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e381317fbf
RIOT/drivers/sdcard_spi/sdcard_spi.c
smlng e381317fbf make: fix sign-compare errors 
cpu, nrf5x_common: fix sign-compare in periph/flashpage
    drivers, periph_common: fix sign-compare in flashpage
    cpu, sam0_common: fix sign-compare error in periph/gpio
    cpu, cc2538: fix sign-compare in periph/timer
    cpu, sam3: fix sign-compare in periph/gpio
    cpu, stm32_common: fix sign-compare in periph/pwm
    cpu, stm32_common: fix sign-compare in periph/timer
    cpu, stm32_common: fix sign-compare in periph/flashpage
    cpu, nrf5x_common: fix sign-compare in radio/nrfmin
    cpu, samd21: fix sign-compare in periph/pwm
    cpu, ezr32wg: fix sign-compare in periph/gpio
    cpu, ezr32wg: fix sign-compare in periph/timer
    drivers, ethos: fix sign-compare
    sys, net: fix sign-compare
    cpu, atmega_common: fix sign-compare error
    cpu, msp430fxyz: fix sign-compare in periph/gpio
    boards, msb-430-common: fix sign-compare in board_init
    driver, cc2420: fix sign-compared
    sys/net: fix sign-compare in gnrc_tftp
    driver, pcd8544: fix sign-compare
    driver, pn532: fix sign-compare
    driver, sdcard_spi: fix sign-compare
    tests: fix sign_compare
    sys/net, lwmac: fix sign_compare
    pkg, lwip: fix sign-compare
    boards, waspmote: make CORECLOCK unsigned long to fix sign_compare error
    tests, sock_ip: fix sign compare
    tests, msg_avail: fix sign compare
    tests, sock_udp: fix sign compare
    boards: fix sign-compare for calliope and microbit matrix
2017-11-28 11:55:48 +01:00

1055 lines
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Raw Blame History

/*
* Copyright (C) 2016 Michel Rottleuthner <michel.rottleuthner@haw-hamburg.de>
*
* This file is subject to the terms and conditions of the GNU Lesser
* General Public License v2.1. See the file LICENSE in the top level
* directory for more details.
*/
/**
* @ingroup drivers_sdcard_spi
* @{
*
* @file
* @brief low level driver for accessing sd-cards via spi interface.
*
* @author Michel Rottleuthner <michel.rottleuthner@haw-hamburg.de>
*
* @}
*/
#define ENABLE_DEBUG (0)
#include "debug.h"
#include "sdcard_spi_internal.h"
#include "sdcard_spi.h"
#include "sdcard_spi_params.h"
#include "periph/spi.h"
#include "periph/gpio.h"
#include "xtimer.h"
#include <stdio.h>
#include <string.h>
#include <inttypes.h>
static inline void _select_card_spi(sdcard_spi_t *card);
static inline void _unselect_card_spi(sdcard_spi_t *card);
static inline char _wait_for_r1(sdcard_spi_t *card, int32_t max_retries);
static inline void _send_dummy_byte(sdcard_spi_t *card);
static inline bool _wait_for_not_busy(sdcard_spi_t *card, int32_t max_retries);
static inline bool _wait_for_token(sdcard_spi_t *card, char token, int32_t max_retries);
static sd_init_fsm_state_t _init_sd_fsm_step(sdcard_spi_t *card, sd_init_fsm_state_t state);
static sd_rw_response_t _read_cid(sdcard_spi_t *card);
static sd_rw_response_t _read_csd(sdcard_spi_t *card);
static sd_rw_response_t _read_data_packet(sdcard_spi_t *card, char token, char *data, int size);
static sd_rw_response_t _write_data_packet(sdcard_spi_t *card, char token, const char *data, int size);
/* CRC-7 (polynomial: x^7 + x^3 + 1) LSB of CRC-7 in a 8-bit variable is always 1*/
static char _crc_7(const char *data, int n);
/* CRC-16 (CRC-CCITT) (polynomial: x^16 + x^12 + x^5 + x^1) */
static uint16_t _crc_16(const char *data, size_t n);
/* use this transfer method instead of _transfer_bytes to force the use of 0xFF as dummy bytes */
static inline int _transfer_bytes(sdcard_spi_t *card, const char *out, char *in, unsigned int length);
/* uses bitbanging for spi communication which allows to enable pull-up on the miso pin for
greater card compatibility on platforms that don't have a hw pull up installed */
static inline int _sw_spi_rxtx_byte(sdcard_spi_t *card, char out, char *in);
/* wrapper for default spi_transfer_byte function */
static inline int _hw_spi_rxtx_byte(sdcard_spi_t *card, char out, char *in);
/* function pointer to switch to hw spi mode after init sequence */
static int (*_dyn_spi_rxtx_byte)(sdcard_spi_t *card, char out, char *in);
int sdcard_spi_init(sdcard_spi_t *card, const sdcard_spi_params_t *params)
{
sd_init_fsm_state_t state = SD_INIT_START;
memcpy(&card->params, params, sizeof(sdcard_spi_params_t));
card->spi_clk = SD_CARD_SPI_SPEED_PREINIT;
do {
state = _init_sd_fsm_step(card, state);
} while (state != SD_INIT_FINISH);
if (card->card_type != SD_UNKNOWN) {
card->init_done = true;
return SDCARD_SPI_OK;
}
card->init_done = false;
return SDCARD_SPI_INIT_ERROR;
}
static sd_init_fsm_state_t _init_sd_fsm_step(sdcard_spi_t *card, sd_init_fsm_state_t state)
{
switch (state) {
case SD_INIT_START:
DEBUG("SD_INIT_START\n");
if ((gpio_init(card->params.mosi, GPIO_OUT) == 0) &&
(gpio_init(card->params.clk, GPIO_OUT) == 0) &&
(gpio_init(card->params.cs, GPIO_OUT) == 0) &&
(gpio_init(card->params.miso, GPIO_IN_PU) == 0) &&
( (card->params.power == GPIO_UNDEF) ||
(gpio_init(card->params.power, GPIO_OUT) == 0)) ) {
DEBUG("gpio_init(): [OK]\n");
return SD_INIT_SPI_POWER_SEQ;
}
DEBUG("gpio_init(): [ERROR]\n");
return SD_INIT_CARD_UNKNOWN;
case SD_INIT_SPI_POWER_SEQ:
DEBUG("SD_INIT_SPI_POWER_SEQ\n");
if (card->params.power != GPIO_UNDEF) {
gpio_write(card->params.power, card->params.power_act_high);
xtimer_usleep(SD_CARD_WAIT_AFTER_POWER_UP_US);
}
gpio_set(card->params.mosi);
gpio_set(card->params.cs); /* unselect sdcard for power up sequence */
/* powersequence: perform at least 74 clockcycles with mosi_pin being high
* (same as sending dummy bytes with 0xFF) */
for (int i = 0; i < SD_POWERSEQUENCE_CLOCK_COUNT; i += 1) {
gpio_set(card->params.clk);
xtimer_usleep(SD_CARD_PREINIT_CLOCK_PERIOD_US/2);
gpio_clear(card->params.clk);
xtimer_usleep(SD_CARD_PREINIT_CLOCK_PERIOD_US/2);
}
return SD_INIT_SEND_CMD0;
case SD_INIT_SEND_CMD0:
DEBUG("SD_INIT_SEND_CMD0\n");
gpio_clear(card->params.mosi);
/* use soft-spi to perform init command to allow use of internal pull-ups on miso */
_dyn_spi_rxtx_byte = &_sw_spi_rxtx_byte;
/* select sdcard for cmd0 */
gpio_clear(card->params.cs);
char cmd0_r1 = sdcard_spi_send_cmd(card, SD_CMD_0, SD_CMD_NO_ARG, INIT_CMD0_RETRY_CNT);
gpio_set(card->params.cs);
if (R1_VALID(cmd0_r1) && !R1_ERROR(cmd0_r1) && R1_IDLE_BIT_SET(cmd0_r1)) {
DEBUG("CMD0: [OK]\n");
/* give control over SPI pins back to HW SPI device */
spi_init_pins(card->params.spi_dev);
/* switch to HW SPI since SD card is now in real SPI mode */
_dyn_spi_rxtx_byte = &_hw_spi_rxtx_byte;
return SD_INIT_ENABLE_CRC;
}
return SD_INIT_CARD_UNKNOWN;
case SD_INIT_ENABLE_CRC:
DEBUG("SD_INIT_ENABLE_CRC\n");
_select_card_spi(card);
char r1 = sdcard_spi_send_cmd(card, SD_CMD_59, SD_CMD_59_ARG_EN, INIT_CMD_RETRY_CNT);
_unselect_card_spi(card);
if (R1_VALID(r1) && !R1_ERROR(r1)) {
DEBUG("CMD59: [OK]\n");
return SD_INIT_SEND_CMD8;
}
return SD_INIT_CARD_UNKNOWN;
case SD_INIT_SEND_CMD8:
DEBUG("SD_INIT_SEND_CMD8\n");
_select_card_spi(card);
int cmd8_arg = (SD_CMD_8_VHS_2_7_V_TO_3_6_V << 8) | SD_CMD_8_CHECK_PATTERN;
char cmd8_r1 = sdcard_spi_send_cmd(card, SD_CMD_8, cmd8_arg, INIT_CMD_RETRY_CNT);
if (R1_VALID(cmd8_r1) && !R1_ERROR(cmd8_r1)) {
DEBUG("CMD8: [OK] --> reading remaining bytes for R7\n");
char r7[4];
if (_transfer_bytes(card, 0, &r7[0], sizeof(r7)) == sizeof(r7)) {
DEBUG("R7 response: 0x%02x 0x%02x 0x%02x 0x%02x\n", r7[0], r7[1], r7[2], r7[3]);
/* check if lower 12 bits (voltage range and check pattern) of response and arg
are equal to verify compatibility and communication is working properly */
if (((r7[2] & 0x0F) == ((cmd8_arg >> 8) & 0x0F)) &&
(r7[3] == (cmd8_arg & 0xFF))) {
DEBUG("CMD8: [R7 MATCH]\n");
return SD_INIT_SEND_ACMD41_HCS;
}
DEBUG("CMD8: [R7 MISMATCH]\n");
_unselect_card_spi(card);
return SD_INIT_CARD_UNKNOWN;;
}
DEBUG("CMD8: _transfer_bytes (R7): [ERROR]\n");
return SD_INIT_CARD_UNKNOWN;
}
DEBUG("CMD8: [ERROR / NO RESPONSE]\n");
return SD_INIT_SEND_ACMD41;
case SD_INIT_CARD_UNKNOWN:
DEBUG("SD_INIT_CARD_UNKNOWN\n");
card->card_type = SD_UNKNOWN;
return SD_INIT_FINISH;
case SD_INIT_SEND_ACMD41_HCS:
DEBUG("SD_INIT_SEND_ACMD41_HCS\n");
int acmd41_hcs_retries = 0;
do {
char acmd41hcs_r1 = sdcard_spi_send_acmd(card, SD_CMD_41, SD_ACMD_41_ARG_HC, 0);
if (R1_VALID(acmd41hcs_r1) && !R1_ERROR(acmd41hcs_r1) &&
!R1_IDLE_BIT_SET(acmd41hcs_r1)) {
DEBUG("ACMD41: [OK]\n");
return SD_INIT_SEND_CMD58;
}
acmd41_hcs_retries++;
} while (INIT_CMD_RETRY_CNT < 0 || acmd41_hcs_retries <= INIT_CMD_RETRY_CNT);;
_unselect_card_spi(card);
return SD_INIT_CARD_UNKNOWN;
case SD_INIT_SEND_ACMD41:
DEBUG("SD_INIT_SEND_ACMD41\n");
int acmd41_retries = 0;
do {
char acmd41_r1 = sdcard_spi_send_acmd(card, SD_CMD_41, SD_CMD_NO_ARG, 0);
if (R1_VALID(acmd41_r1) && !R1_ERROR(acmd41_r1) && !R1_IDLE_BIT_SET(acmd41_r1)) {
DEBUG("ACMD41: [OK]\n");
card->use_block_addr = false;
card->card_type = SD_V1;
return SD_INIT_SEND_CMD16;
}
acmd41_retries++;
} while (INIT_CMD_RETRY_CNT < 0 || acmd41_retries <= INIT_CMD_RETRY_CNT);
DEBUG("ACMD41: [ERROR]\n");
return SD_INIT_SEND_CMD1;
case SD_INIT_SEND_CMD1:
DEBUG("SD_INIT_SEND_CMD1\n");
DEBUG("COULD TRY CMD1 (for MMC-card)-> currently not suported\n");
_unselect_card_spi(card);
return SD_INIT_CARD_UNKNOWN;
case SD_INIT_SEND_CMD58:
DEBUG("SD_INIT_SEND_CMD58\n");
char cmd58_r1 = sdcard_spi_send_cmd(card, SD_CMD_58, SD_CMD_NO_ARG, INIT_CMD_RETRY_CNT);
if (R1_VALID(cmd58_r1) && !R1_ERROR(cmd58_r1)) {
DEBUG("CMD58: [OK]\n");
card->card_type = SD_V2;
char r3[4];
if (_transfer_bytes(card, 0, r3, sizeof(r3)) == sizeof(r3)) {
uint32_t ocr = ((uint32_t)r3[0] << (3 * 8)) |
((uint32_t)r3[1] << (2 * 8)) | (r3[2] << 8) | r3[3];
DEBUG("R3 RESPONSE: 0x%02x 0x%02x 0x%02x 0x%02x\n", r3[0], r3[1], r3[2], r3[3]);
DEBUG("OCR: 0x%"PRIx32"\n", ocr);
if ((ocr & SYSTEM_VOLTAGE) != 0) {
DEBUG("OCR: SYS VOLTAGE SUPPORTED\n");
if ((ocr & OCR_POWER_UP_STATUS) != 0) { //if power up outine is finished
DEBUG("OCR: POWER UP ROUTINE FINISHED\n");
if ((ocr & OCR_CCS) != 0) { //if sd card is sdhc
DEBUG("OCR: CARD TYPE IS SDHC (SD_V2 with block adressing)\n");
card->use_block_addr = true;
_unselect_card_spi(card);
return SD_INIT_READ_CID;
}
DEBUG("OCR: CARD TYPE IS SDSC (SD_v2 with byte adressing)\n");
card->use_block_addr = false;
return SD_INIT_SEND_CMD16;
}
DEBUG("OCR: POWER UP ROUTINE NOT FINISHED!\n");
/* poll status till power up is finished */
return SD_INIT_SEND_CMD58;
}
DEBUG("OCR: SYS VOLTAGE NOT SUPPORTED!\n");
}
DEBUG("CMD58 response: [READ ERROR]\n");
}
DEBUG("CMD58: [ERROR]\n");
_unselect_card_spi(card);
return SD_INIT_CARD_UNKNOWN;
case SD_INIT_SEND_CMD16:
DEBUG("SD_INIT_SEND_CMD16\n");
char r1_16 = sdcard_spi_send_cmd(card, SD_CMD_16, SD_HC_BLOCK_SIZE, INIT_CMD_RETRY_CNT);
if (R1_VALID(r1_16) && !R1_ERROR(r1_16)) {
DEBUG("CARD TYPE IS SDSC (SD_V1 with byte adressing)\n");
_unselect_card_spi(card);
return SD_INIT_READ_CID;
}
else {
_unselect_card_spi(card);
return SD_INIT_CARD_UNKNOWN;
}
case SD_INIT_READ_CID:
DEBUG("SD_INIT_READ_CID\n");
if (_read_cid(card) == SD_RW_OK) {
return SD_INIT_READ_CSD;
}
else {
DEBUG("reading cid register failed!\n");
return SD_INIT_CARD_UNKNOWN;
}
case SD_INIT_READ_CSD:
DEBUG("SD_INIT_READ_CSD\n");
if (_read_csd(card) == SD_RW_OK) {
if (card->csd_structure == SD_CSD_V1) {
DEBUG("csd_structure is version 1\n");
}
else if (card->csd_structure == SD_CSD_V2) {
DEBUG("csd_structure is version 2\n");
}
return SD_INIT_SET_MAX_SPI_SPEED;
}
else {
DEBUG("reading csd register failed!\n");
return SD_INIT_CARD_UNKNOWN;
}
case SD_INIT_SET_MAX_SPI_SPEED:
DEBUG("SD_INIT_SET_MAX_SPI_SPEED\n");
card->spi_clk = SD_CARD_SPI_SPEED_POSTINIT;
DEBUG("SD_INIT_SET_MAX_SPI_SPEED: [OK]\n");
return SD_INIT_FINISH;
default:
DEBUG("SD-INIT-FSM REACHED INVALID STATE!\n");
return SD_INIT_CARD_UNKNOWN;
}
}
static inline bool _wait_for_token(sdcard_spi_t *card, char token, int32_t max_retries)
{
int tried = 0;
do {
char read_byte = 0;
read_byte = spi_transfer_byte(card->params.spi_dev, GPIO_UNDEF, true,
SD_CARD_DUMMY_BYTE);
if (read_byte == token) {
DEBUG("_wait_for_token: [MATCH]\n");
return true;
}
else {
DEBUG("_wait_for_token: [NO MATCH] (0x%02x)\n", read_byte);
}
tried++;
} while ((max_retries < 0) || (tried <= max_retries));
return false;
}
static inline void _send_dummy_byte(sdcard_spi_t *card)
{
char read_byte;
if (_dyn_spi_rxtx_byte(card, SD_CARD_DUMMY_BYTE, &read_byte) == 1) {
DEBUG("_send_dummy_byte:echo: 0x%02x\n", read_byte);
}
else {
DEBUG("_send_dummy_byte:_dyn_spi_rxtx_byte: [FAILED]\n");
}
}
static inline bool _wait_for_not_busy(sdcard_spi_t *card, int32_t max_retries)
{
char read_byte;
int tried = 0;
do {
if (_dyn_spi_rxtx_byte(card, SD_CARD_DUMMY_BYTE, &read_byte) == 1) {
if (read_byte == 0xFF) {
DEBUG("_wait_for_not_busy: [OK]\n");
return true;
}
else {
DEBUG("_wait_for_not_busy: [BUSY]\n");
}
}
else {
DEBUG("_wait_for_not_busy:_dyn_spi_rxtx_byte: [FAILED]\n");
return false;
}
tried++;
} while ((max_retries < 0) || (tried <= max_retries));
DEBUG("_wait_for_not_busy: [FAILED]\n");
return false;
}
static char _crc_7(const char *data, int n)
{
char crc = 0;
for (int i = 0; i < n; i++) {
char d = data[i];
for (int j = 0; j < 8; j++) {
crc <<= 1;
if ((d & 0x80) ^ (crc & 0x80)) {
crc ^= 0x09;
}
d <<= 1;
}
}
return (crc << 1) | 1;
}
static uint16_t _crc_16(const char *data, size_t n)
{
uint16_t crc = 0;
for (size_t i = 0; i < n; i++) {
crc = (uint8_t)(crc >> 8) | (crc << 8);
crc ^= data[i];
crc ^= (uint8_t)(crc & 0xFF) >> 4;
crc ^= crc << 12;
crc ^= (crc & 0xFF) << 5;
}
return crc;
}
char sdcard_spi_send_cmd(sdcard_spi_t *card, char sd_cmd_idx, uint32_t argument, int32_t max_retry)
{
int try_cnt = 0;
char r1_resu;
char cmd_data[6];
cmd_data[0] = SD_CMD_PREFIX_MASK | sd_cmd_idx;
cmd_data[1] = argument >> (3 * 8);
cmd_data[2] = (argument >> (2 * 8)) & 0xFF;
cmd_data[3] = (argument >> 8) & 0xFF;
cmd_data[4] = argument & 0xFF;
cmd_data[5] = _crc_7(cmd_data, sizeof(cmd_data) - 1);
char echo[sizeof(cmd_data)];
do {
DEBUG("sdcard_spi_send_cmd: CMD%02d (0x%08lx) (retry %d)\n", sd_cmd_idx, argument, try_cnt);
if (!_wait_for_not_busy(card, SD_WAIT_FOR_NOT_BUSY_CNT)) {
DEBUG("sdcard_spi_send_cmd: timeout while waiting for bus to be not busy!\n");
r1_resu = SD_INVALID_R1_RESPONSE;
try_cnt++;
continue;
}
if (_transfer_bytes(card, cmd_data, echo, sizeof(cmd_data)) != sizeof(cmd_data)) {
DEBUG("sdcard_spi_send_cmd: _transfer_bytes: send cmd [%d]: [ERROR]\n", sd_cmd_idx);
r1_resu = SD_INVALID_R1_RESPONSE;
try_cnt++;
continue;
}
DEBUG("CMD%02d echo: ", sd_cmd_idx);
for (unsigned i = 0; i < sizeof(echo); i++) {
DEBUG("0x%02X ", echo[i]);
}
DEBUG("\n");
/* received byte after cmd12 is a dummy byte and should be ignored */
if (sd_cmd_idx == SD_CMD_12) {
_send_dummy_byte(card);
}
r1_resu = _wait_for_r1(card, R1_POLLING_RETRY_CNT);
if (R1_VALID(r1_resu)) {
break;
}
else {
DEBUG("sdcard_spi_send_cmd: R1_TIMEOUT (0x%02x)\n", r1_resu);
r1_resu = SD_INVALID_R1_RESPONSE;
}
try_cnt++;
} while ((max_retry < 0) || (try_cnt <= max_retry));
return r1_resu;
}
char sdcard_spi_send_acmd(sdcard_spi_t *card, char sd_cmd_idx, uint32_t argument, int32_t max_retry)
{
int err_cnt = 0;
char r1_resu;
do {
DEBUG("sdcard_spi_send_acmd: CMD%02d (0x%08lx)(retry %d)\n", sd_cmd_idx, argument, err_cnt);
r1_resu = sdcard_spi_send_cmd(card, SD_CMD_55, SD_CMD_NO_ARG, 0);
if (R1_VALID(r1_resu) && !R1_ERROR(r1_resu)) {
r1_resu = sdcard_spi_send_cmd(card, sd_cmd_idx, argument, 0);
if (R1_VALID(r1_resu) && !R1_ERROR(r1_resu)) {
return r1_resu;
}
else {
DEBUG("ACMD%02d: [ERROR / NO RESPONSE]\n", sd_cmd_idx);
err_cnt++;
}
}
else {
DEBUG("CMD55: [ERROR / NO RESPONSE]\n");
err_cnt++;
}
} while ((max_retry < 0) || (err_cnt <= max_retry));
DEBUG("sdcard_spi_send_acmd: [TIMEOUT]\n");
return r1_resu;
}
static inline char _wait_for_r1(sdcard_spi_t *card, int32_t max_retries)
{
int tried = 0;
char r1;
do {
if (_dyn_spi_rxtx_byte(card, SD_CARD_DUMMY_BYTE, &r1) != 1) {
DEBUG("_wait_for_r1: _dyn_spi_rxtx_byte:[ERROR]\n");
tried++;
continue;
}
else {
DEBUG("_wait_for_r1: r1=0x%02x\n", r1);
}
if (R1_VALID(r1)) {
DEBUG("_wait_for_r1: R1_VALID\n");
return r1;
}
tried++;
} while ((max_retries < 0) || (tried <= max_retries));
DEBUG("_wait_for_r1: [TIMEOUT]\n");
return r1;
}
void _select_card_spi(sdcard_spi_t *card)
{
spi_acquire(card->params.spi_dev, GPIO_UNDEF,
SD_CARD_SPI_MODE, card->spi_clk);
gpio_clear(card->params.cs);
}
void _unselect_card_spi(sdcard_spi_t *card)
{
gpio_set(card->params.cs);
spi_release(card->params.spi_dev);
}
static inline int _sw_spi_rxtx_byte(sdcard_spi_t *card, char out, char *in){
char rx = 0;
int i = 7;
for(; i >= 0; i--){
if( ((out >> (i)) & 0x01) == 1){
gpio_set(card->params.mosi);
}else{
gpio_clear(card->params.mosi);
}
xtimer_usleep(SD_CARD_PREINIT_CLOCK_PERIOD_US/2);
gpio_set(card->params.clk);
rx = (rx | ((gpio_read(card->params.miso) > 0) << i));
xtimer_usleep(SD_CARD_PREINIT_CLOCK_PERIOD_US/2);
gpio_clear(card->params.clk);
}
*in = rx;
return 1;
}
static inline int _hw_spi_rxtx_byte(sdcard_spi_t *card, char out, char *in){
*in = spi_transfer_byte(card->params.spi_dev, GPIO_UNDEF, true, out);
return 1;
}
static inline int _transfer_bytes(sdcard_spi_t *card, const char *out, char *in, unsigned int length){
int trans_ret;
unsigned trans_bytes = 0;
char in_temp;
for (trans_bytes = 0; trans_bytes < length; trans_bytes++) {
if (out != NULL) {
trans_ret = _dyn_spi_rxtx_byte(card, out[trans_bytes], &in_temp);
}
else {
trans_ret = _dyn_spi_rxtx_byte(card, SD_CARD_DUMMY_BYTE, &in_temp);
}
if (trans_ret < 0) {
return trans_ret;
}
if (in != NULL) {
in[trans_bytes] = in_temp;
}
}
return trans_bytes;
}
static sd_rw_response_t _read_data_packet(sdcard_spi_t *card, char token, char *data, int size)
{
DEBUG("_read_data_packet: size: %d\n", size);
if (_wait_for_token(card, token, SD_DATA_TOKEN_RETRY_CNT) == true) {
DEBUG("_read_data_packet: [GOT TOKEN]\n");
}
else {
DEBUG("_read_data_packet: [GOT NO TOKEN]\n");
return SD_RW_NO_TOKEN;
}
if (_transfer_bytes(card, NULL, data, size) == size) {
DEBUG("_read_data_packet: data: ");
for (int i = 0; i < size; i++) {
DEBUG("0x%02X ", data[i]);
}
DEBUG("\n");
char crc_bytes[2];
if (_transfer_bytes(card, 0, crc_bytes, sizeof(crc_bytes)) == sizeof(crc_bytes)) {
uint16_t data__crc_16 = (crc_bytes[0] << 8) | crc_bytes[1];
if (_crc_16(data, size) == data__crc_16) {
DEBUG("_read_data_packet: [OK]\n");
return SD_RW_OK;
}
else {
DEBUG("_read_data_packet: [CRC_MISMATCH]\n");
return SD_RW_CRC_MISMATCH;
}
}
DEBUG("_read_data_packet: _transfer_bytes [RX_TX_ERROR] (while transmitting crc)\n");
return SD_RW_RX_TX_ERROR;
}
DEBUG("_read_data_packet: _transfer_bytes [RX_TX_ERROR] (while transmitting payload)\n");
return SD_RW_RX_TX_ERROR;
}
static inline int _read_blocks(sdcard_spi_t *card, int cmd_idx, int bladdr, char *data, int blsz,
int nbl, sd_rw_response_t *state)
{
_select_card_spi(card);
int reads = 0;
uint32_t addr = card->use_block_addr ? bladdr : (bladdr * SD_HC_BLOCK_SIZE);
char cmd_r1_resu = sdcard_spi_send_cmd(card, cmd_idx, addr, SD_BLOCK_READ_CMD_RETRIES);
if (R1_VALID(cmd_r1_resu) && !R1_ERROR(cmd_r1_resu)) {
DEBUG("_read_blocks: send CMD%d: [OK]\n", cmd_idx);
for (int i = 0; i < nbl; i++) {
*state = _read_data_packet(card, SD_DATA_TOKEN_CMD_17_18_24, &(data[i * blsz]), blsz);
if (*state != SD_RW_OK) {
DEBUG("_read_blocks: _read_data_packet: [FAILED]\n");
_unselect_card_spi(card);
return reads;
}
else {
reads++;
}
}
/* if this was a multi-block read */
if (cmd_idx == SD_CMD_18) {
cmd_r1_resu = sdcard_spi_send_cmd(card, SD_CMD_12, 0, 1);
if (R1_VALID(cmd_r1_resu) && !R1_ERROR(cmd_r1_resu)) {
DEBUG("_read_blocks: read multi (%d) blocks [OK]\n", nbl);
*state = SD_RW_OK;
}
else {
DEBUG("_read_blocks: send CMD12: [RX_TX_ERROR]\n");
*state = SD_RW_RX_TX_ERROR;
}
}
else {
DEBUG("_read_blocks: read single block [OK]\n");
*state = SD_RW_OK;
}
}
else {
DEBUG("_read_blocks: send CMD%d: [RX_TX_ERROR]\n", cmd_idx);
*state = SD_RW_RX_TX_ERROR;
}
_unselect_card_spi(card);
return reads;
}
int sdcard_spi_read_blocks(sdcard_spi_t *card, int blockaddr, char *data, int blocksize,
int nblocks, sd_rw_response_t *state)
{
if (nblocks > 1) {
return _read_blocks(card, SD_CMD_18, blockaddr, data, blocksize, nblocks, state);
}
else {
return _read_blocks(card, SD_CMD_17, blockaddr, data, blocksize, nblocks, state);
}
}
static sd_rw_response_t _write_data_packet(sdcard_spi_t *card, char token, const char *data, int size)
{
spi_transfer_byte(card->params.spi_dev, GPIO_UNDEF, true, token);
if (_transfer_bytes(card, data, 0, size) == size) {
uint16_t data__crc_16 = _crc_16(data, size);
char crc[sizeof(uint16_t)] = { data__crc_16 >> 8, data__crc_16 & 0xFF };
if (_transfer_bytes(card, crc, 0, sizeof(crc)) == sizeof(crc)) {
char data_response;
data_response = (char)spi_transfer_byte(card->params.spi_dev, GPIO_UNDEF,
true, SD_CARD_DUMMY_BYTE);
DEBUG("_write_data_packet: DATA_RESPONSE: 0x%02x\n", data_response);
if (DATA_RESPONSE_IS_VALID(data_response)) {
if (DATA_RESPONSE_ACCEPTED(data_response)) {
DEBUG("_write_data_packet: DATA_RESPONSE: [OK]\n");
return SD_RW_OK;
}
else {
if (DATA_RESPONSE_WRITE_ERR(data_response)) {
DEBUG("_write_data_packet: DATA_RESPONSE: [WRITE_ERROR]\n");
}
if (DATA_RESPONSE_CRC_ERR(data_response)) {
DEBUG("_write_data_packet: DATA_RESPONSE: [CRC_ERROR]\n");
}
return SD_RW_WRITE_ERROR;
}
}
else {
DEBUG("_write_data_packet: DATA_RESPONSE invalid\n");
return SD_RW_RX_TX_ERROR;
}
}
else {
DEBUG("_write_data_packet: [RX_TX_ERROR] (while transmitting CRC16)\n");
return SD_RW_RX_TX_ERROR;
}
}
else {
DEBUG("_write_data_packet: [RX_TX_ERROR] (while transmitting payload)\n");
return SD_RW_RX_TX_ERROR;
}
}
static inline int _write_blocks(sdcard_spi_t *card, char cmd_idx, int bladdr, const char *data, int blsz,
int nbl, sd_rw_response_t *state)
{
_select_card_spi(card);
int written = 0;
uint32_t addr = card->use_block_addr ? bladdr : (bladdr * SD_HC_BLOCK_SIZE);
char cmd_r1_resu = sdcard_spi_send_cmd(card, cmd_idx, addr, SD_BLOCK_WRITE_CMD_RETRIES);
if (R1_VALID(cmd_r1_resu) && !R1_ERROR(cmd_r1_resu)) {
DEBUG("_write_blocks: send CMD%d: [OK]\n", cmd_idx);
int token;
if (cmd_idx == SD_CMD_25) {
token = SD_DATA_TOKEN_CMD_25;
}
else {
token = SD_DATA_TOKEN_CMD_17_18_24;
}
for (int i = 0; i < nbl; i++) {
sd_rw_response_t write_resu = _write_data_packet(card, token, &(data[i * blsz]), blsz);
if (write_resu != SD_RW_OK) {
DEBUG("_write_blocks: _write_data_packet: [FAILED]\n");
_unselect_card_spi(card);
*state = write_resu;
return written;
}
if (!_wait_for_not_busy(card, SD_WAIT_FOR_NOT_BUSY_CNT)) {
DEBUG("_write_blocks: _wait_for_not_busy: [FAILED]\n");
_unselect_card_spi(card);
*state = SD_RW_TIMEOUT;
return written;
}
written++;
}
/* if this is a multi-block write it is needed to issue a stop command*/
if (cmd_idx == SD_CMD_25) {
spi_transfer_byte(card->params.spi_dev, GPIO_UNDEF, true,
SD_DATA_TOKEN_CMD_25_STOP);
DEBUG("_write_blocks: write multi (%d) blocks: [OK]\n", nbl);
_send_dummy_byte(card); //sd card needs dummy byte before we can wait for not-busy state
if (!_wait_for_not_busy(card, SD_WAIT_FOR_NOT_BUSY_CNT)) {
_unselect_card_spi(card);
*state = SD_RW_TIMEOUT;
}
}
else {
DEBUG("_write_blocks: write single block: [OK]\n");
*state = SD_RW_OK;
}
_unselect_card_spi(card);
return written;
}
else {
DEBUG("_write_blocks: sdcard_spi_send_cmd: SD_CMD_ERROR_NO_RESP\n");
_unselect_card_spi(card);
*state = SD_RW_RX_TX_ERROR;
return written;
}
}
int sdcard_spi_write_blocks(sdcard_spi_t *card, int blockaddr, const char *data, int blocksize,
int nblocks, sd_rw_response_t *state)
{
if (nblocks > 1) {
return _write_blocks(card, SD_CMD_25, blockaddr, data, blocksize, nblocks, state);
}
else {
return _write_blocks(card, SD_CMD_24, blockaddr, data, blocksize, nblocks, state);
}
}
sd_rw_response_t _read_cid(sdcard_spi_t *card)
{
char cid_raw_data[SD_SIZE_OF_CID_AND_CSD_REG];
sd_rw_response_t state;
int nbl = _read_blocks(card, SD_CMD_10, 0, cid_raw_data, SD_SIZE_OF_CID_AND_CSD_REG,
SD_BLOCKS_FOR_REG_READ, &state);
DEBUG("_read_cid: _read_blocks: nbl=%d state=%d\n", nbl, state);
DEBUG("_read_cid: cid_raw_data: ");
for (unsigned i = 0; i < sizeof(cid_raw_data); i++) {
DEBUG("0x%02X ", cid_raw_data[i]);
}
DEBUG("\n");
char crc7 = _crc_7(&(cid_raw_data[0]), SD_SIZE_OF_CID_AND_CSD_REG - 1);
if (nbl == SD_BLOCKS_FOR_REG_READ) {
if (crc7 == cid_raw_data[SD_SIZE_OF_CID_AND_CSD_REG - 1]) {
card->cid.MID = cid_raw_data[0];
memcpy(&card->cid.OID[0], &cid_raw_data[1], SD_SIZE_OF_OID);
memcpy(&card->cid.PNM[0], &cid_raw_data[2], SD_SIZE_OF_PNM);
card->cid.PRV = cid_raw_data[8];
memcpy((char *)&card->cid.PSN, &cid_raw_data[9], 4);
card->cid.MDT = (cid_raw_data[13]<<4) | cid_raw_data[14];
card->cid.CID_CRC = cid_raw_data[15];
DEBUG("_read_cid: [OK]\n");
return SD_RW_OK;
}
else {
DEBUG("_read_cid: [SD_RW_CRC_MISMATCH] (data-crc: 0x%02x | calc-crc: 0x%02x)\n",
cid_raw_data[SD_SIZE_OF_CID_AND_CSD_REG - 1], crc7);
return SD_RW_CRC_MISMATCH;
}
}
return state;
}
sd_rw_response_t _read_csd(sdcard_spi_t *card)
{
char c[SD_SIZE_OF_CID_AND_CSD_REG];
sd_rw_response_t state;
int read_resu = _read_blocks(card, SD_CMD_9, 0, c, SD_SIZE_OF_CID_AND_CSD_REG,
SD_BLOCKS_FOR_REG_READ, &state);
DEBUG("_read_csd: _read_blocks: read_resu=%d state=%d\n", read_resu, state);
DEBUG("_read_csd: raw data: ");
for (unsigned i = 0; i < sizeof(c); i++) {
DEBUG("0x%02X ", c[i]);
}
DEBUG("\n");
if (read_resu == SD_BLOCKS_FOR_REG_READ) {
if (_crc_7(c, SD_SIZE_OF_CID_AND_CSD_REG - 1) == c[SD_SIZE_OF_CID_AND_CSD_REG - 1]) {
if (SD_GET_CSD_STRUCTURE(c) == SD_CSD_V1) {
card->csd.v1.CSD_STRUCTURE = c[0]>>6;
card->csd.v1.TAAC = c[1];
card->csd.v1.NSAC = c[2];
card->csd.v1.TRAN_SPEED = c[3];
card->csd.v1.CCC = (c[4]<<4) | ((c[5] & 0xF0)>>4);
card->csd.v1.READ_BL_LEN = (c[5] & 0x0F);
card->csd.v1.READ_BL_PARTIAL = (c[6] & (1<<7))>>7;
card->csd.v1.WRITE_BLK_MISALIGN = (c[6] & (1<<6))>>6;
card->csd.v1.READ_BLK_MISALIGN = (c[6] & (1<<5))>>5;
card->csd.v1.DSR_IMP = (c[6] & (1<<4))>>4;
card->csd.v1.C_SIZE = ((c[6] & 0x03)<<10) | (c[7]<<2) | (c[8]>>6);
card->csd.v1.VDD_R_CURR_MIN = (c[8] & 0x38)>>3;
card->csd.v1.VDD_R_CURR_MAX = (c[8] & 0x07);
card->csd.v1.VDD_W_CURR_MIN = (c[9] & 0xE0)>>5;
card->csd.v1.VDD_W_CURR_MAX = (c[9] & 0x1C)>>2;
card->csd.v1.C_SIZE_MULT = ((c[9] & 0x03)<<1) | (c[10]>>7);
card->csd.v1.ERASE_BLK_EN = (c[10] & (1<<6))>>6;
card->csd.v1.SECTOR_SIZE = ((c[10] & 0x3F)<<1) | (c[11]>>7);
card->csd.v1.WP_GRP_SIZE = (c[11] & 0x7F);
card->csd.v1.WP_GRP_ENABLE = c[12]>>7;
card->csd.v1.R2W_FACTOR = (c[12] & 0x1C)>>2;
card->csd.v1.WRITE_BL_LEN = (c[12] & 0x03)<<2 | (c[13]>>6);
card->csd.v1.WRITE_BL_PARTIAL = (c[13] & (1<<5))>>5;
card->csd.v1.FILE_FORMAT_GRP = (c[14] & (1<<7))>>7;
card->csd.v1.COPY = (c[14] & (1<<6))>>6;
card->csd.v1.PERM_WRITE_PROTECT = (c[14] & (1<<5))>>5;
card->csd.v1.TMP_WRITE_PROTECT = (c[14] & (1<<4))>>4;
card->csd.v1.FILE_FORMAT = (c[14] & 0x0C)>>2;
card->csd.v1.CSD_CRC = c[15];
card->csd_structure = SD_CSD_V1;
return SD_RW_OK;
}
else if (SD_GET_CSD_STRUCTURE(c) == SD_CSD_V2) {
card->csd.v2.CSD_STRUCTURE = c[0]>>6;
card->csd.v2.TAAC = c[1];
card->csd.v2.NSAC = c[2];
card->csd.v2.TRAN_SPEED = c[3];
card->csd.v2.CCC = (c[4]<<4) | ((c[5] & 0xF0)>>4);
card->csd.v2.READ_BL_LEN = (c[5] & 0x0F);
card->csd.v2.READ_BL_PARTIAL = (c[6] & (1<<7))>>7;
card->csd.v2.WRITE_BLK_MISALIGN = (c[6] & (1<<6))>>6;
card->csd.v2.READ_BLK_MISALIGN = (c[6] & (1<<5))>>5;
card->csd.v2.DSR_IMP = (c[6] & (1<<4))>>4;
card->csd.v2.C_SIZE = (((uint32_t)c[7] & 0x3F)<<16)
| (c[8]<<8) | c[9];
card->csd.v2.ERASE_BLK_EN = (c[10] & (1<<6))>>6;
card->csd.v2.SECTOR_SIZE = (c[10] & 0x3F)<<1 | (c[11]>>7);
card->csd.v2.WP_GRP_SIZE = (c[11] & 0x7F);
card->csd.v2.WP_GRP_ENABLE = (c[12] & (1<<7))>> 7;
card->csd.v2.R2W_FACTOR = (c[12] & 0x1C)>> 2;
card->csd.v2.WRITE_BL_LEN = ((c[12] & 0x03)<<2) | (c[13]>>6);
card->csd.v2.WRITE_BL_PARTIAL = (c[13] & (1<<5))>>5;
card->csd.v2.FILE_FORMAT_GRP = (c[14] & (1<<7))>>7;
card->csd.v2.COPY = (c[14] & (1<<6))>>6;
card->csd.v2.PERM_WRITE_PROTECT = (c[14] & (1<<5))>>5;
card->csd.v2.TMP_WRITE_PROTECT = (c[14] & (1<<4))>>4;
card->csd.v2.FILE_FORMAT = (c[14] & 0x0C)>>2;
card->csd.v2.CSD_CRC = c[15];
card->csd_structure = SD_CSD_V2;
return SD_RW_OK;
}
else {
return SD_RW_NOT_SUPPORTED;
}
}
else {
return SD_RW_CRC_MISMATCH;
}
}
return state;
}
sd_rw_response_t sdcard_spi_read_sds(sdcard_spi_t *card, sd_status_t *sd_status){
_select_card_spi(card);
char sds_raw_data[SD_SIZE_OF_SD_STATUS];
char r1_resu = sdcard_spi_send_cmd(card, SD_CMD_55, SD_CMD_NO_ARG, 0);
_unselect_card_spi(card);
if (R1_VALID(r1_resu)) {
if(!R1_ERROR(r1_resu)){
sd_rw_response_t state;
int nbl = _read_blocks(card, SD_CMD_13, 0, sds_raw_data, SD_SIZE_OF_SD_STATUS,
SD_BLOCKS_FOR_REG_READ, &state);
DEBUG("sdcard_spi_read_sds: _read_blocks: nbl=%d state=%d\n", nbl, state);
DEBUG("sdcard_spi_read_sds: sds_raw_data: ");
for (unsigned i = 0; i < sizeof(sds_raw_data); i++) {
DEBUG("0x%02X ", sds_raw_data[i]);
}
DEBUG("\n");
if (nbl == SD_BLOCKS_FOR_REG_READ) {
sd_status->DAT_BUS_WIDTH = sds_raw_data[0] >> 6;
sd_status->SECURED_MODE = (sds_raw_data[0] & (1<<5)) >> 5;
sd_status->SD_CARD_TYPE = (sds_raw_data[2] << 8) | sds_raw_data[3];
sd_status->SIZE_OF_PROTECTED_AREA = ((uint32_t)sds_raw_data[4] << (3*8)) |
((uint32_t)sds_raw_data[5] << (2*8)) |
(sds_raw_data[6] << 8 ) |
sds_raw_data[7];
sd_status->SPEED_CLASS = sds_raw_data[8];
sd_status->PERFORMANCE_MOVE = sds_raw_data[9];
sd_status->AU_SIZE = sds_raw_data[10] >> 4;
sd_status->ERASE_SIZE = (sds_raw_data[11] << 8) | sds_raw_data[12];
sd_status->ERASE_TIMEOUT = sds_raw_data[13] >> 2;
sd_status->ERASE_OFFSET = sds_raw_data[13] & 0x03;
sd_status->UHS_SPEED_GRADE = sds_raw_data[14] >> 4;
sd_status->UHS_AU_SIZE = sds_raw_data[14] & 0x0F;
sd_status->VIDEO_SPEED_CLASS = sds_raw_data[15];
sd_status->VSC_AU_SIZE = ((sds_raw_data[16] & 0x03) << 8)
| sds_raw_data[17];
sd_status->SUS_ADDR = (sds_raw_data[18] << 14) |
(sds_raw_data[19] << 6 ) |
(sds_raw_data[20] >> 2 );
DEBUG("sdcard_spi_read_sds: [OK]\n");
return SD_RW_OK;
}
return state;
}
return SD_RW_RX_TX_ERROR;
}
return SD_RW_TIMEOUT;
}
uint64_t sdcard_spi_get_capacity(sdcard_spi_t *card)
{
if (card->csd_structure == SD_CSD_V1) {
uint32_t block_len = (1 << card->csd.v1.READ_BL_LEN);
uint32_t mult = 1 << (card->csd.v1.C_SIZE_MULT + 2);
uint32_t blocknr = (card->csd.v1.C_SIZE + 1) * mult;
return blocknr * block_len;
}
else if (card->csd_structure == SD_CSD_V2) {
return (card->csd.v2.C_SIZE + 1) * (uint64_t)(SD_HC_BLOCK_SIZE << 10);
}
return 0;
}
uint32_t sdcard_spi_get_sector_count(sdcard_spi_t *card)
{
return sdcard_spi_get_capacity(card) / SD_HC_BLOCK_SIZE;
}
uint32_t sdcard_spi_get_au_size(sdcard_spi_t *card)
{
sd_status_t sds;
if(sdcard_spi_read_sds(card, &sds) == SD_RW_OK) {
if (sds.AU_SIZE < 0xB) {
return 1 << (13 + sds.AU_SIZE); /* sds->AU_SIZE = 1 maps to 16KB; 2 to 32KB etc.*/
}
else if (sds.AU_SIZE == 0xB) {
return 12 * SDCARD_SPI_IEC_KIBI * SDCARD_SPI_IEC_KIBI; /* 12 MB */
}
else if (sds.AU_SIZE == 0xC) {
return 1 << (12 + sds.AU_SIZE); /* 16 MB */
}
else if (sds.AU_SIZE == 0xD) {
return 24 * SDCARD_SPI_IEC_KIBI * SDCARD_SPI_IEC_KIBI; /* 24 MB */
}
else if (sds.AU_SIZE > 0xD) {
return 1 << (11 + sds.AU_SIZE); /* 32 MB or 64 MB */
}
}
return 0; /* AU_SIZE is not defined by the card */
}
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