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rcar_gen3: drivers: emmc 

Signed-off-by: ldts <jramirez@baylibre.com>
This commit is contained in:
Jorge Ramirez-Ortiz 2018-09-23 09:39:56 +02:00 committed by ldts
parent 2f7de7271f
commit 3bfe202af6
11 changed files with 3073 additions and 0 deletions
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491
drivers/renesas/rcar/emmc/emmc_cmd.c Normal file
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/*
* Copyright (c) 2015-2017, Renesas Electronics Corporation. All rights reserved.
*
* SPDX-License-Identifier: BSD-3-Clause
*/
#include <debug.h>
#include "emmc_config.h"
#include "emmc_hal.h"
#include "emmc_std.h"
#include "emmc_registers.h"
#include "emmc_def.h"
#include "micro_delay.h"
static void emmc_little_to_big(uint8_t *p, uint32_t value)
{
if (p == NULL)
return;
p[0] = (uint8_t) (value >> 24);
p[1] = (uint8_t) (value >> 16);
p[2] = (uint8_t) (value >> 8);
p[3] = (uint8_t) value;
}
static void emmc_softreset(void)
{
int32_t loop = 10000;
int32_t retry = 1000;
/* flag clear */
mmc_drv_obj.during_cmd_processing = FALSE;
mmc_drv_obj.during_transfer = FALSE;
mmc_drv_obj.during_dma_transfer = FALSE;
mmc_drv_obj.state_machine_blocking = FALSE;
mmc_drv_obj.force_terminate = FALSE;
mmc_drv_obj.dma_error_flag = FALSE;
/* during operation ? */
if ((GETR_32(SD_INFO2) & SD_INFO2_CBSY) == 0)
goto reset;
/* wait CMDSEQ = 0 */
while (loop > 0) {
if ((GETR_32(SD_INFO2) & SD_INFO2_CBSY) == 0)
break; /* ready */
loop--;
if ((loop == 0) && (retry > 0)) {
rcar_micro_delay(1000U); /* wait 1ms */
loop = 10000;
retry--;
}
}
reset:
/* reset */
SETR_32(SOFT_RST, (GETR_32(SOFT_RST) & (~SOFT_RST_SDRST)));
SETR_32(SOFT_RST, (GETR_32(SOFT_RST) | SOFT_RST_SDRST));
/* initialize */
SETR_32(SD_INFO1, 0x00000000U);
SETR_32(SD_INFO2, SD_INFO2_CLEAR);
SETR_32(SD_INFO1_MASK, 0x00000000U); /* all interrupt disable */
SETR_32(SD_INFO2_MASK, SD_INFO2_CLEAR); /* all interrupt disable */
}
static void emmc_read_response(uint32_t *response)
{
uint8_t *p;
if (response == NULL)
return;
/* read response */
if (mmc_drv_obj.response_length != EMMC_MAX_RESPONSE_LENGTH) {
*response = GETR_32(SD_RSP10); /* [39:8] */
return;
}
/* CSD or CID */
p = (uint8_t *) (response);
emmc_little_to_big(p, ((GETR_32(SD_RSP76) << 8)
| (GETR_32(SD_RSP54) >> 24))); /* [127:96] */
emmc_little_to_big(p + 4, ((GETR_32(SD_RSP54) << 8)
| (GETR_32(SD_RSP32) >> 24))); /* [95:64] */
emmc_little_to_big(p + 8, ((GETR_32(SD_RSP32) << 8)
| (GETR_32(SD_RSP10) >> 24))); /* [63:32] */
emmc_little_to_big(p + 12, (GETR_32(SD_RSP10) << 8));
}
static EMMC_ERROR_CODE emmc_response_check(uint32_t *response,
uint32_t error_mask)
{
HAL_MEMCARD_RESPONSE_TYPE response_type =
(HAL_MEMCARD_RESPONSE_TYPE) (mmc_drv_obj.cmd_info.
cmd & HAL_MEMCARD_RESPONSE_TYPE_MASK);
if (response == NULL)
return EMMC_ERR_PARAM;
if (response_type == HAL_MEMCARD_RESPONSE_NONE)
return EMMC_SUCCESS;
if (response_type <= HAL_MEMCARD_RESPONSE_R1b) {
/* R1 or R1b */
mmc_drv_obj.current_state =
(EMMC_R1_STATE) ((*response & EMMC_R1_STATE_MASK) >>
EMMC_R1_STATE_SHIFT);
if ((*response & error_mask) != 0) {
if ((0x80 & *response) != 0) {
ERROR("BL2: emmc SWITCH_ERROR\n");
}
return EMMC_ERR_CARD_STATUS_BIT;
}
return EMMC_SUCCESS;;
}
if (response_type == HAL_MEMCARD_RESPONSE_R4) {
if ((*response & EMMC_R4_STATUS) != 0)
return EMMC_ERR_CARD_STATUS_BIT;
}
return EMMC_SUCCESS;
}
static void emmc_WaitCmd2Cmd_8Cycle(void)
{
uint32_t dataL, wait = 0;
dataL = GETR_32(SD_CLK_CTRL);
dataL &= 0x000000FF;
switch (dataL) {
case 0xFF:
case 0x00:
case 0x01:
case 0x02:
case 0x04:
case 0x08:
case 0x10:
case 0x20:
wait = 10U;
break;
case 0x40:
wait = 20U;
break;
case 0x80:
wait = 30U;
break;
}
rcar_micro_delay(wait);
}
static void cmdErrSdInfo2Log(void)
{
ERROR("BL2: emmc ERR SD_INFO2 = 0x%x\n", mmc_drv_obj.error_info.info2);
}
static void emmc_data_transfer_dma(void)
{
mmc_drv_obj.during_dma_transfer = TRUE;
mmc_drv_obj.dma_error_flag = FALSE;
SETR_32(SD_INFO1_MASK, 0x00000000U);
SETR_32(SD_INFO2_MASK, (SD_INFO2_ALL_ERR | SD_INFO2_CLEAR));
/* DMAC setting */
if (mmc_drv_obj.cmd_info.dir == HAL_MEMCARD_WRITE) {
/* transfer complete interrupt enable */
SETR_32(DM_CM_INFO1_MASK,
(DM_CM_INFO_MASK_CLEAR | DM_CM_INFO_CH0_ENABLE));
SETR_32(DM_CM_INFO2_MASK,
(DM_CM_INFO_MASK_CLEAR | DM_CM_INFO_CH0_ENABLE));
/* BUFF --> FIFO */
SETR_32(DM_CM_DTRAN_MODE, (DM_CM_DTRAN_MODE_CH0 |
DM_CM_DTRAN_MODE_BIT_WIDTH));
} else {
/* transfer complete interrupt enable */
SETR_32(DM_CM_INFO1_MASK,
(DM_CM_INFO_MASK_CLEAR | DM_CM_INFO_CH1_ENABLE));
SETR_32(DM_CM_INFO2_MASK,
(DM_CM_INFO_MASK_CLEAR | DM_CM_INFO_CH1_ENABLE));
/* FIFO --> BUFF */
SETR_32(DM_CM_DTRAN_MODE, (DM_CM_DTRAN_MODE_CH1
| DM_CM_DTRAN_MODE_BIT_WIDTH));
}
SETR_32(DM_DTRAN_ADDR, (((uintptr_t) mmc_drv_obj.buff_address_virtual &
DM_DTRAN_ADDR_WRITE_MASK)));
SETR_32(DM_CM_DTRAN_CTRL, DM_CM_DTRAN_CTRL_START);
}
EMMC_ERROR_CODE emmc_exec_cmd(uint32_t error_mask, uint32_t *response)
{
EMMC_ERROR_CODE rtn_code = EMMC_SUCCESS;
HAL_MEMCARD_RESPONSE_TYPE response_type;
HAL_MEMCARD_COMMAND_TYPE cmd_type;
EMMC_INT_STATE state;
uint32_t err_not_care_flag = FALSE;
/* parameter check */
if (response == NULL) {
emmc_write_error_info(EMMC_FUNCNO_EXEC_CMD, EMMC_ERR_PARAM);
return EMMC_ERR_PARAM;
}
/* state check */
if (mmc_drv_obj.clock_enable != TRUE) {
emmc_write_error_info(EMMC_FUNCNO_EXEC_CMD, EMMC_ERR_STATE);
return EMMC_ERR_STATE;
}
if (mmc_drv_obj.state_machine_blocking == TRUE) {
emmc_write_error_info(EMMC_FUNCNO_EXEC_CMD, EMMC_ERR);
return EMMC_ERR;
}
state = ESTATE_BEGIN;
response_type =
(HAL_MEMCARD_RESPONSE_TYPE) (mmc_drv_obj.cmd_info.
cmd & HAL_MEMCARD_RESPONSE_TYPE_MASK);
cmd_type =
(HAL_MEMCARD_COMMAND_TYPE) (mmc_drv_obj.cmd_info.
cmd & HAL_MEMCARD_COMMAND_TYPE_MASK);
/* state machine */
while ((mmc_drv_obj.force_terminate != TRUE) && (state != ESTATE_END)) {
/* The interrupt factor flag is observed. */
emmc_interrupt();
/* wait interrupt */
if (mmc_drv_obj.state_machine_blocking == TRUE)
continue;
switch (state) {
case ESTATE_BEGIN:
/* Busy check */
if ((mmc_drv_obj.error_info.info2 & SD_INFO2_CBSY) != 0) {
emmc_write_error_info(EMMC_FUNCNO_EXEC_CMD,
EMMC_ERR_CARD_BUSY);
return EMMC_ERR_CARD_BUSY;
}
/* clear register */
SETR_32(SD_INFO1, 0x00000000U);
SETR_32(SD_INFO2, SD_INFO2_CLEAR);
SETR_32(SD_INFO1_MASK, SD_INFO1_INFO0);
SETR_32(SD_INFO2_MASK,
(SD_INFO2_ALL_ERR | SD_INFO2_CLEAR));
state = ESTATE_ISSUE_CMD;
/* through */
case ESTATE_ISSUE_CMD:
/* ARG */
SETR_32(SD_ARG, mmc_drv_obj.cmd_info.arg);
/* issue cmd */
SETR_32(SD_CMD, mmc_drv_obj.cmd_info.hw);
/* Set driver flag */
mmc_drv_obj.during_cmd_processing = TRUE;
mmc_drv_obj.state_machine_blocking = TRUE;
if (response_type == HAL_MEMCARD_RESPONSE_NONE) {
state = ESTATE_NON_RESP_CMD;
} else {
state = ESTATE_RCV_RESP;
}
break;
case ESTATE_NON_RESP_CMD:
/* interrupt disable */
SETR_32(SD_INFO1_MASK, 0x00000000U);
SETR_32(SD_INFO2_MASK, SD_INFO2_CLEAR);
/* check interrupt */
if ((mmc_drv_obj.int_event2 & SD_INFO2_ALL_ERR) != 0) {
/* error interrupt */
cmdErrSdInfo2Log();
rtn_code = EMMC_ERR_INFO2;
state = ESTATE_ERROR;
} else if ((mmc_drv_obj.int_event1 & SD_INFO1_INFO0) ==
0) {
/* not receive expected interrupt */
rtn_code = EMMC_ERR_RESPONSE;
state = ESTATE_ERROR;
} else {
emmc_WaitCmd2Cmd_8Cycle();
state = ESTATE_END;
}
break;
case ESTATE_RCV_RESP:
/* interrupt disable */
SETR_32(SD_INFO1_MASK, 0x00000000U);
SETR_32(SD_INFO2_MASK, SD_INFO2_CLEAR);
/* check interrupt */
if ((mmc_drv_obj.int_event2 & SD_INFO2_ALL_ERR) != 0) {
if ((mmc_drv_obj.get_partition_access_flag ==
TRUE)
&& ((mmc_drv_obj.int_event2 & SD_INFO2_ERR6)
!= 0U)) {
err_not_care_flag = TRUE;
rtn_code = EMMC_ERR_CMD_TIMEOUT;
} else {
/* error interrupt */
cmdErrSdInfo2Log();
rtn_code = EMMC_ERR_INFO2;
}
state = ESTATE_ERROR;
break;
} else if ((mmc_drv_obj.int_event1 & SD_INFO1_INFO0) ==
0) {
/* not receive expected interrupt */
rtn_code = EMMC_ERR_RESPONSE;
state = ESTATE_ERROR;
break;
}
/* read response */
emmc_read_response(response);
/* check response */
rtn_code = emmc_response_check(response, error_mask);
if (rtn_code != EMMC_SUCCESS) {
state = ESTATE_ERROR;
break;
}
if (response_type == HAL_MEMCARD_RESPONSE_R1b) {
/* R1b */
SETR_32(SD_INFO2_MASK,
(SD_INFO2_ALL_ERR | SD_INFO2_CLEAR));
state = ESTATE_RCV_RESPONSE_BUSY;
} else {
state = ESTATE_CHECK_RESPONSE_COMPLETE;
}
break;
case ESTATE_RCV_RESPONSE_BUSY:
/* check interrupt */
if ((mmc_drv_obj.int_event2 & SD_INFO2_ALL_ERR) != 0) {
/* error interrupt */
cmdErrSdInfo2Log();
rtn_code = EMMC_ERR_INFO2;
state = ESTATE_ERROR;
break;
}
/* DAT0 not Busy */
if ((SD_INFO2_DAT0 & mmc_drv_obj.error_info.info2) != 0) {
state = ESTATE_CHECK_RESPONSE_COMPLETE;
break;
}
break;
case ESTATE_CHECK_RESPONSE_COMPLETE:
if (cmd_type >= HAL_MEMCARD_COMMAND_TYPE_ADTC_WRITE) {
state = ESTATE_DATA_TRANSFER;
} else {
emmc_WaitCmd2Cmd_8Cycle();
state = ESTATE_END;
}
break;
case ESTATE_DATA_TRANSFER:
/* ADTC command */
mmc_drv_obj.during_transfer = TRUE;
mmc_drv_obj.state_machine_blocking = TRUE;
if (mmc_drv_obj.transfer_mode == HAL_MEMCARD_DMA) {
/* DMA */
emmc_data_transfer_dma();
} else {
/* PIO */
/* interrupt enable (FIFO read/write enable) */
if (mmc_drv_obj.cmd_info.dir ==
HAL_MEMCARD_WRITE) {
SETR_32(SD_INFO2_MASK,
(SD_INFO2_BWE | SD_INFO2_ALL_ERR
| SD_INFO2_CLEAR));
} else {
SETR_32(SD_INFO2_MASK,
(SD_INFO2_BRE | SD_INFO2_ALL_ERR
| SD_INFO2_CLEAR));
}
}
state = ESTATE_DATA_TRANSFER_COMPLETE;
break;
case ESTATE_DATA_TRANSFER_COMPLETE:
/* check interrupt */
if ((mmc_drv_obj.int_event2 & SD_INFO2_ALL_ERR) != 0) {
/* error interrupt */
cmdErrSdInfo2Log();
rtn_code = EMMC_ERR_INFO2;
state = ESTATE_TRANSFER_ERROR;
break;
}
/* DMAC error ? */
if (mmc_drv_obj.dma_error_flag == TRUE) {
/* Error occurred in DMAC driver. */
rtn_code = EMMC_ERR_FROM_DMAC_TRANSFER;
state = ESTATE_TRANSFER_ERROR;
} else if (mmc_drv_obj.during_dma_transfer == TRUE) {
/* DMAC not finished. unknown error */
rtn_code = EMMC_ERR;
state = ESTATE_TRANSFER_ERROR;
} else {
SETR_32(SD_INFO1_MASK, SD_INFO1_INFO2);
SETR_32(SD_INFO2_MASK,
(SD_INFO2_ALL_ERR | SD_INFO2_CLEAR));
mmc_drv_obj.state_machine_blocking = TRUE;
state = ESTATE_ACCESS_END;
}
break;
case ESTATE_ACCESS_END:
/* clear flag */
if (HAL_MEMCARD_DMA == mmc_drv_obj.transfer_mode) {
SETR_32(CC_EXT_MODE, CC_EXT_MODE_CLEAR); /* W (CC_EXT_MODE, H'0000_1010) SD_BUF DMA transfer disabled */
SETR_32(SD_STOP, 0x00000000U);
mmc_drv_obj.during_dma_transfer = FALSE;
}
SETR_32(SD_INFO1_MASK, 0x00000000U);
SETR_32(SD_INFO2_MASK, SD_INFO2_CLEAR);
SETR_32(SD_INFO1, 0x00000000U);
SETR_32(SD_INFO2, SD_INFO2_CLEAR);
if ((mmc_drv_obj.int_event1 & SD_INFO1_INFO2) != 0) {
emmc_WaitCmd2Cmd_8Cycle();
state = ESTATE_END;
} else {
state = ESTATE_ERROR;
}
break;
case ESTATE_TRANSFER_ERROR:
/* The error occurred in the Data transfer. */
if (HAL_MEMCARD_DMA == mmc_drv_obj.transfer_mode) {
SETR_32(CC_EXT_MODE, CC_EXT_MODE_CLEAR); /* W (CC_EXT_MODE, H'0000_1010) SD_BUF DMA transfer disabled */
SETR_32(SD_STOP, 0x00000000U);
mmc_drv_obj.during_dma_transfer = FALSE;
}
/* through */
case ESTATE_ERROR:
if (err_not_care_flag == TRUE) {
mmc_drv_obj.during_cmd_processing = FALSE;
} else {
emmc_softreset();
emmc_write_error_info(EMMC_FUNCNO_EXEC_CMD,
rtn_code);
}
return rtn_code;
default:
state = ESTATE_END;
break;
} /* switch (state) */
} /* while ( (mmc_drv_obj.force_terminate != TRUE) && (state != ESTATE_END) ) */
/* force terminate */
if (mmc_drv_obj.force_terminate == TRUE) {
/* timeout timer is expired. Or, PIO data transfer error. */
/* Timeout occurred in the DMA transfer. */
if (mmc_drv_obj.during_dma_transfer == TRUE) {
mmc_drv_obj.during_dma_transfer = FALSE;
}
ERROR("BL2: emmc exec_cmd:EMMC_ERR_FORCE_TERMINATE\n");
emmc_softreset();
return EMMC_ERR_FORCE_TERMINATE; /* error information has already been written. */
}
/* success */
mmc_drv_obj.during_cmd_processing = FALSE;
mmc_drv_obj.during_transfer = FALSE;
return EMMC_SUCCESS;
}

40
drivers/renesas/rcar/emmc/emmc_config.h Normal file
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/*
* Copyright (c) 2015-2017, Renesas Electronics Corporation. All rights reserved.
*
* SPDX-License-Identifier: BSD-3-Clause
*/
/**
* @file emmc_config.h
* @brief Configuration file
*
*/
#ifndef __EMMC_CONFIG_H__
#define __EMMC_CONFIG_H__
/* ************************ HEADER (INCLUDE) SECTION *********************** */
/* ***************** MACROS, CONSTANTS, COMPILATION FLAGS ****************** */
/** @brief MMC driver config
*/
#define EMMC_RCA 1UL /* RCA */
#define EMMC_RW_DATA_TIMEOUT 0x40UL /* 314ms (freq = 400KHz, timeout Counter = 0x04(SDCLK * 2^17) */
#define EMMC_RETRY_COUNT 0 /* how many times to try after fail. Don't change. */
#define EMMC_CMD_MAX 60UL /* Don't change. */
/** @brief etc
*/
#define LOADIMAGE_FLAGS_DMA_ENABLE 0x00000001UL
/* ********************** STRUCTURES, TYPE DEFINITIONS ********************* */
/* ********************** DECLARATION OF EXTERNAL DATA ********************* */
/* ************************** FUNCTION PROTOTYPES ************************** */
/* ********************************* CODE ********************************** */
#endif /* #ifndef __EMMC_CONFIG_H__ */
/* ******************************** END ************************************ */

78
drivers/renesas/rcar/emmc/emmc_def.h Normal file
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/*
* Copyright (c) 2015-2017, Renesas Electronics Corporation. All rights reserved.
*
* SPDX-License-Identifier: BSD-3-Clause
*/
/**
* @file emmc_def.h
* @brief eMMC boot is expecting this header file
*
*/
#ifndef __EMMC_DEF_H__
#define __EMMC_DEF_H__
#include "emmc_std.h"
/* ************************ HEADER (INCLUDE) SECTION *********************** */
/* ***************** MACROS, CONSTANTS, COMPILATION FLAGS ****************** */
#define EMMC_POWER_ON (1U)
/* ********************** STRUCTURES, TYPE DEFINITIONS ********************* */
/* ********************** DECLARATION OF EXTERNAL DATA ********************* */
extern st_mmc_base mmc_drv_obj;
/* ************************** FUNCTION PROTOTYPES ************************** */
/** @brief for assembler program
*/
uint32_t _rom_emmc_finalize(void);
/** @brief eMMC driver API
*/
EMMC_ERROR_CODE rcar_emmc_init(void);
EMMC_ERROR_CODE emmc_terminate(void);
EMMC_ERROR_CODE rcar_emmc_memcard_power(uint8_t mode);
EMMC_ERROR_CODE rcar_emmc_mount(void);
EMMC_ERROR_CODE emmc_set_request_mmc_clock(uint32_t *freq);
EMMC_ERROR_CODE emmc_send_idle_cmd(uint32_t arg);
EMMC_ERROR_CODE emmc_select_partition(EMMC_PARTITION_ID id);
EMMC_ERROR_CODE emmc_read_sector(uint32_t *buff_address_virtual,
uint32_t sector_number, uint32_t count,
uint32_t feature_flags);
EMMC_ERROR_CODE emmc_write_sector(uint32_t *buff_address_virtual,
uint32_t sector_number, uint32_t count,
uint32_t feature_flags);
EMMC_ERROR_CODE emmc_erase_sector(uint32_t *start_address,
uint32_t *end_address);
uint32_t emmc_bit_field(uint8_t *data, uint32_t top, uint32_t bottom);
/** @brief interrupt service
*/
uint32_t emmc_interrupt(void);
/** @brief DMA
*/
/** @brief send command API
*/
EMMC_ERROR_CODE emmc_exec_cmd(uint32_t error_mask, uint32_t *response);
void emmc_make_nontrans_cmd(HAL_MEMCARD_COMMAND cmd, uint32_t arg);
void emmc_make_trans_cmd(HAL_MEMCARD_COMMAND cmd, uint32_t arg,
uint32_t *buff_address_virtual, uint32_t len,
HAL_MEMCARD_OPERATION dir,
HAL_MEMCARD_DATA_TRANSFER_MODE transfer_mode);
EMMC_ERROR_CODE emmc_set_ext_csd(uint32_t arg);
/** @brief for error information
*/
void emmc_write_error_info(uint16_t func_no, EMMC_ERROR_CODE error_code);
void emmc_write_error_info_func_no(uint16_t func_no);
/* ********************************* CODE ********************************** */
#endif /* #define __EMMC_DEF_H__ */
/* ******************************** END ************************************ */

318
drivers/renesas/rcar/emmc/emmc_hal.h Normal file
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/*
* Copyright (c) 2015-2017, Renesas Electronics Corporation. All rights reserved.
*
* SPDX-License-Identifier: BSD-3-Clause
*/
/**
* @file emmc_hal.h
* @brief emmc boot driver is expecting this header file
*
*/
#ifndef __EMMC_HAL_H__
#define __EMMC_HAL_H__
/* ************************ HEADER (INCLUDE) SECTION *********************** */
#include <stdint.h>
/* ***************** MACROS, CONSTANTS, COMPILATION FLAGS ****************** */
/** @brief memory card error/status types
*/
#define HAL_MEMCARD_OUT_OF_RANGE 0x80000000L
#define HAL_MEMCARD_ADDRESS_ERROR 0x40000000L
#define HAL_MEMCARD_BLOCK_LEN_ERROR 0x20000000L
#define HAL_MEMCARD_ERASE_SEQ_ERROR 0x10000000L
#define HAL_MEMCARD_ERASE_PARAM 0x08000000L
#define HAL_MEMCARD_WP_VIOLATION 0x04000000L
#define HAL_MEMCARD_CARD_IS_LOCKED 0x02000000L
#define HAL_MEMCARD_LOCK_UNLOCK_FAILED 0x01000000L
#define HAL_MEMCARD_COM_CRC_ERROR 0x00800000L
#define HAL_MEMCARD_ILEGAL_COMMAND 0x00400000L
#define HAL_MEMCARD_CARD_ECC_FAILED 0x00200000L
#define HAL_MEMCARD_CC_ERROR 0x00100000L
#define HAL_MEMCARD_ERROR 0x00080000L
#define HAL_MEMCARD_UNDERRUN 0x00040000L
#define HAL_MEMCARD_OVERRUN 0x00020000L
#define HAL_MEMCARD_CIDCSD_OVERWRITE 0x00010000L
#define HAL_MEMCARD_WP_ERASE_SKIP 0x00008000L
#define HAL_MEMCARD_CARD_ECC_DISABLED 0x00004000L
#define HAL_MEMCARD_ERASE_RESET 0x00002000L
#define HAL_MEMCARD_CARD_STATE 0x00001E00L
#define HAL_MEMCARD_CARD_READY_FOR_DATA 0x00000100L
#define HAL_MEMCARD_APP_CMD 0x00000020L
#define HAL_MEMCARD_SWITCH_ERROR 0x00000080L
#define HAL_MEMCARD_AKE_SEQ_ERROR 0x00000008L
#define HAL_MEMCARD_NO_ERRORS 0x00000000L
/** @brief Memory card response types
*/
#define HAL_MEMCARD_COMMAND_INDEX_MASK 0x0003f
/* ********************** STRUCTURES, TYPE DEFINITIONS ********************* */
/** @brief Type of the return value.
*/
typedef enum {
HAL_MEMCARD_FAIL = 0U,
HAL_MEMCARD_OK = 1U,
HAL_MEMCARD_DMA_ALLOC_FAIL = 2U, /**< DMA channel allocation failed */
HAL_MEMCARD_DMA_TRANSFER_FAIL = 3U, /**< DMA transfer failed */
HAL_MEMCARD_CARD_STATUS_ERROR = 4U, /**< A non-masked error bit was set in the card status */
HAL_MEMCARD_CMD_TIMEOUT = 5U, /**< Command timeout occurred */
HAL_MEMCARD_DATA_TIMEOUT = 6U, /**< Data timeout occurred */
HAL_MEMCARD_CMD_CRC_ERROR = 7U, /**< Command CRC error occurred */
HAL_MEMCARD_DATA_CRC_ERROR = 8U /**< Data CRC error occurred */
} HAL_MEMCARD_RETURN;
/** @brief memory access operation
*/
typedef enum {
HAL_MEMCARD_READ = 0U, /**< read */
HAL_MEMCARD_WRITE = 1U /**< write */
} HAL_MEMCARD_OPERATION;
/** @brief Type of data width on memorycard bus
*/
typedef enum {
HAL_MEMCARD_DATA_WIDTH_1_BIT = 0U,
HAL_MEMCARD_DATA_WIDTH_4_BIT = 1U,
HAL_MEMCARD_DATA_WIDTH_8_BIT = 2U
} HAL_MEMCARD_DATA_WIDTH; /**< data (bus) width types */
/** @brief Presence of the memory card
*/
typedef enum {
HAL_MEMCARD_CARD_IS_IN = 0U,
HAL_MEMCARD_CARD_IS_OUT = 1U
} HAL_MEMCARD_PRESENCE_STATUS; /* presence status of the memory card */
/** @brief mode of data transfer
*/
typedef enum {
HAL_MEMCARD_DMA = 0U,
HAL_MEMCARD_NOT_DMA = 1U
} HAL_MEMCARD_DATA_TRANSFER_MODE;
/** @brief Memory card response types.
*/
typedef enum hal_memcard_response_type {
HAL_MEMCARD_RESPONSE_NONE = 0x00000U,
HAL_MEMCARD_RESPONSE_R1 = 0x00100U,
HAL_MEMCARD_RESPONSE_R1b = 0x00200U,
HAL_MEMCARD_RESPONSE_R2 = 0x00300U,
HAL_MEMCARD_RESPONSE_R3 = 0x00400U,
HAL_MEMCARD_RESPONSE_R4 = 0x00500U,
HAL_MEMCARD_RESPONSE_R5 = 0x00600U,
HAL_MEMCARD_RESPONSE_R6 = 0x00700U,
HAL_MEMCARD_RESPONSE_R7 = 0x00800U,
HAL_MEMCARD_RESPONSE_TYPE_MASK = 0x00f00U
} HAL_MEMCARD_RESPONSE_TYPE;
/** @brief Memory card command types.
*/
typedef enum hal_memcard_command_type {
HAL_MEMCARD_COMMAND_TYPE_BC = 0x00000U,
HAL_MEMCARD_COMMAND_TYPE_BCR = 0x01000U,
HAL_MEMCARD_COMMAND_TYPE_AC = 0x02000U,
HAL_MEMCARD_COMMAND_TYPE_ADTC_WRITE = 0x03000U,
HAL_MEMCARD_COMMAND_TYPE_ADTC_READ = 0x04000U,
HAL_MEMCARD_COMMAND_TYPE_MASK = 0x07000U
} HAL_MEMCARD_COMMAND_TYPE;
/** @brief Type of memory card
*/
typedef enum hal_memcard_command_card_type {
HAL_MEMCARD_COMMAND_CARD_TYPE_COMMON = 0x00000U,
HAL_MEMCARD_COMMAND_CARD_TYPE_MMC = 0x08000U,
HAL_MEMCARD_COMMAND_CARD_TYPE_SD = 0x10000U,
HAL_MEMCARD_COMMAND_CARD_TYPE_MASK = 0x18000U
} HAL_MEMCARD_COMMAND_CARD_TYPE;
/** @brief Memory card application command.
*/
typedef enum hal_memcard_command_app_norm {
HAL_MEMCARD_COMMAND_NORMAL = 0x00000U,
HAL_MEMCARD_COMMAND_APP = 0x20000U,
HAL_MEMCARD_COMMAND_APP_NORM_MASK = 0x20000U
} HAL_MEMCARD_COMMAND_APP_NORM;
/** @brief Memory card command codes.
*/
typedef enum {
/* class 0 and class 1 */
CMD0_GO_IDLE_STATE = 0 | HAL_MEMCARD_RESPONSE_NONE | HAL_MEMCARD_COMMAND_TYPE_BC | HAL_MEMCARD_COMMAND_CARD_TYPE_COMMON | HAL_MEMCARD_COMMAND_NORMAL, /* CMD0 */
CMD1_SEND_OP_COND = 1 | HAL_MEMCARD_RESPONSE_R3 | HAL_MEMCARD_COMMAND_TYPE_BCR | HAL_MEMCARD_COMMAND_CARD_TYPE_MMC | HAL_MEMCARD_COMMAND_NORMAL, /* CMD1 */
CMD2_ALL_SEND_CID_MMC = 2 | HAL_MEMCARD_RESPONSE_R2 | HAL_MEMCARD_COMMAND_TYPE_BCR | HAL_MEMCARD_COMMAND_CARD_TYPE_MMC | HAL_MEMCARD_COMMAND_NORMAL, /* CMD2 */
CMD2_ALL_SEND_CID_SD =
2 | HAL_MEMCARD_RESPONSE_R2 | HAL_MEMCARD_COMMAND_TYPE_BCR |
HAL_MEMCARD_COMMAND_CARD_TYPE_SD | HAL_MEMCARD_COMMAND_NORMAL,
CMD3_SET_RELATIVE_ADDR = 3 | HAL_MEMCARD_RESPONSE_R1 | HAL_MEMCARD_COMMAND_TYPE_AC | HAL_MEMCARD_COMMAND_CARD_TYPE_MMC | HAL_MEMCARD_COMMAND_NORMAL, /* CMD3 */
CMD3_SEND_RELATIVE_ADDR =
3 | HAL_MEMCARD_RESPONSE_R6 | HAL_MEMCARD_COMMAND_TYPE_AC |
HAL_MEMCARD_COMMAND_CARD_TYPE_SD | HAL_MEMCARD_COMMAND_NORMAL,
CMD4_SET_DSR = 4 | HAL_MEMCARD_RESPONSE_NONE | HAL_MEMCARD_COMMAND_TYPE_BC | HAL_MEMCARD_COMMAND_CARD_TYPE_COMMON | HAL_MEMCARD_COMMAND_NORMAL, /* CMD4 */
CMD5_SLEEP_AWAKE = 5 | HAL_MEMCARD_RESPONSE_R1b | HAL_MEMCARD_COMMAND_TYPE_AC | HAL_MEMCARD_COMMAND_CARD_TYPE_MMC | HAL_MEMCARD_COMMAND_NORMAL, /* CMD5 */
CMD6_SWITCH = 6 | HAL_MEMCARD_RESPONSE_R1b | HAL_MEMCARD_COMMAND_TYPE_AC | HAL_MEMCARD_COMMAND_CARD_TYPE_MMC | HAL_MEMCARD_COMMAND_NORMAL, /* CMD6 */
CMD6_SWITCH_FUNC =
6 | HAL_MEMCARD_RESPONSE_R1 | HAL_MEMCARD_COMMAND_TYPE_AC |
HAL_MEMCARD_COMMAND_CARD_TYPE_SD | HAL_MEMCARD_COMMAND_NORMAL,
ACMD6_SET_BUS_WIDTH =
6 | HAL_MEMCARD_RESPONSE_R1 | HAL_MEMCARD_COMMAND_TYPE_AC |
HAL_MEMCARD_COMMAND_CARD_TYPE_SD | HAL_MEMCARD_COMMAND_APP,
CMD7_SELECT_CARD = 7 | HAL_MEMCARD_RESPONSE_R1 | HAL_MEMCARD_COMMAND_TYPE_AC | HAL_MEMCARD_COMMAND_CARD_TYPE_COMMON | HAL_MEMCARD_COMMAND_NORMAL, /* CMD7 */
CMD7_SELECT_CARD_PROG = 7 | HAL_MEMCARD_RESPONSE_R1b | HAL_MEMCARD_COMMAND_TYPE_AC | HAL_MEMCARD_COMMAND_CARD_TYPE_COMMON | HAL_MEMCARD_COMMAND_NORMAL, /* CMD7(from Disconnected State to Programming State) */
CMD7_DESELECT_CARD =
7 | HAL_MEMCARD_RESPONSE_R1 | HAL_MEMCARD_COMMAND_TYPE_AC |
HAL_MEMCARD_COMMAND_CARD_TYPE_COMMON | HAL_MEMCARD_COMMAND_NORMAL,
CMD8_SEND_EXT_CSD = 8 | HAL_MEMCARD_RESPONSE_R1 | HAL_MEMCARD_COMMAND_TYPE_ADTC_READ | HAL_MEMCARD_COMMAND_CARD_TYPE_MMC | HAL_MEMCARD_COMMAND_NORMAL, /* CMD8 */
CMD8_SEND_IF_COND =
8 | HAL_MEMCARD_RESPONSE_R7 | HAL_MEMCARD_COMMAND_TYPE_BCR |
HAL_MEMCARD_COMMAND_CARD_TYPE_SD | HAL_MEMCARD_COMMAND_NORMAL,
CMD9_SEND_CSD = 9 | HAL_MEMCARD_RESPONSE_R2 | HAL_MEMCARD_COMMAND_TYPE_AC | HAL_MEMCARD_COMMAND_CARD_TYPE_COMMON | HAL_MEMCARD_COMMAND_NORMAL, /* CMD9 */
CMD10_SEND_CID = 10 | HAL_MEMCARD_RESPONSE_R2 | HAL_MEMCARD_COMMAND_TYPE_AC | HAL_MEMCARD_COMMAND_CARD_TYPE_COMMON | HAL_MEMCARD_COMMAND_NORMAL, /* CMD10 */
CMD11_READ_DAT_UNTIL_STOP = 11 | HAL_MEMCARD_RESPONSE_R1 | HAL_MEMCARD_COMMAND_TYPE_ADTC_READ | HAL_MEMCARD_COMMAND_CARD_TYPE_SD | HAL_MEMCARD_COMMAND_NORMAL, /* CMD11 */
CMD12_STOP_TRANSMISSION = 12 | HAL_MEMCARD_RESPONSE_R1 | HAL_MEMCARD_COMMAND_TYPE_AC | HAL_MEMCARD_COMMAND_CARD_TYPE_COMMON | HAL_MEMCARD_COMMAND_NORMAL, /* CMD12 */
CMD12_STOP_TRANSMISSION_WRITE = 12 | HAL_MEMCARD_RESPONSE_R1b | HAL_MEMCARD_COMMAND_TYPE_AC | HAL_MEMCARD_COMMAND_CARD_TYPE_COMMON | HAL_MEMCARD_COMMAND_NORMAL, /* CMD12(R1b : write case) */
CMD13_SEND_STATUS = 13 | HAL_MEMCARD_RESPONSE_R1 | HAL_MEMCARD_COMMAND_TYPE_AC | HAL_MEMCARD_COMMAND_CARD_TYPE_COMMON | HAL_MEMCARD_COMMAND_NORMAL, /* CMD13 */
ACMD13_SD_STATUS =
13 | HAL_MEMCARD_RESPONSE_R1 | HAL_MEMCARD_COMMAND_TYPE_ADTC_READ |
HAL_MEMCARD_COMMAND_CARD_TYPE_SD | HAL_MEMCARD_COMMAND_APP,
CMD14_BUSTEST_R = 14 | HAL_MEMCARD_RESPONSE_R1 | HAL_MEMCARD_COMMAND_TYPE_ADTC_READ | HAL_MEMCARD_COMMAND_CARD_TYPE_MMC | HAL_MEMCARD_COMMAND_NORMAL, /* CMD14 */
CMD15_GO_INACTIVE_STATE = 15 | HAL_MEMCARD_RESPONSE_NONE | HAL_MEMCARD_COMMAND_TYPE_AC | HAL_MEMCARD_COMMAND_CARD_TYPE_COMMON | HAL_MEMCARD_COMMAND_NORMAL, /* CMD15 */
/* class 2 */
CMD16_SET_BLOCKLEN = 16 | HAL_MEMCARD_RESPONSE_R1 | HAL_MEMCARD_COMMAND_TYPE_AC | HAL_MEMCARD_COMMAND_CARD_TYPE_COMMON | HAL_MEMCARD_COMMAND_NORMAL, /* CMD16 */
CMD17_READ_SINGLE_BLOCK = 17 | HAL_MEMCARD_RESPONSE_R1 | HAL_MEMCARD_COMMAND_TYPE_ADTC_READ | HAL_MEMCARD_COMMAND_CARD_TYPE_COMMON | HAL_MEMCARD_COMMAND_NORMAL, /* CMD17 */
CMD18_READ_MULTIPLE_BLOCK = 18 | HAL_MEMCARD_RESPONSE_R1 | HAL_MEMCARD_COMMAND_TYPE_ADTC_READ | HAL_MEMCARD_COMMAND_CARD_TYPE_COMMON | HAL_MEMCARD_COMMAND_NORMAL, /* CMD18 */
CMD19_BUS_TEST_W = 19 | HAL_MEMCARD_RESPONSE_R1 | HAL_MEMCARD_COMMAND_TYPE_ADTC_WRITE | HAL_MEMCARD_COMMAND_CARD_TYPE_MMC | HAL_MEMCARD_COMMAND_NORMAL, /* CMD19 */
/* class 3 */
CMD20_WRITE_DAT_UNTIL_STOP = 20 | HAL_MEMCARD_RESPONSE_R1 | HAL_MEMCARD_COMMAND_TYPE_ADTC_WRITE | HAL_MEMCARD_COMMAND_CARD_TYPE_MMC | HAL_MEMCARD_COMMAND_NORMAL, /* CMD20 */
CMD21 = 21, /* CMD21 */
CMD22 = 22, /* CMD22 */
ACMD22_SEND_NUM_WR_BLOCKS =
22 | HAL_MEMCARD_RESPONSE_R1 | HAL_MEMCARD_COMMAND_TYPE_AC |
HAL_MEMCARD_COMMAND_CARD_TYPE_SD | HAL_MEMCARD_COMMAND_APP,
/* class 4 */
CMD23_SET_BLOCK_COUNT = 23 | HAL_MEMCARD_RESPONSE_R1 | HAL_MEMCARD_COMMAND_TYPE_AC | HAL_MEMCARD_COMMAND_CARD_TYPE_MMC | HAL_MEMCARD_COMMAND_NORMAL, /* CMD23 */
ACMD23_SET_WR_BLK_ERASE_COUNT =
23 | HAL_MEMCARD_RESPONSE_R1 | HAL_MEMCARD_COMMAND_TYPE_AC |
HAL_MEMCARD_COMMAND_CARD_TYPE_SD | HAL_MEMCARD_COMMAND_APP,
CMD24_WRITE_BLOCK = 24 | HAL_MEMCARD_RESPONSE_R1 | HAL_MEMCARD_COMMAND_TYPE_ADTC_WRITE | HAL_MEMCARD_COMMAND_CARD_TYPE_COMMON | HAL_MEMCARD_COMMAND_NORMAL, /* CMD24 */
CMD25_WRITE_MULTIPLE_BLOCK = 25 | HAL_MEMCARD_RESPONSE_R1 | HAL_MEMCARD_COMMAND_TYPE_ADTC_WRITE | HAL_MEMCARD_COMMAND_CARD_TYPE_COMMON | HAL_MEMCARD_COMMAND_NORMAL, /* CMD25 */
CMD26_PROGRAM_CID = 26 | HAL_MEMCARD_RESPONSE_R1 | HAL_MEMCARD_COMMAND_TYPE_ADTC_WRITE | HAL_MEMCARD_COMMAND_CARD_TYPE_MMC | HAL_MEMCARD_COMMAND_NORMAL, /* CMD26 */
CMD27_PROGRAM_CSD = 27 | HAL_MEMCARD_RESPONSE_R1 | HAL_MEMCARD_COMMAND_TYPE_ADTC_WRITE | HAL_MEMCARD_COMMAND_CARD_TYPE_COMMON | HAL_MEMCARD_COMMAND_NORMAL, /* CMD27 */
/* class 6 */
CMD28_SET_WRITE_PROT = 28 | HAL_MEMCARD_RESPONSE_R1b | HAL_MEMCARD_COMMAND_TYPE_AC | HAL_MEMCARD_COMMAND_CARD_TYPE_COMMON | HAL_MEMCARD_COMMAND_NORMAL, /* CMD28 */
CMD29_CLR_WRITE_PROT = 29 | HAL_MEMCARD_RESPONSE_R1b | HAL_MEMCARD_COMMAND_TYPE_AC | HAL_MEMCARD_COMMAND_CARD_TYPE_COMMON | HAL_MEMCARD_COMMAND_NORMAL, /* CMD29 */
CMD30_SEND_WRITE_PROT = 30 | HAL_MEMCARD_RESPONSE_R1 | HAL_MEMCARD_COMMAND_TYPE_ADTC_READ | HAL_MEMCARD_COMMAND_CARD_TYPE_COMMON | HAL_MEMCARD_COMMAND_NORMAL, /* CMD30 */
CMD30_SEND_WRITE_PROT_TYPE = 31 | HAL_MEMCARD_RESPONSE_R1 | HAL_MEMCARD_COMMAND_TYPE_ADTC_READ | HAL_MEMCARD_COMMAND_CARD_TYPE_COMMON | HAL_MEMCARD_COMMAND_NORMAL, /* CMD31 */
/* class 5 */
CMD32_ERASE_WR_BLK_START = 32 | HAL_MEMCARD_RESPONSE_R1 | HAL_MEMCARD_COMMAND_TYPE_AC | HAL_MEMCARD_COMMAND_CARD_TYPE_SD | HAL_MEMCARD_COMMAND_NORMAL, /* CMD32 */
CMD33_ERASE_WR_BLK_END = 33 | HAL_MEMCARD_RESPONSE_R1 | HAL_MEMCARD_COMMAND_TYPE_AC | HAL_MEMCARD_COMMAND_CARD_TYPE_SD | HAL_MEMCARD_COMMAND_NORMAL, /* CMD33 */
CMD34 = 34, /* CMD34 */
CMD35_ERASE_GROUP_START = 35 | HAL_MEMCARD_RESPONSE_R1 | HAL_MEMCARD_COMMAND_TYPE_AC | HAL_MEMCARD_COMMAND_CARD_TYPE_MMC | HAL_MEMCARD_COMMAND_NORMAL, /* CMD35 */
CMD36_ERASE_GROUP_END = 36 | HAL_MEMCARD_RESPONSE_R1 | HAL_MEMCARD_COMMAND_TYPE_AC | HAL_MEMCARD_COMMAND_CARD_TYPE_MMC | HAL_MEMCARD_COMMAND_NORMAL, /* CMD36 */
CMD37 = 37, /* CMD37 */
CMD38_ERASE = 38 | HAL_MEMCARD_RESPONSE_R1b | HAL_MEMCARD_COMMAND_TYPE_AC | HAL_MEMCARD_COMMAND_CARD_TYPE_COMMON | HAL_MEMCARD_COMMAND_NORMAL, /* CMD38 */
/* class 9 */
CMD39_FASTIO = 39 | HAL_MEMCARD_RESPONSE_R4 | HAL_MEMCARD_COMMAND_TYPE_AC | HAL_MEMCARD_COMMAND_CARD_TYPE_MMC | HAL_MEMCARD_COMMAND_NORMAL, /* CMD39 */
CMD40_GO_IRQSTATE = 40 | HAL_MEMCARD_RESPONSE_R5 | HAL_MEMCARD_COMMAND_TYPE_BCR | HAL_MEMCARD_COMMAND_CARD_TYPE_MMC | HAL_MEMCARD_COMMAND_NORMAL, /* CMD40 */
CMD41 = 41, /* CMD41 */
ACMD41_SD_SEND_OP_COND =
41 | HAL_MEMCARD_RESPONSE_R3 | HAL_MEMCARD_COMMAND_TYPE_BCR |
HAL_MEMCARD_COMMAND_CARD_TYPE_SD | HAL_MEMCARD_COMMAND_APP,
/* class 7 */
CMD42_LOCK_UNLOCK = 42 | HAL_MEMCARD_RESPONSE_R1 | HAL_MEMCARD_COMMAND_TYPE_ADTC_WRITE | HAL_MEMCARD_COMMAND_CARD_TYPE_COMMON | HAL_MEMCARD_COMMAND_NORMAL, /* CMD42 */
ACMD42_SET_CLR_CARD_DETECT =
42 | HAL_MEMCARD_RESPONSE_R1 | HAL_MEMCARD_COMMAND_TYPE_AC |
HAL_MEMCARD_COMMAND_CARD_TYPE_SD | HAL_MEMCARD_COMMAND_APP,
CMD43 = 43, /* CMD43 */
CMD44 = 44, /* CMD44 */
CMD45 = 45, /* CMD45 */
CMD46 = 46, /* CMD46 */
CMD47 = 47, /* CMD47 */
CMD48 = 48, /* CMD48 */
CMD49 = 49, /* CMD49 */
CMD50 = 50, /* CMD50 */
CMD51 = 51, /* CMD51 */
ACMD51_SEND_SCR =
51 | HAL_MEMCARD_RESPONSE_R1 | HAL_MEMCARD_COMMAND_TYPE_ADTC_READ |
HAL_MEMCARD_COMMAND_CARD_TYPE_SD | HAL_MEMCARD_COMMAND_APP,
CMD52 = 52, /* CMD52 */
CMD53 = 53, /* CMD53 */
CMD54 = 54, /* CMD54 */
/* class 8 */
CMD55_APP_CMD = 55 | HAL_MEMCARD_RESPONSE_R1 | HAL_MEMCARD_COMMAND_TYPE_AC | HAL_MEMCARD_COMMAND_CARD_TYPE_COMMON | HAL_MEMCARD_COMMAND_NORMAL, /* CMD55 */
CMD56_GEN_CMD = 56 | HAL_MEMCARD_RESPONSE_R1 | HAL_MEMCARD_COMMAND_TYPE_ADTC_WRITE | HAL_MEMCARD_COMMAND_CARD_TYPE_COMMON | HAL_MEMCARD_COMMAND_NORMAL, /* CMD56 */
CMD57 = 57, /* CMD57 */
CMD58 = 58, /* CMD58 */
CMD59 = 59, /* CMD59 */
CMD60 = 60, /* CMD60 */
CMD61 = 61, /* CMD61 */
CMD62 = 62, /* CMD62 */
CMD63 = 63 /* CMD63 */
} HAL_MEMCARD_COMMAND;
/** @brief Configuration structure from HAL layer.
*
* If some field is not available it should be filled with 0xFF.
* The API version is 32-bit unsigned integer telling the version of the API. The integer is divided to four sections which each can be treated as a 8-bit unsigned number:
* Bits 31-24 make the most significant part of the version number. This number starts from 1 i.e. the second version of the API will be 0x02xxxxxx. This number changes only, if the API itself changes so much that it is not compatible anymore with older releases.
* Bits 23-16 API minor version number. For example API version 2.1 would be 0x0201xxxx.
* Bits 15-8 are the number of the year when release is done. The 0 is year 2000, 1 is year 2001 and so on
* Bits 7- are the week number when release is done. First full week of the year is 1
*
* @note Example: let's assume that release 2.1 is done on week 10 year 2008 the version will get the value 0x0201080A
*/
typedef struct {
/**
* Version of the chipset API implementation
*
* bits [31:24] API specification major version number.<br>
* bits [23:16] API specification minor version number.<br>
* bits [15:8] API implemention year. (2000 = 0, 2001 = 1, ...)<br>
* bits [7:0] API implemention week.<br>
* Example: API specification version 4.0, implementation w46 2008 => 0x0400082E
*/
uint32_t api_version;
/** maximum block count which can be transferred at once */
uint32_t max_block_count;
/** maximum clock frequence in Hz supported by HW */
uint32_t max_clock_freq;
/** maximum data bus width supported by HW */
uint16_t max_data_width;
/** Is high-speed mode supported by HW (yes=1, no=0) */
uint8_t hs_mode_supported;
/** Is memory card removable (yes=1, no=0) */
uint8_t card_removable;
} HAL_MEMCARD_HW_CONF;
/** @brief Configuration structure to HAL layer.
*/
typedef struct {
/** how many times to try after fail, for instance sending command */
uint32_t retries_after_fail;
} HAL_MEMCARD_INIT_CONF;
/* ********************** DECLARATION OF EXTERNAL DATA ********************* */
/* ************************** FUNCTION PROTOTYPES ************************** */
/* ********************************* CODE ********************************** */
#endif /* __EMMC_HAL_H__ */
/* ******************************** END ************************************ */

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/*
* Copyright (c) 2015-2018, Renesas Electronics Corporation. All rights reserved.
*
* SPDX-License-Identifier: BSD-3-Clause
*/
#include <stddef.h>
#include <mmio.h>
#include "emmc_config.h"
#include "emmc_hal.h"
#include "emmc_std.h"
#include "emmc_registers.h"
#include "emmc_def.h"
#include "rcar_private.h"
st_mmc_base mmc_drv_obj;
EMMC_ERROR_CODE rcar_emmc_memcard_power(uint8_t mode)
{
if (mode == TRUE) {
/* power on (Vcc&Vccq is always power on) */
mmc_drv_obj.card_power_enable = TRUE;
} else {
/* power off (Vcc&Vccq is always power on) */
mmc_drv_obj.card_power_enable = FALSE;
mmc_drv_obj.mount = FALSE;
mmc_drv_obj.selected = FALSE;
}
return EMMC_SUCCESS;
}
static __inline void emmc_set_retry_count(uint32_t retry)
{
mmc_drv_obj.retries_after_fail = retry;
}
static __inline void emmc_set_data_timeout(uint32_t data_timeout)
{
mmc_drv_obj.data_timeout = data_timeout;
}
static void emmc_memset(uint8_t *buff, uint8_t data, uint32_t cnt)
{
if (buff == NULL) {
return;
}
while (cnt > 0) {
*buff++ = data;
cnt--;
}
}
static void emmc_driver_config(void)
{
emmc_set_retry_count(EMMC_RETRY_COUNT);
emmc_set_data_timeout(EMMC_RW_DATA_TIMEOUT);
}
static void emmc_drv_init(void)
{
emmc_memset((uint8_t *) (&mmc_drv_obj), 0, sizeof(st_mmc_base));
mmc_drv_obj.card_present = HAL_MEMCARD_CARD_IS_IN;
mmc_drv_obj.data_timeout = EMMC_RW_DATA_TIMEOUT;
mmc_drv_obj.bus_width = HAL_MEMCARD_DATA_WIDTH_1_BIT;
}
static EMMC_ERROR_CODE emmc_dev_finalize(void)
{
EMMC_ERROR_CODE result;
uint32_t dataL;
/* MMC power off
* the power supply of eMMC device is always turning on.
* RST_n : Hi --> Low level.
*/
result = rcar_emmc_memcard_power(FALSE);
/* host controller reset */
SETR_32(SD_INFO1, 0x00000000U); /* all interrupt clear */
SETR_32(SD_INFO2, SD_INFO2_CLEAR); /* all interrupt clear */
SETR_32(SD_INFO1_MASK, 0x00000000U); /* all interrupt disable */
SETR_32(SD_INFO2_MASK, SD_INFO2_CLEAR); /* all interrupt disable */
SETR_32(SD_CLK_CTRL, 0x00000000U); /* MMC clock stop */
dataL = mmio_read_32(CPG_SMSTPCR3);
if ((dataL & CPG_MSTP_MMC) == 0U) {
dataL |= (CPG_MSTP_MMC);
mmio_write_32(CPG_CPGWPR, (~dataL));
mmio_write_32(CPG_SMSTPCR3, dataL);
}
return result;
}
static EMMC_ERROR_CODE emmc_dev_init(void)
{
/* Enable clock supply to eMMC. */
mstpcr_write(CPG_SMSTPCR3, CPG_MSTPSR3, CPG_MSTP_MMC);
/* Set SD clock */
mmio_write_32(CPG_CPGWPR, ~((uint32_t) (BIT9 | BIT0))); /* SD phy 200MHz */
/* Stop SDnH clock & SDn=200MHz */
mmio_write_32(CPG_SDxCKCR, (BIT9 | BIT0));
/* MMCIF initialize */
SETR_32(SD_INFO1, 0x00000000U); /* all interrupt clear */
SETR_32(SD_INFO2, SD_INFO2_CLEAR); /* all interrupt clear */
SETR_32(SD_INFO1_MASK, 0x00000000U); /* all interrupt disable */
SETR_32(SD_INFO2_MASK, SD_INFO2_CLEAR); /* all interrupt disable */
SETR_32(HOST_MODE, 0x00000000U); /* SD_BUF access width = 64-bit */
SETR_32(SD_OPTION, 0x0000C0EEU); /* Bus width = 1bit, timeout=MAX */
SETR_32(SD_CLK_CTRL, 0x00000000U); /* Automatic Control=Disable, Clock Output=Disable */
return EMMC_SUCCESS;
}
static EMMC_ERROR_CODE emmc_reset_controller(void)
{
EMMC_ERROR_CODE retult;
/* initialize mmc driver */
emmc_drv_init();
/* initialize H/W */
retult = emmc_dev_init();
if (EMMC_SUCCESS != retult) {
return retult;
}
mmc_drv_obj.initialize = TRUE;
return retult;
}
EMMC_ERROR_CODE emmc_terminate(void)
{
EMMC_ERROR_CODE result;
result = emmc_dev_finalize();
emmc_memset((uint8_t *) (&mmc_drv_obj), 0, sizeof(st_mmc_base));
return result;
}
EMMC_ERROR_CODE rcar_emmc_init(void)
{
EMMC_ERROR_CODE retult;
retult = emmc_reset_controller();
if (EMMC_SUCCESS != retult) {
return retult;
}
emmc_driver_config();
return EMMC_SUCCESS;
}

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/*
* Copyright (c) 2015-2018, Renesas Electronics Corporation. All rights
* reserved.
*
* SPDX-License-Identifier: BSD-3-Clause
*/
#include "emmc_config.h"
#include "emmc_def.h"
#include "emmc_hal.h"
#include "emmc_registers.h"
#include "emmc_std.h"
#include "rcar_def.h"
#include <mmio.h>
#include <stddef.h>
static EMMC_ERROR_CODE emmc_trans_sector(uint32_t *buff_address_virtual);
uint32_t emmc_interrupt(void)
{
EMMC_ERROR_CODE result;
uint32_t prr_data;
uint32_t cut_ver;
uint32_t end_bit;
prr_data = mmio_read_32((uintptr_t) RCAR_PRR);
cut_ver = prr_data & RCAR_CUT_MASK;
if ((prr_data & RCAR_PRODUCT_MASK) == RCAR_PRODUCT_H3) {
if (cut_ver == RCAR_CUT_VER10) {
end_bit = BIT17;
} else if (cut_ver == RCAR_CUT_VER11) {
end_bit = BIT17;
} else {
end_bit = BIT20;
}
} else if ((prr_data & RCAR_PRODUCT_MASK) == RCAR_PRODUCT_M3) {
if (cut_ver == RCAR_CUT_VER10) {
end_bit = BIT17;
} else {
end_bit = BIT20;
}
} else {
end_bit = BIT20;
}
/* SD_INFO */
mmc_drv_obj.error_info.info1 = GETR_32(SD_INFO1);
mmc_drv_obj.error_info.info2 = GETR_32(SD_INFO2);
/* SD_INFO EVENT */
mmc_drv_obj.int_event1 =
mmc_drv_obj.error_info.info1 & GETR_32(SD_INFO1_MASK);
mmc_drv_obj.int_event2 =
mmc_drv_obj.error_info.info2 & GETR_32(SD_INFO2_MASK);
/* ERR_STS */
mmc_drv_obj.error_info.status1 = GETR_32(SD_ERR_STS1);
mmc_drv_obj.error_info.status2 = GETR_32(SD_ERR_STS2);
/* DM_CM_INFO */
mmc_drv_obj.error_info.dm_info1 = GETR_32(DM_CM_INFO1);
mmc_drv_obj.error_info.dm_info2 = GETR_32(DM_CM_INFO2);
/* DM_CM_INFO EVENT */
mmc_drv_obj.dm_event1 =
mmc_drv_obj.error_info.dm_info1 & GETR_32(DM_CM_INFO1_MASK);
mmc_drv_obj.dm_event2 =
mmc_drv_obj.error_info.dm_info2 & GETR_32(DM_CM_INFO2_MASK);
/* ERR SD_INFO2 */
if ((SD_INFO2_ALL_ERR & mmc_drv_obj.int_event2) != 0) {
SETR_32(SD_INFO1_MASK, 0x00000000U); /* interrupt disable */
SETR_32(SD_INFO2_MASK, SD_INFO2_CLEAR); /* interrupt disable */
SETR_32(SD_INFO1, 0x00000000U); /* interrupt clear */
SETR_32(SD_INFO2, SD_INFO2_CLEAR); /* interrupt clear */
mmc_drv_obj.state_machine_blocking = FALSE;
}
/* PIO Transfer */
/* BWE/BRE */
else if (((SD_INFO2_BWE | SD_INFO2_BRE) & mmc_drv_obj.int_event2)) {
/* BWE */
if (SD_INFO2_BWE & mmc_drv_obj.int_event2) {
SETR_32(SD_INFO2, (GETR_32(SD_INFO2) & ~SD_INFO2_BWE));
}
/* BRE */
else {
SETR_32(SD_INFO2, (GETR_32(SD_INFO2) & ~SD_INFO2_BRE));
}
result = emmc_trans_sector(mmc_drv_obj.buff_address_virtual);
mmc_drv_obj.buff_address_virtual += EMMC_BLOCK_LENGTH;
mmc_drv_obj.remain_size -= EMMC_BLOCK_LENGTH;
if (result != EMMC_SUCCESS) {
/* data transfer error */
emmc_write_error_info(EMMC_FUNCNO_NONE, result);
/* Panic */
SETR_32(SD_INFO1_MASK, 0x00000000U);
SETR_32(SD_INFO2_MASK, SD_INFO2_CLEAR);
SETR_32(SD_INFO1, 0x00000000U);
/* interrupt clear */
SETR_32(SD_INFO2, SD_INFO2_CLEAR);
mmc_drv_obj.force_terminate = TRUE;
} else {
mmc_drv_obj.during_transfer = FALSE;
}
mmc_drv_obj.state_machine_blocking = FALSE;
}
/* DMA_TRANSFER */
/* DM_CM_INFO1: DMA-ch0 transfer complete or error occurred */
else if ((BIT16 & mmc_drv_obj.dm_event1) != 0) {
SETR_32(DM_CM_INFO1, 0x00000000U);
SETR_32(DM_CM_INFO2, 0x00000000U);
/* interrupt clear */
SETR_32(SD_INFO2, (GETR_32(SD_INFO2) & ~SD_INFO2_BWE));
/* DM_CM_INFO2: DMA-ch0 error occured */
if ((BIT16 & mmc_drv_obj.dm_event2) != 0) {
mmc_drv_obj.dma_error_flag = TRUE;
} else {
mmc_drv_obj.during_dma_transfer = FALSE;
mmc_drv_obj.during_transfer = FALSE;
}
/* wait next interrupt */
mmc_drv_obj.state_machine_blocking = FALSE;
}
/* DM_CM_INFO1: DMA-ch1 transfer complete or error occured */
else if ((end_bit & mmc_drv_obj.dm_event1) != 0U) {
SETR_32(DM_CM_INFO1, 0x00000000U);
SETR_32(DM_CM_INFO2, 0x00000000U);
/* interrupt clear */
SETR_32(SD_INFO2, (GETR_32(SD_INFO2) & ~SD_INFO2_BRE));
/* DM_CM_INFO2: DMA-ch1 error occured */
if ((BIT17 & mmc_drv_obj.dm_event2) != 0) {
mmc_drv_obj.dma_error_flag = TRUE;
} else {
mmc_drv_obj.during_dma_transfer = FALSE;
mmc_drv_obj.during_transfer = FALSE;
}
/* wait next interrupt */
mmc_drv_obj.state_machine_blocking = FALSE;
}
/* Response end */
else if ((SD_INFO1_INFO0 & mmc_drv_obj.int_event1) != 0) {
/* interrupt clear */
SETR_32(SD_INFO1, (GETR_32(SD_INFO1) & ~SD_INFO1_INFO0));
mmc_drv_obj.state_machine_blocking = FALSE;
}
/* Access end */
else if ((SD_INFO1_INFO2 & mmc_drv_obj.int_event1) != 0) {
/* interrupt clear */
SETR_32(SD_INFO1, (GETR_32(SD_INFO1) & ~SD_INFO1_INFO2));
mmc_drv_obj.state_machine_blocking = FALSE;
} else {
/* nothing to do. */
}
return (uint32_t) 0;
}
static EMMC_ERROR_CODE emmc_trans_sector(uint32_t *buff_address_virtual)
{
uint32_t length, i;
uint64_t *bufPtrLL;
if (buff_address_virtual == NULL) {
return EMMC_ERR_PARAM;
}
if ((mmc_drv_obj.during_transfer != TRUE)
|| (mmc_drv_obj.remain_size == 0)) {
return EMMC_ERR_STATE;
}
bufPtrLL = (uint64_t *) buff_address_virtual;
length = mmc_drv_obj.remain_size;
/* data transefer */
for (i = 0; i < (length >> 3); i++) {
/* Write */
if (mmc_drv_obj.cmd_info.dir == HAL_MEMCARD_WRITE) {
SETR_64(SD_BUF0, *bufPtrLL); /* buffer --> FIFO */
}
/* Read */
else {
/* Checks when the read data reaches SD_SIZE. */
/* The BRE bit is cleared at emmc_interrupt function. */
if (((i %
(uint32_t) (EMMC_BLOCK_LENGTH >>
EMMC_BUF_SIZE_SHIFT)) == 0U)
&& (i != 0U)) {
/* BRE check */
while (((GETR_32(SD_INFO2)) & SD_INFO2_BRE) ==
0U) {
/* ERROR check */
if (((GETR_32(SD_INFO2)) &
SD_INFO2_ALL_ERR) != 0U) {
return EMMC_ERR_TRANSFER;
}
}
/* BRE clear */
SETR_32(SD_INFO2,
(uint32_t) (GETR_32(SD_INFO2) &
~SD_INFO2_BRE));
}
*bufPtrLL = GETR_64(SD_BUF0); /* FIFO --> buffer */
}
bufPtrLL++;
}
return EMMC_SUCCESS;
}

680
drivers/renesas/rcar/emmc/emmc_mount.c Normal file
View File

@ -0,0 +1,680 @@
/*
* Copyright (c) 2015-2017, Renesas Electronics Corporation. All rights reserved.
*
* SPDX-License-Identifier: BSD-3-Clause
*/
#include <debug.h>
#include <mmio.h>
#include "emmc_config.h"
#include "emmc_hal.h"
#include "emmc_std.h"
#include "emmc_registers.h"
#include "emmc_def.h"
#include "micro_delay.h"
#include "rcar_def.h"
static EMMC_ERROR_CODE emmc_clock_ctrl(uint8_t mode);
static EMMC_ERROR_CODE emmc_card_init(void);
static EMMC_ERROR_CODE emmc_high_speed(void);
static EMMC_ERROR_CODE emmc_bus_width(uint32_t width);
static uint32_t emmc_set_timeout_register_value(uint32_t freq);
static void set_sd_clk(uint32_t clkDiv);
static uint32_t emmc_calc_tran_speed(uint32_t *freq);
static void emmc_get_partition_access(void);
static void emmc_set_bootpartition(void);
static void emmc_set_bootpartition(void)
{
uint32_t reg;
reg = mmio_read_32(RCAR_PRR) & (RCAR_PRODUCT_MASK | RCAR_CUT_MASK);
if (reg == RCAR_PRODUCT_M3_CUT10) {
mmc_drv_obj.boot_partition_en =
(EMMC_PARTITION_ID) ((mmc_drv_obj.ext_csd_data[179] &
EMMC_BOOT_PARTITION_EN_MASK) >>
EMMC_BOOT_PARTITION_EN_SHIFT);
} else if ((reg == RCAR_PRODUCT_H3_CUT20)
|| (reg == RCAR_PRODUCT_M3_CUT11)) {
mmc_drv_obj.boot_partition_en = mmc_drv_obj.partition_access;
} else {
if ((mmio_read_32(MFISBTSTSR) & MFISBTSTSR_BOOT_PARTITION) !=
0U) {
mmc_drv_obj.boot_partition_en = PARTITION_ID_BOOT_2;
} else {
mmc_drv_obj.boot_partition_en = PARTITION_ID_BOOT_1;
}
}
}
static EMMC_ERROR_CODE emmc_card_init(void)
{
int32_t retry;
uint32_t freq = MMC_400KHZ; /* 390KHz */
EMMC_ERROR_CODE result;
uint32_t resultCalc;
/* state check */
if ((mmc_drv_obj.initialize != TRUE)
|| (mmc_drv_obj.card_power_enable != TRUE)
|| ((GETR_32(SD_INFO2) & SD_INFO2_CBSY) != 0)
) {
emmc_write_error_info(EMMC_FUNCNO_CARD_INIT, EMMC_ERR_STATE);
return EMMC_ERR_STATE;
}
/* clock on (force change) */
mmc_drv_obj.current_freq = 0;
mmc_drv_obj.max_freq = MMC_20MHZ;
result = emmc_set_request_mmc_clock(&freq);
if (result != EMMC_SUCCESS) {
emmc_write_error_info_func_no(EMMC_FUNCNO_CARD_INIT);
return EMMC_ERR;
}
rcar_micro_delay(1000U); /* wait 1ms */
/* Get current access partition */
emmc_get_partition_access();
/* CMD0, arg=0x00000000 */
result = emmc_send_idle_cmd(0x00000000);
if (result != EMMC_SUCCESS) {
emmc_write_error_info_func_no(EMMC_FUNCNO_CARD_INIT);
return result;
}
rcar_micro_delay(200U); /* wait 74clock 390kHz(189.74us) */
/* CMD1 */
emmc_make_nontrans_cmd(CMD1_SEND_OP_COND, EMMC_HOST_OCR_VALUE);
for (retry = 300; retry > 0; retry--) {
result =
emmc_exec_cmd(EMMC_R1_ERROR_MASK, mmc_drv_obj.response);
if (result != EMMC_SUCCESS) {
emmc_write_error_info_func_no(EMMC_FUNCNO_CARD_INIT);
return result;
}
if ((mmc_drv_obj.r3_ocr & EMMC_OCR_STATUS_BIT) != 0) {
break; /* card is ready. exit loop */
}
rcar_micro_delay(1000U); /* wait 1ms */
}
if (retry == 0) {
emmc_write_error_info(EMMC_FUNCNO_CARD_INIT, EMMC_ERR_TIMEOUT);
return EMMC_ERR_TIMEOUT;
}
switch (mmc_drv_obj.r3_ocr & EMMC_OCR_ACCESS_MODE_MASK) {
case EMMC_OCR_ACCESS_MODE_SECT:
mmc_drv_obj.access_mode = TRUE; /* sector mode */
break;
default:
/* unknown value */
emmc_write_error_info(EMMC_FUNCNO_CARD_INIT, EMMC_ERR);
return EMMC_ERR;
}
/* CMD2 */
emmc_make_nontrans_cmd(CMD2_ALL_SEND_CID_MMC, 0x00000000);
mmc_drv_obj.response = (uint32_t *) (&mmc_drv_obj.cid_data[0]); /* use CID special buffer */
result = emmc_exec_cmd(EMMC_R1_ERROR_MASK, mmc_drv_obj.response);
if (result != EMMC_SUCCESS) {
emmc_write_error_info_func_no(EMMC_FUNCNO_CARD_INIT);
return result;
}
/* CMD3 */
emmc_make_nontrans_cmd(CMD3_SET_RELATIVE_ADDR, EMMC_RCA << 16);
result = emmc_exec_cmd(EMMC_R1_ERROR_MASK, mmc_drv_obj.response);
if (result != EMMC_SUCCESS) {
emmc_write_error_info_func_no(EMMC_FUNCNO_CARD_INIT);
return result;
}
/* CMD9 (CSD) */
emmc_make_nontrans_cmd(CMD9_SEND_CSD, EMMC_RCA << 16);
mmc_drv_obj.response = (uint32_t *) (&mmc_drv_obj.csd_data[0]); /* use CSD special buffer */
result = emmc_exec_cmd(EMMC_R1_ERROR_MASK, mmc_drv_obj.response);
if (result != EMMC_SUCCESS) {
emmc_write_error_info_func_no(EMMC_FUNCNO_CARD_INIT);
return result;
}
/* card version check */
if (EMMC_CSD_SPEC_VARS() < 4) {
emmc_write_error_info(EMMC_FUNCNO_CARD_INIT,
EMMC_ERR_ILLEGAL_CARD);
return EMMC_ERR_ILLEGAL_CARD;
}
/* CMD7 (select card) */
emmc_make_nontrans_cmd(CMD7_SELECT_CARD, EMMC_RCA << 16);
result = emmc_exec_cmd(EMMC_R1_ERROR_MASK, mmc_drv_obj.response);
if (result != EMMC_SUCCESS) {
emmc_write_error_info_func_no(EMMC_FUNCNO_CARD_INIT);
return result;
}
mmc_drv_obj.selected = TRUE;
/* card speed check */
resultCalc = emmc_calc_tran_speed(&freq); /* Card spec is calculated from TRAN_SPEED(CSD). */
if (resultCalc == 0) {
emmc_write_error_info(EMMC_FUNCNO_CARD_INIT,
EMMC_ERR_ILLEGAL_CARD);
return EMMC_ERR_ILLEGAL_CARD;
}
mmc_drv_obj.max_freq = freq; /* max frequency (card spec) */
result = emmc_set_request_mmc_clock(&freq);
if (result != EMMC_SUCCESS) {
emmc_write_error_info_func_no(EMMC_FUNCNO_CARD_INIT);
return EMMC_ERR;
}
/* set read/write timeout */
mmc_drv_obj.data_timeout = emmc_set_timeout_register_value(freq);
SETR_32(SD_OPTION,
((GETR_32(SD_OPTION) & ~(SD_OPTION_TIMEOUT_CNT_MASK)) |
mmc_drv_obj.data_timeout));
/* SET_BLOCKLEN(512byte) */
/* CMD16 */
emmc_make_nontrans_cmd(CMD16_SET_BLOCKLEN, EMMC_BLOCK_LENGTH);
result = emmc_exec_cmd(EMMC_R1_ERROR_MASK, mmc_drv_obj.response);
if (result != EMMC_SUCCESS) {
emmc_write_error_info_func_no(EMMC_FUNCNO_CARD_INIT);
return result;
}
/* Transfer Data Length */
SETR_32(SD_SIZE, EMMC_BLOCK_LENGTH);
/* CMD8 (EXT_CSD) */
emmc_make_trans_cmd(CMD8_SEND_EXT_CSD, 0x00000000,
(uint32_t *) (&mmc_drv_obj.ext_csd_data[0]),
EMMC_MAX_EXT_CSD_LENGTH, HAL_MEMCARD_READ,
HAL_MEMCARD_NOT_DMA);
result = emmc_exec_cmd(EMMC_R1_ERROR_MASK, mmc_drv_obj.response);
if (result != EMMC_SUCCESS) {
/* CMD12 is not send.
* If BUS initialization is failed, user must be execute Bus initialization again.
* Bus initialization is start CMD0(soft reset command).
*/
emmc_write_error_info_func_no(EMMC_FUNCNO_CARD_INIT);
return result;
}
/* Set boot partition */
emmc_set_bootpartition();
return EMMC_SUCCESS;
}
static EMMC_ERROR_CODE emmc_high_speed(void)
{
uint32_t freq; /**< High speed mode clock frequency */
EMMC_ERROR_CODE result;
uint8_t cardType;
/* state check */
if (mmc_drv_obj.selected != TRUE) {
emmc_write_error_info(EMMC_FUNCNO_HIGH_SPEED, EMMC_ERR_STATE);
return EMMC_ERR_STATE;
}
/* max frequency */
cardType = (uint8_t) mmc_drv_obj.ext_csd_data[EMMC_EXT_CSD_CARD_TYPE];
if ((cardType & EMMC_EXT_CSD_CARD_TYPE_52MHZ) != 0)
freq = MMC_52MHZ;
else if ((cardType & EMMC_EXT_CSD_CARD_TYPE_26MHZ) != 0)
freq = MMC_26MHZ;
else
freq = MMC_20MHZ;
/* Hi-Speed-mode selction */
if ((MMC_52MHZ == freq) || (MMC_26MHZ == freq)) {
/* CMD6 */
emmc_make_nontrans_cmd(CMD6_SWITCH, EMMC_SWITCH_HS_TIMING);
result =
emmc_exec_cmd(EMMC_R1_ERROR_MASK, mmc_drv_obj.response);
if (result != EMMC_SUCCESS) {
emmc_write_error_info_func_no(EMMC_FUNCNO_HIGH_SPEED);
return result;
}
mmc_drv_obj.hs_timing = TIMING_HIGH_SPEED; /* High-Speed */
}
/* set mmc clock */
mmc_drv_obj.max_freq = freq;
result = emmc_set_request_mmc_clock(&freq);
if (result != EMMC_SUCCESS) {
emmc_write_error_info_func_no(EMMC_FUNCNO_HIGH_SPEED);
return EMMC_ERR;
}
/* set read/write timeout */
mmc_drv_obj.data_timeout = emmc_set_timeout_register_value(freq);
SETR_32(SD_OPTION,
((GETR_32(SD_OPTION) & ~(SD_OPTION_TIMEOUT_CNT_MASK)) |
mmc_drv_obj.data_timeout));
/* CMD13 */
emmc_make_nontrans_cmd(CMD13_SEND_STATUS, EMMC_RCA << 16);
result =
emmc_exec_cmd(EMMC_R1_ERROR_MASK_WITHOUT_CRC, mmc_drv_obj.response);
if (result != EMMC_SUCCESS) {
emmc_write_error_info_func_no(EMMC_FUNCNO_HIGH_SPEED);
return result;
}
return EMMC_SUCCESS;
}
static EMMC_ERROR_CODE emmc_clock_ctrl(uint8_t mode)
{
uint32_t value;
/* busy check */
if ((GETR_32(SD_INFO2) & SD_INFO2_CBSY) != 0) {
emmc_write_error_info(EMMC_FUNCNO_SET_CLOCK,
EMMC_ERR_CARD_BUSY);
return EMMC_ERR;
}
if (mode == TRUE) {
/* clock ON */
value =
((GETR_32(SD_CLK_CTRL) | MMC_SD_CLK_START) &
SD_CLK_WRITE_MASK);
SETR_32(SD_CLK_CTRL, value); /* on */
mmc_drv_obj.clock_enable = TRUE;
} else {
/* clock OFF */
value =
((GETR_32(SD_CLK_CTRL) & MMC_SD_CLK_STOP) &
SD_CLK_WRITE_MASK);
SETR_32(SD_CLK_CTRL, value); /* off */
mmc_drv_obj.clock_enable = FALSE;
}
return EMMC_SUCCESS;
}
static EMMC_ERROR_CODE emmc_bus_width(uint32_t width)
{
EMMC_ERROR_CODE result = EMMC_ERR;
/* parameter check */
if ((width != 8) && (width != 4) && (width != 1)) {
emmc_write_error_info(EMMC_FUNCNO_BUS_WIDTH, EMMC_ERR_PARAM);
return EMMC_ERR_PARAM;
}
/* state check */
if (mmc_drv_obj.selected != TRUE) {
emmc_write_error_info(EMMC_FUNCNO_BUS_WIDTH, EMMC_ERR_STATE);
return EMMC_ERR_STATE;
}
mmc_drv_obj.bus_width = (HAL_MEMCARD_DATA_WIDTH) (width >> 2); /* 2 = 8bit, 1 = 4bit, 0 =1bit */
/* CMD6 */
emmc_make_nontrans_cmd(CMD6_SWITCH,
(EMMC_SWITCH_BUS_WIDTH_1 |
(mmc_drv_obj.bus_width << 8)));
result = emmc_exec_cmd(EMMC_R1_ERROR_MASK, mmc_drv_obj.response);
if (result != EMMC_SUCCESS) {
/* occurred error */
mmc_drv_obj.bus_width = HAL_MEMCARD_DATA_WIDTH_1_BIT;
goto EXIT;
}
switch (mmc_drv_obj.bus_width) {
case HAL_MEMCARD_DATA_WIDTH_1_BIT:
SETR_32(SD_OPTION,
((GETR_32(SD_OPTION) & ~(BIT15 | BIT13)) | BIT15));
break;
case HAL_MEMCARD_DATA_WIDTH_4_BIT:
SETR_32(SD_OPTION, (GETR_32(SD_OPTION) & ~(BIT15 | BIT13)));
break;
case HAL_MEMCARD_DATA_WIDTH_8_BIT:
SETR_32(SD_OPTION,
((GETR_32(SD_OPTION) & ~(BIT15 | BIT13)) | BIT13));
break;
default:
goto EXIT;
}
/* CMD13 */
emmc_make_nontrans_cmd(CMD13_SEND_STATUS, EMMC_RCA << 16);
result = emmc_exec_cmd(EMMC_R1_ERROR_MASK, mmc_drv_obj.response);
if (result != EMMC_SUCCESS) {
goto EXIT;
}
/* CMD8 (EXT_CSD) */
emmc_make_trans_cmd(CMD8_SEND_EXT_CSD, 0x00000000,
(uint32_t *) (&mmc_drv_obj.ext_csd_data[0]),
EMMC_MAX_EXT_CSD_LENGTH, HAL_MEMCARD_READ,
HAL_MEMCARD_NOT_DMA);
result = emmc_exec_cmd(EMMC_R1_ERROR_MASK, mmc_drv_obj.response);
if (result != EMMC_SUCCESS) {
goto EXIT;
}
return EMMC_SUCCESS;
EXIT:
emmc_write_error_info(EMMC_FUNCNO_BUS_WIDTH, result);
ERROR("BL2: emmc bus_width error end\n");
return result;
}
EMMC_ERROR_CODE emmc_select_partition(EMMC_PARTITION_ID id)
{
EMMC_ERROR_CODE result;
uint32_t arg;
uint32_t partition_config;
/* state check */
if (mmc_drv_obj.mount != TRUE) {
emmc_write_error_info(EMMC_FUNCNO_NONE, EMMC_ERR_STATE);
return EMMC_ERR_STATE;
}
/* id = PARTITION_ACCESS(Bit[2:0]) */
if ((id & ~PARTITION_ID_MASK) != 0) {
emmc_write_error_info(EMMC_FUNCNO_NONE, EMMC_ERR_PARAM);
return EMMC_ERR_PARAM;
}
/* EXT_CSD[179] value */
partition_config =
(uint32_t) mmc_drv_obj.ext_csd_data[EMMC_EXT_CSD_PARTITION_CONFIG];
if ((partition_config & PARTITION_ID_MASK) == id) {
result = EMMC_SUCCESS;
} else {
partition_config =
(uint32_t) ((partition_config & ~PARTITION_ID_MASK) | id);
arg = EMMC_SWITCH_PARTITION_CONFIG | (partition_config << 8);
result = emmc_set_ext_csd(arg);
}
return result;
}
static void set_sd_clk(uint32_t clkDiv)
{
uint32_t dataL;
dataL = (GETR_32(SD_CLK_CTRL) & (~SD_CLK_CTRL_CLKDIV_MASK));
switch (clkDiv) {
case 1:
dataL |= 0x000000FFU;
break; /* 1/1 */
case 2:
dataL |= 0x00000000U;
break; /* 1/2 */
case 4:
dataL |= 0x00000001U;
break; /* 1/4 */
case 8:
dataL |= 0x00000002U;
break; /* 1/8 */
case 16:
dataL |= 0x00000004U;
break; /* 1/16 */
case 32:
dataL |= 0x00000008U;
break; /* 1/32 */
case 64:
dataL |= 0x00000010U;
break; /* 1/64 */
case 128:
dataL |= 0x00000020U;
break; /* 1/128 */
case 256:
dataL |= 0x00000040U;
break; /* 1/256 */
case 512:
dataL |= 0x00000080U;
break; /* 1/512 */
}
SETR_32(SD_CLK_CTRL, dataL);
mmc_drv_obj.current_freq = (uint32_t) clkDiv;
}
static void emmc_get_partition_access(void)
{
uint32_t reg;
EMMC_ERROR_CODE result;
reg = mmio_read_32(RCAR_PRR) & (RCAR_PRODUCT_MASK | RCAR_CUT_MASK);
if ((reg == RCAR_PRODUCT_H3_CUT20) || (reg == RCAR_PRODUCT_M3_CUT11)) {
SETR_32(SD_OPTION, 0x000060EEU); /* 8 bits width */
/* CMD8 (EXT_CSD) */
emmc_make_trans_cmd(CMD8_SEND_EXT_CSD, 0x00000000U,
(uint32_t *) (&mmc_drv_obj.ext_csd_data[0]),
EMMC_MAX_EXT_CSD_LENGTH,
HAL_MEMCARD_READ, HAL_MEMCARD_NOT_DMA);
mmc_drv_obj.get_partition_access_flag = TRUE;
result =
emmc_exec_cmd(EMMC_R1_ERROR_MASK, mmc_drv_obj.response);
mmc_drv_obj.get_partition_access_flag = FALSE;
if (result == EMMC_SUCCESS) {
mmc_drv_obj.partition_access =
(EMMC_PARTITION_ID) (mmc_drv_obj.ext_csd_data[179]
& PARTITION_ID_MASK);
} else if (result == EMMC_ERR_CMD_TIMEOUT) {
mmc_drv_obj.partition_access = PARTITION_ID_BOOT_1;
} else {
emmc_write_error_info(EMMC_FUNCNO_GET_PERTITION_ACCESS,
result);
panic();
}
SETR_32(SD_OPTION, 0x0000C0EEU); /* Initialize */
}
}
static uint32_t emmc_calc_tran_speed(uint32_t *freq)
{
const uint32_t unit[8] = { 10000, 100000, 1000000, 10000000,
0, 0, 0, 0 }; /**< frequency unit (1/10) */
const uint32_t mult[16] = { 0, 10, 12, 13, 15, 20, 26, 30, 35, 40, 45,
52, 55, 60, 70, 80 };
uint32_t maxFreq;
uint32_t result;
uint32_t tran_speed = EMMC_CSD_TRAN_SPEED();
/* tran_speed = 0x32
* unit[tran_speed&0x7] = uint[0x2] = 1000000
* mult[(tran_speed&0x78)>>3] = mult[0x30>>3] = mult[6] = 26
* 1000000 * 26 = 26000000 (26MHz)
*/
result = 1;
maxFreq =
unit[tran_speed & EMMC_TRANSPEED_FREQ_UNIT_MASK] *
mult[(tran_speed & EMMC_TRANSPEED_MULT_MASK) >>
EMMC_TRANSPEED_MULT_SHIFT];
if (maxFreq == 0) {
result = 0;
} else if (MMC_FREQ_52MHZ <= maxFreq)
*freq = MMC_52MHZ;
else if (MMC_FREQ_26MHZ <= maxFreq)
*freq = MMC_26MHZ;
else if (MMC_FREQ_20MHZ <= maxFreq)
*freq = MMC_20MHZ;
else
*freq = MMC_400KHZ;
return result;
}
static uint32_t emmc_set_timeout_register_value(uint32_t freq)
{
uint32_t timeoutCnt; /* SD_OPTION - Timeout Counter */
switch (freq) {
case 1U:
timeoutCnt = 0xE0U;
break; /* SDCLK * 2^27 */
case 2U:
timeoutCnt = 0xE0U;
break; /* SDCLK * 2^27 */
case 4U:
timeoutCnt = 0xD0U;
break; /* SDCLK * 2^26 */
case 8U:
timeoutCnt = 0xC0U;
break; /* SDCLK * 2^25 */
case 16U:
timeoutCnt = 0xB0U;
break; /* SDCLK * 2^24 */
case 32U:
timeoutCnt = 0xA0U;
break; /* SDCLK * 2^23 */
case 64U:
timeoutCnt = 0x90U;
break; /* SDCLK * 2^22 */
case 128U:
timeoutCnt = 0x80U;
break; /* SDCLK * 2^21 */
case 256U:
timeoutCnt = 0x70U;
break; /* SDCLK * 2^20 */
case 512U:
timeoutCnt = 0x70U;
break; /* SDCLK * 2^20 */
default:
timeoutCnt = 0xE0U;
break; /* SDCLK * 2^27 */
}
return timeoutCnt;
}
EMMC_ERROR_CODE emmc_set_ext_csd(uint32_t arg)
{
EMMC_ERROR_CODE result;
/* CMD6 */
emmc_make_nontrans_cmd(CMD6_SWITCH, arg);
result = emmc_exec_cmd(EMMC_R1_ERROR_MASK, mmc_drv_obj.response);
if (result != EMMC_SUCCESS) {
return result;
}
/* CMD13 */
emmc_make_nontrans_cmd(CMD13_SEND_STATUS, EMMC_RCA << 16);
result = emmc_exec_cmd(EMMC_R1_ERROR_MASK, mmc_drv_obj.response);
if (result != EMMC_SUCCESS) {
return result;
}
/* CMD8 (EXT_CSD) */
emmc_make_trans_cmd(CMD8_SEND_EXT_CSD, 0x00000000,
(uint32_t *) (&mmc_drv_obj.ext_csd_data[0]),
EMMC_MAX_EXT_CSD_LENGTH, HAL_MEMCARD_READ,
HAL_MEMCARD_NOT_DMA);
result = emmc_exec_cmd(EMMC_R1_ERROR_MASK, mmc_drv_obj.response);
if (result != EMMC_SUCCESS) {
return result;
}
return EMMC_SUCCESS;
}
EMMC_ERROR_CODE emmc_set_request_mmc_clock(uint32_t *freq)
{
/* parameter check */
if (freq == NULL) {
emmc_write_error_info(EMMC_FUNCNO_SET_CLOCK, EMMC_ERR_PARAM);
return EMMC_ERR_PARAM;
}
/* state check */
if ((mmc_drv_obj.initialize != TRUE)
|| (mmc_drv_obj.card_power_enable != TRUE)) {
emmc_write_error_info(EMMC_FUNCNO_SET_CLOCK, EMMC_ERR_STATE);
return EMMC_ERR_STATE;
}
/* clock is already running in the desired frequency. */
if ((mmc_drv_obj.clock_enable == TRUE)
&& (mmc_drv_obj.current_freq == *freq)) {
return EMMC_SUCCESS;
}
/* busy check */
if ((GETR_32(SD_INFO2) & SD_INFO2_CBSY) != 0) {
emmc_write_error_info(EMMC_FUNCNO_SET_CLOCK,
EMMC_ERR_CARD_BUSY);
return EMMC_ERR;
}
set_sd_clk(*freq);
mmc_drv_obj.clock_enable = FALSE;
return emmc_clock_ctrl(TRUE); /* clock on */
}
EMMC_ERROR_CODE rcar_emmc_mount(void)
{
EMMC_ERROR_CODE result;
/* state check */
if ((mmc_drv_obj.initialize != TRUE)
|| (mmc_drv_obj.card_power_enable != TRUE)
|| ((GETR_32(SD_INFO2) & SD_INFO2_CBSY) != 0)
) {
emmc_write_error_info(EMMC_FUNCNO_MOUNT, EMMC_ERR_STATE);
return EMMC_ERR_STATE;
}
/* initialize card (IDLE state --> Transfer state) */
result = emmc_card_init();
if (result != EMMC_SUCCESS) {
emmc_write_error_info_func_no(EMMC_FUNCNO_CARD_INIT);
if (emmc_clock_ctrl(FALSE) != EMMC_SUCCESS) {
/* nothing to do. */
}
return result;
}
/* Switching high speed mode */
result = emmc_high_speed();
if (result != EMMC_SUCCESS) {
emmc_write_error_info_func_no(EMMC_FUNCNO_HIGH_SPEED);
if (emmc_clock_ctrl(FALSE) != EMMC_SUCCESS) {
/* nothing to do. */
}
return result;
}
/* Changing the data bus width */
result = emmc_bus_width(8);
if (result != EMMC_SUCCESS) {
emmc_write_error_info_func_no(EMMC_FUNCNO_BUS_WIDTH);
if (emmc_clock_ctrl(FALSE) != EMMC_SUCCESS) {
/* nothing to do. */
}
return result;
}
/* mount complete */
mmc_drv_obj.mount = TRUE;
return EMMC_SUCCESS;
}

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/*
* Copyright (c) 2015-2017, Renesas Electronics Corporation. All rights reserved.
*
* SPDX-License-Identifier: BSD-3-Clause
*/
#include <arch_helpers.h>
#include "emmc_config.h"
#include "emmc_hal.h"
#include "emmc_std.h"
#include "emmc_registers.h"
#include "emmc_def.h"
#define MIN_EMMC(a, b) (((a) < (b)) ? (a) : (b))
#define EMMC_RW_SECTOR_COUNT_MAX 0x0000ffffU
static EMMC_ERROR_CODE emmc_multiple_block_read (uint32_t *buff_address_virtual,
uint32_t sector_number, uint32_t count,
HAL_MEMCARD_DATA_TRANSFER_MODE transfer_mode)
{
EMMC_ERROR_CODE result;
/* parameter check */
if ((count > EMMC_RW_SECTOR_COUNT_MAX)
|| (count == 0)
|| ((transfer_mode != HAL_MEMCARD_DMA)
&& (transfer_mode != HAL_MEMCARD_NOT_DMA))
) {
emmc_write_error_info(EMMC_FUNCNO_READ_SECTOR, EMMC_ERR_PARAM);
return EMMC_ERR_PARAM;
}
/* CMD23 */
emmc_make_nontrans_cmd(CMD23_SET_BLOCK_COUNT, count);
result = emmc_exec_cmd(EMMC_R1_ERROR_MASK, mmc_drv_obj.response);
if (result != EMMC_SUCCESS) {
return result;
}
SETR_32(SD_SECCNT, count);
SETR_32(SD_STOP, 0x00000100);
SETR_32(CC_EXT_MODE, (CC_EXT_MODE_CLEAR | CC_EXT_MODE_DMASDRW_ENABLE)); /* SD_BUF Read/Write DMA Transfer enable */
/* CMD18 */
emmc_make_trans_cmd(CMD18_READ_MULTIPLE_BLOCK, sector_number,
buff_address_virtual,
count << EMMC_SECTOR_SIZE_SHIFT, HAL_MEMCARD_READ,
transfer_mode);
result = emmc_exec_cmd(EMMC_R1_ERROR_MASK, mmc_drv_obj.response);
if (result != EMMC_SUCCESS) {
return result; /* CMD18 error code */
}
/* CMD13 */
emmc_make_nontrans_cmd(CMD13_SEND_STATUS, EMMC_RCA << 16);
result = emmc_exec_cmd(EMMC_R1_ERROR_MASK, mmc_drv_obj.response);
if (result != EMMC_SUCCESS) {
return result;
}
#if RCAR_BL2_DCACHE == 1
if (transfer_mode == HAL_MEMCARD_NOT_DMA) {
flush_dcache_range((uint64_t) buff_address_virtual,
((size_t) count << EMMC_SECTOR_SIZE_SHIFT));
}
#endif /* RCAR_BL2_DCACHE == 1 */
/* ready status check */
if ((mmc_drv_obj.r1_card_status & EMMC_R1_READY) == 0) {
emmc_write_error_info(EMMC_FUNCNO_READ_SECTOR,
EMMC_ERR_CARD_BUSY);
return EMMC_ERR_CARD_BUSY;
}
/* state check */
if (mmc_drv_obj.current_state != EMMC_R1_STATE_TRAN) {
emmc_write_error_info(EMMC_FUNCNO_READ_SECTOR,
EMMC_ERR_CARD_STATE);
return EMMC_ERR_CARD_STATE;
}
return EMMC_SUCCESS;
}
EMMC_ERROR_CODE emmc_read_sector(uint32_t *buff_address_virtual,
uint32_t sector_number,
uint32_t count, uint32_t feature_flags)
{
uint32_t trans_count;
uint32_t remain;
EMMC_ERROR_CODE result;
HAL_MEMCARD_DATA_TRANSFER_MODE transfer_mode;
/* parameter check */
if (count == 0) {
emmc_write_error_info(EMMC_FUNCNO_READ_SECTOR, EMMC_ERR_PARAM);
return EMMC_ERR_PARAM;
}
/* state check */
if (mmc_drv_obj.mount != TRUE) {
emmc_write_error_info(EMMC_FUNCNO_READ_SECTOR, EMMC_ERR_STATE);
return EMMC_ERR_STATE;
}
/* DMA? */
if ((feature_flags & LOADIMAGE_FLAGS_DMA_ENABLE) != 0) {
transfer_mode = HAL_MEMCARD_DMA;
} else {
transfer_mode = HAL_MEMCARD_NOT_DMA;
}
remain = count;
while (remain != 0) {
trans_count = MIN_EMMC(remain, EMMC_RW_SECTOR_COUNT_MAX);
result =
emmc_multiple_block_read(buff_address_virtual,
sector_number, trans_count,
transfer_mode);
if (result != EMMC_SUCCESS) {
return result;
}
buff_address_virtual += (EMMC_BLOCK_LENGTH_DW * trans_count);
sector_number += trans_count;
remain -= trans_count;
}
return EMMC_SUCCESS;
}

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/*
* Copyright (c) 2015-2018, Renesas Electronics Corporation. All rights reserved.
*
* SPDX-License-Identifier: BSD-3-Clause
*/
/**
* @file emmc_registers.h
* @brief emmc boot driver is expecting this header file. HS-MMC module header file.
*
*/
#ifndef __EMMC_REGISTERS_H__
#define __EMMC_REGISTERS_H__
/* ************************ HEADER (INCLUDE) SECTION *********************** */
/* ***************** MACROS, CONSTANTS, COMPILATION FLAGS ****************** */
/* MMC channel select */
#define MMC_CH0 (0U) /* SDHI2/MMC0 */
#define MMC_CH1 (1U) /* SDHI3/MMC1 */
#if RCAR_LSI == RCAR_E3
#define USE_MMC_CH (MMC_CH1) /* R-Car E3 */
#else /* RCAR_LSI == RCAR_E3 */
#define USE_MMC_CH (MMC_CH0) /* R-Car H3/M3/M3N */
#endif /* RCAR_LSI == RCAR_E3 */
#define BIT0 (0x00000001U)
#define BIT1 (0x00000002U)
#define BIT2 (0x00000004U)
#define BIT3 (0x00000008U)
#define BIT4 (0x00000010U)
#define BIT5 (0x00000020U)
#define BIT6 (0x00000040U)
#define BIT7 (0x00000080U)
#define BIT8 (0x00000100U)
#define BIT9 (0x00000200U)
#define BIT10 (0x00000400U)
#define BIT11 (0x00000800U)
#define BIT12 (0x00001000U)
#define BIT13 (0x00002000U)
#define BIT14 (0x00004000U)
#define BIT15 (0x00008000U)
#define BIT16 (0x00010000U)
#define BIT17 (0x00020000U)
#define BIT18 (0x00040000U)
#define BIT19 (0x00080000U)
#define BIT20 (0x00100000U)
#define BIT21 (0x00200000U)
#define BIT22 (0x00400000U)
#define BIT23 (0x00800000U)
#define BIT24 (0x01000000U)
#define BIT25 (0x02000000U)
#define BIT26 (0x04000000U)
#define BIT27 (0x08000000U)
#define BIT28 (0x10000000U)
#define BIT29 (0x20000000U)
#define BIT30 (0x40000000U)
#define BIT31 (0x80000000U)
/** @brief Clock Pulse Generator (CPG) registers
*/
#define CPG_BASE (0xE6150000U)
#define CPG_MSTPSR3 (CPG_BASE+0x0048U) /* Module stop status register 3 */
#define CPG_SMSTPCR3 (CPG_BASE+0x013CU) /* System module stop control register 3 */
#define CPG_SD2CKCR (CPG_BASE+0x0268U) /* SDHI2 clock frequency control register */
#define CPG_SD3CKCR (CPG_BASE+0x026CU) /* SDHI3 clock frequency control register */
#define CPG_CPGWPR (CPG_BASE+0x0900U) /* CPG Write Protect Register */
#if USE_MMC_CH == MMC_CH0
#define CPG_SDxCKCR (CPG_SD2CKCR) /* SDHI2/MMC0 */
#else /* USE_MMC_CH == MMC_CH0 */
#define CPG_SDxCKCR (CPG_SD3CKCR) /* SDHI3/MMC1 */
#endif /* USE_MMC_CH == MMC_CH0 */
/** Boot Status register
*/
#define MFISBTSTSR (0xE6260604U)
#define MFISBTSTSR_BOOT_PARTITION (0x00000010U)
/** brief eMMC registers
*/
#define MMC0_SD_BASE (0xEE140000U)
#define MMC1_SD_BASE (0xEE160000U)
#if USE_MMC_CH == MMC_CH0
#define MMC_SD_BASE (MMC0_SD_BASE)
#else /* USE_MMC_CH == MMC_CH0 */
#define MMC_SD_BASE (MMC1_SD_BASE)
#endif /* USE_MMC_CH == MMC_CH0 */
#define SD_CMD (MMC_SD_BASE + 0x0000U)
#define SD_PORTSEL (MMC_SD_BASE + 0x0008U)
#define SD_ARG (MMC_SD_BASE + 0x0010U)
#define SD_ARG1 (MMC_SD_BASE + 0x0018U)
#define SD_STOP (MMC_SD_BASE + 0x0020U)
#define SD_SECCNT (MMC_SD_BASE + 0x0028U)
#define SD_RSP10 (MMC_SD_BASE + 0x0030U)
#define SD_RSP1 (MMC_SD_BASE + 0x0038U)
#define SD_RSP32 (MMC_SD_BASE + 0x0040U)
#define SD_RSP3 (MMC_SD_BASE + 0x0048U)
#define SD_RSP54 (MMC_SD_BASE + 0x0050U)
#define SD_RSP5 (MMC_SD_BASE + 0x0058U)
#define SD_RSP76 (MMC_SD_BASE + 0x0060U)
#define SD_RSP7 (MMC_SD_BASE + 0x0068U)
#define SD_INFO1 (MMC_SD_BASE + 0x0070U)
#define SD_INFO2 (MMC_SD_BASE + 0x0078U)
#define SD_INFO1_MASK (MMC_SD_BASE + 0x0080U)
#define SD_INFO2_MASK (MMC_SD_BASE + 0x0088U)
#define SD_CLK_CTRL (MMC_SD_BASE + 0x0090U)
#define SD_SIZE (MMC_SD_BASE + 0x0098U)
#define SD_OPTION (MMC_SD_BASE + 0x00A0U)
#define SD_ERR_STS1 (MMC_SD_BASE + 0x00B0U)
#define SD_ERR_STS2 (MMC_SD_BASE + 0x00B8U)
#define SD_BUF0 (MMC_SD_BASE + 0x00C0U)
#define SDIO_MODE (MMC_SD_BASE + 0x00D0U)
#define SDIO_INFO1 (MMC_SD_BASE + 0x00D8U)
#define SDIO_INFO1_MASK (MMC_SD_BASE + 0x00E0U)
#define CC_EXT_MODE (MMC_SD_BASE + 0x0360U)
#define SOFT_RST (MMC_SD_BASE + 0x0380U)
#define VERSION (MMC_SD_BASE + 0x0388U)
#define HOST_MODE (MMC_SD_BASE + 0x0390U)
#define DM_CM_DTRAN_MODE (MMC_SD_BASE + 0x0820U)
#define DM_CM_DTRAN_CTRL (MMC_SD_BASE + 0x0828U)
#define DM_CM_RST (MMC_SD_BASE + 0x0830U)
#define DM_CM_INFO1 (MMC_SD_BASE + 0x0840U)
#define DM_CM_INFO1_MASK (MMC_SD_BASE + 0x0848U)
#define DM_CM_INFO2 (MMC_SD_BASE + 0x0850U)
#define DM_CM_INFO2_MASK (MMC_SD_BASE + 0x0858U)
#define DM_DTRAN_ADDR (MMC_SD_BASE + 0x0880U)
/** @brief SD_INFO1 Registers
*/
#define SD_INFO1_HPIRES 0x00010000UL /* Response Reception Completion */
#define SD_INFO1_INFO10 0x00000400UL /* Indicates the SDDAT3 state */
#define SD_INFO1_INFO9 0x00000200UL /* SDDAT3 Card Insertion */
#define SD_INFO1_INFO8 0x00000100UL /* SDDAT3 Card Removal */
#define SD_INFO1_INFO7 0x00000080UL /* Write Protect */
#define SD_INFO1_INFO5 0x00000020UL /* Indicates the ISDCD state */
#define SD_INFO1_INFO4 0x00000010UL /* ISDCD Card Insertion */
#define SD_INFO1_INFO3 0x00000008UL /* ISDCD Card Removal */
#define SD_INFO1_INFO2 0x00000004UL /* Access end */
#define SD_INFO1_INFO0 0x00000001UL /* Response end */
/** @brief SD_INFO2 Registers
*/
#define SD_INFO2_ILA 0x00008000UL /* Illegal Access Error */
#define SD_INFO2_CBSY 0x00004000UL /* Command Type Register Busy */
#define SD_INFO2_SCLKDIVEN 0x00002000UL
#define SD_INFO2_BWE 0x00000200UL /* SD_BUF Write Enable */
#define SD_INFO2_BRE 0x00000100UL /* SD_BUF Read Enable */
#define SD_INFO2_DAT0 0x00000080UL /* SDDAT0 */
#define SD_INFO2_ERR6 0x00000040UL /* Response Timeout */
#define SD_INFO2_ERR5 0x00000020UL /* SD_BUF Illegal Read Access */
#define SD_INFO2_ERR4 0x00000010UL /* SD_BUF Illegal Write Access */
#define SD_INFO2_ERR3 0x00000008UL /* Data Timeout */
#define SD_INFO2_ERR2 0x00000004UL /* END Error */
#define SD_INFO2_ERR1 0x00000002UL /* CRC Error */
#define SD_INFO2_ERR0 0x00000001UL /* CMD Error */
#define SD_INFO2_ALL_ERR 0x0000807FUL
#define SD_INFO2_CLEAR 0x00000800UL /* BIT11 The write value should always be 1. HWM_0003 */
/** @brief SOFT_RST
*/
#define SOFT_RST_SDRST 0x00000001UL
/** @brief SD_CLK_CTRL
*/
#define SD_CLK_CTRL_SDCLKOFFEN 0x00000200UL
#define SD_CLK_CTRL_SCLKEN 0x00000100UL
#define SD_CLK_CTRL_CLKDIV_MASK 0x000000FFUL
#define SD_CLOCK_ENABLE 0x00000100UL
#define SD_CLOCK_DISABLE 0x00000000UL
#define SD_CLK_WRITE_MASK 0x000003FFUL
#define SD_CLK_CLKDIV_CLEAR_MASK 0xFFFFFF0FUL
/** @brief SD_OPTION
*/
#define SD_OPTION_TIMEOUT_CNT_MASK 0x000000F0UL
/** @brief MMC Clock Frequency
* 200MHz * 1/x = output clock
*/
#define MMC_CLK_OFF 0UL /* Clock output is disabled */
#define MMC_400KHZ 512UL /* 200MHz * 1/512 = 390 KHz */
#define MMC_20MHZ 16UL /* 200MHz * 1/16 = 12.5 MHz Normal speed mode */
#define MMC_26MHZ 8UL /* 200MHz * 1/8 = 25 MHz High speed mode 26Mhz */
#define MMC_52MHZ 4UL /* 200MHz * 1/4 = 50 MHz High speed mode 52Mhz */
#define MMC_100MHZ 2UL /* 200MHz * 1/2 = 100 MHz */
#define MMC_200MHZ 1UL /* 200MHz * 1/1 = 200 MHz */
#define MMC_FREQ_52MHZ 52000000UL
#define MMC_FREQ_26MHZ 26000000UL
#define MMC_FREQ_20MHZ 20000000UL
/** @brief MMC Clock DIV
*/
#define MMC_SD_CLK_START 0x00000100UL /* CLOCK On */
#define MMC_SD_CLK_STOP (~0x00000100UL) /* CLOCK stop */
#define MMC_SD_CLK_DIV1 0x000000FFUL /* 1/1 */
#define MMC_SD_CLK_DIV2 0x00000000UL /* 1/2 */
#define MMC_SD_CLK_DIV4 0x00000001UL /* 1/4 */
#define MMC_SD_CLK_DIV8 0x00000002UL /* 1/8 */
#define MMC_SD_CLK_DIV16 0x00000004UL /* 1/16 */
#define MMC_SD_CLK_DIV32 0x00000008UL /* 1/32 */
#define MMC_SD_CLK_DIV64 0x00000010UL /* 1/64 */
#define MMC_SD_CLK_DIV128 0x00000020UL /* 1/128 */
#define MMC_SD_CLK_DIV256 0x00000040UL /* 1/256 */
#define MMC_SD_CLK_DIV512 0x00000080UL /* 1/512 */
/** @brief DM_CM_DTRAN_MODE
*/
#define DM_CM_DTRAN_MODE_CH0 0x00000000UL /* CH0(downstream) */
#define DM_CM_DTRAN_MODE_CH1 0x00010000UL /* CH1(upstream) */
#define DM_CM_DTRAN_MODE_BIT_WIDTH 0x00000030UL
/** @brief CC_EXT_MODE
*/
#define CC_EXT_MODE_DMASDRW_ENABLE 0x00000002UL /* SD_BUF Read/Write DMA Transfer */
#define CC_EXT_MODE_CLEAR 0x00001010UL /* BIT 12 & 4 always 1. */
/** @brief DM_CM_INFO_MASK
*/
#define DM_CM_INFO_MASK_CLEAR 0xFFFCFFFEUL
#define DM_CM_INFO_CH0_ENABLE 0x00010001UL
#define DM_CM_INFO_CH1_ENABLE 0x00020001UL
/** @brief DM_DTRAN_ADDR
*/
#define DM_DTRAN_ADDR_WRITE_MASK 0xFFFFFFF8UL
/** @brief DM_CM_DTRAN_CTRL
*/
#define DM_CM_DTRAN_CTRL_START 0x00000001UL
/** @brief SYSC Registers
*/
#if USE_MMC_CH == MMC_CH0
#define CPG_MSTP_MMC (BIT12) /* SDHI2/MMC0 */
#else /* USE_MMC_CH == MMC_CH0 */
#define CPG_MSTP_MMC (BIT11) /* SDHI3/MMC1 */
#endif /* USE_MMC_CH == MMC_CH0 */
/* ********************** STRUCTURES, TYPE DEFINITIONS ********************* */
/* ********************** DECLARATION OF EXTERNAL DATA ********************* */
/* ************************** FUNCTION PROTOTYPES ************************** */
/* ********************************* CODE ********************************** */
#endif /* __EMMC_REGISTERS_H__ */
/* ******************************** END ************************************ */

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/*
* Copyright (c) 2015-2018, Renesas Electronics Corporation. All rights reserved.
*
* SPDX-License-Identifier: BSD-3-Clause
*/
/**
* @file emmc_std.h
* @brief eMMC boot is expecting this header file
*
*/
#ifndef __EMMC_STD_H__
#define __EMMC_STD_H__
#include "emmc_hal.h"
/* ************************ HEADER (INCLUDE) SECTION *********************** */
/* ***************** MACROS, CONSTANTS, COMPILATION FLAGS ****************** */
#ifndef FALSE
#define FALSE 0U
#endif
#ifndef TRUE
#define TRUE 1U
#endif
/** @brief 64bit registers
**/
#define SETR_64(r, v) (*(volatile uint64_t *)(r) = (v))
#define GETR_64(r) (*(volatile uint64_t *)(r))
/** @brief 32bit registers
**/
#define SETR_32(r, v) (*(volatile uint32_t *)(r) = (v))
#define GETR_32(r) (*(volatile uint32_t *)(r))
/** @brief 16bit registers
*/
#define SETR_16(r, v) (*(volatile uint16_t *)(r) = (v))
#define GETR_16(r) (*(volatile uint16_t *)(r))
/** @brief 8bit registers
*/
#define SETR_8(r, v) (*(volatile uint8_t *)(r) = (v))
#define GETR_8(r) (*(volatile uint8_t *)(r))
/** @brief CSD register Macros
*/
#define EMMC_GET_CID(x, y) (emmc_bit_field(mmc_drv_obj.cid_data, (x), (y)))
#define EMMC_CID_MID() (EMMC_GET_CID(127, 120))
#define EMMC_CID_CBX() (EMMC_GET_CID(113, 112))
#define EMMC_CID_OID() (EMMC_GET_CID(111, 104))
#define EMMC_CID_PNM1() (EMMC_GET_CID(103, 88))
#define EMMC_CID_PNM2() (EMMC_GET_CID(87, 56))
#define EMMC_CID_PRV() (EMMC_GET_CID(55, 48))
#define EMMC_CID_PSN() (EMMC_GET_CID(47, 16))
#define EMMC_CID_MDT() (EMMC_GET_CID(15, 8))
#define EMMC_CID_CRC() (EMMC_GET_CID(7, 1))
/** @brief CSD register Macros
*/
#define EMMC_GET_CSD(x, y) (emmc_bit_field(mmc_drv_obj.csd_data, (x), (y)))
#define EMMC_CSD_CSD_STRUCTURE() (EMMC_GET_CSD(127, 126))
#define EMMC_CSD_SPEC_VARS() (EMMC_GET_CSD(125, 122))
#define EMMC_CSD_TAAC() (EMMC_GET_CSD(119, 112))
#define EMMC_CSD_NSAC() (EMMC_GET_CSD(111, 104))
#define EMMC_CSD_TRAN_SPEED() (EMMC_GET_CSD(103, 96))
#define EMMC_CSD_CCC() (EMMC_GET_CSD(95, 84))
#define EMMC_CSD_READ_BL_LEN() (EMMC_GET_CSD(83, 80))
#define EMMC_CSD_READ_BL_PARTIAL() (EMMC_GET_CSD(79, 79))
#define EMMC_CSD_WRITE_BLK_MISALIGN() (EMMC_GET_CSD(78, 78))
#define EMMC_CSD_READ_BLK_MISALIGN() (EMMC_GET_CSD(77, 77))
#define EMMC_CSD_DSR_IMP() (EMMC_GET_CSD(76, 76))
#define EMMC_CSD_C_SIZE() (EMMC_GET_CSD(73, 62))
#define EMMC_CSD_VDD_R_CURR_MIN() (EMMC_GET_CSD(61, 59))
#define EMMC_CSD_VDD_R_CURR_MAX() (EMMC_GET_CSD(58, 56))
#define EMMC_CSD_VDD_W_CURR_MIN() (EMMC_GET_CSD(55, 53))
#define EMMC_CSD_VDD_W_CURR_MAX() (EMMC_GET_CSD(52, 50))
#define EMMC_CSD_C_SIZE_MULT() (EMMC_GET_CSD(49, 47))
#define EMMC_CSD_ERASE_GRP_SIZE() (EMMC_GET_CSD(46, 42))
#define EMMC_CSD_ERASE_GRP_MULT() (EMMC_GET_CSD(41, 37))
#define EMMC_CSD_WP_GRP_SIZE() (EMMC_GET_CSD(36, 32))
#define EMMC_CSD_WP_GRP_ENABLE() (EMMC_GET_CSD(31, 31))
#define EMMC_CSD_DEFALT_ECC() (EMMC_GET_CSD(30, 29))
#define EMMC_CSD_R2W_FACTOR() (EMMC_GET_CSD(28, 26))
#define EMMC_CSD_WRITE_BL_LEN() (EMMC_GET_CSD(25, 22))
#define EMMC_CSD_WRITE_BL_PARTIAL() (EMMC_GET_CSD(21, 21))
#define EMMC_CSD_CONTENT_PROT_APP() (EMMC_GET_CSD(16, 16))
#define EMMC_CSD_FILE_FORMAT_GRP() (EMMC_GET_CSD(15, 15))
#define EMMC_CSD_COPY() (EMMC_GET_CSD(14, 14))
#define EMMC_CSD_PERM_WRITE_PROTECT() (EMMC_GET_CSD(13, 13))
#define EMMC_CSD_TMP_WRITE_PROTECT() (EMMC_GET_CSD(12, 12))
#define EMMC_CSD_FILE_FORMAT() (EMMC_GET_CSD(11, 10))
#define EMMC_CSD_ECC() (EMMC_GET_CSD(9, 8))
#define EMMC_CSD_CRC() (EMMC_GET_CSD(7, 1))
/** @brief for sector access
*/
#define EMMC_4B_BOUNDARY_CHECK_MASK 0x00000003
#define EMMC_SECTOR_SIZE_SHIFT 9U /* 512 = 2^9 */
#define EMMC_SECTOR_SIZE 512
#define EMMC_BLOCK_LENGTH 512
#define EMMC_BLOCK_LENGTH_DW 128
#define EMMC_BUF_SIZE_SHIFT 3U /* 8byte = 2^3 */
/** @brief eMMC specification clock
*/
#define EMMC_CLOCK_SPEC_400K 400000UL /**< initialize clock 400KHz */
#define EMMC_CLOCK_SPEC_20M 20000000UL /**< normal speed 20MHz */
#define EMMC_CLOCK_SPEC_26M 26000000UL /**< high speed 26MHz */
#define EMMC_CLOCK_SPEC_52M 52000000UL /**< high speed 52MHz */
#define EMMC_CLOCK_SPEC_100M 100000000UL /**< high speed 100MHz */
/** @brief EMMC driver error code. (extended HAL_MEMCARD_RETURN)
*/
typedef enum {
EMMC_ERR = 0, /**< unknown error */
EMMC_SUCCESS, /**< OK */
EMMC_ERR_FROM_DMAC, /**< DMAC allocation error */
EMMC_ERR_FROM_DMAC_TRANSFER, /**< DMAC transfer error */
EMMC_ERR_CARD_STATUS_BIT, /**< card status error. Non-masked error bit was set in the card status */
EMMC_ERR_CMD_TIMEOUT, /**< command timeout error */
EMMC_ERR_DATA_TIMEOUT, /**< data timeout error */
EMMC_ERR_CMD_CRC, /**< command CRC error */
EMMC_ERR_DATA_CRC, /**< data CRC error */
EMMC_ERR_PARAM, /**< parameter error */
EMMC_ERR_RESPONSE, /**< response error */
EMMC_ERR_RESPONSE_BUSY, /**< response busy error */
EMMC_ERR_TRANSFER, /**< data transfer error */
EMMC_ERR_READ_SECTOR, /**< read sector error */
EMMC_ERR_WRITE_SECTOR, /**< write sector error */
EMMC_ERR_STATE, /**< state error */
EMMC_ERR_TIMEOUT, /**< timeout error */
EMMC_ERR_ILLEGAL_CARD, /**< illegal card */
EMMC_ERR_CARD_BUSY, /**< Busy state */
EMMC_ERR_CARD_STATE, /**< card state error */
EMMC_ERR_SET_TRACE, /**< trace information error */
EMMC_ERR_FROM_TIMER, /**< Timer error */
EMMC_ERR_FORCE_TERMINATE, /**< Force terminate */
EMMC_ERR_CARD_POWER, /**< card power fail */
EMMC_ERR_ERASE_SECTOR, /**< erase sector error */
EMMC_ERR_INFO2 /**< exec cmd error info2 */
} EMMC_ERROR_CODE;
/** @brief Function number */
#define EMMC_FUNCNO_NONE 0U
#define EMMC_FUNCNO_DRIVER_INIT 1U
#define EMMC_FUNCNO_CARD_POWER_ON 2U
#define EMMC_FUNCNO_MOUNT 3U
#define EMMC_FUNCNO_CARD_INIT 4U
#define EMMC_FUNCNO_HIGH_SPEED 5U
#define EMMC_FUNCNO_BUS_WIDTH 6U
#define EMMC_FUNCNO_MULTI_BOOT_SELECT_PARTITION 7U
#define EMMC_FUNCNO_MULTI_BOOT_READ_SECTOR 8U
#define EMMC_FUNCNO_TRANS_DATA_READ_SECTOR 9U
#define EMMC_FUNCNO_UBOOT_IMAGE_SELECT_PARTITION 10U
#define EMMC_FUNCNO_UBOOT_IMAGE_READ_SECTOR 11U
#define EMMC_FUNCNO_SET_CLOCK 12U
#define EMMC_FUNCNO_EXEC_CMD 13U
#define EMMC_FUNCNO_READ_SECTOR 14U
#define EMMC_FUNCNO_WRITE_SECTOR 15U
#define EMMC_FUNCNO_ERASE_SECTOR 16U
#define EMMC_FUNCNO_GET_PERTITION_ACCESS 17U
/** @brief Response
*/
/** R1 */
#define EMMC_R1_ERROR_MASK 0xFDBFE080U /* Type 'E' bit and bit14(must be 0). ignore bit22 */
#define EMMC_R1_ERROR_MASK_WITHOUT_CRC (0xFD3FE080U) /* Ignore bit23 (Not check CRC error) */
#define EMMC_R1_STATE_MASK 0x00001E00U /* [12:9] */
#define EMMC_R1_READY 0x00000100U /* bit8 */
#define EMMC_R1_STATE_SHIFT 9
/** R4 */
#define EMMC_R4_RCA_MASK 0xFFFF0000UL
#define EMMC_R4_STATUS 0x00008000UL
/** CSD */
#define EMMC_TRANSPEED_FREQ_UNIT_MASK 0x07 /* bit[2:0] */
#define EMMC_TRANSPEED_FREQ_UNIT_SHIFT 0
#define EMMC_TRANSPEED_MULT_MASK 0x78 /* bit[6:3] */
#define EMMC_TRANSPEED_MULT_SHIFT 3
/** OCR */
#define EMMC_HOST_OCR_VALUE 0x40FF8080
#define EMMC_OCR_STATUS_BIT 0x80000000L /* Card power up status bit */
#define EMMC_OCR_ACCESS_MODE_MASK 0x60000000L /* bit[30:29] */
#define EMMC_OCR_ACCESS_MODE_SECT 0x40000000L
#define EMMC_OCR_ACCESS_MODE_BYTE 0x00000000L
/** EXT_CSD */
#define EMMC_EXT_CSD_S_CMD_SET 504
#define EMMC_EXT_CSD_INI_TIMEOUT_AP 241
#define EMMC_EXT_CSD_PWR_CL_DDR_52_360 239
#define EMMC_EXT_CSD_PWR_CL_DDR_52_195 238
#define EMMC_EXT_CSD_MIN_PERF_DDR_W_8_52 235
#define EMMC_EXT_CSD_MIN_PERF_DDR_R_8_52 234
#define EMMC_EXT_CSD_TRIM_MULT 232
#define EMMC_EXT_CSD_SEC_FEATURE_SUPPORT 231
#define EMMC_EXT_CSD_SEC_ERASE_MULT 229
#define EMMC_EXT_CSD_BOOT_INFO 228
#define EMMC_EXT_CSD_BOOT_SIZE_MULTI 226
#define EMMC_EXT_CSD_ACC_SIZE 225
#define EMMC_EXT_CSD_HC_ERASE_GRP_SIZE 224
#define EMMC_EXT_CSD_ERASE_TIMEOUT_MULT 223
#define EMMC_EXT_CSD_PEL_WR_SEC_C 222
#define EMMC_EXT_CSD_HC_WP_GRP_SIZE 221
#define EMMC_EXT_CSD_S_C_VCC 220
#define EMMC_EXT_CSD_S_C_VCCQ 219
#define EMMC_EXT_CSD_S_A_TIMEOUT 217
#define EMMC_EXT_CSD_SEC_COUNT 215
#define EMMC_EXT_CSD_MIN_PERF_W_8_52 210
#define EMMC_EXT_CSD_MIN_PERF_R_8_52 209
#define EMMC_EXT_CSD_MIN_PERF_W_8_26_4_52 208
#define EMMC_EXT_CSD_MIN_PERF_R_8_26_4_52 207
#define EMMC_EXT_CSD_MIN_PERF_W_4_26 206
#define EMMC_EXT_CSD_MIN_PERF_R_4_26 205
#define EMMC_EXT_CSD_PWR_CL_26_360 203
#define EMMC_EXT_CSD_PWR_CL_52_360 202
#define EMMC_EXT_CSD_PWR_CL_26_195 201
#define EMMC_EXT_CSD_PWR_CL_52_195 200
#define EMMC_EXT_CSD_CARD_TYPE 196
#define EMMC_EXT_CSD_CSD_STRUCTURE 194
#define EMMC_EXT_CSD_EXT_CSD_REV 192
#define EMMC_EXT_CSD_CMD_SET 191
#define EMMC_EXT_CSD_CMD_SET_REV 189
#define EMMC_EXT_CSD_POWER_CLASS 187
#define EMMC_EXT_CSD_HS_TIMING 185
#define EMMC_EXT_CSD_BUS_WIDTH 183
#define EMMC_EXT_CSD_ERASED_MEM_CONT 181
#define EMMC_EXT_CSD_PARTITION_CONFIG 179
#define EMMC_EXT_CSD_BOOT_CONFIG_PROT 178
#define EMMC_EXT_CSD_BOOT_BUS_WIDTH 177
#define EMMC_EXT_CSD_ERASE_GROUP_DEF 175
#define EMMC_EXT_CSD_BOOT_WP 173
#define EMMC_EXT_CSD_USER_WP 171
#define EMMC_EXT_CSD_FW_CONFIG 169
#define EMMC_EXT_CSD_RPMB_SIZE_MULT 168
#define EMMC_EXT_CSD_RST_n_FUNCTION 162
#define EMMC_EXT_CSD_PARTITIONING_SUPPORT 160
#define EMMC_EXT_CSD_MAX_ENH_SIZE_MULT 159
#define EMMC_EXT_CSD_PARTITIONS_ATTRIBUTE 156
#define EMMC_EXT_CSD_PARTITION_SETTING_COMPLETED 155
#define EMMC_EXT_CSD_GP_SIZE_MULT 154
#define EMMC_EXT_CSD_ENH_SIZE_MULT 142
#define EMMC_EXT_CSD_ENH_START_ADDR 139
#define EMMC_EXT_CSD_SEC_BAD_BLK_MGMNT 134
#define EMMC_EXT_CSD_CARD_TYPE_26MHZ 0x01
#define EMMC_EXT_CSD_CARD_TYPE_52MHZ 0x02
#define EMMC_EXT_CSD_CARD_TYPE_DDR_52MHZ_12V 0x04
#define EMMC_EXT_CSD_CARD_TYPE_DDR_52MHZ_18V 0x08
#define EMMC_EXT_CSD_CARD_TYPE_52MHZ_MASK 0x0e
/** SWITCH (CMD6) argument */
#define EXTCSD_ACCESS_BYTE (BIT25|BIT24)
#define EXTCSD_SET_BITS BIT24
#define HS_TIMING_ADD (185<<16) /* H'b9 */
#define HS_TIMING_1 (1<<8)
#define HS_TIMING_HS200 (2<<8)
#define HS_TIMING_HS400 (3<<8)
#define BUS_WIDTH_ADD (183<<16) /* H'b7 */
#define BUS_WIDTH_1 (0<<8)
#define BUS_WIDTH_4 (1<<8)
#define BUS_WIDTH_8 (2<<8)
#define BUS_WIDTH_4DDR (5<<8)
#define BUS_WIDTH_8DDR (6<<8)
#define EMMC_SWITCH_HS_TIMING (EXTCSD_ACCESS_BYTE|HS_TIMING_ADD|HS_TIMING_1) /**< H'03b90100 */
#define EMMC_SWITCH_HS_TIMING_OFF (EXTCSD_ACCESS_BYTE|HS_TIMING_ADD) /**< H'03b90000 */
#define EMMC_SWITCH_BUS_WIDTH_1 (EXTCSD_ACCESS_BYTE|BUS_WIDTH_ADD|BUS_WIDTH_1) /**< H'03b70000 */
#define EMMC_SWITCH_BUS_WIDTH_4 (EXTCSD_ACCESS_BYTE|BUS_WIDTH_ADD|BUS_WIDTH_4) /**< H'03b70100 */
#define EMMC_SWITCH_BUS_WIDTH_8 (EXTCSD_ACCESS_BYTE|BUS_WIDTH_ADD|BUS_WIDTH_8) /**< H'03b70200 */
#define EMMC_SWITCH_BUS_WIDTH_4DDR (EXTCSD_ACCESS_BYTE|BUS_WIDTH_ADD|BUS_WIDTH_4DDR) /**< H'03b70500 */
#define EMMC_SWITCH_BUS_WIDTH_8DDR (EXTCSD_ACCESS_BYTE|BUS_WIDTH_ADD|BUS_WIDTH_8DDR) /**< H'03b70600 */
#define EMMC_SWITCH_PARTITION_CONFIG 0x03B30000UL /**< Partition config = 0x00 */
#define TIMING_HIGH_SPEED 1UL
#define EMMC_BOOT_PARTITION_EN_MASK 0x38U
#define EMMC_BOOT_PARTITION_EN_SHIFT 3U
/** Bus width */
#define EMMC_BUSWIDTH_1BIT CE_CMD_SET_DATW_1BIT
#define EMMC_BUSWIDTH_4BIT CE_CMD_SET_DATW_4BIT
#define EMMC_BUSWIDTH_8BIT CE_CMD_SET_DATW_8BIT
/** for st_mmc_base */
#define EMMC_MAX_RESPONSE_LENGTH 17
#define EMMC_MAX_CID_LENGTH 16
#define EMMC_MAX_CSD_LENGTH 16
#define EMMC_MAX_EXT_CSD_LENGTH 512U
#define EMMC_RES_REG_ALIGNED 4U
#define EMMC_BUF_REG_ALIGNED 8U
/** @brief for TAAC mask
*/
#define TAAC_TIME_UNIT_MASK (0x07)
#define TAAC_MULTIPLIER_FACTOR_MASK (0x0F)
/* ********************** STRUCTURES, TYPE DEFINITIONS ********************* */
/** @brief Partition id
*/
typedef enum {
PARTITION_ID_USER = 0x0, /**< User Area */
PARTITION_ID_BOOT_1 = 0x1, /**< boot partition 1 */
PARTITION_ID_BOOT_2 = 0x2, /**< boot partition 2 */
PARTITION_ID_RPMB = 0x3, /**< Replay Protected Memory Block */
PARTITION_ID_GP_1 = 0x4, /**< General Purpose partition 1 */
PARTITION_ID_GP_2 = 0x5, /**< General Purpose partition 2 */
PARTITION_ID_GP_3 = 0x6, /**< General Purpose partition 3 */
PARTITION_ID_GP_4 = 0x7, /**< General Purpose partition 4 */
PARTITION_ID_MASK = 0x7 /**< [2:0] */
} EMMC_PARTITION_ID;
/** @brief card state in R1 response [12:9]
*/
typedef enum {
EMMC_R1_STATE_IDLE = 0,
EMMC_R1_STATE_READY,
EMMC_R1_STATE_IDENT,
EMMC_R1_STATE_STBY,
EMMC_R1_STATE_TRAN,
EMMC_R1_STATE_DATA,
EMMC_R1_STATE_RCV,
EMMC_R1_STATE_PRG,
EMMC_R1_STATE_DIS,
EMMC_R1_STATE_BTST,
EMMC_R1_STATE_SLEP
} EMMC_R1_STATE;
typedef enum {
ESTATE_BEGIN = 0,
ESTATE_ISSUE_CMD,
ESTATE_NON_RESP_CMD,
ESTATE_RCV_RESP,
ESTATE_RCV_RESPONSE_BUSY,
ESTATE_CHECK_RESPONSE_COMPLETE,
ESTATE_DATA_TRANSFER,
ESTATE_DATA_TRANSFER_COMPLETE,
ESTATE_ACCESS_END,
ESTATE_TRANSFER_ERROR,
ESTATE_ERROR,
ESTATE_END
} EMMC_INT_STATE;
/** @brief eMMC boot driver error information
*/
typedef struct {
uint16_t num; /**< error no */
uint16_t code; /**< error code */
volatile uint32_t info1; /**< SD_INFO1 register value. (hardware dependence) */
volatile uint32_t info2; /**< SD_INFO2 register value. (hardware dependence) */
volatile uint32_t status1;/**< SD_ERR_STS1 register value. (hardware dependence) */
volatile uint32_t status2;/**< SD_ERR_STS2 register value. (hardware dependence) */
volatile uint32_t dm_info1;/**< DM_CM_INFO1 register value. (hardware dependence) */
volatile uint32_t dm_info2;/**< DM_CM_INFO2 register value. (hardware dependence) */
} st_error_info;
/** @brief Command information
*/
typedef struct {
HAL_MEMCARD_COMMAND cmd; /**< Command information */
uint32_t arg; /**< argument */
HAL_MEMCARD_OPERATION dir; /**< direction */
uint32_t hw; /**< H/W dependence. SD_CMD register value. */
} st_command_info;
/** @brief MMC driver base
*/
typedef struct {
st_error_info error_info; /**< error information */
st_command_info cmd_info; /**< command information */
/* for data transfer */
uint32_t *buff_address_virtual; /**< Dest or Src buff */
uint32_t *buff_address_physical; /**< Dest or Src buff */
HAL_MEMCARD_DATA_WIDTH bus_width;
/**< bus width */
uint32_t trans_size; /**< transfer size for this command */
uint32_t remain_size; /**< remain size for this command */
uint32_t response_length; /**< response length for this command */
uint32_t sector_size; /**< sector_size */
/* clock */
uint32_t base_clock; /**< MMC host controller clock */
uint32_t max_freq; /**< Max frequency (Card Spec)[Hz]. It changes dynamically by CSD and EXT_CSD. */
uint32_t request_freq; /**< request freq [Hz] (400K, 26MHz, 52MHz, etc) */
uint32_t current_freq; /**< current MMC clock[Hz] (the closest frequency supported by HW) */
/* state flag */
HAL_MEMCARD_PRESENCE_STATUS card_present;
/**< presence status of the memory card */
uint32_t card_power_enable; /**< True : Power ON */
uint32_t clock_enable; /**< True : Clock ON */
uint32_t initialize; /**< True : initialize complete. */
uint32_t access_mode; /**< True : sector access, FALSE : byte access */
uint32_t mount; /**< True : mount complete. */
uint32_t selected; /**< True : selected card. */
HAL_MEMCARD_DATA_TRANSFER_MODE transfer_mode;
/**< 0: DMA, 1:PIO */
uint32_t image_num; /**< loaded ISSW image No. ISSW have copy image. */
EMMC_R1_STATE current_state; /**< card state */
volatile uint32_t during_cmd_processing; /**< True : during command processing */
volatile uint32_t during_transfer; /**< True : during transfer */
volatile uint32_t during_dma_transfer; /**< True : during transfer (DMA)*/
volatile uint32_t dma_error_flag; /**< True : occurred DMAC error */
volatile uint32_t force_terminate; /**< force terminate flag */
volatile uint32_t state_machine_blocking; /**< state machine blocking flag : True or False */
volatile uint32_t get_partition_access_flag;
/**< True : get partition access processing */
EMMC_PARTITION_ID boot_partition_en; /**< Boot partition */
EMMC_PARTITION_ID partition_access; /**< Current access partition */
/* timeout */
uint32_t hs_timing; /**< high speed */
/* timeout */
uint32_t data_timeout; /**< read and write data timeout.*/
/* retry */
uint32_t retries_after_fail; /**< how many times to try after fail, for instance sending command */
/* interrupt */
volatile uint32_t int_event1; /**< interrupt SD_INFO1 Event */
volatile uint32_t int_event2; /**< interrupt SD_INFO2 Event */
volatile uint32_t dm_event1; /**< interrupt DM_CM_INFO1 Event */
volatile uint32_t dm_event2; /**< interrupt DM_CM_INFO2 Event */
/* response */
uint32_t *response; /**< pointer to buffer for executing command. */
uint32_t r1_card_status; /**< R1 response data */
uint32_t r3_ocr; /**< R3 response data */
uint32_t r4_resp; /**< R4 response data */
uint32_t r5_resp; /**< R5 response data */
uint32_t low_clock_mode_enable;
/**< True : clock mode is low. (MMC clock = Max26MHz) */
uint32_t reserved2;
uint32_t reserved3;
uint32_t reserved4;
/* CSD registers (4byte align) */
uint8_t csd_data[EMMC_MAX_CSD_LENGTH] /**< CSD */
__attribute__ ((aligned(EMMC_RES_REG_ALIGNED)));
/* CID registers (4byte align) */
uint8_t cid_data[EMMC_MAX_CID_LENGTH] /**< CID */
__attribute__ ((aligned(EMMC_RES_REG_ALIGNED)));
/* EXT CSD registers (8byte align) */
uint8_t ext_csd_data[EMMC_MAX_EXT_CSD_LENGTH] /**< EXT_CSD */
__attribute__ ((aligned(EMMC_BUF_REG_ALIGNED)));
/* Response registers (4byte align) */
uint8_t response_data[EMMC_MAX_RESPONSE_LENGTH] /**< other response */
__attribute__ ((aligned(EMMC_RES_REG_ALIGNED)));
} st_mmc_base;
typedef int (*func) (void);
/* ********************** DECLARATION OF EXTERNAL DATA ********************* */
/* ************************** FUNCTION PROTOTYPES ************************** */
uint32_t emmc_get_csd_time(void);
#define MMC_DEBUG
/* ********************************* CODE ********************************** */
/* ******************************** END ************************************ */
#endif /* __EMMC_STD_H__ */

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drivers/renesas/rcar/emmc/emmc_utility.c Normal file
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/*
* Copyright (c) 2015-2017, Renesas Electronics Corporation. All rights reserved.
*
* SPDX-License-Identifier: BSD-3-Clause
*/
#include <debug.h>
#include "emmc_config.h"
#include "emmc_hal.h"
#include "emmc_std.h"
#include "emmc_registers.h"
#include "emmc_def.h"
static const uint32_t cmd_reg_hw[EMMC_CMD_MAX + 1] = {
0x00000000, /* CMD0 */
0x00000701, /* CMD1 */
0x00000002, /* CMD2 */
0x00000003, /* CMD3 */
0x00000004, /* CMD4 */
0x00000505, /* CMD5 */
0x00000406, /* CMD6 */
0x00000007, /* CMD7 */
0x00001C08, /* CMD8 */
0x00000009, /* CMD9 */
0x0000000A, /* CMD10 */
0x00000000, /* reserved */
0x0000000C, /* CMD12 */
0x0000000D, /* CMD13 */
0x00001C0E, /* CMD14 */
0x0000000F, /* CMD15 */
0x00000010, /* CMD16 */
0x00000011, /* CMD17 */
0x00007C12, /* CMD18 */
0x00000C13, /* CMD19 */
0x00000000,
0x00001C15, /* CMD21 */
0x00000000,
0x00000017, /* CMD23 */
0x00000018, /* CMD24 */
0x00006C19, /* CMD25 */
0x00000C1A, /* CMD26 */
0x0000001B, /* CMD27 */
0x0000001C, /* CMD28 */
0x0000001D, /* CMD29 */
0x0000001E, /* CMD30 */
0x00001C1F, /* CMD31 */
0x00000000,
0x00000000,
0x00000000,
0x00000423, /* CMD35 */
0x00000424, /* CMD36 */
0x00000000,
0x00000026, /* CMD38 */
0x00000427, /* CMD39 */
0x00000428, /* CMD40(send cmd) */
0x00000000,
0x0000002A, /* CMD42 */
0x00000000,
0x00000000,
0x00000000,
0x00000000,
0x00000000,
0x00000000,
0x00000C31,
0x00000000,
0x00000000,
0x00000000,
0x00007C35,
0x00006C36,
0x00000037, /* CMD55 */
0x00000038, /* CMD56(Read) */
0x00000000,
0x00000000,
0x00000000,
0x00000000
};
uint32_t emmc_bit_field(uint8_t *data, uint32_t top, uint32_t bottom)
{
uint32_t value;
uint32_t index_top = (uint32_t) (15 - (top >> 3));
uint32_t index_bottom = (uint32_t) (15 - (bottom >> 3));
if (index_top == index_bottom) {
value = data[index_top];
} else if ((index_top + 1) == index_bottom) {
value =
(uint32_t) ((data[index_top] << 8) | data[index_bottom]);
} else if ((index_top + 2) == index_bottom) {
value =
(uint32_t) ((data[index_top] << 16) |
(data[index_top + 1] << 8) | data[index_top +
2]);
} else {
value =
(uint32_t) ((data[index_top] << 24) |
(data[index_top + 1] << 16) |
(data[index_top + 2] << 8) | data[index_top +
3]);
}
value = ((value >> (bottom & 0x07)) & ((1 << (top - bottom + 1)) - 1));
return value;
}
void emmc_write_error_info(uint16_t func_no, EMMC_ERROR_CODE error_code)
{
mmc_drv_obj.error_info.num = func_no;
mmc_drv_obj.error_info.code = (uint16_t) error_code;
ERROR("BL2: emmc err:func_no=0x%x code=0x%x\n", func_no, error_code);
}
void emmc_write_error_info_func_no(uint16_t func_no)
{
mmc_drv_obj.error_info.num = func_no;
ERROR("BL2: emmc err:func_no=0x%x\n", func_no);
}
void emmc_make_nontrans_cmd(HAL_MEMCARD_COMMAND cmd, uint32_t arg)
{
/* command information */
mmc_drv_obj.cmd_info.cmd = cmd;
mmc_drv_obj.cmd_info.arg = arg;
mmc_drv_obj.cmd_info.dir = HAL_MEMCARD_READ;
mmc_drv_obj.cmd_info.hw =
cmd_reg_hw[cmd & HAL_MEMCARD_COMMAND_INDEX_MASK];
/* clear data transfer information */
mmc_drv_obj.trans_size = 0;
mmc_drv_obj.remain_size = 0;
mmc_drv_obj.buff_address_virtual = NULL;
mmc_drv_obj.buff_address_physical = NULL;
/* response information */
mmc_drv_obj.response_length = 6;
switch (mmc_drv_obj.cmd_info.cmd & HAL_MEMCARD_RESPONSE_TYPE_MASK) {
case HAL_MEMCARD_RESPONSE_NONE:
mmc_drv_obj.response = (uint32_t *) mmc_drv_obj.response_data;
mmc_drv_obj.response_length = 0;
break;
case HAL_MEMCARD_RESPONSE_R1:
mmc_drv_obj.response = &mmc_drv_obj.r1_card_status;
break;
case HAL_MEMCARD_RESPONSE_R1b:
mmc_drv_obj.cmd_info.hw |= BIT10; /* bit10 = R1 busy bit */
mmc_drv_obj.response = &mmc_drv_obj.r1_card_status;
break;
case HAL_MEMCARD_RESPONSE_R2:
mmc_drv_obj.response = (uint32_t *) mmc_drv_obj.response_data;
mmc_drv_obj.response_length = 17;
break;
case HAL_MEMCARD_RESPONSE_R3:
mmc_drv_obj.response = &mmc_drv_obj.r3_ocr;
break;
case HAL_MEMCARD_RESPONSE_R4:
mmc_drv_obj.response = &mmc_drv_obj.r4_resp;
break;
case HAL_MEMCARD_RESPONSE_R5:
mmc_drv_obj.response = &mmc_drv_obj.r5_resp;
break;
default:
mmc_drv_obj.response = (uint32_t *) mmc_drv_obj.response_data;
break;
}
}
void emmc_make_trans_cmd(HAL_MEMCARD_COMMAND cmd, uint32_t arg,
uint32_t *buff_address_virtual,
uint32_t len,
HAL_MEMCARD_OPERATION dir,
HAL_MEMCARD_DATA_TRANSFER_MODE transfer_mode)
{
emmc_make_nontrans_cmd(cmd, arg); /* update common information */
/* for data transfer command */
mmc_drv_obj.cmd_info.dir = dir;
mmc_drv_obj.buff_address_virtual = buff_address_virtual;
mmc_drv_obj.buff_address_physical = buff_address_virtual;
mmc_drv_obj.trans_size = len;
mmc_drv_obj.remain_size = len;
mmc_drv_obj.transfer_mode = transfer_mode;
}
EMMC_ERROR_CODE emmc_send_idle_cmd(uint32_t arg)
{
EMMC_ERROR_CODE result;
uint32_t freq;
/* initialize state */
mmc_drv_obj.mount = FALSE;
mmc_drv_obj.selected = FALSE;
mmc_drv_obj.during_transfer = FALSE;
mmc_drv_obj.during_cmd_processing = FALSE;
mmc_drv_obj.during_dma_transfer = FALSE;
mmc_drv_obj.dma_error_flag = FALSE;
mmc_drv_obj.force_terminate = FALSE;
mmc_drv_obj.state_machine_blocking = FALSE;
mmc_drv_obj.bus_width = HAL_MEMCARD_DATA_WIDTH_1_BIT;
mmc_drv_obj.max_freq = MMC_20MHZ; /* 20MHz */
mmc_drv_obj.current_state = EMMC_R1_STATE_IDLE;
/* CMD0 (MMC clock is current frequency. if Data transfer mode, 20MHz or higher.) */
emmc_make_nontrans_cmd(CMD0_GO_IDLE_STATE, arg); /* CMD0 */
result = emmc_exec_cmd(EMMC_R1_ERROR_MASK, mmc_drv_obj.response);
if (result != EMMC_SUCCESS) {
return result;
}
/* change MMC clock(400KHz) */
freq = MMC_400KHZ;
result = emmc_set_request_mmc_clock(&freq);
if (result != EMMC_SUCCESS) {
return result;
}
return EMMC_SUCCESS;
}