Ctrl_status sd_mmc_usb_write_10(uint8_t slot, uint32_t addr, uint16_t nb_sector)
{
bool b_first_step = true;
uint16_t nb_step;
switch (sd_mmc_init_write_blocks(slot, addr, nb_sector)) {
case SD_MMC_OK:
break;
case SD_MMC_ERR_NO_CARD:
return CTRL_NO_PRESENT;
default:
return CTRL_FAIL;
}
// Pipeline the 2 transfer in order to speed-up the performances
nb_step = nb_sector + 1;
while (nb_step--) {
if (!b_first_step) { // Skip first step
// RAM -> MCI
if (SD_MMC_OK != sd_mmc_start_write_blocks(((nb_step % 2) == 0) ?
sector_buf_0 : sector_buf_1, 1)) {
return CTRL_FAIL;
}
}
if (nb_step) { // Skip last step
// USB -> RAM
if (!udi_msc_trans_block(false,
((nb_step % 2) == 0) ?
sector_buf_1 : sector_buf_0,
SD_MMC_BLOCK_SIZE,
NULL)) {
if (!b_first_step) {
sd_mmc_wait_end_of_write_blocks(true);
}
return CTRL_FAIL;
}
}
if (!b_first_step) { // Skip first step
if (SD_MMC_OK != sd_mmc_wait_end_of_write_blocks(false)) {
return CTRL_FAIL;
}
} else {
b_first_step = false;
}
}
return CTRL_GOOD;
}
/* Changes the encryption level of the drive.
If encrypt is true: encrypt drive, else decrypt */
uint8_t sd_change_encryption(uint8_t slot, bool encrypt, bool change_key, uint8_t *old_passwd, uint8_t *new_passwd)
{
sd_mmc_err_t err;
uint32_t i, nb_blocks;
encrypt_config_t *config_ptr = NULL;
security_get_config(&config_ptr);
if ((encrypt == config_ptr->encryption_level) && !change_key)
return CTRL_GOOD;
if (change_key) {
sha2(old_passwd, MAX_PASS_LENGTH, old_hash_cipher_key, 0);
sha2(new_passwd, MAX_PASS_LENGTH, new_hash_cipher_key, 0);
}
if (old_hash_cipher_key == new_hash_cipher_key)
return CTRL_GOOD;
do {
err = sd_mmc_check(slot);
if ((SD_MMC_ERR_NO_CARD != err)
&& (SD_MMC_INIT_ONGOING != err)
&& (SD_MMC_OK != err)) {
while (SD_MMC_ERR_NO_CARD != sd_mmc_check(slot)) {
}
}
} while (SD_MMC_OK != err);
nb_blocks = sd_mmc_get_capacity(slot) * (1024 / SD_MMC_BLOCK_SIZE);
for (i = 0; i < nb_blocks / SD_BLOCKS_PER_ACCESS; ++i) {
if (SD_MMC_OK != sd_mmc_init_read_blocks(slot, i, SD_BLOCKS_PER_ACCESS))
return CTRL_FAIL;
if (SD_MMC_OK != sd_mmc_start_read_blocks(src_buf, SD_BLOCKS_PER_ACCESS))
return CTRL_FAIL;
if (SD_MMC_OK != sd_mmc_wait_end_of_read_blocks())
return CTRL_FAIL;
aes_set_key(&AVR32_AES, (unsigned int *)old_hash_cipher_key);
ram_aes_ram(change_key ? false : encrypt, SD_MMC_BLOCK_SIZE * SD_BLOCKS_PER_ACCESS / sizeof(unsigned int), (unsigned int *)src_buf, (unsigned int *)dest_buf);
if (change_key) {
aes_set_key(&AVR32_AES, (unsigned int *)new_hash_cipher_key);
ram_aes_ram(true, SD_MMC_BLOCK_SIZE * SD_BLOCKS_PER_ACCESS / sizeof(unsigned int), (unsigned int *)dest_buf, (unsigned int *)src_buf);
}
if (SD_MMC_OK != sd_mmc_init_write_blocks(slot, i, SD_BLOCKS_PER_ACCESS))
return CTRL_FAIL;
if (SD_MMC_OK != sd_mmc_start_write_blocks(src_buf, SD_BLOCKS_PER_ACCESS))
return CTRL_FAIL;
if (SD_MMC_OK != sd_mmc_wait_end_of_write_blocks())
return CTRL_FAIL;
}
return CTRL_GOOD;
}
Ctrl_status sd_mmc_ram_2_mem(uint8_t slot, uint32_t addr, const void *ram)
{
switch (sd_mmc_init_write_blocks(slot, addr, 1)) {
case SD_MMC_OK:
break;
case SD_MMC_ERR_NO_CARD:
return CTRL_NO_PRESENT;
default:
return CTRL_FAIL;
}
if (SD_MMC_OK != sd_mmc_start_write_blocks(ram, 1)) {
return CTRL_FAIL;
}
if (SD_MMC_OK != sd_mmc_wait_end_of_write_blocks(false)) {
return CTRL_FAIL;
}
return CTRL_GOOD;
}
/**
* \brief Card R/W tests
*
* \param slot SD/MMC slot to test
*/
static void main_test_memory(uint8_t slot)
{
uint32_t last_blocks_addr, i, nb_trans;
REDTIMESTAMP tick_start;
uint32_t time_ms;
// Compute the last address
last_blocks_addr = sd_mmc_get_capacity(slot) *
(1024 / SD_MMC_BLOCK_SIZE);
if (last_blocks_addr < (TEST_MEM_START_OFFSET / 512lu)) {
printf("[Memory is too small.]\n\r");
return;
}
last_blocks_addr -= (TEST_MEM_START_OFFSET / SD_MMC_BLOCK_SIZE);
printf("Card R/W test:\n\r");
// Read the last block
printf(" Read... ");
tick_start = RedOsTimestamp();
if (SD_MMC_OK != sd_mmc_init_read_blocks(slot,
last_blocks_addr,
TEST_MEM_AREA_SIZE / SD_MMC_BLOCK_SIZE)) {
printf("[FAIL]\n\r");
return;
}
for (nb_trans = 0; nb_trans < (TEST_MEM_AREA_SIZE / TEST_MEM_ACCESS_SIZE);
nb_trans++) {
if (SD_MMC_OK != sd_mmc_start_read_blocks(buf_test,
TEST_MEM_ACCESS_SIZE / SD_MMC_BLOCK_SIZE)) {
printf("[FAIL]\n\r");
return;
}
if (SD_MMC_OK != sd_mmc_wait_end_of_read_blocks(false)) {
printf("[FAIL]\n\r");
return;
}
}
time_ms = RedOsTimePassed(tick_start) / 1000U;
if (time_ms) { // Valid time_ms
printf(" %d KBps ", (int)(((TEST_MEM_AREA_SIZE
* 1000lu) / 1024lu) / time_ms));
}
printf("[OK]\n\r");
if (sd_mmc_is_write_protected(slot)) {
printf("Card is write protected [WRITE TEST SKIPPED]\n\r");
return;
}
// Fill buffer with a pattern
for (i = 0; i < (TEST_MEM_ACCESS_SIZE / sizeof(uint32_t)); i++) {
((uint32_t*)buf_test)[i] = TEST_FILL_VALUE_U32;
}
printf(" Write pattern... ");
if (SD_MMC_OK != sd_mmc_init_write_blocks(slot,
last_blocks_addr,
TEST_MEM_AREA_SIZE / SD_MMC_BLOCK_SIZE)) {
printf("[FAIL]\n\r");
return;
}
tick_start = RedOsTimestamp();
for (nb_trans = 0; nb_trans < (TEST_MEM_AREA_SIZE / TEST_MEM_ACCESS_SIZE);
nb_trans++) {
((uint32_t*)buf_test)[0] = nb_trans; // Unique value for each area
if (SD_MMC_OK != sd_mmc_start_write_blocks(buf_test,
TEST_MEM_ACCESS_SIZE / SD_MMC_BLOCK_SIZE)) {
printf("[FAIL]\n\r");
return;
}
if (SD_MMC_OK != sd_mmc_wait_end_of_write_blocks(false)) {
printf("[FAIL]\n\r");
return;
}
}
time_ms = RedOsTimePassed(tick_start) / 1000U;
if (time_ms) { // Valid time_ms
printf(" %d KBps ", (int)(((TEST_MEM_AREA_SIZE
* 1000lu) / 1024lu) / time_ms));
}
printf("[OK]\n\r");
printf(" Read and check pattern... ");
if (SD_MMC_OK != sd_mmc_init_read_blocks(slot,
last_blocks_addr,
TEST_MEM_AREA_SIZE / SD_MMC_BLOCK_SIZE)) {
printf("Read [FAIL]\n\r");
return;
}
for (nb_trans = 0; nb_trans < (TEST_MEM_AREA_SIZE / TEST_MEM_ACCESS_SIZE);
nb_trans++) {
// Clear buffer
for (i = 0; i < (TEST_MEM_ACCESS_SIZE / sizeof(uint32_t)); i++) {
((uint32_t*)buf_test)[i] = 0xFFFFFFFF;
}
// Fill buffer
if (SD_MMC_OK != sd_mmc_start_read_blocks(buf_test,
TEST_MEM_ACCESS_SIZE / SD_MMC_BLOCK_SIZE)) {
printf("Read [FAIL]\n\r");
return;
}
if (SD_MMC_OK != sd_mmc_wait_end_of_read_blocks(false)) {
printf("Read [FAIL]\n\r");
return;
}
// Check the unique value of the area
if (((uint32_t*)buf_test)[0] != nb_trans) {
printf("Check [FAIL]\n\r");
return;
}
// Check buffer
for (i = 1; i < (TEST_MEM_ACCESS_SIZE / sizeof(uint32_t)); i++) {
if (((uint32_t*)buf_test)[i] != TEST_FILL_VALUE_U32) {
printf("Check [FAIL]\n\r");
return;
}
}
}
printf("[OK]\n\r");
}
/**
* \brief SD/MMC card read and write test.
*
* \param test Current test case.
*/
static void run_sd_mmc_rw_test(const struct test_case *test)
{
uint32_t i;
uint32_t last_blocks_addr;
uint16_t nb_block, nb_trans;
bool split_tansfer = false;
/* Compute the last address */
last_blocks_addr = sd_mmc_get_capacity(0) * (1024/SD_MMC_BLOCK_SIZE) - 50;
test_assert_true(test, last_blocks_addr > NB_MULTI_BLOCKS,
"Error: SD/MMC capacity.");
last_blocks_addr -= NB_MULTI_BLOCKS;
nb_block = 1;
run_sd_mmc_rw_test_next:
/* Read (save blocks) the last blocks */
test_assert_true(test, SD_MMC_OK ==
sd_mmc_init_read_blocks(0, last_blocks_addr, nb_block),
"Error: SD/MMC initialize read sector(s).");
for (nb_trans = 0; nb_trans < (split_tansfer? nb_block : 1); nb_trans++) {
test_assert_true(test, SD_MMC_OK ==
sd_mmc_start_read_blocks(
&buf_save[nb_trans * SD_MMC_BLOCK_SIZE],
split_tansfer? 1 : nb_block),
"Error: SD/MMC start read sector(s).");
test_assert_true(test, SD_MMC_OK ==
sd_mmc_wait_end_of_read_blocks(false),
"Error: SD/MMC wait end of read sector(s).");
}
test_assert_true(test, !sd_mmc_is_write_protected(0),
"Error: SD/MMC is write protected.");
/* Fill buffer */
for (i = 0; i < (SD_MMC_BLOCK_SIZE * nb_block / sizeof(uint32_t)); i++) {
((uint32_t*)buf_test)[i] = TEST_FILL_VALUE_U32;
}
/* Write the last blocks */
test_assert_true(test, SD_MMC_OK ==
sd_mmc_init_write_blocks(0, last_blocks_addr, nb_block),
"Error: SD/MMC initialize write sector(s).");
for (nb_trans = 0; nb_trans < (split_tansfer? nb_block : 1); nb_trans++) {
test_assert_true(test, SD_MMC_OK ==
sd_mmc_start_write_blocks(
&buf_test[nb_trans * SD_MMC_BLOCK_SIZE],
split_tansfer? 1 : nb_block),
"Error: SD/MMC start write sector(s).");
test_assert_true(test, SD_MMC_OK ==
sd_mmc_wait_end_of_write_blocks(false),
"Error: SD/MMC wait end of write sector(s).");
}
/* Clean buffer */
for (i = 0; i < (SD_MMC_BLOCK_SIZE * nb_block / sizeof(uint32_t)); i++) {
((uint32_t*)buf_test)[i] = 0xFFFFFFFF;
}
/* Read the last block */
test_assert_true(test, SD_MMC_OK ==
sd_mmc_init_read_blocks(0, last_blocks_addr, nb_block),
"Error: SD/MMC initialize read sector(s).");
for (nb_trans = 0; nb_trans < (split_tansfer? nb_block : 1); nb_trans++) {
test_assert_true(test, SD_MMC_OK ==
sd_mmc_start_read_blocks(
&buf_test[nb_trans * SD_MMC_BLOCK_SIZE],
split_tansfer? 1 : nb_block),
"Error: SD/MMC start read sector(s).");
test_assert_true(test, SD_MMC_OK ==
sd_mmc_wait_end_of_read_blocks(false),
"Error: SD/MMC wait end of read sector(s).");
}
/* Check buffer */
for (i = 0; i < (SD_MMC_BLOCK_SIZE * nb_block / sizeof(uint32_t)); i++) {
test_assert_true(test,
((uint32_t*)buf_test)[i] == TEST_FILL_VALUE_U32,
"Error: SD/MMC verify write operation.");
}
/* Write (restore) the last block */
test_assert_true(test, SD_MMC_OK ==
sd_mmc_init_write_blocks(0, last_blocks_addr, nb_block),
"Error: SD/MMC initialize write restore sector(s).");
for (nb_trans = 0; nb_trans < (split_tansfer? nb_block : 1); nb_trans++) {
test_assert_true(test, SD_MMC_OK ==
sd_mmc_start_write_blocks(
&buf_save[nb_trans * SD_MMC_BLOCK_SIZE],
split_tansfer? 1 : nb_block),
"Error: SD/MMC start write restore sector(s).");
test_assert_true(test, SD_MMC_OK ==
sd_mmc_wait_end_of_write_blocks(false),
"Error: SD/MMC wait end of write restore sector(s).");
}
/* Read (check restore) the last block */
test_assert_true(test, SD_MMC_OK ==
sd_mmc_init_read_blocks(0, last_blocks_addr, nb_block),
"Error: SD/MMC initialize read sector(s).");
for (nb_trans = 0; nb_trans < (split_tansfer? nb_block : 1); nb_trans++) {
test_assert_true(test, SD_MMC_OK ==
sd_mmc_start_read_blocks(
&buf_test[nb_trans * SD_MMC_BLOCK_SIZE],
split_tansfer? 1 : nb_block),
"Error: SD/MMC start read sector(s).");
test_assert_true(test, SD_MMC_OK ==
sd_mmc_wait_end_of_read_blocks(false),
"Error: SD/MMC wait end of read sector(s).");
}
/* Check buffer restored */
for (i = 0; i < (SD_MMC_BLOCK_SIZE * nb_block / sizeof(uint32_t)); i++) {
test_assert_true(test,
((uint32_t*)buf_test)[i] == ((uint32_t*)buf_save)[i],
"Error: SD/MMC verify restore operation.");
}
if (nb_block == 1) {
/* Launch second test */
nb_block = NB_MULTI_BLOCKS;
goto run_sd_mmc_rw_test_next;
}
if (!split_tansfer) {
/* Launch third test */
split_tansfer = true;
goto run_sd_mmc_rw_test_next;
}
}
Ctrl_status sd_mmc_usb_write_10(uint8_t slot, uint32_t addr, uint16_t nb_sector)
{
bool b_first_step = true;
uint16_t nb_step;
#if defined(USE_ENCRYPTION) && !defined(FAKE_RW)
aes_encrypt_ctx aes_ctx[1];
MD5_CTX md5_ctx;
unsigned char IV[16];
#endif // USE_ENCRYPTION
#ifdef CLEAR_ON_WRITE
if (!sd_mmc_usb_check_sector(addr, nb_sector))
return CTRL_FAIL;
#endif
#ifndef FAKE_RW
switch (sd_mmc_init_write_blocks(slot, addr, nb_sector)) {
case SD_MMC_OK:
break;
case SD_MMC_ERR_NO_CARD:
return CTRL_NO_PRESENT;
default:
return CTRL_FAIL;
}
#endif // FAKE_RW
// Pipeline the 2 transfer in order to speed-up the performances
nb_step = nb_sector + 1;
while (nb_step--) {
if (!b_first_step) { // Skip first step
// RAM -> MCI
#ifdef FAKE_RW
cached_sectors[next_cached_sector].sector = addr + nb_sector - nb_step - 1;
memcpy(cached_sectors[next_cached_sector++].contents, ((nb_step % 2) == 0) ? sector_buf_0 : sector_buf_1, SD_MMC_BLOCK_SIZE);
if (cached_sector_count < 20)
cached_sector_count++;
next_cached_sector %= NUM_CACHED_SECTORS;
#else // FAKE_RW
if (SD_MMC_OK != sd_mmc_start_write_blocks(((nb_step % 2) == 0) ?
sector_buf_0 : sector_buf_1, 1)) {
return CTRL_FAIL;
}
#endif // !FAKE_RW
}
if (nb_step) { // Skip last step
#if defined(USE_ENCRYPTION) && !defined(FAKE_RW)
uint32_t sector = addr + nb_sector - nb_step;
#endif // USE_ENCRYPTION && !FAKE_RW
// USB -> RAM
if (!udi_msc_trans_block(false,
#if defined(USE_ENCRYPTION) && !defined(FAKE_RW)
use_user_page_values() && sector >= CRYPT_START ? aes_buf :
#endif // USE_ENCRYPTION && !FAKE_RW
(((nb_step % 2) == 0) ? sector_buf_1 : sector_buf_0),
SD_MMC_BLOCK_SIZE, NULL)) {
return CTRL_FAIL;
}
#if defined(USE_ENCRYPTION) && !defined(FAKE_RW)
// Encrypt
if (use_user_page_values() && sector >= CRYPT_START) {
MD5_Init (&md5_ctx);
MD5_Update (&md5_ctx, §or, sizeof(uint32_t));
MD5_Final (IV, &md5_ctx);
aes_encrypt_key128(AES_KEY, aes_ctx);
aes_cbc_encrypt(aes_buf, ((nb_step % 2) == 0) ? sector_buf_1 : sector_buf_0,
SD_MMC_BLOCK_SIZE, IV, aes_ctx);
}
#endif // USE_ENCRYPTION && !FAKE_RW
}
if (!b_first_step) { // Skip first step
#ifndef FAKE_RW
if (SD_MMC_OK != sd_mmc_wait_end_of_write_blocks()) {
return CTRL_FAIL;
}
#endif // !FAKE_RW
} else {
b_first_step = false;
}
}
return CTRL_GOOD;
}
