zephyr/subsys/sd/sd.c

318 lines
8.0 KiB
C

/*
* Copyright 2022 NXP
*
* SPDX-License-Identifier: Apache-2.0
*/
#include <zephyr/kernel.h>
#include <zephyr/drivers/sdhc.h>
#include <zephyr/sd/sd.h>
#include <zephyr/sd/sdmmc.h>
#include <zephyr/sd/sd_spec.h>
#include <zephyr/logging/log.h>
#include <zephyr/sys/__assert.h>
#include "sd_utils.h"
#include "sd_init.h"
LOG_MODULE_REGISTER(sd, CONFIG_SD_LOG_LEVEL);
/* Idle all cards on bus. Can be used to clear errors on cards */
static inline int sd_idle(struct sd_card *card)
{
struct sdhc_command cmd;
/* Reset card with CMD0 */
cmd.opcode = SD_GO_IDLE_STATE;
cmd.arg = 0x0;
cmd.response_type = (SD_RSP_TYPE_NONE | SD_SPI_RSP_TYPE_R1);
cmd.retries = CONFIG_SD_CMD_RETRIES;
cmd.timeout_ms = CONFIG_SD_CMD_TIMEOUT;
return sdhc_request(card->sdhc, &cmd, NULL);
}
/* Sends CMD8 during SD initialization */
static int sd_send_interface_condition(struct sd_card *card)
{
struct sdhc_command cmd;
int ret;
uint32_t resp;
cmd.opcode = SD_SEND_IF_COND;
cmd.arg = SD_IF_COND_VHS_3V3 | SD_IF_COND_CHECK;
cmd.response_type = (SD_RSP_TYPE_R7 | SD_SPI_RSP_TYPE_R7);
cmd.retries = CONFIG_SD_CMD_RETRIES;
cmd.timeout_ms = CONFIG_SD_CMD_TIMEOUT;
ret = sdhc_request(card->sdhc, &cmd, NULL);
if (ret) {
LOG_DBG("SD CMD8 failed with error %d", ret);
/* Retry */
return SD_RETRY;
}
if (card->host_props.is_spi) {
resp = cmd.response[1];
} else {
resp = cmd.response[0];
}
if ((resp & 0xFF) != SD_IF_COND_CHECK) {
LOG_INF("Legacy card detected, no CMD8 support");
/* Retry probe */
return SD_RETRY;
}
if ((resp & SD_IF_COND_VHS_MASK) != SD_IF_COND_VHS_3V3) {
/* Card does not support 3.3V */
return -ENOTSUP;
}
LOG_DBG("Found SDHC with CMD8 support");
card->flags |= SD_SDHC_FLAG;
return 0;
}
/* Sends CMD59 to enable CRC checking for SD card in SPI mode */
static int sd_enable_crc(struct sd_card *card)
{
struct sdhc_command cmd;
/* CMD59 for CRC mode is only valid for SPI hosts */
__ASSERT_NO_MSG(card->host_props.is_spi);
cmd.opcode = SD_SPI_CRC_ON_OFF;
cmd.arg = 0x1; /* Enable CRC */
cmd.response_type = SD_SPI_RSP_TYPE_R1;
cmd.retries = CONFIG_SD_CMD_RETRIES;
cmd.timeout_ms = CONFIG_SD_CMD_TIMEOUT;
return sdhc_request(card->sdhc, &cmd, NULL);
}
/*
* Perform init required for both SD and SDIO cards.
* This function performs the following portions of SD initialization
* - CMD0 (SD reset)
* - CMD8 (SD voltage check)
*/
static int sd_common_init(struct sd_card *card)
{
int ret;
/* Reset card with CMD0 */
ret = sd_idle(card);
if (ret) {
LOG_ERR("Card error on CMD0");
return ret;
}
/* Perform voltage check using SD CMD8 */
ret = sd_retry(sd_send_interface_condition, card, CONFIG_SD_RETRY_COUNT);
if (ret == -ETIMEDOUT) {
LOG_INF("Card does not support CMD8, assuming legacy card");
return sd_idle(card);
} else if (ret) {
LOG_ERR("Card error on CMD 8");
return ret;
}
if (card->host_props.is_spi &&
IS_ENABLED(CONFIG_SDHC_SUPPORTS_SPI_MODE)) {
/* Enable CRC for spi commands using CMD59 */
ret = sd_enable_crc(card);
}
return ret;
}
static int sd_init_io(struct sd_card *card)
{
struct sdhc_io *bus_io = &card->bus_io;
struct sdhc_host_props *host_props = &card->host_props;
int ret, voltage;
/* SD clock should start gated */
bus_io->clock = 0;
/* SPI requires SDHC PUSH PULL, and open drain buses use more power */
bus_io->bus_mode = SDHC_BUSMODE_PUSHPULL;
bus_io->power_mode = SDHC_POWER_ON;
bus_io->bus_width = SDHC_BUS_WIDTH1BIT;
/* Cards start with legacy timing and Maximum voltage Host controller support */
bus_io->timing = SDHC_TIMING_LEGACY;
if (host_props->host_caps.vol_330_support) {
LOG_DBG("Host controller support 3.3V max");
voltage = SD_VOL_3_3_V;
} else if (host_props->host_caps.vol_300_support) {
LOG_DBG("Host controller support 3.0V max");
voltage = SD_VOL_3_0_V;
} else {
LOG_DBG("Host controller support 1.8V max");
voltage = SD_VOL_1_8_V;
}
/* Set to maximum voltage support by Host controller */
bus_io->signal_voltage = voltage;
/* Toggle power to card to reset it */
LOG_DBG("Resetting power to card");
bus_io->power_mode = SDHC_POWER_OFF;
ret = sdhc_set_io(card->sdhc, bus_io);
if (ret) {
LOG_ERR("Could not disable card power via SDHC");
return ret;
}
sd_delay(card->host_props.power_delay);
bus_io->power_mode = SDHC_POWER_ON;
ret = sdhc_set_io(card->sdhc, bus_io);
if (ret) {
LOG_ERR("Could not disable card power via SDHC");
return ret;
}
/* After reset or init, card voltage should be max HC support */
card->card_voltage = voltage;
/* Reset card flags */
card->flags = 0U;
/* Delay so card can power up */
sd_delay(card->host_props.power_delay);
/* Start bus clock */
bus_io->clock = SDMMC_CLOCK_400KHZ;
ret = sdhc_set_io(card->sdhc, bus_io);
if (ret) {
LOG_ERR("Could not start bus clock");
return ret;
}
return 0;
}
/*
* Performs init flow described in section 3.6 of SD specification.
*/
static int sd_command_init(struct sd_card *card)
{
int ret;
/*
* We must wait 74 clock cycles, per SD spec, to use card after power
* on. At 400000KHz, this is a 185us delay. Wait 1ms to be safe.
*/
sd_delay(1);
/*
* Start card initialization and identification
* flow described in section 3.6 of SD specification
* Common to SDIO and SDMMC. Some eMMC chips break the
* specification and expect something like this too.
*/
ret = sd_common_init(card);
if (ret) {
return ret;
}
#ifdef CONFIG_SDIO_STACK
/* Attempt to initialize SDIO card */
if (!sdio_card_init(card)) {
return 0;
}
#endif /* CONFIG_SDIO_STACK */
#ifdef CONFIG_SDMMC_STACK
/* Attempt to initialize SDMMC card */
if (!sdmmc_card_init(card)) {
return 0;
}
#endif /* CONFIG_SDIO_STACK */
#ifdef CONFIG_MMC_STACK
ret = sd_idle(card);
if (ret) {
LOG_ERR("Card error on CMD0");
return ret;
}
if (!mmc_card_init(card)) {
return 0;
}
#endif /* CONFIG_MMC_STACK */
/* Unknown card type */
return -ENOTSUP;
}
/* Initializes SD/SDIO card */
int sd_init(const struct device *sdhc_dev, struct sd_card *card)
{
int ret;
if (!sdhc_dev) {
return -ENODEV;
}
card->sdhc = sdhc_dev;
ret = sdhc_get_host_props(card->sdhc, &card->host_props);
if (ret) {
LOG_ERR("SD host controller returned invalid properties");
return ret;
}
/* init and lock card mutex */
ret = k_mutex_init(&card->lock);
if (ret) {
LOG_DBG("Could not init card mutex");
return ret;
}
ret = k_mutex_lock(&card->lock, K_MSEC(CONFIG_SD_INIT_TIMEOUT));
if (ret) {
LOG_ERR("Timeout while trying to acquire card mutex");
return ret;
}
/* Initialize SDHC IO with defaults */
ret = sd_init_io(card);
if (ret) {
k_mutex_unlock(&card->lock);
return ret;
}
/*
* SD protocol is stateful, so we must account for the possibility
* that the card is in a bad state. The return code SD_RESTART
* indicates that the initialization left the card in a bad state.
* In this case the subsystem takes the following steps:
* - set card status to error
* - re init host I/O (will also toggle power to the SD card)
* - retry initialization once more
* If initialization then fails, the sd_init routine will assume the
* card is inaccessible
*/
ret = sd_command_init(card);
if (ret == SD_RESTART) {
/* Reset I/O, and retry sd initialization once more */
card->status = CARD_ERROR;
/* Reset I/O to default */
ret = sd_init_io(card);
if (ret) {
LOG_ERR("Failed to reset SDHC I/O");
k_mutex_unlock(&card->lock);
return ret;
}
ret = sd_command_init(card);
if (ret) {
LOG_ERR("Failed to init SD card after I/O reset");
k_mutex_unlock(&card->lock);
return ret;
}
} else if (ret != 0) {
/* Initialization failed */
k_mutex_unlock(&card->lock);
card->status = CARD_ERROR;
return ret;
}
/* Card initialization succeeded. */
card->status = CARD_INITIALIZED;
/* Unlock card mutex */
ret = k_mutex_unlock(&card->lock);
if (ret) {
LOG_DBG("Could not unlock card mutex");
return ret;
}
return ret;
}
/* Return true if card is present, false otherwise */
bool sd_is_card_present(const struct device *sdhc_dev)
{
if (!sdhc_dev) {
return false;
}
return sdhc_card_present(sdhc_dev) == 1;
}