/*
* libcryptsetup - cryptsetup library
*
- * Copyright (C) 2004, Christophe Saout <christophe@saout.de>
+ * Copyright (C) 2004, Jana Saout <jana@saout.de>
* Copyright (C) 2004-2007, Clemens Fruhwirth <clemens@endorphin.org>
* Copyright (C) 2009-2012, Red Hat, Inc. All rights reserved.
+ * Copyright (C) 2009-2014, Milan Broz
*
* This program is free software; you can redistribute it and/or
* modify it under the terms of the GNU General Public License
- * version 2 as published by the Free Software Foundation.
+ * 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
#include <stdio.h>
#include <stdlib.h>
#include <stdarg.h>
+#include <sys/utsname.h>
#include <fcntl.h>
#include <errno.h>
int password_verify;
int rng_type;
- // FIXME: switch to union
- // FIXME: privatre binary headers and access it properly
+ // FIXME: private binary headers and access it properly
// through sub-library (LUKS1, TCRYPT)
- /* used in CRYPT_LUKS1 */
- struct luks_phdr hdr;
- uint64_t PBKDF2_per_sec;
-
- /* used in CRYPT_PLAIN */
- struct crypt_params_plain plain_hdr;
- char *plain_cipher;
- char *plain_cipher_mode;
- char *plain_uuid;
- unsigned int plain_key_size;
-
- /* used in CRYPT_LOOPAES */
- struct crypt_params_loopaes loopaes_hdr;
- char *loopaes_cipher;
- char *loopaes_cipher_mode;
- char *loopaes_uuid;
- unsigned int loopaes_key_size;
-
- /* used in CRYPT_VERITY */
- struct crypt_params_verity verity_hdr;
- char *verity_root_hash;
- unsigned int verity_root_hash_size;
- char *verity_uuid;
-
- /* used in CRYPT_TCRYPT */
- struct crypt_params_tcrypt tcrypt_params;
- struct tcrypt_phdr tcrypt_hdr;
+ union {
+ struct { /* used in CRYPT_LUKS1 */
+ struct luks_phdr hdr;
+ uint64_t PBKDF2_per_sec;
+ } luks1;
+ struct { /* used in CRYPT_PLAIN */
+ struct crypt_params_plain hdr;
+ char *cipher;
+ char *cipher_mode;
+ unsigned int key_size;
+ } plain;
+ struct { /* used in CRYPT_LOOPAES */
+ struct crypt_params_loopaes hdr;
+ char *cipher;
+ char *cipher_mode;
+ unsigned int key_size;
+ } loopaes;
+ struct { /* used in CRYPT_VERITY */
+ struct crypt_params_verity hdr;
+ char *root_hash;
+ unsigned int root_hash_size;
+ char *uuid;
+ } verity;
+ struct { /* used in CRYPT_TCRYPT */
+ struct crypt_params_tcrypt params;
+ struct tcrypt_phdr hdr;
+ } tcrypt;
+ struct { /* used if initialized without header by name */
+ char *active_name;
+ /* buffers, must refresh from kernel on every query */
+ char cipher[MAX_CIPHER_LEN];
+ char cipher_mode[MAX_CIPHER_LEN];
+ unsigned int key_size;
+ } none;
+ } u;
/* callbacks definitions */
void (*log)(int level, const char *msg, void *usrptr);
char error[MAX_ERROR_LENGTH];
};
+/* Just to suppress redundant messages about crypto backend */
+static int _crypto_logged = 0;
+
/* Global error */
/* FIXME: not thread safe, remove this later */
static char global_error[MAX_ERROR_LENGTH] = {0};
int init_crypto(struct crypt_device *ctx)
{
+ struct utsname uts;
int r;
- crypt_fips_libcryptsetup_check(ctx);
-
r = crypt_random_init(ctx);
if (r < 0) {
log_err(ctx, _("Cannot initialize crypto RNG backend.\n"));
if (r < 0)
log_err(ctx, _("Cannot initialize crypto backend.\n"));
- log_dbg("Crypto backend (%s) initialized.", crypt_backend_version());
+ if (!r && !_crypto_logged) {
+ log_dbg("Crypto backend (%s) initialized.", crypt_backend_version());
+ if (!uname(&uts))
+ log_dbg("Detected kernel %s %s %s.",
+ uts.sysname, uts.release, uts.machine);
+ _crypto_logged = 1;
+ }
+
return r;
}
return (type && !strcmp(CRYPT_TCRYPT, type));
}
+static int onlyLUKS(struct crypt_device *cd)
+{
+ int r = 0;
+
+ if (cd && !cd->type) {
+ log_err(cd, _("Cannot determine device type. Incompatible activation of device?\n"));
+ r = -EINVAL;
+ }
+ if (!cd || !isLUKS(cd->type)) {
+ log_err(cd, _("This operation is supported only for LUKS device.\n"));
+ r = -EINVAL;
+ }
+
+ return r;
+}
+
+static void crypt_set_null_type(struct crypt_device *cd)
+{
+ if (!cd->type)
+ return;
+
+ free(cd->type);
+ cd->type = NULL;
+ cd->u.none.active_name = NULL;
+}
+
+static void crypt_reset_null_type(struct crypt_device *cd)
+{
+ if (cd->type)
+ return;
+
+ free(cd->u.none.active_name);
+ cd->u.none.active_name = NULL;
+}
+
/* keyslot helpers */
static int keyslot_verify_or_find_empty(struct crypt_device *cd, int *keyslot)
{
if (*keyslot == CRYPT_ANY_SLOT) {
- *keyslot = LUKS_keyslot_find_empty(&cd->hdr);
+ *keyslot = LUKS_keyslot_find_empty(&cd->u.luks1.hdr);
if (*keyslot < 0) {
log_err(cd, _("All key slots full.\n"));
return -EINVAL;
}
}
- switch (LUKS_keyslot_info(&cd->hdr, *keyslot)) {
+ switch (LUKS_keyslot_info(&cd->u.luks1.hdr, *keyslot)) {
case CRYPT_SLOT_INVALID:
log_err(cd, _("Key slot %d is invalid, please select between 0 and %d.\n"),
*keyslot, LUKS_NUMKEYS - 1);
return 0;
}
+/*
+ * compares type of active device to provided string (only if there is no explicit type)
+ */
+static int crypt_uuid_type_cmp(struct crypt_device *cd, const char *type)
+{
+ struct crypt_dm_active_device dmd = {};
+ size_t len;
+ int r;
+
+ /* Must user header-on-disk if we know type here */
+ if (cd->type || !cd->u.none.active_name)
+ return -EINVAL;
+
+ log_dbg("Checking if active device %s without header has UUID type %s.",
+ cd->u.none.active_name, type);
+
+ r = dm_query_device(cd, cd->u.none.active_name, DM_ACTIVE_UUID, &dmd);
+ if (r < 0)
+ return r;
+
+ r = -ENODEV;
+ len = strlen(type);
+ if (dmd.uuid && strlen(dmd.uuid) > len &&
+ !strncmp(dmd.uuid, type, len) && dmd.uuid[len] == '-')
+ r = 0;
+
+ free(CONST_CAST(void*)dmd.uuid);
+ return r;
+}
+
int PLAIN_activate(struct crypt_device *cd,
const char *name,
struct volume_key *vk,
enum devcheck device_check;
struct crypt_dm_active_device dmd = {
.target = DM_CRYPT,
- .uuid = crypt_get_uuid(cd),
.size = size,
.flags = flags,
.data_device = crypt_data_device(cd),
r = dm_create_device(cd, name, CRYPT_PLAIN, &dmd, 0);
- // FIXME
- if (!cd->plain_uuid && dm_query_device(cd, name, DM_ACTIVE_UUID, &dmd) >= 0)
- cd->plain_uuid = CONST_CAST(char*)dmd.uuid;
-
free(dm_cipher);
return r;
}
goto out;
r = LUKS_open_key_with_hdr(keyslot, passphrase_read,
- passphrase_size_read, &cd->hdr, vk, cd);
+ passphrase_size_read, &cd->u.luks1.hdr, vk, cd);
if (r == -EPERM)
eperm = 1;
crypt_safe_free(passphrase_read);
if (!cd->type && !(cd->type = strdup(CRYPT_LUKS1)))
return -ENOMEM;
- memcpy(&cd->hdr, &hdr, sizeof(hdr));
+ memcpy(&cd->u.luks1.hdr, &hdr, sizeof(hdr));
return r;
}
{
int r;
+ if (!params)
+ return -EINVAL;
+
r = init_crypto(cd);
if (r < 0)
return r;
- memcpy(&cd->tcrypt_params, params, sizeof(*params));
+ memcpy(&cd->u.tcrypt.params, params, sizeof(*params));
- r = TCRYPT_read_phdr(cd, &cd->tcrypt_hdr, &cd->tcrypt_params);
+ r = TCRYPT_read_phdr(cd, &cd->u.tcrypt.hdr, &cd->u.tcrypt.params);
- cd->tcrypt_params.passphrase = NULL;
- cd->tcrypt_params.passphrase_size = 0;
- cd->tcrypt_params.keyfiles = NULL;
- cd->tcrypt_params.keyfiles_count = 0;
+ cd->u.tcrypt.params.passphrase = NULL;
+ cd->u.tcrypt.params.passphrase_size = 0;
+ cd->u.tcrypt.params.keyfiles = NULL;
+ cd->u.tcrypt.params.keyfiles_count = 0;
if (r < 0)
return r;
if (params)
sb_offset = params->hash_area_offset;
- r = VERITY_read_sb(cd, sb_offset, &cd->verity_uuid, &cd->verity_hdr);
+ r = VERITY_read_sb(cd, sb_offset, &cd->u.verity.uuid, &cd->u.verity.hdr);
if (r < 0)
return r;
if (params)
- cd->verity_hdr.flags = params->flags;
+ cd->u.verity.hdr.flags = params->flags;
/* Hash availability checked in sb load */
- cd->verity_root_hash_size = crypt_hash_size(cd->verity_hdr.hash_name);
- if (cd->verity_root_hash_size > 4096)
+ cd->u.verity.root_hash_size = crypt_hash_size(cd->u.verity.hdr.hash_name);
+ if (cd->u.verity.root_hash_size > 4096)
return -EINVAL;
if (!cd->type && !(cd->type = strdup(CRYPT_VERITY)))
DM_ACTIVE_CRYPT_KEYSIZE, &dmd);
if (r < 0)
goto out;
+ if (r > 0)
+ r = 0;
if (isPLAIN(cd->type)) {
- cd->plain_uuid = dmd.uuid ? strdup(dmd.uuid) : NULL;
- cd->plain_hdr.hash = NULL; /* no way to get this */
- cd->plain_hdr.offset = dmd.u.crypt.offset;
- cd->plain_hdr.skip = dmd.u.crypt.iv_offset;
- cd->plain_key_size = dmd.u.crypt.vk->keylength;
+ cd->u.plain.hdr.hash = NULL; /* no way to get this */
+ cd->u.plain.hdr.offset = dmd.u.crypt.offset;
+ cd->u.plain.hdr.skip = dmd.u.crypt.iv_offset;
+ cd->u.plain.key_size = dmd.u.crypt.vk->keylength;
r = crypt_parse_name_and_mode(dmd.u.crypt.cipher, cipher, NULL, cipher_mode);
if (!r) {
- cd->plain_cipher = strdup(cipher);
- cd->plain_cipher_mode = strdup(cipher_mode);
+ cd->u.plain.cipher = strdup(cipher);
+ cd->u.plain.cipher_mode = strdup(cipher_mode);
}
} else if (isLOOPAES(cd->type)) {
- cd->loopaes_uuid = dmd.uuid ? strdup(dmd.uuid) : NULL;
- cd->loopaes_hdr.offset = dmd.u.crypt.offset;
+ cd->u.loopaes.hdr.offset = dmd.u.crypt.offset;
r = crypt_parse_name_and_mode(dmd.u.crypt.cipher, cipher,
&key_nums, cipher_mode);
if (!r) {
- cd->loopaes_cipher = strdup(cipher);
- cd->loopaes_cipher_mode = strdup(cipher_mode);
+ cd->u.loopaes.cipher = strdup(cipher);
+ cd->u.loopaes.cipher_mode = strdup(cipher_mode);
/* version 3 uses last key for IV */
if (dmd.u.crypt.vk->keylength % key_nums)
key_nums++;
- cd->loopaes_key_size = dmd.u.crypt.vk->keylength / key_nums;
+ cd->u.loopaes.key_size = dmd.u.crypt.vk->keylength / key_nums;
}
} else if (isLUKS(cd->type)) {
if (crypt_metadata_device(cd)) {
r = _crypt_load_luks1(cd, 0, 0);
if (r < 0) {
log_dbg("LUKS device header does not match active device.");
- free(cd->type);
- cd->type = NULL;
+ crypt_set_null_type(cd);
r = 0;
goto out;
}
/* check whether UUIDs match each other */
- r = crypt_uuid_cmp(dmd.uuid, cd->hdr.uuid);
+ r = crypt_uuid_cmp(dmd.uuid, cd->u.luks1.hdr.uuid);
if (r < 0) {
log_dbg("LUKS device header uuid: %s mismatches DM returned uuid %s",
- cd->hdr.uuid, dmd.uuid);
- free(cd->type);
- cd->type = NULL;
+ cd->u.luks1.hdr.uuid, dmd.uuid);
+ crypt_set_null_type(cd);
r = 0;
- goto out;
}
+ } else {
+ log_dbg("LUKS device header not available.");
+ crypt_set_null_type(cd);
+ r = 0;
}
} else if (isTCRYPT(cd->type)) {
r = TCRYPT_init_by_name(cd, name, &dmd, &cd->device,
- &cd->tcrypt_params, &cd->tcrypt_hdr);
+ &cd->u.tcrypt.params, &cd->u.tcrypt.hdr);
}
out:
crypt_free_volume_key(dmd.u.crypt.vk);
r = dm_query_device(cd, name,
DM_ACTIVE_DEVICE |
- DM_ACTIVE_UUID |
DM_ACTIVE_VERITY_HASH_DEVICE |
DM_ACTIVE_VERITY_PARAMS, &dmd);
if (r < 0)
goto out;
+ if (r > 0)
+ r = 0;
if (isVERITY(cd->type)) {
- cd->verity_uuid = dmd.uuid ? strdup(dmd.uuid) : NULL;
- cd->verity_hdr.flags = CRYPT_VERITY_NO_HEADER; //FIXME
- cd->verity_hdr.data_size = params.data_size;
- cd->verity_root_hash_size = dmd.u.verity.root_hash_size;
- cd->verity_root_hash = NULL;
- cd->verity_hdr.hash_name = params.hash_name;
- cd->verity_hdr.data_device = NULL;
- cd->verity_hdr.hash_device = NULL;
- cd->verity_hdr.data_block_size = params.data_block_size;
- cd->verity_hdr.hash_block_size = params.hash_block_size;
- cd->verity_hdr.hash_area_offset = dmd.u.verity.hash_offset;
- cd->verity_hdr.hash_type = params.hash_type;
- cd->verity_hdr.flags = params.flags;
- cd->verity_hdr.salt_size = params.salt_size;
- cd->verity_hdr.salt = params.salt;
+ cd->u.verity.uuid = NULL; // FIXME
+ cd->u.verity.hdr.flags = CRYPT_VERITY_NO_HEADER; //FIXME
+ cd->u.verity.hdr.data_size = params.data_size;
+ cd->u.verity.root_hash_size = dmd.u.verity.root_hash_size;
+ cd->u.verity.root_hash = NULL;
+ cd->u.verity.hdr.hash_name = params.hash_name;
+ cd->u.verity.hdr.data_device = NULL;
+ cd->u.verity.hdr.hash_device = NULL;
+ cd->u.verity.hdr.data_block_size = params.data_block_size;
+ cd->u.verity.hdr.hash_block_size = params.hash_block_size;
+ cd->u.verity.hdr.hash_area_offset = dmd.u.verity.hash_offset;
+ cd->u.verity.hdr.hash_type = params.hash_type;
+ cd->u.verity.hdr.flags = params.flags;
+ cd->u.verity.hdr.salt_size = params.salt_size;
+ cd->u.verity.hdr.salt = params.salt;
cd->metadata_device = dmd.u.verity.hash_device;
}
out:
device_free(dmd.data_device);
- free(CONST_CAST(void*)dmd.uuid);
return r;
}
if (r < 0) {
crypt_free(*cd);
*cd = NULL;
+ } else if (!(*cd)->type && name) {
+ /* For anonymous device (no header found) remember initialized name */
+ (*cd)->u.none.active_name = strdup(name);
}
+
device_free(dmd.data_device);
free(CONST_CAST(void*)dmd.uuid);
return r;
return -EINVAL;
}
+ if (uuid) {
+ log_err(cd, _("UUID is not supported for this crypt type.\n"));
+ return -EINVAL;
+ }
+
if (!(cd->type = strdup(CRYPT_PLAIN)))
return -ENOMEM;
- cd->plain_key_size = volume_key_size;
+ cd->u.plain.key_size = volume_key_size;
cd->volume_key = crypt_alloc_volume_key(volume_key_size, NULL);
if (!cd->volume_key)
return -ENOMEM;
- cd->plain_cipher = strdup(cipher);
- cd->plain_cipher_mode = strdup(cipher_mode);
+ cd->u.plain.cipher = strdup(cipher);
+ cd->u.plain.cipher_mode = strdup(cipher_mode);
- if (uuid)
- cd->plain_uuid = strdup(uuid);
if (params && params->hash)
- cd->plain_hdr.hash = strdup(params->hash);
+ cd->u.plain.hdr.hash = strdup(params->hash);
- cd->plain_hdr.offset = params ? params->offset : 0;
- cd->plain_hdr.skip = params ? params->skip : 0;
- cd->plain_hdr.size = params ? params->size : 0;
+ cd->u.plain.hdr.offset = params ? params->offset : 0;
+ cd->u.plain.hdr.skip = params ? params->skip : 0;
+ cd->u.plain.hdr.size = params ? params->size : 0;
- if (!cd->plain_cipher || !cd->plain_cipher_mode)
+ if (!cd->u.plain.cipher || !cd->u.plain.cipher_mode)
return -ENOMEM;
return 0;
&required_alignment,
&alignment_offset, DEFAULT_DISK_ALIGNMENT);
- /* Check early if we cannot allocate block device for key slot access */
- r = device_block_adjust(cd, cd->device, DEV_OK, 0, NULL, NULL);
- if(r < 0)
- return r;
-
- r = LUKS_generate_phdr(&cd->hdr, cd->volume_key, cipher, cipher_mode,
+ r = LUKS_generate_phdr(&cd->u.luks1.hdr, cd->volume_key, cipher, cipher_mode,
(params && params->hash) ? params->hash : "sha1",
uuid, LUKS_STRIPES,
required_alignment / SECTOR_SIZE,
alignment_offset / SECTOR_SIZE,
- cd->iteration_time, &cd->PBKDF2_per_sec,
+ cd->iteration_time, &cd->u.luks1.PBKDF2_per_sec,
cd->metadata_device ? 1 : 0, cd);
if(r < 0)
return r;
return r;
}
- r = LUKS_write_phdr(&cd->hdr, cd);
+ r = LUKS_write_phdr(&cd->u.luks1.hdr, cd);
return r;
}
return -EINVAL;
}
+ if (uuid) {
+ log_err(cd, _("UUID is not supported for this crypt type.\n"));
+ return -EINVAL;
+ }
+
if (!(cd->type = strdup(CRYPT_LOOPAES)))
return -ENOMEM;
- cd->loopaes_key_size = volume_key_size;
+ cd->u.loopaes.key_size = volume_key_size;
- cd->loopaes_cipher = strdup(cipher ?: DEFAULT_LOOPAES_CIPHER);
-
- if (uuid)
- cd->loopaes_uuid = strdup(uuid);
+ cd->u.loopaes.cipher = strdup(cipher ?: DEFAULT_LOOPAES_CIPHER);
if (params && params->hash)
- cd->loopaes_hdr.hash = strdup(params->hash);
+ cd->u.loopaes.hdr.hash = strdup(params->hash);
- cd->loopaes_hdr.offset = params ? params->offset : 0;
- cd->loopaes_hdr.skip = params ? params->skip : 0;
+ cd->u.loopaes.hdr.offset = params ? params->offset : 0;
+ cd->u.loopaes.hdr.skip = params ? params->skip : 0;
return 0;
}
if (r < 0)
return r;
- cd->verity_hdr.data_size = data_device_size / params->data_block_size;
+ cd->u.verity.hdr.data_size = data_device_size / params->data_block_size;
} else
- cd->verity_hdr.data_size = params->data_size;
+ cd->u.verity.hdr.data_size = params->data_size;
hash_size = crypt_hash_size(params->hash_name);
if (hash_size <= 0) {
params->hash_name);
return -EINVAL;
}
- cd->verity_root_hash_size = hash_size;
+ cd->u.verity.root_hash_size = hash_size;
- cd->verity_root_hash = malloc(cd->verity_root_hash_size);
- if (!cd->verity_root_hash)
+ cd->u.verity.root_hash = malloc(cd->u.verity.root_hash_size);
+ if (!cd->u.verity.root_hash)
return -ENOMEM;
- cd->verity_hdr.flags = params->flags;
- if (!(cd->verity_hdr.hash_name = strdup(params->hash_name)))
+ cd->u.verity.hdr.flags = params->flags;
+ if (!(cd->u.verity.hdr.hash_name = strdup(params->hash_name)))
return -ENOMEM;
- cd->verity_hdr.data_device = NULL;
- cd->verity_hdr.data_block_size = params->data_block_size;
- cd->verity_hdr.hash_block_size = params->hash_block_size;
- cd->verity_hdr.hash_area_offset = params->hash_area_offset;
- cd->verity_hdr.hash_type = params->hash_type;
- cd->verity_hdr.flags = params->flags;
- cd->verity_hdr.salt_size = params->salt_size;
- if (!(cd->verity_hdr.salt = malloc(params->salt_size)))
+ cd->u.verity.hdr.data_device = NULL;
+ cd->u.verity.hdr.data_block_size = params->data_block_size;
+ cd->u.verity.hdr.hash_block_size = params->hash_block_size;
+ cd->u.verity.hdr.hash_area_offset = params->hash_area_offset;
+ cd->u.verity.hdr.hash_type = params->hash_type;
+ cd->u.verity.hdr.flags = params->flags;
+ cd->u.verity.hdr.salt_size = params->salt_size;
+ if (!(cd->u.verity.hdr.salt = malloc(params->salt_size)))
return -ENOMEM;
if (params->salt)
- memcpy(CONST_CAST(char*)cd->verity_hdr.salt, params->salt,
+ memcpy(CONST_CAST(char*)cd->u.verity.hdr.salt, params->salt,
params->salt_size);
else
- r = crypt_random_get(cd, CONST_CAST(char*)cd->verity_hdr.salt,
+ r = crypt_random_get(cd, CONST_CAST(char*)cd->u.verity.hdr.salt,
params->salt_size, CRYPT_RND_SALT);
if (r)
return r;
if (params->flags & CRYPT_VERITY_CREATE_HASH) {
- r = VERITY_create(cd, &cd->verity_hdr,
- cd->verity_root_hash, cd->verity_root_hash_size);
+ r = VERITY_create(cd, &cd->u.verity.hdr,
+ cd->u.verity.root_hash, cd->u.verity.root_hash_size);
if (r)
return r;
}
if (!(params->flags & CRYPT_VERITY_NO_HEADER)) {
if (uuid)
- cd->verity_uuid = strdup(uuid);
+ cd->u.verity.uuid = strdup(uuid);
else {
- r = VERITY_UUID_generate(cd, &cd->verity_uuid);
+ r = VERITY_UUID_generate(cd, &cd->u.verity.uuid);
if (r)
return r;
}
- r = VERITY_write_sb(cd, cd->verity_hdr.hash_area_offset,
- cd->verity_uuid,
- &cd->verity_hdr);
+ r = VERITY_write_sb(cd, cd->u.verity.hdr.hash_area_offset,
+ cd->u.verity.uuid,
+ &cd->u.verity.hdr);
}
return r;
}
log_dbg("Formatting device %s as type %s.", mdata_device_path(cd) ?: "(none)", type);
+ crypt_reset_null_type(cd);
+
r = init_crypto(cd);
if (r < 0)
return r;
}
if (r < 0) {
- free(cd->type);
- cd->type = NULL;
+ crypt_set_null_type(cd);
crypt_free_volume_key(cd->volume_key);
cd->volume_key = NULL;
}
if (!crypt_metadata_device(cd))
return -EINVAL;
+ crypt_reset_null_type(cd);
+
if (!requested_type || isLUKS(requested_type)) {
if (cd->type && !isLUKS(cd->type)) {
log_dbg("Context is already initialised to type %s", cd->type);
/* cd->type and header must be set in context */
r = crypt_check_data_device_size(cd);
- if (r < 0) {
- free(cd->type);
- cd->type = NULL;
- }
+ if (r < 0)
+ crypt_set_null_type(cd);
return r;
}
int r;
/* Device context type must be initialised */
- if (!cd->type || !crypt_get_uuid(cd))
+ if (!cd->type)
return -EINVAL;
log_dbg("Resizing device %s to %" PRIu64 " sectors.", name, new_size);
return -EINVAL;
}
- if (uuid && !strncmp(uuid, cd->hdr.uuid, sizeof(cd->hdr.uuid))) {
+ if (uuid && !strncmp(uuid, cd->u.luks1.hdr.uuid, sizeof(cd->u.luks1.hdr.uuid))) {
log_dbg("UUID is the same as requested (%s) for device %s.",
uuid, mdata_device_path(cd));
return 0;
if (!crypt_confirm(cd, _("Do you really want to change UUID of device?")))
return -EPERM;
- return LUKS_hdr_uuid_set(&cd->hdr, uuid, cd);
+ return LUKS_hdr_uuid_set(&cd->u.luks1.hdr, uuid, cd);
}
int crypt_header_backup(struct crypt_device *cd,
if ((requested_type && !isLUKS(requested_type)) || !backup_file)
return -EINVAL;
+ if (cd->type && !isLUKS(cd->type))
+ return -EINVAL;
+
r = init_crypto(cd);
if (r < 0)
return r;
log_dbg("Requested header backup of device %s (%s) to "
"file %s.", mdata_device_path(cd), requested_type, backup_file);
- return LUKS_hdr_backup(backup_file, &cd->hdr, cd);
+ r = LUKS_hdr_backup(backup_file, cd);
+ return r;
}
int crypt_header_restore(struct crypt_device *cd,
const char *requested_type,
const char *backup_file)
{
+ struct luks_phdr hdr;
int r;
if (requested_type && !isLUKS(requested_type))
return -EINVAL;
+ if (cd->type && !isLUKS(cd->type))
+ return -EINVAL;
+
r = init_crypto(cd);
if (r < 0)
return r;
log_dbg("Requested header restore to device %s (%s) from "
"file %s.", mdata_device_path(cd), requested_type, backup_file);
- return LUKS_hdr_restore(backup_file, &cd->hdr, cd);
+ r = LUKS_hdr_restore(backup_file, isLUKS(cd->type) ? &cd->u.luks1.hdr : &hdr, cd);
+
+ crypt_memzero(&hdr, sizeof(hdr));
+ return r;
}
void crypt_free(struct crypt_device *cd)
device_free(cd->device);
device_free(cd->metadata_device);
- free(cd->type);
-
- /* used in plain device only */
- free(CONST_CAST(void*)cd->plain_hdr.hash);
- free(cd->plain_cipher);
- free(cd->plain_cipher_mode);
- free(cd->plain_uuid);
- /* used in loop-AES device only */
- free(CONST_CAST(void*)cd->loopaes_hdr.hash);
- free(cd->loopaes_cipher);
- free(cd->loopaes_uuid);
-
- /* used in verity device only */
- free(CONST_CAST(void*)cd->verity_hdr.hash_name);
- free(CONST_CAST(void*)cd->verity_hdr.salt);
- free(cd->verity_root_hash);
- free(cd->verity_uuid);
+ if (isPLAIN(cd->type)) {
+ free(CONST_CAST(void*)cd->u.plain.hdr.hash);
+ free(cd->u.plain.cipher);
+ free(cd->u.plain.cipher_mode);
+ } else if (isLOOPAES(cd->type)) {
+ free(CONST_CAST(void*)cd->u.loopaes.hdr.hash);
+ free(cd->u.loopaes.cipher);
+ } else if (isVERITY(cd->type)) {
+ free(CONST_CAST(void*)cd->u.verity.hdr.hash_name);
+ free(CONST_CAST(void*)cd->u.verity.hdr.salt);
+ free(cd->u.verity.root_hash);
+ free(cd->u.verity.uuid);
+ } else if (!cd->type) {
+ free(cd->u.none.active_name);
+ }
+ free(cd->type);
+ /* Some structures can contain keys (TCRYPT), wipe it */
+ crypt_memzero(cd, sizeof(*cd));
free(cd);
}
}
log_dbg("Suspending volume %s.", name);
- if (!cd || !isLUKS(cd->type)) {
- log_err(cd, _("This operation is supported only for LUKS device.\n"));
- r = -EINVAL;
- goto out;
+ if (cd->type) {
+ r = onlyLUKS(cd);
+ } else {
+ r = crypt_uuid_type_cmp(cd, CRYPT_LUKS1);
+ if (r < 0)
+ log_err(cd, _("This operation is supported only for LUKS device.\n"));
}
+ if (r < 0)
+ return r;
+
ci = crypt_status(NULL, name);
if (ci < CRYPT_ACTIVE) {
log_err(cd, _("Volume %s is not active.\n"), name);
r = dm_suspend_and_wipe_key(cd, name);
if (r == -ENOTSUP)
- log_err(cd, "Suspend is not supported for device %s.\n", name);
+ log_err(cd, _("Suspend is not supported for device %s.\n"), name);
else if (r)
- log_err(cd, "Error during suspending device %s.\n", name);
+ log_err(cd, _("Error during suspending device %s.\n"), name);
out:
dm_backend_exit();
return r;
log_dbg("Resuming volume %s.", name);
- if (!isLUKS(cd->type)) {
- log_err(cd, _("This operation is supported only for LUKS device.\n"));
- r = -EINVAL;
- goto out;
- }
+ r = onlyLUKS(cd);
+ if (r < 0)
+ return r;
r = dm_status_suspended(cd, name);
if (r < 0)
if (passphrase) {
r = LUKS_open_key_with_hdr(keyslot, passphrase, passphrase_size,
- &cd->hdr, &vk, cd);
+ &cd->u.luks1.hdr, &vk, cd);
} else
r = volume_key_by_terminal_passphrase(cd, keyslot, &vk);
keyslot = r;
r = dm_resume_and_reinstate_key(cd, name, vk->keylength, vk->key);
if (r == -ENOTSUP)
- log_err(cd, "Resume is not supported for device %s.\n", name);
+ log_err(cd, _("Resume is not supported for device %s.\n"), name);
else if (r)
- log_err(cd, "Error during resuming device %s.\n", name);
+ log_err(cd, _("Error during resuming device %s.\n"), name);
} else
r = keyslot;
-out:
+
crypt_free_volume_key(vk);
return r < 0 ? r : keyslot;
}
log_dbg("Resuming volume %s.", name);
- if (!isLUKS(cd->type)) {
- log_err(cd, _("This operation is supported only for LUKS device.\n"));
- r = -EINVAL;
- goto out;
- }
+ r = onlyLUKS(cd);
+ if (r < 0)
+ return r;
r = dm_status_suspended(cd, name);
if (r < 0)
goto out;
r = LUKS_open_key_with_hdr(keyslot, passphrase_read,
- passphrase_size_read, &cd->hdr, &vk, cd);
+ passphrase_size_read, &cd->u.luks1.hdr, &vk, cd);
if (r < 0)
goto out;
keyslot = r;
r = dm_resume_and_reinstate_key(cd, name, vk->keylength, vk->key);
if (r)
- log_err(cd, "Error during resuming device %s.\n", name);
+ log_err(cd, _("Error during resuming device %s.\n"), name);
out:
crypt_safe_free(passphrase_read);
crypt_free_volume_key(vk);
"new passphrase %sprovided.",
passphrase ? "" : "not ", new_passphrase ? "" : "not ");
- if (!isLUKS(cd->type)) {
- log_err(cd, _("This operation is supported only for LUKS device.\n"));
- return -EINVAL;
- }
+ r = onlyLUKS(cd);
+ if (r < 0)
+ return r;
r = keyslot_verify_or_find_empty(cd, &keyslot);
if (r)
return r;
- if (!LUKS_keyslot_active_count(&cd->hdr)) {
+ if (!LUKS_keyslot_active_count(&cd->u.luks1.hdr)) {
/* No slots used, try to use pre-generated key in header */
if (cd->volume_key) {
vk = crypt_alloc_volume_key(cd->volume_key->keylength, cd->volume_key->key);
} else if (passphrase) {
/* Passphrase provided, use it to unlock existing keyslot */
r = LUKS_open_key_with_hdr(CRYPT_ANY_SLOT, passphrase,
- passphrase_size, &cd->hdr, &vk, cd);
+ passphrase_size, &cd->u.luks1.hdr, &vk, cd);
} else {
/* Passphrase not provided, ask first and use it to unlock existing keyslot */
r = key_from_terminal(cd, _("Enter any passphrase: "),
goto out;
r = LUKS_open_key_with_hdr(CRYPT_ANY_SLOT, password,
- passwordLen, &cd->hdr, &vk, cd);
+ passwordLen, &cd->u.luks1.hdr, &vk, cd);
crypt_safe_free(password);
}
}
r = LUKS_set_key(keyslot, new_password, new_passwordLen,
- &cd->hdr, vk, cd->iteration_time, &cd->PBKDF2_per_sec, cd);
- if(r < 0) goto out;
+ &cd->u.luks1.hdr, vk, cd->iteration_time, &cd->u.luks1.PBKDF2_per_sec, cd);
+ if(r < 0)
+ goto out;
r = 0;
out:
if (!new_passphrase)
crypt_safe_free(new_password);
crypt_free_volume_key(vk);
- return r ?: keyslot;
+ return r < 0 ? r : keyslot;
+}
+
+int crypt_keyslot_change_by_passphrase(struct crypt_device *cd,
+ int keyslot_old,
+ int keyslot_new,
+ const char *passphrase,
+ size_t passphrase_size,
+ const char *new_passphrase,
+ size_t new_passphrase_size)
+{
+ struct volume_key *vk = NULL;
+ int r;
+
+ log_dbg("Changing passphrase from old keyslot %d to new %d.",
+ keyslot_old, keyslot_new);
+
+ r = onlyLUKS(cd);
+ if (r < 0)
+ return r;
+
+ r = LUKS_open_key_with_hdr(keyslot_old, passphrase, passphrase_size,
+ &cd->u.luks1.hdr, &vk, cd);
+ if (r < 0)
+ goto out;
+
+ if (keyslot_old != CRYPT_ANY_SLOT && keyslot_old != r) {
+ log_dbg("Keyslot mismatch.");
+ goto out;
+ }
+ keyslot_old = r;
+
+ if (keyslot_new == CRYPT_ANY_SLOT) {
+ keyslot_new = LUKS_keyslot_find_empty(&cd->u.luks1.hdr);
+ if (keyslot_new < 0)
+ keyslot_new = keyslot_old;
+ }
+
+ if (keyslot_old == keyslot_new) {
+ log_dbg("Key slot %d is going to be overwritten.", keyslot_old);
+ (void)crypt_keyslot_destroy(cd, keyslot_old);
+ }
+
+ r = LUKS_set_key(keyslot_new, new_passphrase, new_passphrase_size,
+ &cd->u.luks1.hdr, vk, cd->iteration_time,
+ &cd->u.luks1.PBKDF2_per_sec, cd);
+
+ if (keyslot_old == keyslot_new) {
+ if (r >= 0)
+ log_verbose(cd, _("Key slot %d changed.\n"), keyslot_new);
+ } else {
+ if (r >= 0) {
+ log_verbose(cd, _("Replaced with key slot %d.\n"), keyslot_new);
+ r = crypt_keyslot_destroy(cd, keyslot_old);
+ }
+ }
+ if (r < 0)
+ log_err(cd, _("Failed to swap new key slot.\n"));
+out:
+ crypt_free_volume_key(vk);
+ return r < 0 ? r : keyslot_new;
}
int crypt_keyslot_add_by_keyfile_offset(struct crypt_device *cd,
log_dbg("Adding new keyslot, existing keyfile %s, new keyfile %s.",
keyfile ?: "[none]", new_keyfile ?: "[none]");
- if (!isLUKS(cd->type)) {
- log_err(cd, _("This operation is supported only for LUKS device.\n"));
- return -EINVAL;
- }
+ r = onlyLUKS(cd);
+ if (r < 0)
+ return r;
r = keyslot_verify_or_find_empty(cd, &keyslot);
if (r)
return r;
- if (!LUKS_keyslot_active_count(&cd->hdr)) {
+ if (!LUKS_keyslot_active_count(&cd->u.luks1.hdr)) {
/* No slots used, try to use pre-generated key in header */
if (cd->volume_key) {
vk = crypt_alloc_volume_key(cd->volume_key->keylength, cd->volume_key->key);
goto out;
r = LUKS_open_key_with_hdr(CRYPT_ANY_SLOT, password, passwordLen,
- &cd->hdr, &vk, cd);
+ &cd->u.luks1.hdr, &vk, cd);
}
if(r < 0)
goto out;
r = LUKS_set_key(keyslot, new_password, new_passwordLen,
- &cd->hdr, vk, cd->iteration_time, &cd->PBKDF2_per_sec, cd);
+ &cd->u.luks1.hdr, vk, cd->iteration_time, &cd->u.luks1.PBKDF2_per_sec, cd);
out:
crypt_safe_free(password);
crypt_safe_free(new_password);
size_t passphrase_size)
{
struct volume_key *vk = NULL;
- int r = -EINVAL;
+ int r;
char *new_password = NULL; size_t new_passwordLen;
log_dbg("Adding new keyslot %d using volume key.", keyslot);
- if (!isLUKS(cd->type)) {
- log_err(cd, _("This operation is supported only for LUKS device.\n"));
- return -EINVAL;
- }
+ r = onlyLUKS(cd);
+ if (r < 0)
+ return r;
if (volume_key)
vk = crypt_alloc_volume_key(volume_key_size, volume_key);
if (!vk)
return -ENOMEM;
- r = LUKS_verify_volume_key(&cd->hdr, vk);
+ r = LUKS_verify_volume_key(&cd->u.luks1.hdr, vk);
if (r < 0) {
log_err(cd, _("Volume key does not match the volume.\n"));
goto out;
}
r = LUKS_set_key(keyslot, passphrase, passphrase_size,
- &cd->hdr, vk, cd->iteration_time, &cd->PBKDF2_per_sec, cd);
+ &cd->u.luks1.hdr, vk, cd->iteration_time, &cd->u.luks1.PBKDF2_per_sec, cd);
out:
crypt_safe_free(new_password);
crypt_free_volume_key(vk);
int crypt_keyslot_destroy(struct crypt_device *cd, int keyslot)
{
crypt_keyslot_info ki;
+ int r;
log_dbg("Destroying keyslot %d.", keyslot);
- if (!isLUKS(cd->type)) {
- log_err(cd, _("This operation is supported only for LUKS device.\n"));
- return -EINVAL;
- }
+ r = onlyLUKS(cd);
+ if (r < 0)
+ return r;
ki = crypt_keyslot_status(cd, keyslot);
if (ki == CRYPT_SLOT_INVALID) {
return -EINVAL;
}
- return LUKS_del_key(keyslot, &cd->hdr, cd);
+ return LUKS_del_key(keyslot, &cd->u.luks1.hdr, cd);
}
// activation/deactivation of device mapping
passphrase_size = passphraseLen;
}
- r = process_key(cd, cd->plain_hdr.hash,
- cd->plain_key_size,
+ r = process_key(cd, cd->u.plain.hdr.hash,
+ cd->u.plain.key_size,
passphrase, passphrase_size, &vk);
if (r < 0)
goto out;
- r = PLAIN_activate(cd, name, vk, cd->plain_hdr.size, flags);
+ r = PLAIN_activate(cd, name, vk, cd->u.plain.hdr.size, flags);
keyslot = 0;
} else if (isLUKS(cd->type)) {
/* provided passphrase, do not retry */
if (passphrase) {
r = LUKS_open_key_with_hdr(keyslot, passphrase,
- passphrase_size, &cd->hdr, &vk, cd);
+ passphrase_size, &cd->u.luks1.hdr, &vk, cd);
} else
r = volume_key_by_terminal_passphrase(cd, keyslot, &vk);
if (r < 0)
goto out;
- r = process_key(cd, cd->plain_hdr.hash,
- cd->plain_key_size,
+ r = process_key(cd, cd->u.plain.hdr.hash,
+ cd->u.plain.key_size,
passphrase_read, passphrase_size_read, &vk);
if (r < 0)
goto out;
- r = PLAIN_activate(cd, name, vk, cd->plain_hdr.size, flags);
+ r = PLAIN_activate(cd, name, vk, cd->u.plain.hdr.size, flags);
} else if (isLUKS(cd->type)) {
r = key_from_file(cd, _("Enter passphrase: "), &passphrase_read,
&passphrase_size_read, keyfile, keyfile_offset, keyfile_size);
if (r < 0)
goto out;
r = LUKS_open_key_with_hdr(keyslot, passphrase_read,
- passphrase_size_read, &cd->hdr, &vk, cd);
+ passphrase_size_read, &cd->u.luks1.hdr, &vk, cd);
if (r < 0)
goto out;
keyslot = r;
keyfile, keyfile_offset, keyfile_size);
if (r < 0)
goto out;
- r = LOOPAES_parse_keyfile(cd, &vk, cd->loopaes_hdr.hash, &key_count,
+ r = LOOPAES_parse_keyfile(cd, &vk, cd->u.loopaes.hdr.hash, &key_count,
passphrase_read, passphrase_size_read);
if (r < 0)
goto out;
if (name)
- r = LOOPAES_activate(cd, name, cd->loopaes_cipher,
+ r = LOOPAES_activate(cd, name, cd->u.loopaes.cipher,
key_count, vk, flags);
} else
r = -EINVAL;
if (!name)
return -EINVAL;
- if (!volume_key || !volume_key_size || volume_key_size != cd->plain_key_size) {
+ if (!volume_key || !volume_key_size || volume_key_size != cd->u.plain.key_size) {
log_err(cd, _("Incorrect volume key specified for plain device.\n"));
return -EINVAL;
}
if (!vk)
return -ENOMEM;
- r = PLAIN_activate(cd, name, vk, cd->plain_hdr.size, flags);
+ r = PLAIN_activate(cd, name, vk, cd->u.plain.hdr.size, flags);
} else if (isLUKS(cd->type)) {
/* If key is not provided, try to use internal key */
if (!volume_key) {
vk = crypt_alloc_volume_key(volume_key_size, volume_key);
if (!vk)
return -ENOMEM;
- r = LUKS_verify_volume_key(&cd->hdr, vk);
+ r = LUKS_verify_volume_key(&cd->u.luks1.hdr, vk);
if (r == -EPERM)
log_err(cd, _("Volume key does not match the volume.\n"));
}
r = VERITY_activate(cd, name, volume_key, volume_key_size,
- &cd->verity_hdr, CRYPT_ACTIVATE_READONLY);
+ &cd->u.verity.hdr, CRYPT_ACTIVATE_READONLY);
if (r == -EPERM) {
- free(cd->verity_root_hash);
- cd->verity_root_hash = NULL;
+ free(cd->u.verity.root_hash);
+ cd->u.verity.root_hash = NULL;
} if (!r) {
- cd->verity_root_hash_size = volume_key_size;
- if (!cd->verity_root_hash)
- cd->verity_root_hash = malloc(volume_key_size);
- if (cd->verity_root_hash)
- memcpy(cd->verity_root_hash, volume_key, volume_key_size);
+ cd->u.verity.root_hash_size = volume_key_size;
+ if (!cd->u.verity.root_hash)
+ cd->u.verity.root_hash = malloc(volume_key_size);
+ if (cd->u.verity.root_hash)
+ memcpy(cd->u.verity.root_hash, volume_key, volume_key_size);
}
} else if (isTCRYPT(cd->type)) {
if (!name)
return 0;
- r = TCRYPT_activate(cd, name, &cd->tcrypt_hdr,
- &cd->tcrypt_params, flags);
+ r = TCRYPT_activate(cd, name, &cd->u.tcrypt.hdr,
+ &cd->u.tcrypt.params, flags);
} else
log_err(cd, _("Device type is not properly initialised.\n"));
int crypt_deactivate(struct crypt_device *cd, const char *name)
{
+ struct crypt_device *fake_cd = NULL;
int r;
if (!name)
log_dbg("Deactivating volume %s.", name);
- if (!cd)
- dm_backend_init();
+ if (!cd) {
+ r = crypt_init_by_name(&fake_cd, name);
+ if (r < 0)
+ return r;
+ cd = fake_cd;
+ }
switch (crypt_status(cd, name)) {
case CRYPT_ACTIVE:
case CRYPT_BUSY:
- if (cd && isTCRYPT(cd->type))
+ if (isTCRYPT(cd->type))
r = TCRYPT_deactivate(cd, name);
else
r = dm_remove_device(cd, name, 0, 0);
+ if (r < 0 && crypt_status(cd, name) == CRYPT_BUSY) {
+ log_err(cd, _("Device %s is still in use.\n"), name);
+ r = -EBUSY;
+ }
break;
case CRYPT_INACTIVE:
log_err(cd, _("Device %s is not active.\n"), name);
r = -EINVAL;
}
- if (!cd)
- dm_backend_exit();
+ crypt_free(fake_cd);
return r;
}
int r = -EINVAL;
if (crypt_fips_mode()) {
- log_err(cd, "Function not available in FIPS mode.\n");
+ log_err(cd, _("Function not available in FIPS mode.\n"));
return -EACCES;
}
return -ENOMEM;
}
- if (isPLAIN(cd->type) && cd->plain_hdr.hash) {
- r = process_key(cd, cd->plain_hdr.hash, key_len,
+ if (isPLAIN(cd->type) && cd->u.plain.hdr.hash) {
+ r = process_key(cd, cd->u.plain.hdr.hash, key_len,
passphrase, passphrase_size, &vk);
if (r < 0)
log_err(cd, _("Cannot retrieve volume key for plain device.\n"));
} else if (isLUKS(cd->type)) {
r = LUKS_open_key_with_hdr(keyslot, passphrase,
- passphrase_size, &cd->hdr, &vk, cd);
+ passphrase_size, &cd->u.luks1.hdr, &vk, cd);
} else if (isTCRYPT(cd->type)) {
- r = TCRYPT_get_volume_key(cd, &cd->tcrypt_hdr, &cd->tcrypt_params, &vk);
+ r = TCRYPT_get_volume_key(cd, &cd->u.tcrypt.hdr, &cd->u.tcrypt.params, &vk);
} else
log_err(cd, _("This operation is not supported for %s crypt device.\n"), cd->type ?: "(none)");
struct volume_key *vk;
int r;
- if (!isLUKS(cd->type)) {
- log_err(cd, _("This operation is supported only for LUKS device.\n"));
- return -EINVAL;
- }
+ r = onlyLUKS(cd);
+ if (r < 0)
+ return r;
vk = crypt_alloc_volume_key(volume_key_size, volume_key);
if (!vk)
return -ENOMEM;
- r = LUKS_verify_volume_key(&cd->hdr, vk);
+ r = LUKS_verify_volume_key(&cd->u.luks1.hdr, vk);
if (r == -EPERM)
log_err(cd, _("Volume key does not match the volume.\n"));
int i;
log_std(cd, "LUKS header information for %s\n\n", mdata_device_path(cd));
- log_std(cd, "Version: \t%d\n", cd->hdr.version);
- log_std(cd, "Cipher name: \t%s\n", cd->hdr.cipherName);
- log_std(cd, "Cipher mode: \t%s\n", cd->hdr.cipherMode);
- log_std(cd, "Hash spec: \t%s\n", cd->hdr.hashSpec);
- log_std(cd, "Payload offset:\t%d\n", cd->hdr.payloadOffset);
- log_std(cd, "MK bits: \t%d\n", cd->hdr.keyBytes * 8);
+ log_std(cd, "Version: \t%" PRIu16 "\n", cd->u.luks1.hdr.version);
+ log_std(cd, "Cipher name: \t%s\n", cd->u.luks1.hdr.cipherName);
+ log_std(cd, "Cipher mode: \t%s\n", cd->u.luks1.hdr.cipherMode);
+ log_std(cd, "Hash spec: \t%s\n", cd->u.luks1.hdr.hashSpec);
+ log_std(cd, "Payload offset:\t%" PRIu32 "\n", cd->u.luks1.hdr.payloadOffset);
+ log_std(cd, "MK bits: \t%" PRIu32 "\n", cd->u.luks1.hdr.keyBytes * 8);
log_std(cd, "MK digest: \t");
- hexprint(cd, cd->hdr.mkDigest, LUKS_DIGESTSIZE, " ");
+ hexprint(cd, cd->u.luks1.hdr.mkDigest, LUKS_DIGESTSIZE, " ");
log_std(cd, "\n");
log_std(cd, "MK salt: \t");
- hexprint(cd, cd->hdr.mkDigestSalt, LUKS_SALTSIZE/2, " ");
+ hexprint(cd, cd->u.luks1.hdr.mkDigestSalt, LUKS_SALTSIZE/2, " ");
log_std(cd, "\n \t");
- hexprint(cd, cd->hdr.mkDigestSalt+LUKS_SALTSIZE/2, LUKS_SALTSIZE/2, " ");
+ hexprint(cd, cd->u.luks1.hdr.mkDigestSalt+LUKS_SALTSIZE/2, LUKS_SALTSIZE/2, " ");
log_std(cd, "\n");
- log_std(cd, "MK iterations: \t%d\n", cd->hdr.mkDigestIterations);
- log_std(cd, "UUID: \t%s\n\n", cd->hdr.uuid);
+ log_std(cd, "MK iterations: \t%" PRIu32 "\n", cd->u.luks1.hdr.mkDigestIterations);
+ log_std(cd, "UUID: \t%s\n\n", cd->u.luks1.hdr.uuid);
for(i = 0; i < LUKS_NUMKEYS; i++) {
- if(cd->hdr.keyblock[i].active == LUKS_KEY_ENABLED) {
+ if(cd->u.luks1.hdr.keyblock[i].active == LUKS_KEY_ENABLED) {
log_std(cd, "Key Slot %d: ENABLED\n",i);
- log_std(cd, "\tIterations: \t%d\n",
- cd->hdr.keyblock[i].passwordIterations);
+ log_std(cd, "\tIterations: \t%" PRIu32 "\n",
+ cd->u.luks1.hdr.keyblock[i].passwordIterations);
log_std(cd, "\tSalt: \t");
- hexprint(cd, cd->hdr.keyblock[i].passwordSalt,
+ hexprint(cd, cd->u.luks1.hdr.keyblock[i].passwordSalt,
LUKS_SALTSIZE/2, " ");
log_std(cd, "\n\t \t");
- hexprint(cd, cd->hdr.keyblock[i].passwordSalt +
+ hexprint(cd, cd->u.luks1.hdr.keyblock[i].passwordSalt +
LUKS_SALTSIZE/2, LUKS_SALTSIZE/2, " ");
log_std(cd, "\n");
- log_std(cd, "\tKey material offset:\t%d\n",
- cd->hdr.keyblock[i].keyMaterialOffset);
- log_std(cd, "\tAF stripes: \t%d\n",
- cd->hdr.keyblock[i].stripes);
+ log_std(cd, "\tKey material offset:\t%" PRIu32 "\n",
+ cd->u.luks1.hdr.keyblock[i].keyMaterialOffset);
+ log_std(cd, "\tAF stripes: \t%" PRIu32 "\n",
+ cd->u.luks1.hdr.keyblock[i].stripes);
}
else
log_std(cd, "Key Slot %d: DISABLED\n", i);
static int _verity_dump(struct crypt_device *cd)
{
log_std(cd, "VERITY header information for %s\n", mdata_device_path(cd));
- log_std(cd, "UUID: \t%s\n", cd->verity_uuid ?: "");
- log_std(cd, "Hash type: \t%u\n", cd->verity_hdr.hash_type);
- log_std(cd, "Data blocks: \t%" PRIu64 "\n", cd->verity_hdr.data_size);
- log_std(cd, "Data block size: \t%u\n", cd->verity_hdr.data_block_size);
- log_std(cd, "Hash block size: \t%u\n", cd->verity_hdr.hash_block_size);
- log_std(cd, "Hash algorithm: \t%s\n", cd->verity_hdr.hash_name);
+ log_std(cd, "UUID: \t%s\n", cd->u.verity.uuid ?: "");
+ log_std(cd, "Hash type: \t%u\n", cd->u.verity.hdr.hash_type);
+ log_std(cd, "Data blocks: \t%" PRIu64 "\n", cd->u.verity.hdr.data_size);
+ log_std(cd, "Data block size: \t%u\n", cd->u.verity.hdr.data_block_size);
+ log_std(cd, "Hash block size: \t%u\n", cd->u.verity.hdr.hash_block_size);
+ log_std(cd, "Hash algorithm: \t%s\n", cd->u.verity.hdr.hash_name);
log_std(cd, "Salt: \t");
- if (cd->verity_hdr.salt_size)
- hexprint(cd, cd->verity_hdr.salt, cd->verity_hdr.salt_size, "");
+ if (cd->u.verity.hdr.salt_size)
+ hexprint(cd, cd->u.verity.hdr.salt, cd->u.verity.hdr.salt_size, "");
else
log_std(cd, "-");
log_std(cd, "\n");
- if (cd->verity_root_hash) {
+ if (cd->u.verity.root_hash) {
log_std(cd, "Root hash: \t");
- hexprint(cd, cd->verity_root_hash, cd->verity_root_hash_size, "");
+ hexprint(cd, cd->u.verity.root_hash, cd->u.verity.root_hash_size, "");
log_std(cd, "\n");
}
return 0;
else if (isVERITY(cd->type))
return _verity_dump(cd);
else if (isTCRYPT(cd->type))
- return TCRYPT_dump(cd, &cd->tcrypt_hdr, &cd->tcrypt_params);
+ return TCRYPT_dump(cd, &cd->u.tcrypt.hdr, &cd->u.tcrypt.params);
log_err(cd, _("Dump operation is not supported for this device type.\n"));
return -EINVAL;
}
+
+static int _init_by_name_crypt_none(struct crypt_device *cd)
+{
+ struct crypt_dm_active_device dmd = {};
+ int r;
+
+ if (cd->type || !cd->u.none.active_name)
+ return -EINVAL;
+
+ r = dm_query_device(cd, cd->u.none.active_name,
+ DM_ACTIVE_CRYPT_CIPHER |
+ DM_ACTIVE_CRYPT_KEYSIZE, &dmd);
+ if (r >= 0)
+ r = crypt_parse_name_and_mode(dmd.u.crypt.cipher,
+ cd->u.none.cipher, NULL,
+ cd->u.none.cipher_mode);
+
+ if (!r)
+ cd->u.none.key_size = dmd.u.crypt.vk->keylength;
+
+ crypt_free_volume_key(dmd.u.crypt.vk);
+ free(CONST_CAST(void*)dmd.u.crypt.cipher);
+ return r;
+}
+
const char *crypt_get_cipher(struct crypt_device *cd)
{
if (isPLAIN(cd->type))
- return cd->plain_cipher;
+ return cd->u.plain.cipher;
if (isLUKS(cd->type))
- return cd->hdr.cipherName;
+ return cd->u.luks1.hdr.cipherName;
if (isLOOPAES(cd->type))
- return cd->loopaes_cipher;
+ return cd->u.loopaes.cipher;
if (isTCRYPT(cd->type))
- return cd->tcrypt_params.cipher;
+ return cd->u.tcrypt.params.cipher;
+
+ if (!cd->type && !_init_by_name_crypt_none(cd))
+ return cd->u.none.cipher;
return NULL;
}
const char *crypt_get_cipher_mode(struct crypt_device *cd)
{
if (isPLAIN(cd->type))
- return cd->plain_cipher_mode;
+ return cd->u.plain.cipher_mode;
if (isLUKS(cd->type))
- return cd->hdr.cipherMode;
+ return cd->u.luks1.hdr.cipherMode;
if (isLOOPAES(cd->type))
- return cd->loopaes_cipher_mode;
+ return cd->u.loopaes.cipher_mode;
if (isTCRYPT(cd->type))
- return cd->tcrypt_params.mode;
+ return cd->u.tcrypt.params.mode;
+
+ if (!cd->type && !_init_by_name_crypt_none(cd))
+ return cd->u.none.cipher_mode;
return NULL;
}
const char *crypt_get_uuid(struct crypt_device *cd)
{
if (isLUKS(cd->type))
- return cd->hdr.uuid;
-
- if (isPLAIN(cd->type))
- return cd->plain_uuid;
-
- if (isLOOPAES(cd->type))
- return cd->loopaes_uuid;
+ return cd->u.luks1.hdr.uuid;
if (isVERITY(cd->type))
- return cd->verity_uuid;
+ return cd->u.verity.uuid;
return NULL;
}
int crypt_get_volume_key_size(struct crypt_device *cd)
{
if (isPLAIN(cd->type))
- return cd->plain_key_size;
+ return cd->u.plain.key_size;
if (isLUKS(cd->type))
- return cd->hdr.keyBytes;
+ return cd->u.luks1.hdr.keyBytes;
if (isLOOPAES(cd->type))
- return cd->loopaes_key_size;
+ return cd->u.loopaes.key_size;
if (isVERITY(cd->type))
- return cd->verity_root_hash_size;
+ return cd->u.verity.root_hash_size;
if (isTCRYPT(cd->type))
- return cd->tcrypt_params.key_size;
+ return cd->u.tcrypt.params.key_size;
+
+ if (!cd->type && !_init_by_name_crypt_none(cd))
+ return cd->u.none.key_size;
return 0;
}
uint64_t crypt_get_data_offset(struct crypt_device *cd)
{
if (isPLAIN(cd->type))
- return cd->plain_hdr.offset;
+ return cd->u.plain.hdr.offset;
if (isLUKS(cd->type))
- return cd->hdr.payloadOffset;
+ return cd->u.luks1.hdr.payloadOffset;
if (isLOOPAES(cd->type))
- return cd->loopaes_hdr.offset;
+ return cd->u.loopaes.hdr.offset;
if (isTCRYPT(cd->type))
- return TCRYPT_get_data_offset(cd, &cd->tcrypt_hdr, &cd->tcrypt_params);
+ return TCRYPT_get_data_offset(cd, &cd->u.tcrypt.hdr, &cd->u.tcrypt.params);
return 0;
}
uint64_t crypt_get_iv_offset(struct crypt_device *cd)
{
if (isPLAIN(cd->type))
- return cd->plain_hdr.skip;
+ return cd->u.plain.hdr.skip;
if (isLUKS(cd->type))
return 0;
if (isLOOPAES(cd->type))
- return cd->loopaes_hdr.skip;
+ return cd->u.loopaes.hdr.skip;
if (isTCRYPT(cd->type))
- return TCRYPT_get_iv_offset(cd, &cd->tcrypt_hdr, &cd->tcrypt_params);
+ return TCRYPT_get_iv_offset(cd, &cd->u.tcrypt.hdr, &cd->u.tcrypt.params);
return 0;
}
crypt_keyslot_info crypt_keyslot_status(struct crypt_device *cd, int keyslot)
{
- if (!isLUKS(cd->type)) {
- log_err(cd, _("This operation is supported only for LUKS device.\n"));
+ if (onlyLUKS(cd) < 0)
return CRYPT_SLOT_INVALID;
- }
- return LUKS_keyslot_info(&cd->hdr, keyslot);
+ return LUKS_keyslot_info(&cd->u.luks1.hdr, keyslot);
}
int crypt_keyslot_max(const char *type)
if (!isLUKS(cd->type))
return -EINVAL;
- return LUKS_keyslot_area(&cd->hdr, keyslot, offset, length);
+ return LUKS_keyslot_area(&cd->u.luks1.hdr, keyslot, offset, length);
}
const char *crypt_get_type(struct crypt_device *cd)
vp->data_device = device_path(cd->device);
vp->hash_device = mdata_device_path(cd);
- vp->hash_name = cd->verity_hdr.hash_name;
- vp->salt = cd->verity_hdr.salt;
- vp->salt_size = cd->verity_hdr.salt_size;
- vp->data_block_size = cd->verity_hdr.data_block_size;
- vp->hash_block_size = cd->verity_hdr.hash_block_size;
- vp->data_size = cd->verity_hdr.data_size;
- vp->hash_area_offset = cd->verity_hdr.hash_area_offset;
- vp->hash_type = cd->verity_hdr.hash_type;
- vp->flags = cd->verity_hdr.flags & CRYPT_VERITY_NO_HEADER;
+ vp->hash_name = cd->u.verity.hdr.hash_name;
+ vp->salt = cd->u.verity.hdr.salt;
+ vp->salt_size = cd->u.verity.hdr.salt_size;
+ vp->data_block_size = cd->u.verity.hdr.data_block_size;
+ vp->hash_block_size = cd->u.verity.hdr.hash_block_size;
+ vp->data_size = cd->u.verity.hdr.data_size;
+ vp->hash_area_offset = cd->u.verity.hdr.hash_area_offset;
+ vp->hash_type = cd->u.verity.hdr.hash_type;
+ vp->flags = cd->u.verity.hdr.flags & CRYPT_VERITY_NO_HEADER;
return 0;
}
return -ENOTSUP;
if (cd && isTCRYPT(cd->type)) {
- cad->offset = TCRYPT_get_data_offset(cd, &cd->tcrypt_hdr, &cd->tcrypt_params);
- cad->iv_offset = TCRYPT_get_iv_offset(cd, &cd->tcrypt_hdr, &cd->tcrypt_params);
+ cad->offset = TCRYPT_get_data_offset(cd, &cd->u.tcrypt.hdr, &cd->u.tcrypt.params);
+ cad->iv_offset = TCRYPT_get_iv_offset(cd, &cd->u.tcrypt.hdr, &cd->u.tcrypt.params);
} else {
cad->offset = dmd.u.crypt.offset;
cad->iv_offset = dmd.u.crypt.iv_offset;