/*
* ks_token.c
* ----------
* Keystore implementation in flash memory.
*
* Authors: Rob Austein, Fredrik Thulin
* Copyright (c) 2015-2017, NORDUnet A/S All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are
* met:
* - Redistributions of source code must retain the above copyright notice,
* this list of conditions and the following disclaimer.
*
* - Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
*
* - Neither the name of the NORDUnet nor the names of its contributors may
* be used to endorse or promote products derived from this software
* without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS
* IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
* TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A
* PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
* HOLDER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
* SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED
* TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
* PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF
* LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING
* NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
/*
* This keystore driver operates over bare flash, versus over a flash file
* system or flash translation layer. The block size is large enough to
* hold an AES-keywrapped 4096-bit RSA key. Any remaining space in the key
* block may be used to store attributes (opaque TLV blobs). If the
* attributes overflow the key block, additional blocks may be added, but
* no attribute may exceed the block size.
*/
#include <stddef.h>
#include <string.h>
#include "hal.h"
#include "hal_internal.h"
#include "ks.h"
#include "last_gasp_pin_internal.h"
#define HAL_OK CMSIS_HAL_OK
#include "stm-keystore.h"
#undef HAL_OK
#ifndef KS_TOKEN_CACHE_SIZE
#define KS_TOKEN_CACHE_SIZE 4
#endif
#if HAL_KS_BLOCK_SIZE % KEYSTORE_SUBSECTOR_SIZE != 0
#error Keystore block size is not a multiple of flash subsector size
#endif
#define NUM_FLASH_BLOCKS ((KEYSTORE_NUM_SUBSECTORS * KEYSTORE_SUBSECTOR_SIZE) / HAL_KS_BLOCK_SIZE)
#define SUBSECTORS_PER_BLOCK (HAL_KS_BLOCK_SIZE / KEYSTORE_SUBSECTOR_SIZE)
/*
* Keystore database.
*/
typedef struct {
hal_ks_t ks; /* Must be first (C "subclassing") */
hal_ks_pin_t wheel_pin;
hal_ks_pin_t so_pin;
hal_ks_pin_t user_pin;
} ks_token_db_t;
/*
* This is a bit silly, but it's safe enough, and it lets us avoid a
* nasty mess of forward references.
*/
#define db ((ks_token_db_t * const) hal_ks_token)
/*
* Calculate offset of the block in the flash address space.
*/
static inline uint32_t ks_token_offset(const unsigned blockno)
{
return blockno * HAL_KS_BLOCK_SIZE;
}
/*
* Read a flash block.
*
* Flash read on the Alpha is slow enough that it pays to check the
* first page before reading the rest of the block.
*/
static hal_error_t ks_token_read(hal_ks_t *ks, const unsigned blockno, hal_ks_block_t *block)
{
if (ks != hal_ks_token || block == NULL || blockno >= NUM_FLASH_BLOCKS || sizeof(*block) != HAL_KS_BLOCK_SIZE)
return HAL_ERROR_IMPOSSIBLE;
if (keystore_read_data(ks_token_offset(blockno),
block->bytes,
KEYSTORE_PAGE_SIZE) != CMSIS_HAL_OK)
return HAL_ERROR_KEYSTORE_ACCESS;
switch (hal_ks_block_get_type(block)) {
case HAL_KS_BLOCK_TYPE_ERASED:
case HAL_KS_BLOCK_TYPE_ZEROED:
return HAL_OK;
case HAL_KS_BLOCK_TYPE_KEY:
case HAL_KS_BLOCK_TYPE_PIN:
break;
default:
return HAL_ERROR_KEYSTORE_BAD_BLOCK_TYPE;
}
switch (hal_ks_block_get_status(block)) {
case HAL_KS_BLOCK_STATUS_LIVE:
case HAL_KS_BLOCK_STATUS_TOMBSTONE:
break;
default:
return HAL_ERROR_KEYSTORE_BAD_BLOCK_TYPE;
}
if (keystore_read_data(ks_token_offset(blockno) + KEYSTORE_PAGE_SIZE,
block->bytes + KEYSTORE_PAGE_SIZE,
sizeof(*block) - KEYSTORE_PAGE_SIZE) != CMSIS_HAL_OK)
return HAL_ERROR_KEYSTORE_ACCESS;
if (hal_ks_block_calculate_crc(block) != block->header.crc)
return HAL_ERROR_KEYSTORE_BAD_CRC;
return HAL_OK;
}
/*
* Convert a live block into a tombstone. Caller is responsible for
* making sure that the block being converted is valid; since we don't
* need to update the CRC for this, we just modify the first page.
*/
static hal_error_t ks_token_deprecate(hal_ks_t *ks, const unsigned blockno)
{
if (ks != hal_ks_token || blockno >= NUM_FLASH_BLOCKS)
return HAL_ERROR_IMPOSSIBLE;
uint8_t page[KEYSTORE_PAGE_SIZE];
hal_ks_block_header_t *header = (void *) page;
uint32_t offset = ks_token_offset(blockno);
if (keystore_read_data(offset, page, sizeof(page)) != CMSIS_HAL_OK)
return HAL_ERROR_KEYSTORE_ACCESS;
header->block_status = HAL_KS_BLOCK_STATUS_TOMBSTONE;
if (keystore_write_data(offset, page, sizeof(page)) != CMSIS_HAL_OK)
return HAL_ERROR_KEYSTORE_ACCESS;
return HAL_OK;
}
/*
* Zero (not erase) a flash block. Just need to zero the first page.
*/
static hal_error_t ks_token_zero(hal_ks_t *ks, const unsigned blockno)
{
if (ks != hal_ks_token || blockno >= NUM_FLASH_BLOCKS)
return HAL_ERROR_IMPOSSIBLE;
uint8_t page[KEYSTORE_PAGE_SIZE] = {0};
if (keystore_write_data(ks_token_offset(blockno), page, sizeof(page)) != CMSIS_HAL_OK)
return HAL_ERROR_KEYSTORE_ACCESS;
return HAL_OK;
}
/*
* Erase a flash block. Also see ks_token_erase_maybe(), below.
*/
static hal_error_t ks_token_erase(hal_ks_t *ks, const unsigned blockno)
{
if (ks != hal_ks_token || blockno >= NUM_FLASH_BLOCKS)
return HAL_ERROR_IMPOSSIBLE;
unsigned subsector = blockno * SUBSECTORS_PER_BLOCK;
const unsigned end = (blockno + 1) * SUBSECTORS_PER_BLOCK;
do {
if (keystore_erase_subsector(subsector) != CMSIS_HAL_OK)
return HAL_ERROR_KEYSTORE_ACCESS;
} while (++subsector < end);
return HAL_OK;
}
/*
* Erase a flash block if it hasn't already been erased.
* May not be necessary, trying to avoid unnecessary wear.
*
* Unclear whether there's any sane reason why this needs to be
* constant time, given how slow erasure is. But side channel attacks
* can be tricky things, and it's theoretically possible that we could
* leak information about, eg, key length, so we do constant time.
*/
static hal_error_t ks_token_erase_maybe(hal_ks_t *ks, const unsigned blockno)
{
if (ks != hal_ks_token || blockno >= NUM_FLASH_BLOCKS)
return HAL_ERROR_IMPOSSIBLE;
uint8_t mask = 0xFF;
for (uint32_t a = ks_token_offset(blockno); a < ks_token_offset(blockno + 1); a += KEYSTORE_PAGE_SIZE) {
uint8_t page[KEYSTORE_PAGE_SIZE];
if (keystore_read_data(a, page, sizeof(page)) != CMSIS_HAL_OK)
return HAL_ERROR_KEYSTORE_ACCESS;
for (int i = 0; i < KEYSTORE_PAGE_SIZE; i++)
mask &= page[i];
}
return mask == 0xFF ? HAL_OK : ks_token_erase(ks, blockno);
}
/*
* Write a flash block, calculating CRC when appropriate.
*/
static hal_error_t ks_token_write(hal_ks_t *ks, const unsigned blockno, hal_ks_block_t *block)
{
if (ks != hal_ks_token || block == NULL || blockno >= NUM_FLASH_BLOCKS || sizeof(*block) != HAL_KS_BLOCK_SIZE)
return HAL_ERROR_IMPOSSIBLE;
hal_error_t err = ks_token_erase_maybe(ks, blockno);
if (err != HAL_OK)
return err;
switch (hal_ks_block_get_type(block)) {
case HAL_KS_BLOCK_TYPE_KEY:
case HAL_KS_BLOCK_TYPE_PIN:
block->header.crc = hal_ks_block_calculate_crc(block);
break;
default:
break;
}
if (keystore_write_data(ks_token_offset(blockno), block->bytes, sizeof(*block)) != CMSIS_HAL_OK)
return HAL_ERROR_KEYSTORE_ACCESS;
return HAL_OK;
}
/*
* The token keystore doesn't implement per-session objects, so these are no-ops.
*/
static hal_error_t ks_token_set_owner(hal_ks_t *ks,
const unsigned blockno,
const hal_client_handle_t client,
const hal_session_handle_t session)
{
return HAL_OK;
}
static hal_error_t ks_token_test_owner(hal_ks_t *ks,
const unsigned blockno,
const hal_client_handle_t client,
const hal_session_handle_t session)
{
return HAL_OK;
}
static hal_error_t ks_token_copy_owner(hal_ks_t *ks,
const unsigned source,
const unsigned target)
{
return HAL_OK;
}
static hal_error_t ks_token_logout(hal_ks_t *ks,
hal_client_handle_t client)
{
return HAL_OK;
}
/*
* Forward reference.
*/
static hal_error_t fetch_pin_block(unsigned *b, hal_ks_block_t **block);
/*
* Initialize keystore.
*/
static hal_error_t ks_token_init(hal_ks_t *ks, const int alloc)
{
if (ks != hal_ks_token)
return HAL_ERROR_IMPOSSIBLE;
hal_ks_block_t *block = NULL;
hal_error_t err = HAL_OK;
if (alloc && (err = hal_ks_alloc_common(ks, NUM_FLASH_BLOCKS, KS_TOKEN_CACHE_SIZE, NULL, 0)) != HAL_OK)
return err;
if ((err = hal_ks_init_common(ks)) != HAL_OK)
return err;
/*
* Fetch or create the PIN block.
*/
memset(&db->wheel_pin, 0, sizeof(db->wheel_pin));
memset(&db->so_pin, 0, sizeof(db->so_pin));
memset(&db->user_pin, 0, sizeof(db->user_pin));
err = fetch_pin_block(NULL, &block);
if (err == HAL_OK) {
db->wheel_pin = block->pin.wheel_pin;
db->so_pin = block->pin.so_pin;
db->user_pin = block->pin.user_pin;
}
else if (err == HAL_ERROR_KEY_NOT_FOUND) {
/*
* We found no PIN block, so create one, with the user and so PINs
* cleared and the wheel PIN set to the last-gasp value. The
* last-gasp WHEEL PIN is a terrible answer, but we need some kind
* of bootstrapping mechanism when all else fails. If you have a
* better suggestion, we'd love to hear it.
*/
unsigned b;
if ((block = hal_ks_cache_pick_lru(ks)) == NULL)
return HAL_ERROR_IMPOSSIBLE;
memset(block, 0xFF, sizeof(*block));
block->header.block_type = HAL_KS_BLOCK_TYPE_PIN;
block->header.block_status = HAL_KS_BLOCK_STATUS_LIVE;
block->pin.wheel_pin = db->wheel_pin = hal_last_gasp_pin;
block->pin.so_pin = db->so_pin;
block->pin.user_pin = db->user_pin;
if ((err = hal_ks_index_add(ks, &hal_ks_pin_uuid, &b, NULL)) != HAL_OK)
return err;
hal_ks_cache_mark_used(ks, block, b);
err = ks_token_write(ks, b, block);
hal_ks_cache_release(ks, block);
}
return err;
}
/*
* Dispatch vector and keystore definition, now that we've defined all
* the driver functions.
*/
static const hal_ks_driver_t ks_token_driver = {
.init = ks_token_init,
.read = ks_token_read,
.write = ks_token_write,
.deprecate = ks_token_deprecate,
.zero = ks_token_zero,
.erase = ks_token_erase,
.erase_maybe = ks_token_erase_maybe,
.set_owner = ks_token_set_owner,
.test_owner = ks_token_test_owner,
.copy_owner = ks_token_copy_owner,
.logout = ks_token_logout
};
static ks_token_db_t _db = { .ks.driver = &ks_token_driver };
hal_ks_t * const hal_ks_token = &_db.ks;
/*
* The remaining functions aren't really part of the keystore API per se,
* but they all involve non-key data which we keep in the keystore
* because it's the flash we've got.
*/
/*
* Special bonus init routine used only by the bootloader, so that it
* can read PINs set by the main firmware. Yes, this is a kludge. We
* could of course call the real ks_init() routine instead, but it's
* slow, and we don't want to allow anything that would modify the
* flash here, so having a special entry point for this kludge is
* simplest, overall. Sigh.
*/
void hal_ks_init_read_only_pins_only(void)
{
unsigned b, best_seen = NUM_FLASH_BLOCKS;
hal_ks_block_t block[1];
hal_ks_lock();
for (b = 0; b < NUM_FLASH_BLOCKS; b++) {
if (hal_ks_block_read(hal_ks_token, b, block) != HAL_OK ||
hal_ks_block_get_type(block) != HAL_KS_BLOCK_TYPE_PIN)
continue;
best_seen = b;
if (hal_ks_block_get_status(block) == HAL_KS_BLOCK_STATUS_LIVE)
break;
}
if (b != best_seen && best_seen != NUM_FLASH_BLOCKS &&
hal_ks_block_read(hal_ks_token, best_seen, block) != HAL_OK)
best_seen = NUM_FLASH_BLOCKS;
if (best_seen == NUM_FLASH_BLOCKS) {
memset(block, 0xFF, sizeof(*block));
block->pin.wheel_pin = hal_last_gasp_pin;
}
db->wheel_pin = block->pin.wheel_pin;
db->so_pin = block->pin.so_pin;
db->user_pin = block->pin.user_pin;
hal_ks_unlock();
}
/*
* Fetch PIN. This is always cached, so just returned cached value.
*/
hal_error_t hal_get_pin(const hal_user_t user,
const hal_ks_pin_t **pin)
{
if (pin == NULL)
return HAL_ERROR_BAD_ARGUMENTS;
hal_error_t err = HAL_OK;
hal_ks_lock();
switch (user) {
case HAL_USER_WHEEL: *pin = &db->wheel_pin; break;
case HAL_USER_SO: *pin = &db->so_pin; break;
case HAL_USER_NORMAL: *pin = &db->user_pin; break;
default: err = HAL_ERROR_BAD_ARGUMENTS;
}
hal_ks_unlock();
return err;
}
/*
* Fetch PIN block. hint = 0 because we know that the all-zeros UUID
* should always sort to first slot in the index.
*/
static hal_error_t fetch_pin_block(unsigned *b, hal_ks_block_t **block)
{
if (block == NULL)
return HAL_ERROR_IMPOSSIBLE;
hal_error_t err;
int hint = 0;
unsigned b_;
if (b == NULL)
b = &b_;
if ((err = hal_ks_index_find(hal_ks_token, &hal_ks_pin_uuid, b, &hint)) != HAL_OK ||
(err = hal_ks_block_read_cached(hal_ks_token, *b, block)) != HAL_OK)
return err;
hal_ks_cache_mark_used(hal_ks_token, *block, *b);
if (hal_ks_block_get_type(*block) != HAL_KS_BLOCK_TYPE_PIN)
return HAL_ERROR_IMPOSSIBLE;
return HAL_OK;
}
/*
* Update the PIN block. This block should always be present, but we
* have to do the zombie jamboree to make sure we write the new PIN
* block before destroying the old one. hint = 0 because we know that
* the all-zeros UUID should always sort to first slot in the index.
*/
static hal_error_t update_pin_block(const unsigned b,
hal_ks_block_t *block,
const hal_ks_pin_block_t * const new_data)
{
if (block == NULL || new_data == NULL || hal_ks_block_get_type(block) != HAL_KS_BLOCK_TYPE_PIN)
return HAL_ERROR_IMPOSSIBLE;
int hint = 0;
block->pin = *new_data;
return hal_ks_block_update(hal_ks_token, b, block, &hal_ks_pin_uuid, &hint);
}
/*
* Change a PIN.
*/
hal_error_t hal_set_pin(const hal_user_t user,
const hal_ks_pin_t * const pin)
{
if (pin == NULL)
return HAL_ERROR_BAD_ARGUMENTS;
hal_ks_block_t *block;
hal_error_t err;
unsigned b;
hal_ks_lock();
if ((err = fetch_pin_block(&b, &block)) != HAL_OK)
goto done;
hal_ks_pin_block_t new_data = block->pin;
hal_ks_pin_t *dp, *bp;
switch (user) {
case HAL_USER_WHEEL: bp = &new_data.wheel_pin; dp = &db->wheel_pin; break;
case HAL_USER_SO: bp = &new_data.so_pin; dp = &db->so_pin; break;
case HAL_USER_NORMAL: bp = &new_data.user_pin; dp = &db->user_pin; break;
default: err = HAL_ERROR_BAD_ARGUMENTS; goto done;
}
const hal_ks_pin_t old_pin = *dp;
*dp = *bp = *pin;
if ((err = update_pin_block(b, block, &new_data)) != HAL_OK)
*dp = old_pin;
done:
hal_ks_unlock();
return err;
}
#if HAL_MKM_FLASH_BACKUP_KLUDGE
/*
* Horrible insecure kludge in lieu of a battery for the MKM.
*
* API here is a little strange: all calls pass a length parameter,
* but any length other than the compiled in constant just returns an
* immediate error, there's no notion of buffer max length vs buffer
* used length, querying for the size of buffer really needed, or
* anything like that.
*
* We might want to rewrite this some day, if we don't replace it with
* a battery first. For now we just preserve the API as we found it
* while re-implementing it on top of the new keystore.
*/
hal_error_t hal_mkm_flash_read_no_lock(uint8_t *buf, const size_t len)
{
if (buf != NULL && len != KEK_LENGTH)
return HAL_ERROR_MASTERKEY_BAD_LENGTH;
hal_ks_block_t *block;
hal_error_t err;
unsigned b;
if ((err = fetch_pin_block(&b, &block)) != HAL_OK)
return err;
if (block->pin.kek_set != FLASH_KEK_SET)
return HAL_ERROR_MASTERKEY_NOT_SET;
if (buf != NULL)
memcpy(buf, block->pin.kek, len);
return HAL_OK;
}
hal_error_t hal_mkm_flash_read(uint8_t *buf, const size_t len)
{
hal_ks_lock();
const hal_error_t err = hal_mkm_flash_read_no_lock(buf, len);
hal_ks_unlock();
return err;
}
hal_error_t hal_mkm_flash_write(const uint8_t * const buf, const size_t len)
{
if (buf == NULL)
return HAL_ERROR_BAD_ARGUMENTS;
if (len != KEK_LENGTH)
return HAL_ERROR_MASTERKEY_BAD_LENGTH;
hal_ks_block_t *block;
hal_error_t err;
unsigned b;
hal_ks_lock();
if ((err = fetch_pin_block(&b, &block)) != HAL_OK)
goto done;
hal_ks_pin_block_t new_data = block->pin;
new_data.kek_set = FLASH_KEK_SET;
memcpy(new_data.kek, buf, len);
err = update_pin_block(b, block, &new_data);
done:
hal_ks_unlock();
return err;
}
hal_error_t hal_mkm_flash_erase(const size_t len)
{
if (len != KEK_LENGTH)
return HAL_ERROR_MASTERKEY_BAD_LENGTH;
hal_ks_block_t *block;
hal_error_t err;
unsigned b;
hal_ks_lock();
if ((err = fetch_pin_block(&b, &block)) != HAL_OK)
goto done;
hal_ks_pin_block_t new_data = block->pin;
new_data.kek_set = FLASH_KEK_NOT_SET;
memset(new_data.kek, 0, len);
err = update_pin_block(b, block, &new_data);
done:
hal_ks_unlock();
return err;
}
#endif /* HAL_MKM_FLASH_BACKUP_KLUDGE */
/*
* Local variables:
* indent-tabs-mode: nil
* End:
*/