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/*
* LUKS - Linux Unified Key Setup v2, keyslot handling
*
* Copyright (C) 2015-2023 Red Hat, Inc. All rights reserved.
* Copyright (C) 2015-2023 Milan Broz
*
* This program is free software; you can redistribute it and/or
* modify it under the terms of the GNU General Public License
* as published by the Free Software Foundation; either version 2
* of the License, or (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software
* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
*/
#include "luks2_internal.h"
/* Internal implementations */
extern const keyslot_handler luks2_keyslot;
extern const keyslot_handler reenc_keyslot;
static const keyslot_handler *keyslot_handlers[LUKS2_KEYSLOTS_MAX] = {
&luks2_keyslot,
#if USE_LUKS2_REENCRYPTION
&reenc_keyslot,
#endif
NULL
};
static const keyslot_handler
*LUKS2_keyslot_handler_type(const char *type)
{
int i;
for (i = 0; i < LUKS2_KEYSLOTS_MAX && keyslot_handlers[i]; i++) {
if (!strcmp(keyslot_handlers[i]->name, type))
return keyslot_handlers[i];
}
return NULL;
}
static const keyslot_handler
*LUKS2_keyslot_handler(struct crypt_device *cd, int keyslot)
{
struct luks2_hdr *hdr;
json_object *jobj1, *jobj2;
if (keyslot < 0)
return NULL;
if (!(hdr = crypt_get_hdr(cd, CRYPT_LUKS2)))
return NULL;
if (!(jobj1 = LUKS2_get_keyslot_jobj(hdr, keyslot)))
return NULL;
if (!json_object_object_get_ex(jobj1, "type", &jobj2))
return NULL;
return LUKS2_keyslot_handler_type(json_object_get_string(jobj2));
}
int LUKS2_keyslot_find_empty(struct crypt_device *cd, struct luks2_hdr *hdr, size_t keylength)
{
int i;
for (i = 0; i < LUKS2_KEYSLOTS_MAX; i++)
if (!LUKS2_get_keyslot_jobj(hdr, i))
break;
if (i == LUKS2_KEYSLOTS_MAX)
return -EINVAL;
/* Check also there is a space for the key in keyslots area */
if (keylength && LUKS2_find_area_gap(cd, hdr, keylength, NULL, NULL) < 0)
return -ENOSPC;
return i;
}
/* Check if a keyslot is assigned to specific segment */
static int _keyslot_for_segment(struct luks2_hdr *hdr, int keyslot, int segment)
{
int keyslot_digest, count = 0;
unsigned s;
keyslot_digest = LUKS2_digest_by_keyslot(hdr, keyslot);
if (keyslot_digest < 0)
return keyslot_digest;
if (segment >= 0)
return keyslot_digest == LUKS2_digest_by_segment(hdr, segment);
for (s = 0; s < json_segments_count(LUKS2_get_segments_jobj(hdr)); s++) {
if (keyslot_digest == LUKS2_digest_by_segment(hdr, s))
count++;
}
return count;
}
static int _keyslot_for_digest(struct luks2_hdr *hdr, int keyslot, int digest)
{
int r = -EINVAL;
r = LUKS2_digest_by_keyslot(hdr, keyslot);
if (r < 0)
return r;
return r == digest ? 0 : -ENOENT;
}
int LUKS2_keyslot_for_segment(struct luks2_hdr *hdr, int keyslot, int segment)
{
int r = -EINVAL;
/* no need to check anything */
if (segment == CRYPT_ANY_SEGMENT)
return 0; /* ok */
if (segment == CRYPT_DEFAULT_SEGMENT) {
segment = LUKS2_get_default_segment(hdr);
if (segment < 0)
return segment;
}
r = _keyslot_for_segment(hdr, keyslot, segment);
if (r < 0)
return r;
return r >= 1 ? 0 : -ENOENT;
}
/* Number of keyslots assigned to a segment or all keyslots for CRYPT_ANY_SEGMENT */
int LUKS2_keyslot_active_count(struct luks2_hdr *hdr, int segment)
{
int num = 0;
json_object *jobj_keyslots;
json_object_object_get_ex(hdr->jobj, "keyslots", &jobj_keyslots);
json_object_object_foreach(jobj_keyslots, slot, val) {
UNUSED(val);
if (!LUKS2_keyslot_for_segment(hdr, atoi(slot), segment))
num++;
}
return num;
}
int LUKS2_keyslot_cipher_incompatible(struct crypt_device *cd, const char *cipher_spec)
{
char cipher[MAX_CIPHER_LEN], cipher_mode[MAX_CIPHER_LEN];
if (!cipher_spec || crypt_is_cipher_null(cipher_spec))
return 1;
if (crypt_parse_name_and_mode(cipher_spec, cipher, NULL, cipher_mode) < 0)
return 1;
/* Keyslot is already authenticated; we cannot use integrity tags here */
if (crypt_get_integrity_tag_size(cd))
return 1;
/* Wrapped key schemes cannot be used for keyslot encryption */
if (crypt_cipher_wrapped_key(cipher, cipher_mode))
return 1;
/* Check if crypto backend can use the cipher */
if (crypt_cipher_ivsize(cipher, cipher_mode) < 0)
return 1;
return 0;
}
int LUKS2_keyslot_params_default(struct crypt_device *cd, struct luks2_hdr *hdr,
struct luks2_keyslot_params *params)
{
const struct crypt_pbkdf_type *pbkdf = crypt_get_pbkdf_type(cd);
const char *cipher_spec;
size_t key_size;
int r;
if (!hdr || !pbkdf || !params)
return -EINVAL;
/*
* set keyslot area encryption parameters
*/
params->area_type = LUKS2_KEYSLOT_AREA_RAW;
cipher_spec = crypt_keyslot_get_encryption(cd, CRYPT_ANY_SLOT, &key_size);
if (!cipher_spec || !key_size)
return -EINVAL;
params->area.raw.key_size = key_size;
r = snprintf(params->area.raw.encryption, sizeof(params->area.raw.encryption), "%s", cipher_spec);
if (r < 0 || (size_t)r >= sizeof(params->area.raw.encryption))
return -EINVAL;
/*
* set keyslot AF parameters
*/
params->af_type = LUKS2_KEYSLOT_AF_LUKS1;
/* currently we use hash for AF from pbkdf settings */
r = snprintf(params->af.luks1.hash, sizeof(params->af.luks1.hash), "%s", pbkdf->hash ?: DEFAULT_LUKS1_HASH);
if (r < 0 || (size_t)r >= sizeof(params->af.luks1.hash))
return -EINVAL;
params->af.luks1.stripes = 4000;
return 0;
}
int LUKS2_keyslot_pbkdf(struct luks2_hdr *hdr, int keyslot, struct crypt_pbkdf_type *pbkdf)
{
json_object *jobj_keyslot, *jobj_kdf, *jobj;
if (!hdr || !pbkdf)
return -EINVAL;
if (LUKS2_keyslot_info(hdr, keyslot) == CRYPT_SLOT_INVALID)
return -EINVAL;
jobj_keyslot = LUKS2_get_keyslot_jobj(hdr, keyslot);
if (!jobj_keyslot)
return -ENOENT;
if (!json_object_object_get_ex(jobj_keyslot, "kdf", &jobj_kdf))
return -EINVAL;
if (!json_object_object_get_ex(jobj_kdf, "type", &jobj))
return -EINVAL;
memset(pbkdf, 0, sizeof(*pbkdf));
pbkdf->type = json_object_get_string(jobj);
if (json_object_object_get_ex(jobj_kdf, "hash", &jobj))
pbkdf->hash = json_object_get_string(jobj);
if (json_object_object_get_ex(jobj_kdf, "iterations", &jobj))
pbkdf->iterations = json_object_get_int(jobj);
if (json_object_object_get_ex(jobj_kdf, "time", &jobj))
pbkdf->iterations = json_object_get_int(jobj);
if (json_object_object_get_ex(jobj_kdf, "memory", &jobj))
pbkdf->max_memory_kb = json_object_get_int(jobj);
if (json_object_object_get_ex(jobj_kdf, "cpus", &jobj))
pbkdf->parallel_threads = json_object_get_int(jobj);
return 0;
}
static int LUKS2_keyslot_unbound(struct luks2_hdr *hdr, int keyslot)
{
json_object *jobj_digest, *jobj_segments;
int digest = LUKS2_digest_by_keyslot(hdr, keyslot);
if (digest < 0)
return 0;
if (!(jobj_digest = LUKS2_get_digest_jobj(hdr, digest)))
return 0;
json_object_object_get_ex(jobj_digest, "segments", &jobj_segments);
if (!jobj_segments || !json_object_is_type(jobj_segments, json_type_array) ||
json_object_array_length(jobj_segments) == 0)
return 1;
return 0;
}
crypt_keyslot_info LUKS2_keyslot_info(struct luks2_hdr *hdr, int keyslot)
{
if(keyslot >= LUKS2_KEYSLOTS_MAX || keyslot < 0)
return CRYPT_SLOT_INVALID;
if (!LUKS2_get_keyslot_jobj(hdr, keyslot))
return CRYPT_SLOT_INACTIVE;
if (LUKS2_digest_by_keyslot(hdr, keyslot) < 0 ||
LUKS2_keyslot_unbound(hdr, keyslot))
return CRYPT_SLOT_UNBOUND;
if (LUKS2_keyslot_active_count(hdr, CRYPT_DEFAULT_SEGMENT) == 1 &&
!LUKS2_keyslot_for_segment(hdr, keyslot, CRYPT_DEFAULT_SEGMENT))
return CRYPT_SLOT_ACTIVE_LAST;
return CRYPT_SLOT_ACTIVE;
}
int LUKS2_keyslot_jobj_area(json_object *jobj_keyslot, uint64_t *offset, uint64_t *length)
{
json_object *jobj_area, *jobj;
if (!json_object_object_get_ex(jobj_keyslot, "area", &jobj_area))
return -EINVAL;
if (!json_object_object_get_ex(jobj_area, "offset", &jobj))
return -EINVAL;
*offset = crypt_jobj_get_uint64(jobj);
if (!json_object_object_get_ex(jobj_area, "size", &jobj))
return -EINVAL;
*length = crypt_jobj_get_uint64(jobj);
return 0;
}
int LUKS2_keyslot_area(struct luks2_hdr *hdr,
int keyslot,
uint64_t *offset,
uint64_t *length)
{
json_object *jobj_keyslot;
if (LUKS2_keyslot_info(hdr, keyslot) == CRYPT_SLOT_INVALID)
return -EINVAL;
jobj_keyslot = LUKS2_get_keyslot_jobj(hdr, keyslot);
if (!jobj_keyslot)
return -ENOENT;
return LUKS2_keyslot_jobj_area(jobj_keyslot, offset, length);
}
static int _open_and_verify(struct crypt_device *cd,
struct luks2_hdr *hdr,
const keyslot_handler *h,
int keyslot,
const char *password,
size_t password_len,
struct volume_key **vk)
{
int r, key_size = LUKS2_get_keyslot_stored_key_size(hdr, keyslot);
if (key_size < 0)
return -EINVAL;
*vk = crypt_alloc_volume_key(key_size, NULL);
if (!*vk)
return -ENOMEM;
r = h->open(cd, keyslot, password, password_len, (*vk)->key, (*vk)->keylength);
if (r < 0)
log_dbg(cd, "Keyslot %d (%s) open failed with %d.", keyslot, h->name, r);
else
r = LUKS2_digest_verify(cd, hdr, *vk, keyslot);
if (r < 0) {
crypt_free_volume_key(*vk);
*vk = NULL;
}
crypt_volume_key_set_id(*vk, r);
return r < 0 ? r : keyslot;
}
static int LUKS2_open_and_verify_by_digest(struct crypt_device *cd,
struct luks2_hdr *hdr,
int keyslot,
int digest,
const char *password,
size_t password_len,
struct volume_key **vk)
{
const keyslot_handler *h;
int r;
if (!(h = LUKS2_keyslot_handler(cd, keyslot)))
return -ENOENT;
r = h->validate(cd, LUKS2_get_keyslot_jobj(hdr, keyslot));
if (r) {
log_dbg(cd, "Keyslot %d validation failed.", keyslot);
return r;
}
r = _keyslot_for_digest(hdr, keyslot, digest);
if (r) {
if (r == -ENOENT)
log_dbg(cd, "Keyslot %d unusable for digest %d.", keyslot, digest);
return r;
}
return _open_and_verify(cd, hdr, h, keyslot, password, password_len, vk);
}
static int LUKS2_open_and_verify(struct crypt_device *cd,
struct luks2_hdr *hdr,
int keyslot,
int segment,
const char *password,
size_t password_len,
struct volume_key **vk)
{
const keyslot_handler *h;
int r;
if (!(h = LUKS2_keyslot_handler(cd, keyslot)))
return -ENOENT;
r = h->validate(cd, LUKS2_get_keyslot_jobj(hdr, keyslot));
if (r) {
log_dbg(cd, "Keyslot %d validation failed.", keyslot);
return r;
}
r = LUKS2_keyslot_for_segment(hdr, keyslot, segment);
if (r) {
if (r == -ENOENT)
log_dbg(cd, "Keyslot %d unusable for segment %d.", keyslot, segment);
return r;
}
return _open_and_verify(cd, hdr, h, keyslot, password, password_len, vk);
}
static int LUKS2_keyslot_open_priority_digest(struct crypt_device *cd,
struct luks2_hdr *hdr,
crypt_keyslot_priority priority,
const char *password,
size_t password_len,
int digest,
struct volume_key **vk)
{
json_object *jobj_keyslots, *jobj;
crypt_keyslot_priority slot_priority;
int keyslot, r = -ENOENT;
json_object_object_get_ex(hdr->jobj, "keyslots", &jobj_keyslots);
json_object_object_foreach(jobj_keyslots, slot, val) {
if (!json_object_object_get_ex(val, "priority", &jobj))
slot_priority = CRYPT_SLOT_PRIORITY_NORMAL;
else
slot_priority = json_object_get_int(jobj);
keyslot = atoi(slot);
if (slot_priority != priority) {
log_dbg(cd, "Keyslot %d priority %d != %d (required), skipped.",
keyslot, slot_priority, priority);
continue;
}
r = LUKS2_open_and_verify_by_digest(cd, hdr, keyslot, digest, password, password_len, vk);
/* Do not retry for errors that are no -EPERM or -ENOENT,
former meaning password wrong, latter key slot unusable for segment */
if ((r != -EPERM) && (r != -ENOENT))
break;
}
return r;
}
static int LUKS2_keyslot_open_priority(struct crypt_device *cd,
struct luks2_hdr *hdr,
crypt_keyslot_priority priority,
const char *password,
size_t password_len,
int segment,
struct volume_key **vk)
{
json_object *jobj_keyslots, *jobj;
crypt_keyslot_priority slot_priority;
int keyslot, r = -ENOENT;
json_object_object_get_ex(hdr->jobj, "keyslots", &jobj_keyslots);
json_object_object_foreach(jobj_keyslots, slot, val) {
if (!json_object_object_get_ex(val, "priority", &jobj))
slot_priority = CRYPT_SLOT_PRIORITY_NORMAL;
else
slot_priority = json_object_get_int(jobj);
keyslot = atoi(slot);
if (slot_priority != priority) {
log_dbg(cd, "Keyslot %d priority %d != %d (required), skipped.",
keyslot, slot_priority, priority);
continue;
}
r = LUKS2_open_and_verify(cd, hdr, keyslot, segment, password, password_len, vk);
/* Do not retry for errors that are no -EPERM or -ENOENT,
former meaning password wrong, latter key slot unusable for segment */
if ((r != -EPERM) && (r != -ENOENT))
break;
}
return r;
}
static int LUKS2_keyslot_open_by_digest(struct crypt_device *cd,
struct luks2_hdr *hdr,
int keyslot,
int digest,
const char *password,
size_t password_len,
struct volume_key **vk)
{
int r_prio, r = -EINVAL;
if (digest < 0)
return r;
if (keyslot == CRYPT_ANY_SLOT) {
r_prio = LUKS2_keyslot_open_priority_digest(cd, hdr, CRYPT_SLOT_PRIORITY_PREFER,
password, password_len, digest, vk);
if (r_prio >= 0)
r = r_prio;
else if (r_prio != -EPERM && r_prio != -ENOENT)
r = r_prio;
else
r = LUKS2_keyslot_open_priority_digest(cd, hdr, CRYPT_SLOT_PRIORITY_NORMAL,
password, password_len, digest, vk);
/* Prefer password wrong to no entry from priority slot */
if (r_prio == -EPERM && r == -ENOENT)
r = r_prio;
} else
r = LUKS2_open_and_verify_by_digest(cd, hdr, keyslot, digest, password, password_len, vk);
return r;
}
int LUKS2_keyslot_open_all_segments(struct crypt_device *cd,
int keyslot_old,
int keyslot_new,
const char *password,
size_t password_len,
struct volume_key **vks)
{
struct volume_key *vk = NULL;
int digest_old, digest_new, r = -EINVAL;
struct luks2_hdr *hdr = crypt_get_hdr(cd, CRYPT_LUKS2);
digest_old = LUKS2_reencrypt_digest_old(hdr);
if (digest_old >= 0) {
log_dbg(cd, "Trying to unlock volume key (digest: %d) using keyslot %d.", digest_old, keyslot_old);
r = LUKS2_keyslot_open_by_digest(cd, hdr, keyslot_old, digest_old, password, password_len, &vk);
if (r < 0)
goto out;
crypt_volume_key_add_next(vks, vk);
}
digest_new = LUKS2_reencrypt_digest_new(hdr);
if (digest_new >= 0 && digest_old != digest_new) {
log_dbg(cd, "Trying to unlock volume key (digest: %d) using keyslot %d.", digest_new, keyslot_new);
r = LUKS2_keyslot_open_by_digest(cd, hdr, keyslot_new, digest_new, password, password_len, &vk);
if (r < 0)
goto out;
crypt_volume_key_add_next(vks, vk);
}
out:
if (r < 0) {
crypt_free_volume_key(*vks);
*vks = NULL;
if (r == -ENOMEM)
log_err(cd, _("Not enough available memory to open a keyslot."));
else if (r != -EPERM && r != -ENOENT)
log_err(cd, _("Keyslot open failed."));
}
return r;
}
int LUKS2_keyslot_open(struct crypt_device *cd,
int keyslot,
int segment,
const char *password,
size_t password_len,
struct volume_key **vk)
{
struct luks2_hdr *hdr;
int r_prio, r = -EINVAL;
hdr = crypt_get_hdr(cd, CRYPT_LUKS2);
if (keyslot == CRYPT_ANY_SLOT) {
r_prio = LUKS2_keyslot_open_priority(cd, hdr, CRYPT_SLOT_PRIORITY_PREFER,
password, password_len, segment, vk);
if (r_prio >= 0)
r = r_prio;
else if (r_prio != -EPERM && r_prio != -ENOENT)
r = r_prio;
else
r = LUKS2_keyslot_open_priority(cd, hdr, CRYPT_SLOT_PRIORITY_NORMAL,
password, password_len, segment, vk);
/* Prefer password wrong to no entry from priority slot */
if (r_prio == -EPERM && r == -ENOENT)
r = r_prio;
} else
r = LUKS2_open_and_verify(cd, hdr, keyslot, segment, password, password_len, vk);
if (r < 0) {
if (r == -ENOMEM)
log_err(cd, _("Not enough available memory to open a keyslot."));
else if (r != -EPERM && r != -ENOENT)
log_err(cd, _("Keyslot open failed."));
}
return r;
}
int LUKS2_keyslot_reencrypt_store(struct crypt_device *cd,
struct luks2_hdr *hdr,
int keyslot,
const void *buffer,
size_t buffer_length)
{
const keyslot_handler *h;
int r;
if (!(h = LUKS2_keyslot_handler(cd, keyslot)) || strcmp(h->name, "reencrypt"))
return -EINVAL;
r = h->validate(cd, LUKS2_get_keyslot_jobj(hdr, keyslot));
if (r) {
log_dbg(cd, "Keyslot validation failed.");
return r;
}
return h->store(cd, keyslot, NULL, 0,
buffer, buffer_length);
}
int LUKS2_keyslot_store(struct crypt_device *cd,
struct luks2_hdr *hdr,
int keyslot,
const char *password,
size_t password_len,
const struct volume_key *vk,
const struct luks2_keyslot_params *params)
{
const keyslot_handler *h;
int r;
if (keyslot == CRYPT_ANY_SLOT)
return -EINVAL;
if (!LUKS2_get_keyslot_jobj(hdr, keyslot)) {
/* Try to allocate default and empty keyslot type */
h = LUKS2_keyslot_handler_type("luks2");
if (!h)
return -EINVAL;
r = h->alloc(cd, keyslot, vk->keylength, params);
if (r)
return r;
} else {
if (!(h = LUKS2_keyslot_handler(cd, keyslot)))
return -EINVAL;
r = h->update(cd, keyslot, params);
if (r) {
log_dbg(cd, "Failed to update keyslot %d json.", keyslot);
return r;
}
}
r = h->validate(cd, LUKS2_get_keyslot_jobj(hdr, keyslot));
if (r) {
log_dbg(cd, "Keyslot validation failed.");
return r;
}
if (LUKS2_hdr_validate(cd, hdr->jobj, hdr->hdr_size - LUKS2_HDR_BIN_LEN))
return -EINVAL;
return h->store(cd, keyslot, password, password_len,
vk->key, vk->keylength);
}
int LUKS2_keyslot_wipe(struct crypt_device *cd,
struct luks2_hdr *hdr,
int keyslot,
int wipe_area_only)
{
struct device *device = crypt_metadata_device(cd);
uint64_t area_offset, area_length;
int r;
json_object *jobj_keyslot, *jobj_keyslots;
const keyslot_handler *h;
h = LUKS2_keyslot_handler(cd, keyslot);
if (!json_object_object_get_ex(hdr->jobj, "keyslots", &jobj_keyslots))
return -EINVAL;
jobj_keyslot = LUKS2_get_keyslot_jobj(hdr, keyslot);
if (!jobj_keyslot)
return -ENOENT;
if (wipe_area_only)
log_dbg(cd, "Wiping keyslot %d area only.", keyslot);
r = LUKS2_device_write_lock(cd, hdr, device);
if (r)
return r;
/* secure deletion of possible key material in keyslot area */
r = crypt_keyslot_area(cd, keyslot, &area_offset, &area_length);
if (r && r != -ENOENT)
goto out;
if (!r) {
r = crypt_wipe_device(cd, device, CRYPT_WIPE_SPECIAL, area_offset,
area_length, area_length, NULL, NULL);
if (r) {
if (r == -EACCES) {
log_err(cd, _("Cannot write to device %s, permission denied."),
device_path(device));
r = -EINVAL;
} else
log_err(cd, _("Cannot wipe device %s."), device_path(device));
goto out;
}
}
if (wipe_area_only)
goto out;
/* Slot specific wipe */
if (h) {
r = h->wipe(cd, keyslot);
if (r < 0)
goto out;
} else
log_dbg(cd, "Wiping keyslot %d without specific-slot handler loaded.", keyslot);
json_object_object_del_by_uint(jobj_keyslots, keyslot);
r = LUKS2_hdr_write(cd, hdr);
out:
device_write_unlock(cd, crypt_metadata_device(cd));
return r;
}
int LUKS2_keyslot_dump(struct crypt_device *cd, int keyslot)
{
const keyslot_handler *h;
if (!(h = LUKS2_keyslot_handler(cd, keyslot)))
return -EINVAL;
return h->dump(cd, keyslot);
}
crypt_keyslot_priority LUKS2_keyslot_priority_get(struct luks2_hdr *hdr, int keyslot)
{
json_object *jobj_keyslot, *jobj_priority;
jobj_keyslot = LUKS2_get_keyslot_jobj(hdr, keyslot);
if (!jobj_keyslot)
return CRYPT_SLOT_PRIORITY_INVALID;
if (!json_object_object_get_ex(jobj_keyslot, "priority", &jobj_priority))
return CRYPT_SLOT_PRIORITY_NORMAL;
return json_object_get_int(jobj_priority);
}
int LUKS2_keyslot_priority_set(struct crypt_device *cd, struct luks2_hdr *hdr,
int keyslot, crypt_keyslot_priority priority, int commit)
{
json_object *jobj_keyslot;
jobj_keyslot = LUKS2_get_keyslot_jobj(hdr, keyslot);
if (!jobj_keyslot)
return -EINVAL;
if (priority == CRYPT_SLOT_PRIORITY_NORMAL)
json_object_object_del(jobj_keyslot, "priority");
else
json_object_object_add(jobj_keyslot, "priority", json_object_new_int(priority));
return commit ? LUKS2_hdr_write(cd, hdr) : 0;
}
int placeholder_keyslot_alloc(struct crypt_device *cd,
int keyslot,
uint64_t area_offset,
uint64_t area_length)
{
struct luks2_hdr *hdr;
json_object *jobj_keyslots, *jobj_keyslot, *jobj_area;
log_dbg(cd, "Allocating placeholder keyslot %d for LUKS1 down conversion.", keyslot);
if (!(hdr = crypt_get_hdr(cd, CRYPT_LUKS2)))
return -EINVAL;
if (keyslot < 0 || keyslot >= LUKS2_KEYSLOTS_MAX)
return -EINVAL;
if (LUKS2_get_keyslot_jobj(hdr, keyslot))
return -EINVAL;
if (!json_object_object_get_ex(hdr->jobj, "keyslots", &jobj_keyslots))
return -EINVAL;
jobj_keyslot = json_object_new_object();
json_object_object_add(jobj_keyslot, "type", json_object_new_string("placeholder"));
/*
* key_size = -1 makes placeholder keyslot impossible to pass validation.
* It's a safeguard against accidentally storing temporary conversion
* LUKS2 header.
*/
json_object_object_add(jobj_keyslot, "key_size", json_object_new_int(-1));
/* Area object */
jobj_area = json_object_new_object();
json_object_object_add(jobj_area, "offset", crypt_jobj_new_uint64(area_offset));
json_object_object_add(jobj_area, "size", crypt_jobj_new_uint64(area_length));
json_object_object_add(jobj_keyslot, "area", jobj_area);
json_object_object_add_by_uint(jobj_keyslots, keyslot, jobj_keyslot);
return 0;
}
static unsigned LUKS2_get_keyslot_digests_count(json_object *hdr_jobj, int keyslot)
{
char num[16];
json_object *jobj_digests, *jobj_keyslots;
unsigned count = 0;
if (!json_object_object_get_ex(hdr_jobj, "digests", &jobj_digests))
return 0;
if (snprintf(num, sizeof(num), "%u", keyslot) < 0)
return 0;
json_object_object_foreach(jobj_digests, key, val) {
UNUSED(key);
json_object_object_get_ex(val, "keyslots", &jobj_keyslots);
if (LUKS2_array_jobj(jobj_keyslots, num))
count++;
}
return count;
}
/* run only on header that passed basic format validation */
int LUKS2_keyslots_validate(struct crypt_device *cd, json_object *hdr_jobj)
{
const keyslot_handler *h;
int keyslot;
json_object *jobj_keyslots, *jobj_type;
uint32_t reqs, reencrypt_count = 0;
struct luks2_hdr dummy = {
.jobj = hdr_jobj
};
if (!json_object_object_get_ex(hdr_jobj, "keyslots", &jobj_keyslots))
return -EINVAL;
if (LUKS2_config_get_requirements(cd, &dummy, &reqs))
return -EINVAL;
json_object_object_foreach(jobj_keyslots, slot, val) {
keyslot = atoi(slot);
json_object_object_get_ex(val, "type", &jobj_type);
h = LUKS2_keyslot_handler_type(json_object_get_string(jobj_type));
if (!h)
continue;
if (h->validate && h->validate(cd, val)) {
log_dbg(cd, "Keyslot type %s validation failed on keyslot %d.", h->name, keyslot);
return -EINVAL;
}
if (!strcmp(h->name, "luks2") && LUKS2_get_keyslot_digests_count(hdr_jobj, keyslot) != 1) {
log_dbg(cd, "Keyslot %d is not assigned to exactly 1 digest.", keyslot);
return -EINVAL;
}
if (!strcmp(h->name, "reencrypt"))
reencrypt_count++;
}
if ((reqs & CRYPT_REQUIREMENT_ONLINE_REENCRYPT) && reencrypt_count == 0) {
log_dbg(cd, "Missing reencryption keyslot.");
return -EINVAL;
}
if (reencrypt_count && !LUKS2_reencrypt_requirement_candidate(&dummy)) {
log_dbg(cd, "Missing reencryption requirement flag.");
return -EINVAL;
}
if (reencrypt_count > 1) {
log_dbg(cd, "Too many reencryption keyslots.");
return -EINVAL;
}
return 0;
}
void LUKS2_keyslots_repair(struct crypt_device *cd, json_object *jobj_keyslots)
{
const keyslot_handler *h;
json_object *jobj_type;
json_object_object_foreach(jobj_keyslots, slot, val) {
UNUSED(slot);
if (!json_object_is_type(val, json_type_object) ||
!json_object_object_get_ex(val, "type", &jobj_type) ||
!json_object_is_type(jobj_type, json_type_string))
continue;
h = LUKS2_keyslot_handler_type(json_object_get_string(jobj_type));
if (h && h->repair)
h->repair(val);
}
}
/* assumes valid header */
int LUKS2_find_keyslot(struct luks2_hdr *hdr, const char *type)
{
int i;
json_object *jobj_keyslot, *jobj_type;
if (!type)
return -EINVAL;
for (i = 0; i < LUKS2_KEYSLOTS_MAX; i++) {
jobj_keyslot = LUKS2_get_keyslot_jobj(hdr, i);
if (!jobj_keyslot)
continue;
json_object_object_get_ex(jobj_keyslot, "type", &jobj_type);
if (!strcmp(json_object_get_string(jobj_type), type))
return i;
}
return -ENOENT;
}
/* assumes valid header, it does not move references in tokens/digests etc! */
int LUKS2_keyslot_swap(struct crypt_device *cd, struct luks2_hdr *hdr,
int keyslot, int keyslot2)
{
json_object *jobj_keyslots, *jobj_keyslot, *jobj_keyslot2;
int r;
if (!json_object_object_get_ex(hdr->jobj, "keyslots", &jobj_keyslots))
return -EINVAL;
jobj_keyslot = LUKS2_get_keyslot_jobj(hdr, keyslot);
if (!jobj_keyslot)
return -EINVAL;
jobj_keyslot2 = LUKS2_get_keyslot_jobj(hdr, keyslot2);
if (!jobj_keyslot2)
return -EINVAL;
/* This transfer owner of object, no need for json_object_put */
json_object_get(jobj_keyslot);
json_object_get(jobj_keyslot2);
json_object_object_del_by_uint(jobj_keyslots, keyslot);
r = json_object_object_add_by_uint(jobj_keyslots, keyslot, jobj_keyslot2);
if (r < 0) {
log_dbg(cd, "Failed to swap keyslot %d.", keyslot);
return r;
}
json_object_object_del_by_uint(jobj_keyslots, keyslot2);
r = json_object_object_add_by_uint(jobj_keyslots, keyslot2, jobj_keyslot);
if (r < 0)
log_dbg(cd, "Failed to swap keyslot2 %d.", keyslot2);
return r;
}
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