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GFX-Development-Board/software/firmware/sd_mmc/sd_mmc.c

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/**
* \file
*
* \brief Common SD/MMC stack
*
* Copyright (c) 2016-2018 Microchip Technology Inc. and its subsidiaries.
*
* \asf_license_start
*
* \page License
*
* Subject to your compliance with these terms, you may use Microchip
* software and any derivatives exclusively with Microchip products.
* It is your responsibility to comply with third party license terms applicable
* to your use of third party software (including open source software) that
* may accompany Microchip software.
*
* THIS SOFTWARE IS SUPPLIED BY MICROCHIP "AS IS". NO WARRANTIES,
* WHETHER EXPRESS, IMPLIED OR STATUTORY, APPLY TO THIS SOFTWARE,
* INCLUDING ANY IMPLIED WARRANTIES OF NON-INFRINGEMENT, MERCHANTABILITY,
* AND FITNESS FOR A PARTICULAR PURPOSE. IN NO EVENT WILL MICROCHIP BE
* LIABLE FOR ANY INDIRECT, SPECIAL, PUNITIVE, INCIDENTAL OR CONSEQUENTIAL
* LOSS, DAMAGE, COST OR EXPENSE OF ANY KIND WHATSOEVER RELATED TO THE
* SOFTWARE, HOWEVER CAUSED, EVEN IF MICROCHIP HAS BEEN ADVISED OF THE
* POSSIBILITY OR THE DAMAGES ARE FORESEEABLE. TO THE FULLEST EXTENT
* ALLOWED BY LAW, MICROCHIP'S TOTAL LIABILITY ON ALL CLAIMS IN ANY WAY
* RELATED TO THIS SOFTWARE WILL NOT EXCEED THE AMOUNT OF FEES, IF ANY,
* THAT YOU HAVE PAID DIRECTLY TO MICROCHIP FOR THIS SOFTWARE.
*
* \asf_license_stop
*
*/
/*
* Support and FAQ: visit <a href="https://www.microchip.com/support/">Microchip Support</a>
*/
#include <string.h>
#include "conf_sd_mmc.h"
#include "sd_mmc_protocol.h"
#include "sd_mmc.h"
#if CONF_OS_SUPPORT
#include <hal_rtos.h>
#endif
#include <hal_gpio.h>
#include <utils.h>
#include <utils_assert.h>
#include <utils_repeat_macro.h>
#define TPASTE2(a, b) a##b
#define ATPASTE2(a, b) TPASTE2(a, b)
/**
* \ingroup sd_mmc_stack
* \defgroup sd_mmc_stack_internal Implementation of SD/MMC/SDIO Stack
* @{
*/
#ifndef CONF_SD_MMC_MEM_CNT
#define CONF_SD_MMC_MEM_CNT 0
#endif
/* Macros to switch SD MMC stack to the correct driver (MCI or SPI) */
#if (CONF_SD_MMC_MEM_CNT != 0)
#if CONF_MCI_OS_SUPPORT
#include "hal_mci_os.h"
#else
#include "hal_mci_sync.h"
#include "hal_spi_m_sync.h"
#endif
#define driver spi_m
#include "sd_mmc_spi.h"
#else
#error No MCI or HSMCI interfaces are defined for SD MMC stack. \
CONF_SD_MMC_MEM_CNT must be added in board.h file.
#endif
#if CONF_MCI_OS_SUPPORT
#define driver_select_device ATPASTE2(driver, _os_select_device)
#define driver_deselect_device ATPASTE2(driver, _os_deselect_device)
#define driver_get_bus_width ATPASTE2(driver, _os_get_bus_width)
#define driver_is_high_speed_capable ATPASTE2(driver, _os_is_high_speed_capable)
#define driver_send_clock ATPASTE2(driver, _os_send_init_sequence)
#define driver_send_cmd ATPASTE2(driver, _os_send_cmd)
#define driver_get_response ATPASTE2(driver, _os_get_response)
#define driver_get_response_128 ATPASTE2(driver, _os_get_response_128)
#define driver_adtc_start ATPASTE2(driver, _os_adtc_start)
#define driver_adtc_stop ATPASTE2(driver, _os_send_cmd)
#define driver_read_word ATPASTE2(driver, _os_read_bytes)
#define driver_write_word ATPASTE2(driver, _os_write_bytes)
#define driver_start_read_blocks ATPASTE2(driver, _os_start_read_blocks)
#define driver_wait_end_of_read_blocks ATPASTE2(driver, _os_wait_end_of_read_blocks)
#define driver_start_write_blocks ATPASTE2(driver, _os_start_write_blocks)
#define driver_wait_end_of_write_blocks ATPASTE2(driver, _os_wait_end_of_write_blocks)
#else
#define driver_select_device ATPASTE2(driver, _sync_select_device)
#define driver_deselect_device ATPASTE2(driver, _sync_deselect_device)
#define driver_get_bus_width ATPASTE2(driver, _sync_get_bus_width)
#define driver_is_high_speed_capable ATPASTE2(driver, _sync_is_high_speed_capable)
#define driver_send_clock ATPASTE2(driver, _sync_send_clock)
#define driver_send_cmd ATPASTE2(driver, _sync_send_cmd)
#define driver_get_response ATPASTE2(driver, _sync_get_response)
#define driver_get_response_128 ATPASTE2(driver, _sync_get_response_128)
#define driver_adtc_start ATPASTE2(driver, _sync_adtc_start)
#define driver_adtc_stop ATPASTE2(driver, _sync_send_cmd)
#define driver_read_word ATPASTE2(driver, _sync_read_word)
#define driver_write_word ATPASTE2(driver, _sync_write_word)
#define driver_start_read_blocks ATPASTE2(driver, _sync_start_read_blocks)
#define driver_wait_end_of_read_blocks ATPASTE2(driver, _sync_wait_end_of_read_blocks)
#define driver_start_write_blocks ATPASTE2(driver, _sync_start_write_blocks)
#define driver_wait_end_of_write_blocks ATPASTE2(driver, _sync_wait_end_of_write_blocks)
#endif
#if (CONF_SDIO_SUPPORT == 1)
#define IS_SDIO() (sd_mmc_card->type & CARD_TYPE_SDIO)
#else
#define IS_SDIO() false
#endif
/** This SD MMC stack supports only the high voltage */
#define SD_MMC_VOLTAGE_SUPPORT \
(OCR_VDD_27_28 | OCR_VDD_28_29 | OCR_VDD_29_30 | OCR_VDD_30_31 | OCR_VDD_31_32 | OCR_VDD_32_33)
/** SD/MMC card states */
enum card_state {
SD_MMC_CARD_STATE_READY = 0, /**< Ready to use */
SD_MMC_CARD_STATE_DEBOUNCE = 1, /**< Debounce on going */
SD_MMC_CARD_STATE_INIT = 2, /**< Initialization on going */
SD_MMC_CARD_STATE_UNUSABLE = 3, /**< Unusable card */
SD_MMC_CARD_STATE_NO_CARD = 4 /**< No SD/MMC card inserted */
};
/** SD/MMC card information structure */
struct sd_mmc_card {
uint32_t clock; /**< Card access clock */
uint32_t capacity; /**< Card capacity in KBytes */
uint16_t rca; /**< Relative card address */
enum card_state state; /**< Card state */
card_type_t type; /**< Card type */
card_version_t version; /**< Card version */
uint8_t bus_width; /**< Number of DATA lin on bus (MCI only) */
uint8_t csd[CSD_REG_BSIZE]; /**< CSD register */
uint8_t high_speed; /**< High speed card (1) */
};
/** Card detect pin */
static sd_mmc_detect_t *_cd;
/** Write protect pin */
static sd_mmc_detect_t *_wp;
/** SD/MMC card list */
/** Note: Initialize card detect pin fields if present */
static struct sd_mmc_card sd_mmc_cards[CONF_SD_MMC_MEM_CNT];
/** HAL driver instance */
static void *sd_mmc_hal;
/** Index of current slot configurated */
static uint8_t sd_mmc_slot_sel;
/** Pointer on current slot configurated */
static struct sd_mmc_card *sd_mmc_card;
/** Number of block to read or write on the current transfer */
static uint16_t sd_mmc_nb_block_to_tranfer = 0;
/** Number of block remaining to read or write on the current transfer */
static uint16_t sd_mmc_nb_block_remaining = 0;
/** SD/MMC transfer rate unit codes (10K) list */
const uint32_t sd_mmc_trans_units[7] = {10, 100, 1000, 10000, 0, 0, 0};
/** SD transfer multiplier factor codes (1/10) list */
const uint32_t sd_trans_multipliers[16] = {0, 10, 12, 13, 15, 20, 25, 30, 35, 40, 45, 50, 55, 60, 70, 80};
/** MMC transfer multiplier factor codes (1/10) list */
const uint32_t mmc_trans_multipliers[16] = {0, 10, 12, 13, 15, 20, 26, 30, 35, 40, 45, 52, 55, 60, 70, 80};
/** \name MMC, SD and SDIO commands process */
/** @{ */
#if CONF_MMC_SUPPORT
static bool mmc_mci_op_cond(void);
static bool mmc_cmd6_set_bus_width(uint8_t bus_width);
static bool mmc_cmd6_set_high_speed(void);
static bool mmc_cmd8(uint8_t *b_authorize_high_speed);
static void mmc_decode_csd(void);
#endif
static bool sd_mci_op_cond(uint8_t v2);
static bool sdio_op_cond(void);
static bool sdio_get_max_speed(void);
static bool sdio_cmd52_set_bus_width(void);
static bool sdio_cmd52_set_high_speed(void);
static bool sd_cm6_set_high_speed(void);
static bool sd_cmd8(uint8_t *v2);
static bool sd_mmc_cmd9_mci(void);
static void sd_decode_csd(void);
static bool sd_mmc_cmd13(void);
#if (CONF_SDIO_SUPPORT == 1)
static bool sdio_cmd52(uint8_t rw_flag, uint8_t func_nb, uint32_t reg_addr, uint8_t rd_after_wr, uint8_t *io_data);
static bool sdio_cmd53(uint8_t rw_flag, uint8_t func_nb, uint32_t reg_addr, uint8_t inc_addr, uint32_t size,
bool access_block);
#endif
static bool sd_acmd6(void);
static bool sd_acmd51(void);
/** @} */
/** \name Internal function to process the initialization and install */
/** @{ */
static sd_mmc_err_t sd_mmc_select_slot(uint8_t slot);
static void sd_mmc_configure_slot(void);
static void sd_mmc_deselect_slot(void);
static bool sd_mmc_mci_card_init(void);
#if CONF_MMC_SUPPORT
static bool sd_mmc_mci_install_mmc(void);
#endif
/** @} */
/** \name Internal functions to manage a large timeout after a card insertion */
/** @{ */
#if CONF_OS_SUPPORT
#define SD_MMC_START_TIMEOUT() os_sleep(CONF_SD_MMC_DEBOUNCE)
#else
#define SD_MMC_START_TIMEOUT()
#endif
#define SD_MMC_IS_TIMEOUT() true
#define SD_MMC_STOP_TIMEOUT()
/** @} */
#if CONF_MMC_SUPPORT
/**
* \brief Sends operation condition command and read OCR (MCI only)
* - CMD1 sends operation condition command
* - CMD1 reads OCR
*
* \return true if success, otherwise false
*/
static bool mmc_mci_op_cond(void)
{
uint32_t retry, resp;
/*
* Timeout 1s = 400KHz / ((6+6)*8) cylces = 4200 retry
* 6 = cmd byte size
* 6 = response byte size
*/
retry = 4200;
do {
if (!driver_send_cmd(sd_mmc_hal, MMC_MCI_CMD1_SEND_OP_COND, SD_MMC_VOLTAGE_SUPPORT | OCR_ACCESS_MODE_SECTOR)) {
return false;
}
/* Check busy flag */
resp = driver_get_response(sd_mmc_hal);
if (resp & OCR_POWER_UP_BUSY) {
/* Check OCR value */
if ((resp & OCR_ACCESS_MODE_MASK) == OCR_ACCESS_MODE_SECTOR) {
sd_mmc_card->type |= CARD_TYPE_HC;
}
break;
}
if (retry-- == 0) {
return false;
}
} while (1);
return true;
}
#endif
/**
* \brief Ask to all cards to send their operations conditions (MCI only).
* - ACMD41 sends operation condition command.
* - ACMD41 reads OCR
*
* \param v2 Shall be 1 if it is a SD card V2
*
* \return true if success, otherwise false
*/
static bool sd_mci_op_cond(uint8_t v2)
{
uint32_t arg, retry, resp;
/*
* Timeout 1s = 400KHz / ((6+6+6+6)*8) cylces = 2100 retry
* 6 = cmd byte size
* 6 = response byte size
* 6 = cmd byte size
* 6 = response byte size
*/
retry = 2100;
do {
/* CMD55 - Indicate to the card that the next command is an
* application specific command rather than a standard command.*/
if (!driver_send_cmd(sd_mmc_hal, SDMMC_CMD55_APP_CMD, 0)) {
return false;
}
/* (ACMD41) Sends host OCR register */
arg = SD_MMC_VOLTAGE_SUPPORT;
if (v2) {
arg |= SD_ACMD41_HCS;
}
/* Check response */
if (!driver_send_cmd(sd_mmc_hal, SD_MCI_ACMD41_SD_SEND_OP_COND, arg)) {
return false;
}
resp = driver_get_response(sd_mmc_hal);
if (resp & OCR_POWER_UP_BUSY) {
/* Card is ready */
if ((resp & OCR_CCS) != 0) {
sd_mmc_card->type |= CARD_TYPE_HC;
}
break;
}
if (retry-- == 0) {
return false;
}
} while (1);
return true;
}
#if (CONF_SDIO_SUPPORT == 1)
/**
* \brief Try to get the SDIO card's operating condition
* - CMD5 to read OCR NF field
* - CMD5 to wait OCR power up busy
* - CMD5 to read OCR MP field
* sd_mmc_card->type is updated
*
* \return true if success, otherwise false
*/
static bool sdio_op_cond(void)
{
uint32_t resp;
/* CMD5 - SDIO send operation condition (OCR) command. */
if (!driver_send_cmd(sd_mmc_hal, SDIO_CMD5_SEND_OP_COND, 0)) {
return true; /* No error but card type not updated */
}
resp = driver_get_response(sd_mmc_hal);
if ((resp & OCR_SDIO_NF) == 0) {
return true; /* No error but card type not updated */
}
/*
* Wait card ready
* Timeout 1s = 400KHz / ((6+4)*8) cylces = 5000 retry
* 6 = cmd byte size
* 4(SPI) 6(MCI) = response byte size
*/
uint32_t cmd5_retry = 5000;
while (1) {
/* CMD5 - SDIO send operation condition (OCR) command.*/
if (!driver_send_cmd(sd_mmc_hal, SDIO_CMD5_SEND_OP_COND, resp & SD_MMC_VOLTAGE_SUPPORT)) {
return false;
}
resp = driver_get_response(sd_mmc_hal);
if ((resp & OCR_POWER_UP_BUSY) == OCR_POWER_UP_BUSY) {
break;
}
if (cmd5_retry-- == 0) {
return false;
}
}
/* Update card type at the end of busy */
if ((resp & OCR_SDIO_MP) > 0) {
sd_mmc_card->type = CARD_TYPE_SD_COMBO;
} else {
sd_mmc_card->type = CARD_TYPE_SDIO;
}
return true; /* No error and card type updated with SDIO type */
}
/**
* \brief Get SDIO max transfer speed in Hz.
* - CMD53 reads CIS area address in CCCR area.
* - Nx CMD53 search Fun0 tuple in CIS area
* - CMD53 reads TPLFE_MAX_TRAN_SPEED in Fun0 tuple
* - Compute maximum speed of SDIO
* and update sd_mmc_card->clock
*
* \return true if success, otherwise false
*/
static bool sdio_get_max_speed(void)
{
uint32_t addr_new, addr_old;
uint8_t buf[6];
uint32_t unit;
uint32_t mul;
uint8_t tplfe_max_tran_speed, i;
uint8_t addr_cis[4];
/* Read CIS area address in CCCR area */
addr_old = SDIO_CCCR_CIS_PTR;
for (i = 0; i < 4; i++) {
sdio_cmd52(SDIO_CMD52_READ_FLAG, SDIO_CIA, addr_old, 0, &addr_cis[i]);
addr_old++;
}
addr_old = addr_cis[0] + (addr_cis[1] << 8) + (addr_cis[2] << 16) + (addr_cis[3] << 24);
addr_new = addr_old;
while (1) {
/* Read a sample of CIA area */
for (i = 0; i < 3; i++) {
sdio_cmd52(SDIO_CMD52_READ_FLAG, SDIO_CIA, addr_new, 0, &buf[i]);
addr_new++;
}
if (buf[0] == SDIO_CISTPL_END) {
return false; /* Tuple error */
}
if (buf[0] == SDIO_CISTPL_FUNCE && buf[2] == 0x00) {
break; /* Fun0 tuple found */
}
if (buf[1] == 0) {
return false; /* Tuple error */
}
/* Next address */
addr_new += buf[1] - 1;
if (addr_new > (addr_old + 256)) {
return false; /* Outoff CIS area */
}
}
/* Read all Fun0 tuple fields: fn0_blk_siz & max_tran_speed */
addr_new -= 3;
for (i = 0; i < 6; i++) {
sdio_cmd52(SDIO_CMD52_READ_FLAG, SDIO_CIA, addr_new, 0, &buf[i]);
addr_new++;
}
tplfe_max_tran_speed = buf[5];
if (tplfe_max_tran_speed > 0x32) {
/* Error on SDIO register, the high speed is not activated
* and the clock can not be more than 25MHz.
* This error is present on specific SDIO card
* (H&D wireless card - HDG104 WiFi SIP).
*/
tplfe_max_tran_speed = 0x32; /* 25Mhz */
}
/* Decode transfer speed in Hz.*/
unit = sd_mmc_trans_units[tplfe_max_tran_speed & 0x7];
mul = sd_trans_multipliers[(tplfe_max_tran_speed >> 3) & 0xF];
sd_mmc_card->clock = unit * mul * 1000;
/**
* Note: A combo card shall be a Full-Speed SDIO card
* which supports upto 25MHz.
* A SDIO card alone can be:
* - a Low-Speed SDIO card which supports 400Khz minimum
* - a Full-Speed SDIO card which supports upto 25MHz
*/
return true;
}
/**
* \brief CMD52 for SDIO - Switches the bus width mode to 4
*
* \note sd_mmc_card->bus_width is updated.
*
* \return true if success, otherwise false
*/
static bool sdio_cmd52_set_bus_width(void)
{
/**
* A SD memory card always supports bus 4bit
* A SD COMBO card always supports bus 4bit
* A SDIO Full-Speed alone always supports 4bit
* A SDIO Low-Speed alone can supports 4bit (Optional)
*/
uint8_t u8_value;
/* Check 4bit support in 4BLS of "Card Capability" register */
if (!sdio_cmd52(SDIO_CMD52_READ_FLAG, SDIO_CIA, SDIO_CCCR_CAP, 0, &u8_value)) {
return false;
}
if ((u8_value & SDIO_CAP_4BLS) != SDIO_CAP_4BLS) {
/* No supported, it is not a protocol error */
return true;
}
/* HS mode possible, then enable */
u8_value = SDIO_BUSWIDTH_4B;
if (!sdio_cmd52(SDIO_CMD52_WRITE_FLAG, SDIO_CIA, SDIO_CCCR_BUS_CTRL, 1, &u8_value)) {
return false;
}
sd_mmc_card->bus_width = 4;
return true;
}
/**
* \brief CMD52 for SDIO - Enable the high speed mode
*
* \note sd_mmc_card->high_speed is updated.
* \note sd_mmc_card->clock is updated.
*
* \return true if success, otherwise false
*/
static bool sdio_cmd52_set_high_speed(void)
{
uint8_t u8_value;
/* Check CIA.HS */
if (!sdio_cmd52(SDIO_CMD52_READ_FLAG, SDIO_CIA, SDIO_CCCR_HS, 0, &u8_value)) {
return false;
}
if ((u8_value & SDIO_SHS) != SDIO_SHS) {
/* No supported, it is not a protocol error */
return true;
}
/* HS mode possible, then enable */
u8_value = SDIO_EHS;
if (!sdio_cmd52(SDIO_CMD52_WRITE_FLAG, SDIO_CIA, SDIO_CCCR_HS, 1, &u8_value)) {
return false;
}
sd_mmc_card->high_speed = 1;
sd_mmc_card->clock *= 2;
return true;
}
#else
static bool sdio_op_cond(void)
{
return true; /* No error but card type not updated */
}
static bool sdio_get_max_speed(void)
{
return false;
}
static bool sdio_cmd52_set_bus_width(void)
{
return false;
}
static bool sdio_cmd52_set_high_speed(void)
{
return false;
}
#endif
/**
* \brief CMD6 for SD - Switch card in high speed mode
*
* \note CMD6 for SD is valid under the "trans" state.
* \note sd_mmc_card->high_speed is updated.
* \note sd_mmc_card->clock is updated.
*
* \return true if success, otherwise false
*/
static bool sd_cm6_set_high_speed(void)
{
uint8_t switch_status[SD_SW_STATUS_BSIZE] = {0};
if (!driver_adtc_start(sd_mmc_hal,
SD_CMD6_SWITCH_FUNC,
SD_CMD6_MODE_SWITCH | SD_CMD6_GRP6_NO_INFLUENCE | SD_CMD6_GRP5_NO_INFLUENCE
| SD_CMD6_GRP4_NO_INFLUENCE | SD_CMD6_GRP3_NO_INFLUENCE | SD_CMD6_GRP2_DEFAULT
| SD_CMD6_GRP1_HIGH_SPEED,
SD_SW_STATUS_BSIZE,
1,
true)) {
return false;
}
if (!driver_start_read_blocks(sd_mmc_hal, switch_status, 1)) {
return false;
}
if (!driver_wait_end_of_read_blocks(sd_mmc_hal)) {
return false;
}
if (driver_get_response(sd_mmc_hal) & CARD_STATUS_SWITCH_ERROR) {
return false;
}
if (SD_SW_STATUS_FUN_GRP1_RC(switch_status) == SD_SW_STATUS_FUN_GRP_RC_ERROR) {
/* No supported, it is not a protocol error */
return true;
}
if (SD_SW_STATUS_FUN_GRP1_BUSY(switch_status)) {
return false;
}
/* CMD6 function switching period is within 8 clocks
* after the end bit of status data.*/
driver_send_clock(sd_mmc_hal);
sd_mmc_card->high_speed = 1;
sd_mmc_card->clock *= 2;
return true;
}
#if CONF_MMC_SUPPORT
/**
* \brief CMD6 for MMC - Switches the bus width mode
*
* \note CMD6 is valid under the "trans" state.
* \note sd_mmc_card->bus_width is updated.
*
* \param bus_width Bus width to set
*
* \return true if success, otherwise false
*/
static bool mmc_cmd6_set_bus_width(uint8_t bus_width)
{
uint32_t arg;
switch (bus_width) {
case 8:
arg = MMC_CMD6_ACCESS_SET_BITS | MMC_CMD6_INDEX_BUS_WIDTH | MMC_CMD6_VALUE_BUS_WIDTH_8BIT;
break;
case 4:
arg = MMC_CMD6_ACCESS_SET_BITS | MMC_CMD6_INDEX_BUS_WIDTH | MMC_CMD6_VALUE_BUS_WIDTH_4BIT;
break;
default:
arg = MMC_CMD6_ACCESS_SET_BITS | MMC_CMD6_INDEX_BUS_WIDTH | MMC_CMD6_VALUE_BUS_WIDTH_1BIT;
break;
}
if (!driver_send_cmd(sd_mmc_hal, MMC_CMD6_SWITCH, arg)) {
return false;
}
if (driver_get_response(sd_mmc_hal) & CARD_STATUS_SWITCH_ERROR) {
/* No supported, it is not a protocol error */
return false;
}
sd_mmc_card->bus_width = bus_width;
return true;
}
/**
* \brief CMD6 for MMC - Switches in high speed mode
*
* \note CMD6 is valid under the "trans" state.
* \note sd_mmc_card->high_speed is updated.
* \note sd_mmc_card->clock is updated.
*
* \return true if success, otherwise false
*/
static bool mmc_cmd6_set_high_speed(void)
{
if (!driver_send_cmd(sd_mmc_hal,
MMC_CMD6_SWITCH,
MMC_CMD6_ACCESS_WRITE_BYTE | MMC_CMD6_INDEX_HS_TIMING | MMC_CMD6_VALUE_HS_TIMING_ENABLE)) {
return false;
}
if (driver_get_response(sd_mmc_hal) & CARD_STATUS_SWITCH_ERROR) {
/* No supported, it is not a protocol error */
return false;
}
sd_mmc_card->high_speed = 1;
sd_mmc_card->clock = 52000000lu;
return true;
}
#endif
/**
* \brief CMD8 for SD card - Send Interface Condition Command.
*
* \note
* Send SD Memory Card interface condition, which includes host supply
* voltage information and asks the card whether card supports voltage.
* Should be performed at initialization time to detect the card type.
*
* \param v2 Pointer to v2 flag to update
*
* \return true if success, otherwise false
* with a update of \ref sd_mmc_err.
*/
static bool sd_cmd8(uint8_t *v2)
{
uint32_t resp;
*v2 = 0;
/* Test for SD version 2 */
if (!driver_send_cmd(sd_mmc_hal, SD_CMD8_SEND_IF_COND, SD_CMD8_PATTERN | SD_CMD8_HIGH_VOLTAGE)) {
return true; /* It is not a V2 */
}
/* Check R7 response */
resp = driver_get_response(sd_mmc_hal);
if (resp == 0xFFFFFFFF) {
/* No compliance R7 value */
return true; /* It is not a V2 */
}
if ((resp & (SD_CMD8_MASK_PATTERN | SD_CMD8_MASK_VOLTAGE)) != (SD_CMD8_PATTERN | SD_CMD8_HIGH_VOLTAGE)) {
return false;
}
*v2 = 1;
return true;
}
#if CONF_MMC_SUPPORT
/**
* \brief CMD8 - The card sends its EXT_CSD register as a block of data.
*
* \param b_authorize_high_speed Pointer to update with the high speed
* support information
*
* \return true if success, otherwise false
*/
static bool mmc_cmd8(uint8_t *b_authorize_high_speed)
{
uint16_t i;
uint32_t ext_csd;
uint32_t sec_count;
if (!driver_adtc_start(sd_mmc_hal, MMC_CMD8_SEND_EXT_CSD, 0, EXT_CSD_BSIZE, 1, false)) {
return false;
}
/* Read and decode Extended Extended CSD
* Note: The read access is done in byte to avoid a buffer
* of EXT_CSD_BSIZE Byte in stack.*/
/* Read card type */
for (i = 0; i < (EXT_CSD_CARD_TYPE_INDEX + 4) / 4; i++) {
if (!driver_read_word(sd_mmc_hal, &ext_csd)) {
return false;
}
}
*b_authorize_high_speed = (ext_csd >> ((EXT_CSD_CARD_TYPE_INDEX % 4) * 8)) & MMC_CTYPE_52MHZ;
if (MMC_CSD_C_SIZE(sd_mmc_card->csd) == 0xFFF) {
/* For high capacity SD/MMC card,
* memory capacity = SEC_COUNT * 512 byte */
for (; i < (EXT_CSD_SEC_COUNT_INDEX + 4) / 4; i++) {
if (!driver_read_word(sd_mmc_hal, &sec_count)) {
return false;
}
}
sd_mmc_card->capacity = sec_count / 2;
}
for (; i < EXT_CSD_BSIZE / 4; i++) {
if (!driver_read_word(sd_mmc_hal, &sec_count)) {
return false;
}
}
return true;
}
#endif
/**
* \brief CMD9: Addressed card sends its card-specific
* data (CSD) on the CMD line mci.
*
* \return true if success, otherwise false
*/
static bool sd_mmc_cmd9_mci(void)
{
if (!driver_send_cmd(sd_mmc_hal, SDMMC_MCI_CMD9_SEND_CSD, (uint32_t)sd_mmc_card->rca << 16)) {
return false;
}
driver_get_response_128(sd_mmc_hal, sd_mmc_card->csd);
return true;
}
#if CONF_MMC_SUPPORT
/**
* \brief Decodes MMC CSD register
*/
static void mmc_decode_csd(void)
{
uint32_t unit;
uint32_t mul;
uint32_t tran_speed;
/* Get MMC System Specification version supported by the card */
switch (MMC_CSD_SPEC_VERS(sd_mmc_card->csd)) {
default:
case 0:
sd_mmc_card->version = CARD_VER_MMC_1_2;
break;
case 1:
sd_mmc_card->version = CARD_VER_MMC_1_4;
break;
case 2:
sd_mmc_card->version = CARD_VER_MMC_2_2;
break;
case 3:
sd_mmc_card->version = CARD_VER_MMC_3;
break;
case 4:
sd_mmc_card->version = CARD_VER_MMC_4;
break;
}
/* Get MMC memory max transfer speed in Hz.*/
tran_speed = CSD_TRAN_SPEED(sd_mmc_card->csd);
unit = sd_mmc_trans_units[tran_speed & 0x7];
mul = mmc_trans_multipliers[(tran_speed >> 3) & 0xF];
sd_mmc_card->clock = unit * mul * 1000;
/*
* Get card capacity.
* ----------------------------------------------------
* For normal SD/MMC card:
* memory capacity = BLOCKNR * BLOCK_LEN
* Where
* BLOCKNR = (C_SIZE+1) * MULT
* MULT = 2 ^ (C_SIZE_MULT+2) (C_SIZE_MULT < 8)
* BLOCK_LEN = 2 ^ READ_BL_LEN (READ_BL_LEN < 12)
* ----------------------------------------------------
* For high capacity SD/MMC card:
* memory capacity = SEC_COUNT * 512 byte
*/
if (MMC_CSD_C_SIZE(sd_mmc_card->csd) != 0xFFF) {
uint32_t blocknr
= ((MMC_CSD_C_SIZE(sd_mmc_card->csd) + 1) * (1 << (MMC_CSD_C_SIZE_MULT(sd_mmc_card->csd) + 2)));
sd_mmc_card->capacity = blocknr * (1 << MMC_CSD_READ_BL_LEN(sd_mmc_card->csd)) / 1024;
}
}
#endif
/**
* \brief Decodes SD CSD register
*/
static void sd_decode_csd(void)
{
uint32_t unit;
uint32_t mul;
uint32_t tran_speed;
/* Get SD memory maximum transfer speed in Hz. */
tran_speed = CSD_TRAN_SPEED(sd_mmc_card->csd);
unit = sd_mmc_trans_units[tran_speed & 0x7];
mul = sd_trans_multipliers[(tran_speed >> 3) & 0xF];
sd_mmc_card->clock = unit * mul * 1000;
/*
* Get card capacity.
* ----------------------------------------------------
* For normal SD/MMC card:
* memory capacity = BLOCKNR * BLOCK_LEN
* Where
* BLOCKNR = (C_SIZE+1) * MULT
* MULT = 2 ^ (C_SIZE_MULT+2) (C_SIZE_MULT < 8)
* BLOCK_LEN = 2 ^ READ_BL_LEN (READ_BL_LEN < 12)
* ----------------------------------------------------
* For high capacity SD card:
* memory capacity = (C_SIZE+1) * 512K byte
*/
if (CSD_STRUCTURE_VERSION(sd_mmc_card->csd) >= SD_CSD_VER_2_0) {
sd_mmc_card->capacity = (SD_CSD_2_0_C_SIZE(sd_mmc_card->csd) + 1) * 512;
} else {
uint32_t blocknr
= ((SD_CSD_1_0_C_SIZE(sd_mmc_card->csd) + 1) * (1 << (SD_CSD_1_0_C_SIZE_MULT(sd_mmc_card->csd) + 2)));
sd_mmc_card->capacity = blocknr * (1 << SD_CSD_1_0_READ_BL_LEN(sd_mmc_card->csd)) / 1024;
}
}
/**
* \brief CMD13 - Addressed card sends its status register.
* This function waits the clear of the busy flag
*
* \return true if success, otherwise false
*/
static bool sd_mmc_cmd13(void)
{
uint32_t nec_timeout;
/* Wait for data ready status.
* Nec timing: 0 to unlimited
* However a timeout is used.
* 200 000 * 8 cycles
*/
nec_timeout = 200000;
do {
if (!driver_send_cmd(sd_mmc_hal, SDMMC_MCI_CMD13_SEND_STATUS, (uint32_t)sd_mmc_card->rca << 16)) {
return false;
}
/* Check busy flag */
if (driver_get_response(sd_mmc_hal) & CARD_STATUS_READY_FOR_DATA) {
break;
}
if (nec_timeout-- == 0) {
return false;
}
} while (1);
return true;
}
#if (CONF_SDIO_SUPPORT == 1)
/**
* \brief CMD52 - SDIO IO_RW_DIRECT command
*
* \param rw_flag Direction, 1:write, 0:read.
* \param func_nb Number of the function.
* \param rd_after_wr Read after Write flag.
* \param reg_addr register address.
* \param io_data Pointer to input argument and response buffer.
*
* \return true if success, otherwise false
*/
static bool sdio_cmd52(uint8_t rw_flag, uint8_t func_nb, uint32_t reg_addr, uint8_t rd_after_wr, uint8_t *io_data)
{
ASSERT(io_data != NULL);
if (!driver_send_cmd(sd_mmc_hal,
SDIO_CMD52_IO_RW_DIRECT,
((uint32_t)*io_data << SDIO_CMD52_WR_DATA) | ((uint32_t)rw_flag << SDIO_CMD52_RW_FLAG)
| ((uint32_t)func_nb << SDIO_CMD52_FUNCTION_NUM)
| ((uint32_t)rd_after_wr << SDIO_CMD52_RAW_FLAG)
| ((uint32_t)reg_addr << SDIO_CMD52_REG_ADRR))) {
return false;
}
*io_data = driver_get_response(sd_mmc_hal) & 0xFF;
return true;
}
/**
* \brief CMD53 - SDIO IO_RW_EXTENDED command
* This implementation support only the SDIO multi-byte transfer mode which is
* similar to the single block transfer on memory.
* Note: The SDIO block transfer mode is optional for SDIO card.
*
* \param rw_flag Direction, 1:write, 0:read.
* \param func_nb Number of the function.
* \param reg_addr Register address.
* \param inc_addr 1:Incrementing address, 0: fixed.
* \param size Transfer data size.
* \param access_block true, if the block access (DMA) is used
*
* \return true if success, otherwise false
*/
static bool sdio_cmd53(uint8_t rw_flag, uint8_t func_nb, uint32_t reg_addr, uint8_t inc_addr, uint32_t size,
bool access_block)
{
ASSERT(size != 0);
ASSERT(size <= 512);
return driver_adtc_start(
sd_mmc_hal,
(rw_flag == SDIO_CMD53_READ_FLAG) ? SDIO_CMD53_IO_R_BYTE_EXTENDED : SDIO_CMD53_IO_W_BYTE_EXTENDED,
((size % 512) << SDIO_CMD53_COUNT) | ((uint32_t)reg_addr << SDIO_CMD53_REG_ADDR)
| ((uint32_t)inc_addr << SDIO_CMD53_OP_CODE) | ((uint32_t)0 << SDIO_CMD53_BLOCK_MODE)
| ((uint32_t)func_nb << SDIO_CMD53_FUNCTION_NUM) | ((uint32_t)rw_flag << SDIO_CMD53_RW_FLAG),
size,
1,
access_block);
}
#endif
/**
* \brief ACMD6 - Define the data bus width to 4 bits bus
*
* \return true if success, otherwise false
*/
static bool sd_acmd6(void)
{
/* CMD55 - Indicate to the card that the next command is an
* application specific command rather than a standard command.*/
if (!driver_send_cmd(sd_mmc_hal, SDMMC_CMD55_APP_CMD, (uint32_t)sd_mmc_card->rca << 16)) {
return false;
}
/* 10b = 4 bits bus */
if (!driver_send_cmd(sd_mmc_hal, SD_ACMD6_SET_BUS_WIDTH, 0x2)) {
return false;
}
sd_mmc_card->bus_width = 4;
return true;
}
/**
* \brief ACMD51 - Read the SD Configuration Register.
*
* \note
* SD Card Configuration Register (SCR) provides information on the SD Memory
* Card's special features that were configured into the given card. The size
* of SCR register is 64 bits.
*
*
* \return true if success, otherwise false
*/
static bool sd_acmd51(void)
{
uint8_t scr[SD_SCR_REG_BSIZE];
/* CMD55 - Indicate to the card that the next command is an
* application specific command rather than a standard command.*/
if (!driver_send_cmd(sd_mmc_hal, SDMMC_CMD55_APP_CMD, (uint32_t)sd_mmc_card->rca << 16)) {
return false;
}
if (!driver_adtc_start(sd_mmc_hal, SD_ACMD51_SEND_SCR, 0, SD_SCR_REG_BSIZE, 1, true)) {
return false;
}
if (!driver_start_read_blocks(sd_mmc_hal, scr, 1)) {
return false;
}
if (!driver_wait_end_of_read_blocks(sd_mmc_hal)) {
return false;
}
/* Get SD Memory Card - Spec. Version */
switch (SD_SCR_SD_SPEC(scr)) {
case SD_SCR_SD_SPEC_1_0_01:
sd_mmc_card->version = CARD_VER_SD_1_0;
break;
case SD_SCR_SD_SPEC_1_10:
sd_mmc_card->version = CARD_VER_SD_1_10;
break;
case SD_SCR_SD_SPEC_2_00:
if (SD_SCR_SD_SPEC3(scr) == SD_SCR_SD_SPEC_3_00) {
sd_mmc_card->version = CARD_VER_SD_3_0;
} else {
sd_mmc_card->version = CARD_VER_SD_2_0;
}
break;
default:
sd_mmc_card->version = CARD_VER_SD_1_0;
break;
}
return true;
}
/**
* \brief Select a card slot and initialize the associated driver
*
* \param slot Card slot number
*
* \retval SD_MMC_ERR_SLOT Wrong slot number
* \retval SD_MMC_ERR_NO_CARD No card present on slot
* \retval SD_MMC_ERR_UNUSABLE Unusable card
* \retval SD_MMC_INIT_ONGOING Card initialization requested
* \retval SD_MMC_OK Card present
*/
static sd_mmc_err_t sd_mmc_select_slot(uint8_t slot)
{
if (slot >= CONF_SD_MMC_MEM_CNT) {
return SD_MMC_ERR_SLOT;
}
if (_cd && _cd[slot].pin != -1) {
/** Card Detect pins */
if (gpio_get_pin_level(_cd[slot].pin) != _cd[slot].val) {
if (sd_mmc_cards[slot].state == SD_MMC_CARD_STATE_DEBOUNCE) {
SD_MMC_STOP_TIMEOUT();
}
sd_mmc_cards[slot].state = SD_MMC_CARD_STATE_NO_CARD;
return SD_MMC_ERR_NO_CARD;
}
if (sd_mmc_cards[slot].state == SD_MMC_CARD_STATE_NO_CARD) {
/* A card plug on going, but this is not initialized */
sd_mmc_cards[slot].state = SD_MMC_CARD_STATE_DEBOUNCE;
/* Debounce + Power On Setup */
SD_MMC_START_TIMEOUT();
return SD_MMC_ERR_NO_CARD;
}
if (sd_mmc_cards[slot].state == SD_MMC_CARD_STATE_DEBOUNCE) {
if (!SD_MMC_IS_TIMEOUT()) {
/* Debounce on going */
return SD_MMC_ERR_NO_CARD;
}
/* Card is not initialized */
sd_mmc_cards[slot].state = SD_MMC_CARD_STATE_INIT;
/* Set 1-bit bus width and low clock for initialization */
sd_mmc_cards[slot].clock = SDMMC_CLOCK_INIT;
sd_mmc_cards[slot].bus_width = 1;
sd_mmc_cards[slot].high_speed = 0;
}
if (sd_mmc_cards[slot].state == SD_MMC_CARD_STATE_UNUSABLE) {
return SD_MMC_ERR_UNUSABLE;
}
} else {
/* No pin card detection, then always try to install it */
if ((sd_mmc_cards[slot].state == SD_MMC_CARD_STATE_NO_CARD)
|| (sd_mmc_cards[slot].state == SD_MMC_CARD_STATE_UNUSABLE)) {
/* Card is not initialized */
sd_mmc_cards[slot].state = SD_MMC_CARD_STATE_INIT;
/* Set 1-bit bus width and low clock for initialization */
sd_mmc_cards[slot].clock = SDMMC_CLOCK_INIT;
sd_mmc_cards[slot].bus_width = 1;
sd_mmc_cards[slot].high_speed = 0;
}
}
ASSERT(!(sd_mmc_slot_sel != slot && sd_mmc_nb_block_remaining != 0));
/* Initialize interface */
sd_mmc_slot_sel = slot;
sd_mmc_card = &sd_mmc_cards[slot];
sd_mmc_configure_slot();
return (sd_mmc_cards[slot].state == SD_MMC_CARD_STATE_INIT) ? SD_MMC_INIT_ONGOING : SD_MMC_OK;
}
/**
* \brief Configures the driver with the selected card configuration
*/
static void sd_mmc_configure_slot(void)
{
driver_select_device(
sd_mmc_hal, sd_mmc_slot_sel, sd_mmc_card->clock, sd_mmc_card->bus_width, sd_mmc_card->high_speed);
}
/**
* \brief Deselect the current card slot
*/
static void sd_mmc_deselect_slot(void)
{
if (sd_mmc_slot_sel < CONF_SD_MMC_MEM_CNT) {
driver_deselect_device(sd_mmc_hal, sd_mmc_slot_sel);
}
}
/**
* \brief Initialize the SD card in MCI mode.
*
* \note
* This function runs the initialization procedure and the identification
* process, then it sets the SD/MMC card in transfer state.
* At last, it will automaticly enable maximum bus width and transfer speed.
*
* \return true if success, otherwise false
*/
static bool sd_mmc_mci_card_init(void)
{
uint8_t v2 = 0;
#if (CONF_SDIO_SUPPORT == 1)
uint8_t data = 0x08;
#endif
/* In first, try to install SD/SDIO card */
sd_mmc_card->type = CARD_TYPE_SD;
sd_mmc_card->version = CARD_VER_UNKNOWN;
sd_mmc_card->rca = 0;
/* Card need of 74 cycles clock minimum to start */
driver_send_clock(sd_mmc_hal);
#if (CONF_SDIO_SUPPORT == 1)
/* CMD52 Reset SDIO */
sdio_cmd52(SDIO_CMD52_WRITE_FLAG, SDIO_CIA, SDIO_CCCR_IOA, 0, &data);
#endif
/* CMD0 - Reset all cards to idle state.*/
if (!driver_send_cmd(sd_mmc_hal, SDMMC_MCI_CMD0_GO_IDLE_STATE, 0)) {
return false;
}
if (!sd_cmd8(&v2)) {
return false;
}
/* Try to get the SDIO card's operating condition */
if (!sdio_op_cond()) {
return false;
}
if (sd_mmc_card->type & CARD_TYPE_SD) {
/* Try to get the SD card's operating condition */
if (!sd_mci_op_cond(v2)) {
/* It is not a SD card */
#if CONF_MMC_SUPPORT
sd_mmc_card->type = CARD_TYPE_MMC;
return sd_mmc_mci_install_mmc();
#else
sd_mmc_card->type = CARD_TYPE_UNKNOWN;
return false;
#endif
}
}
if (sd_mmc_card->type & CARD_TYPE_SD) {
/* SD MEMORY, Put the Card in Identify Mode
* Note: The CID is not used in this stack */
if (!driver_send_cmd(sd_mmc_hal, SDMMC_CMD2_ALL_SEND_CID, 0)) {
return false;
}
}
/* Ask the card to publish a new relative address (RCA).*/
if (!driver_send_cmd(sd_mmc_hal, SD_CMD3_SEND_RELATIVE_ADDR, 0)) {
return false;
}
sd_mmc_card->rca = (driver_get_response(sd_mmc_hal) >> 16) & 0xFFFF;
/* SD MEMORY, Get the Card-Specific Data */
if (sd_mmc_card->type & CARD_TYPE_SD) {
if (!sd_mmc_cmd9_mci()) {
return false;
}
sd_decode_csd();
}
/* Select the and put it into Transfer Mode */
if (!driver_send_cmd(sd_mmc_hal, SDMMC_CMD7_SELECT_CARD_CMD, (uint32_t)sd_mmc_card->rca << 16)) {
return false;
}
/* SD MEMORY, Read the SCR to get card version */
if (sd_mmc_card->type & CARD_TYPE_SD) {
if (!sd_acmd51()) {
return false;
}
}
if (IS_SDIO()) {
if (!sdio_get_max_speed()) {
return false;
}
}
if ((4 <= driver_get_bus_width(sd_mmc_hal, sd_mmc_slot_sel))) {
/* TRY to enable 4-bit mode */
if (IS_SDIO()) {
if (!sdio_cmd52_set_bus_width()) {
return false;
}
}
if (sd_mmc_card->type & CARD_TYPE_SD) {
if (!sd_acmd6()) {
return false;
}
}
/* Switch to selected bus mode */
sd_mmc_configure_slot();
}
if (driver_is_high_speed_capable(sd_mmc_hal)) {
/* TRY to enable High-Speed Mode */
if (IS_SDIO()) {
if (!sdio_cmd52_set_high_speed()) {
return false;
}
}
if (sd_mmc_card->type & CARD_TYPE_SD) {
if (sd_mmc_card->version > CARD_VER_SD_1_0) {
if (!sd_cm6_set_high_speed()) {
return false;
}
}
}
/* Valid new configuration */
sd_mmc_configure_slot();
}
/* SD MEMORY, Set default block size */
if (sd_mmc_card->type & CARD_TYPE_SD) {
if (!driver_send_cmd(sd_mmc_hal, SDMMC_CMD16_SET_BLOCKLEN, SD_MMC_BLOCK_SIZE)) {
return false;
}
}
return true;
}
#if CONF_MMC_SUPPORT
/**
* \brief Initialize the MMC card in MCI mode.
*
* \note
* This function runs the initialization procedure and the identification
* process, then it sets the SD/MMC card in transfer state.
* At last, it will automaticly enable maximum bus width and transfer speed.
*
* \return true if success, otherwise false
*/
static bool sd_mmc_mci_install_mmc(void)
{
uint8_t b_authorize_high_speed;
/* CMD0 - Reset all cards to idle state. */
if (!driver_send_cmd(sd_mmc_hal, SDMMC_MCI_CMD0_GO_IDLE_STATE, 0)) {
return false;
}
if (!mmc_mci_op_cond()) {
return false;
}
/* Put the Card in Identify Mode
* Note: The CID is not used in this stack*/
if (!driver_send_cmd(sd_mmc_hal, SDMMC_CMD2_ALL_SEND_CID, 0)) {
return false;
}
/* Assign relative address to the card.*/
sd_mmc_card->rca = 1;
if (!driver_send_cmd(sd_mmc_hal, MMC_CMD3_SET_RELATIVE_ADDR, (uint32_t)sd_mmc_card->rca << 16)) {
return false;
}
/* Get the Card-Specific Data */
if (!sd_mmc_cmd9_mci()) {
return false;
}
mmc_decode_csd();
/* Select the and put it into Transfer Mode */
if (!driver_send_cmd(sd_mmc_hal, SDMMC_CMD7_SELECT_CARD_CMD, (uint32_t)sd_mmc_card->rca << 16)) {
return false;
}
if (sd_mmc_card->version >= CARD_VER_MMC_4) {
/* For MMC 4.0 Higher version
* Get EXT_CSD */
if (!mmc_cmd8(&b_authorize_high_speed)) {
return false;
}
if (4 <= driver_get_bus_width(sd_mmc_hal, sd_mmc_slot_sel)) {
/* Enable more bus width */
if (!mmc_cmd6_set_bus_width(driver_get_bus_width(sd_mmc_hal, sd_mmc_slot_sel))) {
return false;
}
/* Reinitialize the slot with the bus width */
sd_mmc_configure_slot();
}
if (driver_is_high_speed_capable(sd_mmc_hal) && b_authorize_high_speed) {
/* Enable HS */
if (!mmc_cmd6_set_high_speed()) {
return false;
}
/* Reinitialize the slot with the new speed */
sd_mmc_configure_slot();
}
} else {
/* Reinitialize the slot with the new speed */
sd_mmc_configure_slot();
}
uint8_t retry = 10;
while (retry--) {
/* Retry is a WORKAROUND for no compliance card (Atmel Internal ref. MMC19):
* These cards seem not ready immediatly
* after the end of busy of mmc_cmd6_set_high_speed()*/
/* Set default block size */
if (driver_send_cmd(sd_mmc_hal, SDMMC_CMD16_SET_BLOCKLEN, SD_MMC_BLOCK_SIZE)) {
return true;
}
}
return false;
}
#endif
/*--------------------- PUBLIC FUNCTIONS ----------------------------*/
void sd_mmc_init(void *hal, sd_mmc_detect_t *card_detects, sd_mmc_detect_t *wp_detects)
{
/* GPIO will be used to detect card and write protect.
* The related clocks and pinmux must be configurated in good
* condition. */
for (uint8_t slot = 0; slot < CONF_SD_MMC_MEM_CNT; slot++) {
sd_mmc_cards[slot].state = SD_MMC_CARD_STATE_NO_CARD;
}
sd_mmc_slot_sel = 0xFF; /* No slot configurated */
sd_mmc_hal = hal;
_cd = card_detects;
_wp = wp_detects;
}
uint8_t sd_mmc_nb_slot(void)
{
return CONF_SD_MMC_MEM_CNT;
}
sd_mmc_err_t sd_mmc_check(uint8_t slot)
{
sd_mmc_err_t sd_mmc_err;
sd_mmc_err = sd_mmc_select_slot(slot);
if (sd_mmc_err != SD_MMC_INIT_ONGOING) {
sd_mmc_deselect_slot();
return sd_mmc_err;
}
/* Initialization of the card requested */
if (sd_mmc_mci_card_init()) {
sd_mmc_card->state = SD_MMC_CARD_STATE_READY;
sd_mmc_deselect_slot();
/* To notify that the card has been just initialized
* It is necessary for USB Device MSC */
return SD_MMC_INIT_ONGOING;
}
sd_mmc_card->state = SD_MMC_CARD_STATE_UNUSABLE;
sd_mmc_deselect_slot();
return SD_MMC_ERR_UNUSABLE;
}
card_type_t sd_mmc_get_type(uint8_t slot)
{
if (SD_MMC_OK != sd_mmc_select_slot(slot)) {
return CARD_TYPE_UNKNOWN;
}
sd_mmc_deselect_slot();
return sd_mmc_card->type;
}
card_version_t sd_mmc_get_version(uint8_t slot)
{
if (SD_MMC_OK != sd_mmc_select_slot(slot)) {
return CARD_VER_UNKNOWN;
}
sd_mmc_deselect_slot();
return sd_mmc_card->version;
}
uint32_t sd_mmc_get_capacity(uint8_t slot)
{
if (SD_MMC_OK != sd_mmc_select_slot(slot)) {
return 0;
}
sd_mmc_deselect_slot();
return sd_mmc_card->capacity;
}
bool sd_mmc_is_write_protected(uint8_t slot)
{
/* No detection, always writable */
if (!_wp || _wp[slot].pin == -1) {
return false;
}
/* Write Protect Detect */
if (gpio_get_pin_level(_wp[slot].pin) == _wp[slot].val) {
return true;
}
return false;
}
sd_mmc_err_t sd_mmc_init_read_blocks(uint8_t slot, uint32_t start, uint16_t nb_block)
{
sd_mmc_err_t sd_mmc_err;
uint32_t cmd, arg, resp;
sd_mmc_err = sd_mmc_select_slot(slot);
if (sd_mmc_err != SD_MMC_OK) {
return sd_mmc_err;
}
/* Wait for data ready status */
if (!sd_mmc_cmd13()) {
sd_mmc_deselect_slot();
return SD_MMC_ERR_COMM;
}
if (nb_block > 1) {
cmd = SDMMC_CMD18_READ_MULTIPLE_BLOCK;
} else {
cmd = SDMMC_CMD17_READ_SINGLE_BLOCK;
}
/*
* SDSC Card (CCS=0) uses byte unit address,
* SDHC and SDXC Cards (CCS=1) use block unit address (512 Bytes unit).
*/
if (sd_mmc_card->type & CARD_TYPE_HC) {
arg = start;
} else {
arg = (start * SD_MMC_BLOCK_SIZE);
}
if (!driver_adtc_start(sd_mmc_hal, cmd, arg, SD_MMC_BLOCK_SIZE, nb_block, true)) {
sd_mmc_deselect_slot();
return SD_MMC_ERR_COMM;
}
/* Check response */
resp = driver_get_response(sd_mmc_hal);
if (resp & CARD_STATUS_ERR_RD_WR) {
sd_mmc_deselect_slot();
return SD_MMC_ERR_COMM;
}
sd_mmc_nb_block_remaining = nb_block;
sd_mmc_nb_block_to_tranfer = nb_block;
return SD_MMC_OK;
}
sd_mmc_err_t sd_mmc_start_read_blocks(void *dest, uint16_t nb_block)
{
ASSERT(sd_mmc_nb_block_remaining >= nb_block);
if (!driver_start_read_blocks(sd_mmc_hal, dest, nb_block)) {
sd_mmc_nb_block_remaining = 0;
return SD_MMC_ERR_COMM;
}
sd_mmc_nb_block_remaining -= nb_block;
return SD_MMC_OK;
}
sd_mmc_err_t sd_mmc_wait_end_of_read_blocks(bool abort)
{
if (!driver_wait_end_of_read_blocks(sd_mmc_hal)) {
return SD_MMC_ERR_COMM;
}
if (abort) {
sd_mmc_nb_block_remaining = 0;
} else if (sd_mmc_nb_block_remaining) {
return SD_MMC_OK;
}
/* All blocks are transfered then stop read operation */
if (sd_mmc_nb_block_to_tranfer == 1) {
/* Single block transfer, then nothing to do */
sd_mmc_deselect_slot();
return SD_MMC_OK;
}
/* WORKAROUND for no compliance card (Atmel Internal ref. !MMC7 !SD19):
* The errors on this command must be ignored
* and one retry can be necessary in SPI mode for no compliance card.*/
if (!driver_adtc_stop(sd_mmc_hal, SDMMC_CMD12_STOP_TRANSMISSION, 0)) {
driver_adtc_stop(sd_mmc_hal, SDMMC_CMD12_STOP_TRANSMISSION, 0);
}
sd_mmc_deselect_slot();
return SD_MMC_OK;
}
sd_mmc_err_t sd_mmc_init_write_blocks(uint8_t slot, uint32_t start, uint16_t nb_block)
{
sd_mmc_err_t sd_mmc_err;
uint32_t cmd, arg, resp;
sd_mmc_err = sd_mmc_select_slot(slot);
if (sd_mmc_err != SD_MMC_OK) {
return sd_mmc_err;
}
if (sd_mmc_is_write_protected(slot)) {
sd_mmc_deselect_slot();
return SD_MMC_ERR_WP;
}
if (nb_block > 1) {
cmd = SDMMC_CMD25_WRITE_MULTIPLE_BLOCK;
} else {
cmd = SDMMC_CMD24_WRITE_BLOCK;
}
/*
* SDSC Card (CCS=0) uses byte unit address,
* SDHC and SDXC Cards (CCS=1) use block unit address (512 Bytes unit).
*/
if (sd_mmc_card->type & CARD_TYPE_HC) {
arg = start;
} else {
arg = (start * SD_MMC_BLOCK_SIZE);
}
if (!driver_adtc_start(sd_mmc_hal, cmd, arg, SD_MMC_BLOCK_SIZE, nb_block, true)) {
sd_mmc_deselect_slot();
return SD_MMC_ERR_COMM;
}
/* Check response */
resp = driver_get_response(sd_mmc_hal);
if (resp & CARD_STATUS_ERR_RD_WR) {
sd_mmc_deselect_slot();
return SD_MMC_ERR_COMM;
}
sd_mmc_nb_block_remaining = nb_block;
sd_mmc_nb_block_to_tranfer = nb_block;
return SD_MMC_OK;
}
sd_mmc_err_t sd_mmc_start_write_blocks(const void *src, uint16_t nb_block)
{
ASSERT(sd_mmc_nb_block_remaining >= nb_block);
if (!driver_start_write_blocks(sd_mmc_hal, src, nb_block)) {
sd_mmc_nb_block_remaining = 0;
return SD_MMC_ERR_COMM;
}
sd_mmc_nb_block_remaining -= nb_block;
return SD_MMC_OK;
}
sd_mmc_err_t sd_mmc_wait_end_of_write_blocks(bool abort)
{
if (!driver_wait_end_of_write_blocks(sd_mmc_hal)) {
return SD_MMC_ERR_COMM;
}
if (abort) {
sd_mmc_nb_block_remaining = 0;
} else if (sd_mmc_nb_block_remaining) {
return SD_MMC_OK;
}
/* All blocks are transfered then stop write operation */
if (sd_mmc_nb_block_to_tranfer == 1) {
/* Single block transfer, then nothing to do */
sd_mmc_deselect_slot();
return SD_MMC_OK;
}
/* Note: SPI multiblock writes terminate using a special
* token, not a STOP_TRANSMISSION request.*/
if (!driver_adtc_stop(sd_mmc_hal, SDMMC_CMD12_STOP_TRANSMISSION, 0)) {
sd_mmc_deselect_slot();
return SD_MMC_ERR_COMM;
}
sd_mmc_deselect_slot();
return SD_MMC_OK;
}
#if (CONF_SDIO_SUPPORT == 1)
sd_mmc_err_t sdio_read_direct(uint8_t slot, uint8_t func_num, uint32_t addr, uint8_t *dest)
{
sd_mmc_err_t sd_mmc_err;
if (dest == NULL) {
return SD_MMC_ERR_PARAM;
}
sd_mmc_err = sd_mmc_select_slot(slot);
if (sd_mmc_err != SD_MMC_OK) {
return sd_mmc_err;
}
if (!sdio_cmd52(SDIO_CMD52_READ_FLAG, func_num, addr, 0, dest)) {
sd_mmc_deselect_slot();
return SD_MMC_ERR_COMM;
}
sd_mmc_deselect_slot();
return SD_MMC_OK;
}
sd_mmc_err_t sdio_write_direct(uint8_t slot, uint8_t func_num, uint32_t addr, uint8_t data)
{
sd_mmc_err_t sd_mmc_err;
sd_mmc_err = sd_mmc_select_slot(slot);
if (sd_mmc_err != SD_MMC_OK) {
return sd_mmc_err;
}
if (!sdio_cmd52(SDIO_CMD52_WRITE_FLAG, func_num, addr, 0, &data)) {
sd_mmc_deselect_slot();
return SD_MMC_ERR_COMM;
}
sd_mmc_deselect_slot();
return SD_MMC_OK;
}
sd_mmc_err_t sdio_read_extended(uint8_t slot, uint8_t func_num, uint32_t addr, uint8_t inc_addr, uint8_t *dest,
uint16_t size)
{
sd_mmc_err_t sd_mmc_err;
if ((size == 0) || (size > 512)) {
return SD_MMC_ERR_PARAM;
}
sd_mmc_err = sd_mmc_select_slot(slot);
if (sd_mmc_err != SD_MMC_OK) {
return sd_mmc_err;
}
if (!sdio_cmd53(SDIO_CMD53_READ_FLAG, func_num, addr, inc_addr, size, true)) {
sd_mmc_deselect_slot();
return SD_MMC_ERR_COMM;
}
if (!driver_start_read_blocks(sd_mmc_hal, dest, 1)) {
sd_mmc_deselect_slot();
return SD_MMC_ERR_COMM;
}
if (!driver_wait_end_of_read_blocks(sd_mmc_hal)) {
sd_mmc_deselect_slot();
return SD_MMC_ERR_COMM;
}
sd_mmc_deselect_slot();
return SD_MMC_OK;
}
sd_mmc_err_t sdio_write_extended(uint8_t slot, uint8_t func_num, uint32_t addr, uint8_t inc_addr, uint8_t *src,
uint16_t size)
{
sd_mmc_err_t sd_mmc_err;
if ((size == 0) || (size > 512)) {
return SD_MMC_ERR_PARAM;
}
sd_mmc_err = sd_mmc_select_slot(slot);
if (sd_mmc_err != SD_MMC_OK) {
return sd_mmc_err;
}
if (!sdio_cmd53(SDIO_CMD53_WRITE_FLAG, func_num, addr, inc_addr, size, true)) {
sd_mmc_deselect_slot();
return SD_MMC_ERR_COMM;
}
if (!driver_start_write_blocks(sd_mmc_hal, src, 1)) {
sd_mmc_deselect_slot();
return SD_MMC_ERR_COMM;
}
if (!driver_wait_end_of_write_blocks(sd_mmc_hal)) {
sd_mmc_deselect_slot();
return SD_MMC_ERR_COMM;
}
sd_mmc_deselect_slot();
return SD_MMC_OK;
}
#endif
/** @} */
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