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mirror of https://github.com/trezor/trezor-firmware.git synced 2024-11-17 21:22:10 +00:00
trezor-firmware/storage/pinlogs_bitwise.h

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// Values used in the guard key integrity check.
#define GUARD_KEY_MODULUS 6311
#define GUARD_KEY_REMAINDER 15
#define LOW_MASK 0x55555555
// The length of the guard key in words.
#define GUARD_KEY_WORDS 1
// The length of the PIN entry log or the PIN success log in words.
#define PIN_LOG_WORDS 16
// The length of a word in bytes.
#define WORD_SIZE (sizeof(uint32_t))
static secbool check_guard_key(const uint32_t guard_key) {
if (guard_key % GUARD_KEY_MODULUS != GUARD_KEY_REMAINDER) {
return secfalse;
}
// Check that each byte of (guard_key & 0xAAAAAAAA) has exactly two bits set.
uint32_t count = (guard_key & 0x22222222) + ((guard_key >> 2) & 0x22222222);
count = count + (count >> 4);
if ((count & 0x0e0e0e0e) != 0x04040404) {
return secfalse;
}
// Check that the guard_key does not contain a run of 5 (or more) zeros or
// ones.
uint32_t zero_runs = ~guard_key;
zero_runs = zero_runs & (zero_runs >> 2);
zero_runs = zero_runs & (zero_runs >> 1);
zero_runs = zero_runs & (zero_runs >> 1);
uint32_t one_runs = guard_key;
one_runs = one_runs & (one_runs >> 2);
one_runs = one_runs & (one_runs >> 1);
one_runs = one_runs & (one_runs >> 1);
if ((one_runs != 0) || (zero_runs != 0)) {
return secfalse;
}
return sectrue;
}
static uint32_t generate_guard_key(void) {
uint32_t guard_key = 0;
do {
guard_key = random_uniform((UINT32_MAX / GUARD_KEY_MODULUS) + 1) *
GUARD_KEY_MODULUS +
GUARD_KEY_REMAINDER;
} while (sectrue != check_guard_key(guard_key));
return guard_key;
}
static secbool expand_guard_key(const uint32_t guard_key, uint32_t *guard_mask,
uint32_t *guard) {
if (sectrue != check_guard_key(guard_key)) {
handle_fault("guard key check");
return secfalse;
}
*guard_mask = ((guard_key & LOW_MASK) << 1) | ((~guard_key) & LOW_MASK);
*guard = (((guard_key & LOW_MASK) << 1) & guard_key) |
(((~guard_key) & LOW_MASK) & (guard_key >> 1));
return sectrue;
}
static secbool pin_logs_init(uint32_t fails) {
if (fails >= PIN_MAX_TRIES) {
return secfalse;
}
// The format of the PIN_LOGS_KEY entry is:
// guard_key (1 word), pin_success_log (PIN_LOG_WORDS), pin_entry_log
// (PIN_LOG_WORDS)
uint32_t logs[GUARD_KEY_WORDS + 2 * PIN_LOG_WORDS] = {0};
logs[0] = generate_guard_key();
uint32_t guard_mask = 0;
uint32_t guard = 0;
wait_random();
if (sectrue != expand_guard_key(logs[0], &guard_mask, &guard)) {
return secfalse;
}
uint32_t unused = guard | ~guard_mask;
for (size_t i = 0; i < 2 * PIN_LOG_WORDS; ++i) {
logs[GUARD_KEY_WORDS + i] = unused;
}
// Set the first word of the PIN entry log to indicate the requested number of
// fails.
logs[GUARD_KEY_WORDS + PIN_LOG_WORDS] =
((((uint32_t)0xFFFFFFFF) >> (2 * fails)) & ~guard_mask) | guard;
return norcow_set(PIN_LOGS_KEY, logs, sizeof(logs));
}
static secbool pin_fails_reset(void) {
const void *logs = NULL;
uint16_t len = 0;
if (sectrue != norcow_get(PIN_LOGS_KEY, &logs, &len) ||
len != WORD_SIZE * (GUARD_KEY_WORDS + 2 * PIN_LOG_WORDS)) {
return secfalse;
}
uint32_t new_logs[GUARD_KEY_WORDS + 2 * PIN_LOG_WORDS];
secbool edited = secfalse;
memcpy(new_logs, logs, len);
uint32_t guard_mask = 0;
uint32_t guard = 0;
wait_random();
if (sectrue !=
expand_guard_key(*(const uint32_t *)logs, &guard_mask, &guard)) {
return secfalse;
}
uint32_t unused = guard | ~guard_mask;
const uint32_t *success_log = ((const uint32_t *)logs) + GUARD_KEY_WORDS;
const uint32_t *entry_log = success_log + PIN_LOG_WORDS;
for (size_t i = 0; i < PIN_LOG_WORDS; ++i) {
if (entry_log[i] == unused) {
if (edited == sectrue) {
return norcow_set(PIN_LOGS_KEY, new_logs, sizeof(new_logs));
}
return sectrue;
}
if (success_log[i] != guard) {
if (new_logs[(i + GUARD_KEY_WORDS)] != entry_log[i]) {
edited = sectrue;
new_logs[(i + GUARD_KEY_WORDS)] = entry_log[i];
}
}
}
return pin_logs_init(0);
}
secbool pin_fails_increase(void) {
const void *logs = NULL;
uint16_t len = 0;
wait_random();
if (sectrue != norcow_get(PIN_LOGS_KEY, &logs, &len) ||
len != WORD_SIZE * (GUARD_KEY_WORDS + 2 * PIN_LOG_WORDS)) {
handle_fault("no PIN logs");
return secfalse;
}
uint32_t new_logs[GUARD_KEY_WORDS + 2 * PIN_LOG_WORDS];
memcpy(new_logs, logs, len);
uint32_t guard_mask = 0;
uint32_t guard = 0;
wait_random();
if (sectrue !=
expand_guard_key(*(const uint32_t *)logs, &guard_mask, &guard)) {
handle_fault("guard key expansion");
return secfalse;
}
const uint32_t *entry_log =
((const uint32_t *)logs) + GUARD_KEY_WORDS + PIN_LOG_WORDS;
for (size_t i = 0; i < PIN_LOG_WORDS; ++i) {
wait_random();
if ((entry_log[i] & guard_mask) != guard) {
handle_fault("guard bits check");
return secfalse;
}
if (entry_log[i] != guard) {
wait_random();
uint32_t word = entry_log[i] & ~guard_mask;
word = ((word >> 1) | word) & LOW_MASK;
word = (word >> 2) | (word >> 1);
wait_random();
new_logs[(i + GUARD_KEY_WORDS + PIN_LOG_WORDS)] =
(word & ~guard_mask) | guard;
if (sectrue != norcow_set(PIN_LOGS_KEY, new_logs, sizeof(new_logs))) {
handle_fault("PIN logs update");
return secfalse;
}
return sectrue;
}
}
handle_fault("PIN log exhausted");
return secfalse;
}
static secbool pin_get_fails(uint32_t *ctr) {
*ctr = PIN_MAX_TRIES;
const void *logs = NULL;
uint16_t len = 0;
wait_random();
if (sectrue != norcow_get(PIN_LOGS_KEY, &logs, &len) ||
len != WORD_SIZE * (GUARD_KEY_WORDS + 2 * PIN_LOG_WORDS)) {
handle_fault("no PIN logs");
return secfalse;
}
uint32_t guard_mask = 0;
uint32_t guard = 0;
wait_random();
if (sectrue !=
expand_guard_key(*(const uint32_t *)logs, &guard_mask, &guard)) {
handle_fault("guard key expansion");
return secfalse;
}
const uint32_t unused = guard | ~guard_mask;
const uint32_t *success_log = ((const uint32_t *)logs) + GUARD_KEY_WORDS;
const uint32_t *entry_log = success_log + PIN_LOG_WORDS;
volatile int current = -1;
volatile size_t i = 0;
for (i = 0; i < PIN_LOG_WORDS; ++i) {
if ((entry_log[i] & guard_mask) != guard ||
(success_log[i] & guard_mask) != guard ||
(entry_log[i] & success_log[i]) != entry_log[i]) {
handle_fault("PIN logs format check");
return secfalse;
}
if (current == -1) {
if (entry_log[i] != guard) {
current = i;
}
} else {
if (entry_log[i] != unused) {
handle_fault("PIN entry log format check");
return secfalse;
}
}
}
if (current < 0 || current >= PIN_LOG_WORDS || i != PIN_LOG_WORDS) {
handle_fault("PIN log exhausted");
return secfalse;
}
// Strip the guard bits from the current entry word and duplicate each data
// bit.
wait_random();
uint32_t word = entry_log[current] & ~guard_mask;
word = ((word >> 1) | word) & LOW_MASK;
word = word | (word << 1);
// Verify that the entry word has form 0*1*.
if ((word & (word + 1)) != 0) {
handle_fault("PIN entry log format check");
return secfalse;
}
if (current == 0) {
++current;
}
// Count the number of set bits in the two current words of the success log.
wait_random();
*ctr = hamming_weight(success_log[current - 1] ^ entry_log[current - 1]) +
hamming_weight(success_log[current] ^ entry_log[current]);
return sectrue;
}