_key->keylength, key_size); r = -EINVAL; goto out; } if (is_fvek && strcmp(crypt_get_cipher_mode(cd), "cbc-elephant") == 0 && crypt_get_volume_key_size(cd) == 32) { /* 128bit AES-CBC with Elephant -- key size is 256 bit (2 keys) but key data is 512 bits, data: 16B CBC key, 16B empty, 16B elephant key, 16B empty */ memcpy(outbuf + 16 + BITLK_OPEN_KEY_METADATA_LEN, outbuf + 2 * 16 + BITLK_OPEN_KEY_METADATA_LEN, 16); key_size = 32 + BITLK_OPEN_KEY_METADATA_LEN; } *vk = crypt_alloc_volume_key(key_size - BITLK_OPEN_KEY_METADATA_LEN, (const char *)(outbuf + BITLK_OPEN_KEY_METADATA_LEN)); r = *vk ? 0 : -ENOMEM; out: crypt_safe_free(outbuf); return r; } int BITLK_get_volume_key(struct crypt_device *cd, const char *password, size_t passwordLen, const struct bitlk_metadata *params, struct volume_key **open_fvek_key) { int r = 0; struct volume_key *open_vmk_key = NULL; struct volume_key *vmk_dec_key = NULL; struct volume_key *recovery_key = NULL; const struct bitlk_vmk *next_vmk = NULL; next_vmk = params->vmks; while (next_vmk) { if (next_vmk->protection == BITLK_PROTECTION_PASSPHRASE) { r = bitlk_kdf(cd, password, passwordLen, false, next_vmk->salt, &vmk_dec_key); if (r) { /* something wrong happened, but we still want to check other key slots */ next_vmk = next_vmk->next; continue; } } else if (next_vmk->protection == BITLK_PROTECTION_RECOVERY_PASSPHRASE) { r = get_recovery_key(cd, password, passwordLen, &recovery_key); if (r) { /* something wrong happened, but we still want to check other key slots */ next_vmk = next_vmk->next; continue; } if (recovery_key == NULL) { /* r = 0 but no key -> given passphrase is not a recovery passphrase */ r = -EPERM; next_vmk = next_vmk->next; continue; } log_dbg(cd, "Trying to use given password as a recovery key."); r = bitlk_kdf(cd, recovery_key->key, recovery_key->keylength, true, next_vmk->salt, &vmk_dec_key); crypt_free_volume_key(recovery_key); if (r) return r; } else if (next_vmk->protection == BITLK_PROTECTION_STARTUP_KEY) { r = get_startup_key(cd, password, passwordLen, next_vmk, &vmk_dec_key, params); if (r) { next_vmk = next_vmk->next; continue; } log_dbg(cd, "Trying to use external key found in provided password."); } else { /* only passphrase, recovery passphrase and startup key VMKs supported right now */ log_dbg(cd, "Skipping %s", get_vmk_protection_string(next_vmk->protection)); next_vmk = next_vmk->next; if (r == 0) /* we need to set error code in case we have only unsupported VMKs */ r = -ENOTSUP; continue; } log_dbg(cd, "Trying to decrypt %s.", get_vmk_protection_string(next_vmk->protection)); r = decrypt_key(cd, &open_vmk_key, next_vmk->vk, vmk_dec_key, next_vmk->mac_tag, BITLK_VMK_MAC_TAG_SIZE, next_vmk->nonce, BITLK_NONCE_SIZE, false); if (r < 0) { log_dbg(cd, "Failed to decrypt VMK using provided passphrase."); crypt_free_volume_key(vmk_dec_key); if (r == -ENOTSUP) return r; next_vmk = next_vmk->next; continue; } crypt_free_volume_key(vmk_dec_key); r = decrypt_key(cd, open_fvek_key, params->fvek->vk, open_vmk_key, params->fvek->mac_tag, BITLK_VMK_MAC_TAG_SIZE, params->fvek->nonce, BITLK_NONCE_SIZE, true); if (r < 0) { log_dbg(cd, "Failed to decrypt FVEK using VMK."); crypt_free_volume_key(open_vmk_key); if (r == -ENOTSUP) return r; } else { crypt_free_volume_key(open_vmk_key); break; } next_vmk = next_vmk->next; } if (r) { log_dbg(cd, "No more VMKs to try."); return r; } return 0; } static int _activate_check(struct crypt_device *cd, const struct bitlk_metadata *params) { const struct bitlk_vmk *next_vmk = NULL; if (!params->state) { log_err(cd, _("This BITLK device is in an unsupported state and cannot be activated.")); return -ENOTSUP; } if (params->type != BITLK_ENCRYPTION_TYPE_NORMAL) { log_err(cd, _("BITLK devices with type '%s' cannot be activated."), get_bitlk_type_string(params->type)); return -ENOTSUP; } next_vmk = params->vmks; while (next_vmk) { if (next_vmk->protection == BITLK_PROTECTION_CLEAR_KEY) { log_err(cd, _("Activation of partially decrypted BITLK device is not supported.")); return -ENOTSUP; } next_vmk = next_vmk->next; } return 0; } static int _activate(struct crypt_device *cd, const char *name, struct volume_key *open_fvek_key, const struct bitlk_metadata *params, uint32_t flags) { int r = 0; int i = 0; int j = 0; int min = 0; int num_segments = 0; struct crypt_dm_active_device dmd = { .flags = flags, }; struct dm_target *next_segment = NULL; struct segment segments[MAX_BITLK_SEGMENTS] = {}; struct segment temp; uint64_t next_start = 0; uint64_t next_end = 0; uint64_t last_segment = 0; uint32_t dmt_flags = 0; r = _activate_check(cd, params); if (r) return r; r = device_block_adjust(cd, crypt_data_device(cd), DEV_EXCL, 0, &dmd.size, &dmd.flags); if (r) return r; if (dmd.size * SECTOR_SIZE != params->volume_size) log_std(cd, _("WARNING: BitLocker volume size %" PRIu64 " does not match the underlying device size %" PRIu64 ""), params->volume_size, dmd.size * SECTOR_SIZE); /* there will be always 4 dm-zero segments: 3x metadata, 1x FS header */ for (i = 0; i < 3; i++) { segments[num_segments].offset = params->metadata_offset[i] / SECTOR_SIZE; segments[num_segments].length = BITLK_FVE_METADATA_SIZE / SECTOR_SIZE; segments[num_segments].iv_offset = 0; segments[num_segments].type = BITLK_SEGTYPE_ZERO; num_segments++; } segments[num_segments].offset = params->volume_header_offset / SECTOR_SIZE; segments[num_segments].length = params->volume_header_size / SECTOR_SIZE; segments[num_segments].iv_offset = 0; segments[num_segments].type = BITLK_SEGTYPE_ZERO; num_segments++; /* filesystem header (moved from the special location) */ segments[num_segments].offset = 0; segments[num_segments].length = params->volume_header_size / SECTOR_SIZE; segments[num_segments].iv_offset = params->volume_header_offset / SECTOR_SIZE; segments[num_segments].type = BITLK_SEGTYPE_CRYPT; num_segments++; /* now fill gaps between the dm-zero segments with dm-crypt */ last_segment = params->volume_header_size / SECTOR_SIZE; while (true) { next_start = dmd.size; next_end = dmd.size; /* start of the next segment: end of the first existing segment after the last added */ for (i = 0; i < num_segments; i++) if (segments[i].offset + segments[i].length < next_start && segments[i].offset + segments[i].length >= last_segment) next_start = segments[i].offset + segments[i].length; /* end of the next segment: start of the next segment after start we found above */ for (i = 0; i < num_segments; i++) if (segments[i].offset < next_end && segments[i].offset >= next_start) next_end = segments[i].offset; /* two zero segments next to each other, just bump the last_segment so the algorithm moves */ if (next_end - next_start == 0) { last_segment = next_end + 1; continue; } segments[num_segments].offset = next_start; segments[num_segments].length = next_end - next_start; segments[num_segments].iv_offset = next_start; segments[num_segments].type = BITLK_SEGTYPE_CRYPT; last_segment = next_end; num_segments++; if (next_end == dmd.size) break; if (num_segments == 10) { log_dbg(cd, "Failed to calculate number of dm-crypt segments for open."); r = -EINVAL; goto out; } } /* device mapper needs the segment sorted */ for (i = 0; i < num_segments - 1; i++) { min = i; for (j = i + 1; j < num_segments; j++) if (segments[j].offset < segments[min].offset) min = j; if (min != i) { temp.offset = segments[min].offset; temp.length = segments[min].length; temp.iv_offset = segments[min].iv_offset; temp.type = segments[min].type; segments[min].offset = segments[i].offset; segments[min].length = segments[i].length; segments[min].iv_offset = segments[i].iv_offset; segments[min].type = segments[i].type; segments[i].offset = temp.offset; segments[i].length = temp.length; segments[i].iv_offset = temp.iv_offset; segments[i].type = temp.type; } } if (params->sector_size != SECTOR_SIZE) dmd.flags |= CRYPT_ACTIVATE_IV_LARGE_SECTORS; r = dm_targets_allocate(&dmd.segment, num_segments); if (r) goto out; next_segment = &dmd.segment; for (i = 0; i < num_segments; i++) { if (segments[i].type == BITLK_SEGTYPE_ZERO) r = dm_zero_target_set(next_segment, segments[i].offset, segments[i].length); else if (segments[i].type == BITLK_SEGTYPE_CRYPT) r = dm_crypt_target_set(next_segment, segments[i].offset, segments[i].length, crypt_data_device(cd), open_fvek_key, crypt_get_cipher_spec(cd), segments[i].iv_offset, segments[i].iv_offset, NULL, 0, params->sector_size); if (r) goto out; next_segment = next_segment->next; } log_dbg(cd, "Trying to activate BITLK on device %s%s%s.", device_path(crypt_data_device(cd)), name ? " with name " :"", name ?: ""); r = dm_create_device(cd, name, CRYPT_BITLK, &dmd); if (r < 0) { dm_flags(cd, DM_CRYPT, &dmt_flags); if (!strcmp(params->cipher_mode, "cbc-eboiv") && !(dmt_flags & DM_BITLK_EBOIV_SUPPORTED)) { log_err(cd, _("Cannot activate device, kernel dm-crypt is missing support for BITLK IV.")); r = -ENOTSUP; } if (!strcmp(params->cipher_mode, "cbc-elephant") && !(dmt_flags & DM_BITLK_ELEPHANT_SUPPORTED)) { log_err(cd, _("Cannot activate device, kernel dm-crypt is missing support for BITLK Elephant diffuser.")); r = -ENOTSUP; } if ((dmd.flags & CRYPT_ACTIVATE_IV_LARGE_SECTORS) && !(dmt_flags & DM_SECTOR_SIZE_SUPPORTED)) { log_err(cd, _("Cannot activate device, kernel dm-crypt is missing support for large sector size.")); r = -ENOTSUP; } if (dm_flags(cd, DM_ZERO, &dmt_flags) < 0) { log_err(cd, _("Cannot activate device, kernel dm-zero module is missing.")); r = -ENOTSUP; } } out: dm_targets_free(cd, &dmd); return r; } int BITLK_activate_by_passphrase(struct crypt_device *cd, const char *name, const char *password, size_t passwordLen, const struct bitlk_metadata *params, uint32_t flags) { int r = 0; struct volume_key *open_fvek_key = NULL; r = _activate_check(cd, params); if (r) return r; r = BITLK_get_volume_key(cd, password, passwordLen, params, &open_fvek_key); if (r < 0) goto out; /* Password verify only */ if (!name) goto out; r = _activate(cd, name, open_fvek_key, params, flags); out: crypt_free_volume_key(open_fvek_key); return r; } int BITLK_activate_by_volume_key(struct crypt_device *cd, const char *name, const char *volume_key, size_t volume_key_size, const struct bitlk_metadata *params, uint32_t flags) { int r = 0; struct volume_key *open_fvek_key = NULL; r = _activate_check(cd, params); if (r) return r; open_fvek_key = crypt_alloc_volume_key(volume_key_size, volume_key); if (!open_fvek_key) return -ENOMEM; r = _activate(cd, name, open_fvek_key, params, flags); crypt_free_volume_key(open_fvek_key); return r; }