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|
/*
* LUKS - Linux Unified Key Setup v2
*
* Copyright (C) 2015-2021 Red Hat, Inc. All rights reserved.
* Copyright (C) 2015-2021 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 <assert.h>
#include "luks2_internal.h"
/*
* Helper functions
*/
static json_object *parse_json_len(struct crypt_device *cd, const char *json_area,
uint64_t max_length, int *json_len)
{
json_object *jobj;
struct json_tokener *jtok;
/* INT32_MAX is internal (json-c) json_tokener_parse_ex() limit */
if (!json_area || max_length > INT32_MAX)
return NULL;
jtok = json_tokener_new();
if (!jtok) {
log_dbg(cd, "ERROR: Failed to init json tokener");
return NULL;
}
jobj = json_tokener_parse_ex(jtok, json_area, max_length);
if (!jobj)
log_dbg(cd, "ERROR: Failed to parse json data (%d): %s",
json_tokener_get_error(jtok),
json_tokener_error_desc(json_tokener_get_error(jtok)));
else
*json_len = jtok->char_offset;
json_tokener_free(jtok);
return jobj;
}
static void log_dbg_checksum(struct crypt_device *cd,
const uint8_t *csum, const char *csum_alg, const char *info)
{
char csum_txt[2*LUKS2_CHECKSUM_L+1];
int i;
for (i = 0; i < crypt_hash_size(csum_alg); i++)
snprintf(&csum_txt[i*2], 3, "%02hhx", (const char)csum[i]);
csum_txt[i*2+1] = '\0'; /* Just to be safe, sprintf should write \0 there. */
log_dbg(cd, "Checksum:%s (%s)", &csum_txt[0], info);
}
/*
* Calculate hash (checksum) of |LUKS2_bin|LUKS2_JSON_area| from in-memory structs.
* LUKS2 on-disk header contains uniques salt both for primary and secondary header.
* Checksum is always calculated with zeroed checksum field in binary header.
*/
static int hdr_checksum_calculate(const char *alg, struct luks2_hdr_disk *hdr_disk,
const char *json_area, size_t json_len)
{
struct crypt_hash *hd = NULL;
int hash_size, r;
hash_size = crypt_hash_size(alg);
if (hash_size <= 0 || crypt_hash_init(&hd, alg))
return -EINVAL;
/* Binary header, csum zeroed. */
r = crypt_hash_write(hd, (char*)hdr_disk, LUKS2_HDR_BIN_LEN);
/* JSON area (including unused space) */
if (!r)
r = crypt_hash_write(hd, json_area, json_len);
if (!r)
r = crypt_hash_final(hd, (char*)hdr_disk->csum, (size_t)hash_size);
crypt_hash_destroy(hd);
return r;
}
/*
* Compare hash (checksum) of on-disk and in-memory header.
*/
static int hdr_checksum_check(struct crypt_device *cd,
const char *alg, struct luks2_hdr_disk *hdr_disk,
const char *json_area, size_t json_len)
{
struct luks2_hdr_disk hdr_tmp;
int hash_size, r;
hash_size = crypt_hash_size(alg);
if (hash_size <= 0)
return -EINVAL;
/* Copy header and zero checksum. */
memcpy(&hdr_tmp, hdr_disk, LUKS2_HDR_BIN_LEN);
memset(&hdr_tmp.csum, 0, sizeof(hdr_tmp.csum));
r = hdr_checksum_calculate(alg, &hdr_tmp, json_area, json_len);
if (r < 0)
return r;
log_dbg_checksum(cd, hdr_disk->csum, alg, "on-disk");
log_dbg_checksum(cd, hdr_tmp.csum, alg, "in-memory");
if (memcmp(hdr_tmp.csum, hdr_disk->csum, (size_t)hash_size))
return -EINVAL;
return 0;
}
/*
* Convert header from on-disk format to in-memory struct
*/
static void hdr_from_disk(struct luks2_hdr_disk *hdr_disk1,
struct luks2_hdr_disk *hdr_disk2,
struct luks2_hdr *hdr,
int secondary)
{
hdr->version = be16_to_cpu(hdr_disk1->version);
hdr->hdr_size = be64_to_cpu(hdr_disk1->hdr_size);
hdr->seqid = be64_to_cpu(hdr_disk1->seqid);
memcpy(hdr->label, hdr_disk1->label, LUKS2_LABEL_L);
hdr->label[LUKS2_LABEL_L - 1] = '\0';
memcpy(hdr->subsystem, hdr_disk1->subsystem, LUKS2_LABEL_L);
hdr->subsystem[LUKS2_LABEL_L - 1] = '\0';
memcpy(hdr->checksum_alg, hdr_disk1->checksum_alg, LUKS2_CHECKSUM_ALG_L);
hdr->checksum_alg[LUKS2_CHECKSUM_ALG_L - 1] = '\0';
memcpy(hdr->uuid, hdr_disk1->uuid, LUKS2_UUID_L);
hdr->uuid[LUKS2_UUID_L - 1] = '\0';
if (secondary) {
memcpy(hdr->salt1, hdr_disk2->salt, LUKS2_SALT_L);
memcpy(hdr->salt2, hdr_disk1->salt, LUKS2_SALT_L);
} else {
memcpy(hdr->salt1, hdr_disk1->salt, LUKS2_SALT_L);
memcpy(hdr->salt2, hdr_disk2->salt, LUKS2_SALT_L);
}
}
/*
* Convert header from in-memory struct to on-disk format
*/
static void hdr_to_disk(struct luks2_hdr *hdr,
struct luks2_hdr_disk *hdr_disk,
int secondary, uint64_t offset)
{
assert(((char*)&(hdr_disk->_padding4096) - (char*)&(hdr_disk->magic)) == 512);
memset(hdr_disk, 0, LUKS2_HDR_BIN_LEN);
memcpy(&hdr_disk->magic, secondary ? LUKS2_MAGIC_2ND : LUKS2_MAGIC_1ST, LUKS2_MAGIC_L);
hdr_disk->version = cpu_to_be16(hdr->version);
hdr_disk->hdr_size = cpu_to_be64(hdr->hdr_size);
hdr_disk->hdr_offset = cpu_to_be64(offset);
hdr_disk->seqid = cpu_to_be64(hdr->seqid);
memcpy(hdr_disk->label, hdr->label, MIN(strlen(hdr->label), LUKS2_LABEL_L));
hdr_disk->label[LUKS2_LABEL_L - 1] = '\0';
memcpy(hdr_disk->subsystem, hdr->subsystem, MIN(strlen(hdr->subsystem), LUKS2_LABEL_L));
hdr_disk->subsystem[LUKS2_LABEL_L - 1] = '\0';
memcpy(hdr_disk->checksum_alg, hdr->checksum_alg, MIN(strlen(hdr->checksum_alg), LUKS2_CHECKSUM_ALG_L));
hdr_disk->checksum_alg[LUKS2_CHECKSUM_ALG_L - 1] = '\0';
memcpy(hdr_disk->uuid, hdr->uuid, MIN(strlen(hdr->uuid), LUKS2_UUID_L));
hdr_disk->uuid[LUKS2_UUID_L - 1] = '\0';
memcpy(hdr_disk->salt, secondary ? hdr->salt2 : hdr->salt1, LUKS2_SALT_L);
}
/*
* Sanity checks before checksum is validated
*/
static int hdr_disk_sanity_check_pre(struct crypt_device *cd,
struct luks2_hdr_disk *hdr,
size_t *hdr_json_size, int secondary,
uint64_t offset)
{
if (memcmp(hdr->magic, secondary ? LUKS2_MAGIC_2ND : LUKS2_MAGIC_1ST, LUKS2_MAGIC_L))
return -EINVAL;
if (be16_to_cpu(hdr->version) != 2) {
log_dbg(cd, "Unsupported LUKS2 header version %u.", be16_to_cpu(hdr->version));
return -EINVAL;
}
if (offset != be64_to_cpu(hdr->hdr_offset)) {
log_dbg(cd, "LUKS2 offset 0x%04x on device differs to expected offset 0x%04x.",
(unsigned)be64_to_cpu(hdr->hdr_offset), (unsigned)offset);
return -EINVAL;
}
if (secondary && (offset != be64_to_cpu(hdr->hdr_size))) {
log_dbg(cd, "LUKS2 offset 0x%04x in secondary header does not match size 0x%04x.",
(unsigned)offset, (unsigned)be64_to_cpu(hdr->hdr_size));
return -EINVAL;
}
/* FIXME: sanity check checksum alg. */
log_dbg(cd, "LUKS2 header version %u of size %u bytes, checksum %s.",
(unsigned)be16_to_cpu(hdr->version), (unsigned)be64_to_cpu(hdr->hdr_size),
hdr->checksum_alg);
*hdr_json_size = be64_to_cpu(hdr->hdr_size) - LUKS2_HDR_BIN_LEN;
return 0;
}
/*
* Read LUKS2 header from disk at specific offset.
*/
static int hdr_read_disk(struct crypt_device *cd,
struct device *device, struct luks2_hdr_disk *hdr_disk,
char **json_area, uint64_t offset, int secondary)
{
size_t hdr_json_size = 0;
int devfd, r;
log_dbg(cd, "Trying to read %s LUKS2 header at offset 0x%" PRIx64 ".",
secondary ? "secondary" : "primary", offset);
devfd = device_open_locked(cd, device, O_RDONLY);
if (devfd < 0)
return devfd == -1 ? -EIO : devfd;
/*
* Read binary header and run sanity check before reading
* JSON area and validating checksum.
*/
if (read_lseek_blockwise(devfd, device_block_size(cd, device),
device_alignment(device), hdr_disk,
LUKS2_HDR_BIN_LEN, offset) != LUKS2_HDR_BIN_LEN) {
return -EIO;
}
r = hdr_disk_sanity_check_pre(cd, hdr_disk, &hdr_json_size, secondary, offset);
if (r < 0) {
return r;
}
/*
* Allocate and read JSON area. Always the whole area must be read.
*/
*json_area = malloc(hdr_json_size);
if (!*json_area) {
return -ENOMEM;
}
if (read_lseek_blockwise(devfd, device_block_size(cd, device),
device_alignment(device), *json_area, hdr_json_size,
offset + LUKS2_HDR_BIN_LEN) != (ssize_t)hdr_json_size) {
free(*json_area);
*json_area = NULL;
return -EIO;
}
/*
* Calculate and validate checksum and zero it afterwards.
*/
if (hdr_checksum_check(cd, hdr_disk->checksum_alg, hdr_disk,
*json_area, hdr_json_size)) {
log_dbg(cd, "LUKS2 header checksum error (offset %" PRIu64 ").", offset);
r = -EINVAL;
}
memset(hdr_disk->csum, 0, LUKS2_CHECKSUM_L);
return r;
}
/*
* Write LUKS2 header to disk at specific offset.
*/
static int hdr_write_disk(struct crypt_device *cd,
struct device *device, struct luks2_hdr *hdr,
const char *json_area, int secondary)
{
struct luks2_hdr_disk hdr_disk;
uint64_t offset = secondary ? hdr->hdr_size : 0;
size_t hdr_json_len;
int devfd, r;
log_dbg(cd, "Trying to write LUKS2 header (%zu bytes) at offset %" PRIu64 ".",
hdr->hdr_size, offset);
/* FIXME: read-only device silent fail? */
devfd = device_open_locked(cd, device, O_RDWR);
if (devfd < 0)
return devfd == -1 ? -EINVAL : devfd;
hdr_json_len = hdr->hdr_size - LUKS2_HDR_BIN_LEN;
hdr_to_disk(hdr, &hdr_disk, secondary, offset);
/*
* Write header without checksum but with proper seqid.
*/
if (write_lseek_blockwise(devfd, device_block_size(cd, device),
device_alignment(device), (char *)&hdr_disk,
LUKS2_HDR_BIN_LEN, offset) < (ssize_t)LUKS2_HDR_BIN_LEN) {
return -EIO;
}
/*
* Write json area.
*/
if (write_lseek_blockwise(devfd, device_block_size(cd, device),
device_alignment(device),
CONST_CAST(char*)json_area, hdr_json_len,
LUKS2_HDR_BIN_LEN + offset) < (ssize_t)hdr_json_len) {
return -EIO;
}
/*
* Calculate checksum and write header with checksum.
*/
r = hdr_checksum_calculate(hdr_disk.checksum_alg, &hdr_disk,
json_area, hdr_json_len);
if (r < 0) {
return r;
}
log_dbg_checksum(cd, hdr_disk.csum, hdr_disk.checksum_alg, "in-memory");
if (write_lseek_blockwise(devfd, device_block_size(cd, device),
device_alignment(device), (char *)&hdr_disk,
LUKS2_HDR_BIN_LEN, offset) < (ssize_t)LUKS2_HDR_BIN_LEN)
r = -EIO;
device_sync(cd, device);
return r;
}
static int LUKS2_check_sequence_id(struct crypt_device *cd, struct luks2_hdr *hdr, struct device *device)
{
int devfd;
struct luks2_hdr_disk dhdr;
if (!hdr)
return -EINVAL;
devfd = device_open_locked(cd, device, O_RDONLY);
if (devfd < 0)
return devfd == -1 ? -EINVAL : devfd;
/* we need only first 512 bytes, see luks2_hdr_disk structure */
if ((read_lseek_blockwise(devfd, device_block_size(cd, device),
device_alignment(device), &dhdr, 512, 0) != 512))
return -EIO;
/* there's nothing to check if there's no LUKS2 header */
if ((be16_to_cpu(dhdr.version) != 2) ||
memcmp(dhdr.magic, LUKS2_MAGIC_1ST, LUKS2_MAGIC_L) ||
strcmp(dhdr.uuid, hdr->uuid))
return 0;
return hdr->seqid != be64_to_cpu(dhdr.seqid);
}
int LUKS2_device_write_lock(struct crypt_device *cd, struct luks2_hdr *hdr, struct device *device)
{
int r = device_write_lock(cd, device);
if (r < 0) {
log_err(cd, _("Failed to acquire write lock on device %s."), device_path(device));
return r;
}
/* run sequence id check only on first write lock (r == 1) and w/o LUKS2 reencryption in-progress */
if (r == 1 && !crypt_get_luks2_reencrypt(cd)) {
log_dbg(cd, "Checking context sequence id matches value stored on disk.");
if (LUKS2_check_sequence_id(cd, hdr, device)) {
device_write_unlock(cd, device);
log_err(cd, _("Detected attempt for concurrent LUKS2 metadata update. Aborting operation."));
return -EINVAL;
}
}
return 0;
}
/*
* Convert in-memory LUKS2 header and write it to disk.
* This will increase sequence id, write both header copies and calculate checksum.
*/
int LUKS2_disk_hdr_write(struct crypt_device *cd, struct luks2_hdr *hdr, struct device *device, bool seqid_check)
{
char *json_area;
const char *json_text;
size_t json_area_len;
int r;
if (hdr->version != 2) {
log_dbg(cd, "Unsupported LUKS2 header version (%u).", hdr->version);
return -EINVAL;
}
r = device_check_size(cd, crypt_metadata_device(cd), LUKS2_hdr_and_areas_size(hdr), 1);
if (r)
return r;
/*
* Allocate and zero JSON area (of proper header size).
*/
json_area_len = hdr->hdr_size - LUKS2_HDR_BIN_LEN;
json_area = crypt_zalloc(json_area_len);
if (!json_area)
return -ENOMEM;
/*
* Generate text space-efficient JSON representation to json area.
*/
json_text = json_object_to_json_string_ext(hdr->jobj,
JSON_C_TO_STRING_PLAIN | JSON_C_TO_STRING_NOSLASHESCAPE);
if (!json_text || !*json_text) {
log_dbg(cd, "Cannot parse JSON object to text representation.");
free(json_area);
return -ENOMEM;
}
if (strlen(json_text) > (json_area_len - 1)) {
log_dbg(cd, "JSON is too large (%zu > %zu).", strlen(json_text), json_area_len);
free(json_area);
return -EINVAL;
}
strncpy(json_area, json_text, json_area_len);
if (seqid_check)
r = LUKS2_device_write_lock(cd, hdr, device);
else
r = device_write_lock(cd, device);
if (r < 0) {
free(json_area);
return r;
}
/* Increase sequence id before writing it to disk. */
hdr->seqid++;
/* Write primary and secondary header */
r = hdr_write_disk(cd, device, hdr, json_area, 0);
if (!r)
r = hdr_write_disk(cd, device, hdr, json_area, 1);
if (r)
log_dbg(cd, "LUKS2 header write failed (%d).", r);
device_write_unlock(cd, device);
free(json_area);
return r;
}
static int validate_json_area(struct crypt_device *cd, const char *json_area,
uint64_t json_len, uint64_t max_length)
{
char c;
/* Enforce there are no needless opening bytes */
if (*json_area != '{') {
log_dbg(cd, "ERROR: Opening character must be left curly bracket: '{'.");
return -EINVAL;
}
if (json_len >= max_length) {
log_dbg(cd, "ERROR: Missing trailing null byte beyond parsed json data string.");
return -EINVAL;
}
/*
* TODO:
* validate there are legal json format characters between
* 'json_area' and 'json_area + json_len'
*/
do {
c = *(json_area + json_len);
if (c != '\0') {
log_dbg(cd, "ERROR: Forbidden ascii code 0x%02hhx found beyond json data string at offset %" PRIu64,
c, json_len);
return -EINVAL;
}
} while (++json_len < max_length);
return 0;
}
static int validate_luks2_json_object(struct crypt_device *cd, json_object *jobj_hdr, uint64_t length)
{
int r;
/* we require top level object to be of json_type_object */
r = !json_object_is_type(jobj_hdr, json_type_object);
if (r) {
log_dbg(cd, "ERROR: Resulting object is not a json object type");
return r;
}
r = LUKS2_hdr_validate(cd, jobj_hdr, length);
if (r) {
log_dbg(cd, "Repairing JSON metadata.");
/* try to correct known glitches */
LUKS2_hdr_repair(cd, jobj_hdr);
/* run validation again */
r = LUKS2_hdr_validate(cd, jobj_hdr, length);
}
if (r)
log_dbg(cd, "ERROR: LUKS2 validation failed");
return r;
}
static json_object *parse_and_validate_json(struct crypt_device *cd,
const char *json_area, uint64_t max_length)
{
int json_len, r;
json_object *jobj = parse_json_len(cd, json_area, max_length, &json_len);
if (!jobj)
return NULL;
/* successful parse_json_len must not return offset <= 0 */
assert(json_len > 0);
r = validate_json_area(cd, json_area, json_len, max_length);
if (!r)
r = validate_luks2_json_object(cd, jobj, max_length);
if (r) {
json_object_put(jobj);
jobj = NULL;
}
return jobj;
}
static int detect_device_signatures(struct crypt_device *cd, const char *path)
{
blk_probe_status prb_state;
int r;
struct blkid_handle *h;
if (!blk_supported()) {
log_dbg(cd, "Blkid probing of device signatures disabled.");
return 0;
}
if ((r = blk_init_by_path(&h, path))) {
log_dbg(cd, "Failed to initialize blkid_handle by path.");
return -EINVAL;
}
/* We don't care about details. Be fast. */
blk_set_chains_for_fast_detection(h);
/* Filter out crypto_LUKS. we don't care now */
blk_superblocks_filter_luks(h);
prb_state = blk_safeprobe(h);
switch (prb_state) {
case PRB_AMBIGUOUS:
log_dbg(cd, "Blkid probe couldn't decide device type unambiguously.");
/* fall through */
case PRB_FAIL:
log_dbg(cd, "Blkid probe failed.");
r = -EINVAL;
break;
case PRB_OK: /* crypto_LUKS type is filtered out */
r = -EINVAL;
if (blk_is_partition(h))
log_dbg(cd, "Blkid probe detected partition type '%s'", blk_get_partition_type(h));
else if (blk_is_superblock(h))
log_dbg(cd, "blkid probe detected superblock type '%s'", blk_get_superblock_type(h));
break;
case PRB_EMPTY:
log_dbg(cd, "Blkid probe detected no foreign device signature.");
}
blk_free(h);
return r;
}
/*
* Read and convert on-disk LUKS2 header to in-memory representation..
* Try to do recovery if on-disk state is not consistent.
*/
int LUKS2_disk_hdr_read(struct crypt_device *cd, struct luks2_hdr *hdr,
struct device *device, int do_recovery, int do_blkprobe)
{
enum { HDR_OK, HDR_OBSOLETE, HDR_FAIL, HDR_FAIL_IO } state_hdr1, state_hdr2;
struct luks2_hdr_disk hdr_disk1, hdr_disk2;
char *json_area1 = NULL, *json_area2 = NULL;
json_object *jobj_hdr1 = NULL, *jobj_hdr2 = NULL;
unsigned int i;
int r;
uint64_t hdr_size;
uint64_t hdr2_offsets[] = LUKS2_HDR2_OFFSETS;
/* Skip auto-recovery if locks are disabled and we're not doing LUKS2 explicit repair */
if (do_recovery && do_blkprobe && !crypt_metadata_locking_enabled()) {
do_recovery = 0;
log_dbg(cd, "Disabling header auto-recovery due to locking being disabled.");
}
/*
* Read primary LUKS2 header (offset 0).
*/
state_hdr1 = HDR_FAIL;
r = hdr_read_disk(cd, device, &hdr_disk1, &json_area1, 0, 0);
if (r == 0) {
jobj_hdr1 = parse_and_validate_json(cd, json_area1, be64_to_cpu(hdr_disk1.hdr_size) - LUKS2_HDR_BIN_LEN);
state_hdr1 = jobj_hdr1 ? HDR_OK : HDR_OBSOLETE;
} else if (r == -EIO)
state_hdr1 = HDR_FAIL_IO;
/*
* Read secondary LUKS2 header (follows primary).
*/
state_hdr2 = HDR_FAIL;
if (state_hdr1 != HDR_FAIL && state_hdr1 != HDR_FAIL_IO) {
r = hdr_read_disk(cd, device, &hdr_disk2, &json_area2, be64_to_cpu(hdr_disk1.hdr_size), 1);
if (r == 0) {
jobj_hdr2 = parse_and_validate_json(cd, json_area2, be64_to_cpu(hdr_disk2.hdr_size) - LUKS2_HDR_BIN_LEN);
state_hdr2 = jobj_hdr2 ? HDR_OK : HDR_OBSOLETE;
} else if (r == -EIO)
state_hdr2 = HDR_FAIL_IO;
} else {
/*
* No header size, check all known offsets.
*/
for (r = -EINVAL,i = 0; r < 0 && i < ARRAY_SIZE(hdr2_offsets); i++)
r = hdr_read_disk(cd, device, &hdr_disk2, &json_area2, hdr2_offsets[i], 1);
if (r == 0) {
jobj_hdr2 = parse_and_validate_json(cd, json_area2, be64_to_cpu(hdr_disk2.hdr_size) - LUKS2_HDR_BIN_LEN);
state_hdr2 = jobj_hdr2 ? HDR_OK : HDR_OBSOLETE;
} else if (r == -EIO)
state_hdr2 = HDR_FAIL_IO;
}
/*
* Check sequence id if both headers are read correctly.
*/
if (state_hdr1 == HDR_OK && state_hdr2 == HDR_OK) {
if (be64_to_cpu(hdr_disk1.seqid) > be64_to_cpu(hdr_disk2.seqid))
state_hdr2 = HDR_OBSOLETE;
else if (be64_to_cpu(hdr_disk1.seqid) < be64_to_cpu(hdr_disk2.seqid))
state_hdr1 = HDR_OBSOLETE;
}
/* check header with keyslots to fit the device */
if (state_hdr1 == HDR_OK)
hdr_size = LUKS2_hdr_and_areas_size_jobj(jobj_hdr1);
else if (state_hdr2 == HDR_OK)
hdr_size = LUKS2_hdr_and_areas_size_jobj(jobj_hdr2);
else {
r = (state_hdr1 == HDR_FAIL_IO && state_hdr2 == HDR_FAIL_IO) ? -EIO : -EINVAL;
goto err;
}
r = device_check_size(cd, device, hdr_size, 0);
if (r)
goto err;
/*
* Try to rewrite (recover) bad header. Always regenerate salt for bad header.
*/
if (state_hdr1 == HDR_OK && state_hdr2 != HDR_OK) {
log_dbg(cd, "Secondary LUKS2 header requires recovery.");
if (do_blkprobe && (r = detect_device_signatures(cd, device_path(device)))) {
log_err(cd, _("Device contains ambiguous signatures, cannot auto-recover LUKS2.\n"
"Please run \"cryptsetup repair\" for recovery."));
goto err;
}
if (do_recovery) {
memcpy(&hdr_disk2, &hdr_disk1, LUKS2_HDR_BIN_LEN);
r = crypt_random_get(cd, (char*)hdr_disk2.salt, sizeof(hdr_disk2.salt), CRYPT_RND_SALT);
if (r)
log_dbg(cd, "Cannot generate master salt.");
else {
hdr_from_disk(&hdr_disk1, &hdr_disk2, hdr, 0);
r = hdr_write_disk(cd, device, hdr, json_area1, 1);
}
if (r)
log_dbg(cd, "Secondary LUKS2 header recovery failed.");
}
} else if (state_hdr1 != HDR_OK && state_hdr2 == HDR_OK) {
log_dbg(cd, "Primary LUKS2 header requires recovery.");
if (do_blkprobe && (r = detect_device_signatures(cd, device_path(device)))) {
log_err(cd, _("Device contains ambiguous signatures, cannot auto-recover LUKS2.\n"
"Please run \"cryptsetup repair\" for recovery."));
goto err;
}
if (do_recovery) {
memcpy(&hdr_disk1, &hdr_disk2, LUKS2_HDR_BIN_LEN);
r = crypt_random_get(cd, (char*)hdr_disk1.salt, sizeof(hdr_disk1.salt), CRYPT_RND_SALT);
if (r)
log_dbg(cd, "Cannot generate master salt.");
else {
hdr_from_disk(&hdr_disk2, &hdr_disk1, hdr, 1);
r = hdr_write_disk(cd, device, hdr, json_area2, 0);
}
if (r)
log_dbg(cd, "Primary LUKS2 header recovery failed.");
}
}
free(json_area1);
json_area1 = NULL;
free(json_area2);
json_area2 = NULL;
/* wrong lock for write mode during recovery attempt */
if (r == -EAGAIN)
goto err;
/*
* Even if status is failed, the second header includes salt.
*/
if (state_hdr1 == HDR_OK) {
hdr_from_disk(&hdr_disk1, &hdr_disk2, hdr, 0);
hdr->jobj = jobj_hdr1;
json_object_put(jobj_hdr2);
} else if (state_hdr2 == HDR_OK) {
hdr_from_disk(&hdr_disk2, &hdr_disk1, hdr, 1);
hdr->jobj = jobj_hdr2;
json_object_put(jobj_hdr1);
}
/*
* FIXME: should this fail? At least one header was read correctly.
* r = (state_hdr1 == HDR_FAIL_IO || state_hdr2 == HDR_FAIL_IO) ? -EIO : -EINVAL;
*/
return 0;
err:
log_dbg(cd, "LUKS2 header read failed (%d).", r);
free(json_area1);
free(json_area2);
json_object_put(jobj_hdr1);
json_object_put(jobj_hdr2);
hdr->jobj = NULL;
return r;
}
int LUKS2_hdr_version_unlocked(struct crypt_device *cd, const char *backup_file)
{
struct {
char magic[LUKS2_MAGIC_L];
uint16_t version;
} __attribute__ ((packed)) hdr;
struct device *device = NULL;
int r = 0, devfd = -1, flags;
if (!backup_file)
device = crypt_metadata_device(cd);
else if (device_alloc(cd, &device, backup_file) < 0)
return 0;
if (!device)
return 0;
flags = O_RDONLY;
if (device_direct_io(device))
flags |= O_DIRECT;
devfd = open(device_path(device), flags);
if (devfd < 0)
goto err;
if ((read_lseek_blockwise(devfd, device_block_size(cd, device),
device_alignment(device), &hdr, sizeof(hdr), 0) == sizeof(hdr)) &&
!memcmp(hdr.magic, LUKS2_MAGIC_1ST, LUKS2_MAGIC_L))
r = (int)be16_to_cpu(hdr.version);
err:
if (devfd != -1)
close(devfd);
if (backup_file)
device_free(cd, device);
return r;
}
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